Resuscitation 95 (2015) 1–80 Contents lists available at ScienceDirect Resuscitation journal homepage: www.elsevier.com/locate/resuscitation European Resuscitation Council Guidelines for Resuscitation 2015 Section 1. Executive summary Koenraad G. Monsieursa,b,∗ , Jerry P. Nolanc,d , Leo L. Bossaerte , Robert Greiff,g , Ian K. Maconochieh , Nikolaos I. Nikolaoui , Gavin D. Perkinsj,p , Jasmeet Soark , Anatolij Truhláˇrl,m , Jonathan Wyllien , David A. Zidemano , on behalf of the ERC Guidelines 2015 Writing Group1 a Emergency Medicine, Faculty of Medicine and Health Sciences, University of Antwerp, Antwerp, Belgium b Faculty of Medicine and Health Sciences, University of Ghent, Ghent, Belgium c Anaesthesia and Intensive Care Medicine, Royal United Hospital, Bath, UK d School of Clinical Sciences, University of Bristol, Bristol, UK e University of Antwerp, Antwerp, Belgium f Department of Anaesthesiology and Pain Medicine, University Hospital Bern, Bern, Switzerland g University of Bern, Bern, Switzerland h Paediatric Emergency Medicine Department, Imperial College Healthcare NHS Trust and BRC Imperial NIHR, Imperial College, London, UK i Cardiology Department, Konstantopouleio General Hospital, Athens, Greece j Warwick Medical School, University of Warwick, Coventry, UK k Anaesthesia and Intensive Care Medicine, Southmead Hospital, Bristol, UK l Emergency Medical Services of the Hradec Králové Region, Hradec Králové, Czech Republic m Department of Anaesthesiology and Intensive Care Medicine, University Hospital Hradec Králové, Hradec Králové, Czech Republic n Department of Neonatology, The James Cook University Hospital, Middlesbrough, UK o Imperial College Healthcare NHS Trust, London, UK p Heart of England NHS Foundation Trust, Birmingham, UK Introduction This executive summary provides the essential treatment algorithms for the resuscitation of children and adults and highlights the main guideline changes since 2010. Detailed guidance is provided in each of the ten sections, which are published as individual papers within this issue of Resuscitation. The sections of the ERC Guidelines 2015 are: 1. Executive summary 2. Adult basic life support and automated external defibrillation1 3. Adult advanced life support2 4. Cardiac arrest in special circumstances3 5. Post-resuscitation care4 6. Paediatric life support5 7. Resuscitation and support of transition of babies at birth6 8. Initial management of acute coronary syndromes7 9. First aid8 10. Principles of education in resuscitation9 11. The ethics of resuscitation and end-of-life decisions10 ∗ Corresponding author. E-mail address: koen.monsieurs@uza.be (K.G. Monsieurs). 1 See Appendix 1 for the ERC 2015 Guidelines Writing Group. The ERC Guidelines 2015 that follow do not define the only way that resuscitation can be delivered; they merely represent a widely accepted view of how resuscitation should be undertaken both safely and effectively. The publication of new and revised treatment recommendations does not imply that current clinical care is either unsafe or ineffective. Summary of the changes since the 2010 Guidelines Adult basic life support and automated external defibrillation • The ERC Guidelines 2015 highlight the critical importance of the interactions between the emergency medical dispatcher, the bystander who provides CPR and the timely deployment of an AED. An effective, co-ordinated community response that draws these elements together is key to improving survival from outof-hospital cardiac arrest (Fig. 1.1). • The emergency medical dispatcher plays an important role in the early diagnosis of cardiac arrest, the provision of dispatcherassisted CPR (also known as telephone CPR), and the location and dispatch of an AED. • The bystander who is trained and able should assess the collapsed victim rapidly to determine if the victim is unresponsive and not breathing normally and then immediately alert the emergency services. http://dx.doi.org/10.1016/j.resuscitation.2015.07.038 0300-9572/© 2015 European Resuscitation Council. Published by Elsevier Ireland Ltd. All rights reserved. 2 K.G. Monsieurs et al. / Resuscitation 95 (2015) 1–80 COMMUNITY RESPONSE SAVES LIVES 112 Fig. 1.1. The interactions between the emergency medical dispatcher, the bystander who provides CPR and the timely use of an automated external defibrillator are the key ingredients for improving survival from out of hospital cardiac arrest. • The victim who is unresponsive and not breathing normally is in cardiac arrest and requires CPR. Bystanders and emergency medical dispatchers should be suspicious of cardiac arrest in any patient presenting with seizures and should carefully assess whether the victim is breathing normally. • CPR providers should perform chest compressions for all victims in cardiac arrest. CPR providers trained and able to perform rescue breaths should combine chest compressions and rescue breaths. Our confidence in the equivalence between chest compressiononly and standard CPR is not sufficient to change current practice. • High-quality CPR remains essential to improving outcomes. The guidelines on compression depth and rate have not changed. CPR providers should ensure chest compressions of adequate depth (at least 5 cm but no more than 6 cm) with a rate of 100–120 compressions min−1. After each compression allow the chest to recoil completely and minimise interruptions in compressions. When providing rescue breaths/ventilations spend approximately 1 s inflating the chest with sufficient volume to ensure the chest rises visibly. The ratio of chest compressions to ventilations remains 30:2. Do not interrupt chest compressions for more than 10 s to provide ventilations. • Defibrillation within 3–5 min of collapse can produce survival rates as high as 50–70%. Early defibrillation can be achieved through CPR providers using public access and on-site AEDs. Public access AED programmes should be actively implemented in public places that have a high density of citizens. • The adult CPR sequence can be used safely in children who are unresponsive and not breathing normally. Chest compression depths in children should be at least one third of the depth of the chest (for infants that is 4 cm, for children 5 cm). • A foreign body causing severe airway obstruction is a medical emergency and requires prompt treatment with back blows and, if that fails to relieve the obstruction, abdominal thrusts. If the victim becomes unresponsive CPR should be started immediately whilst help is summoned. Adult advanced life support The ERC 2015 ALS Guidelines emphasise improved care and implementation of the guidelines in order to improve patient focused outcomes.11 The key changes since 2010 are: • Continued emphasis on the use of rapid response systems for care of the deteriorating patient and prevention of in-hospital cardiac arrest. • Continued emphasis on minimally interrupted high-quality chest compressions throughout any ALS intervention: chest compressions are paused briefly only to enable specific interventions. This includes minimising interruptions in chest compressions for less than 5 s to attempt defibrillation. • Keeping the focus on the use of self-adhesive pads for defibrillation and a defibrillation strategy to minimise the preshock pause, although we recognise that defibrillator paddles are used in some settings. • There is a new section on monitoring during ALS with an increased emphasis on the use of waveform capnography to confirm and continually monitor tracheal tube placement, quality of CPR and to provide an early indication of return of spontaneous circulation (ROSC). • There are a variety of approaches to airway management during CPR and a stepwise approach based on patient factors and the skills of the rescuer is recommended. • The recommendations for drug therapy during CPR have not changed, but there is greater equipoise concerning the role of drugs in improving outcomes from cardiac arrest. • The routine use of mechanical chest compression devices is not recommended, but they are a reasonable alternative in situations where sustained high-quality manual chest compressions are impractical or compromise provider safety. • Peri-arrest ultrasound may have a role in identifying reversible causes of cardiac arrest. • Extracorporeal life support techniques may have a role as a rescue therapy in selected patients where standard ALS measures are not successful. Cardiac arrest in special circumstances Special causes This section has been structured to cover the potentially reversible causes of cardiac arrest that must be identified or excluded during any resuscitation. They are divided into two groups of four – 4Hs and 4Ts: hypoxia; hypo-/hyperkalaemia and other electrolyte disorders; hypo-/hyperthermia; hypovolaemia; tension pneumothorax; tamponade (cardiac); thrombosis (coronary and pulmonary); toxins (poisoning). • Survival after an asphyxia-induced cardiac arrest is rare and survivors usually have severe neurological impairment. During CPR, early effective ventilation of the lungs with supplementary oxygen is essential. • A high degree of clinical suspicion and aggressive treatment can prevent cardiac arrest from electrolyte abnormalities. The new algorithm provides clinical guidance to emergency treatment of life-threatening hyperkalaemia. • Hypothermic patients without signs of cardiac instability can be rewarmed externally using minimally invasive techniques. Patients with signs of cardiac instability should be transferred directly to a centre capable of extracorporeal life support (ECLS). • Early recognition and immediate treatment with intramuscular adrenaline remains the mainstay of emergency treatment for anaphylaxis. • A new treatment algorithm for traumatic cardiac arrest was developed to prioritise the sequence of life-saving measures. • Transport with continuing CPR may be beneficial in selected patients where there is immediate hospital access to the catheterisation laboratory and experience in percutaneous coronary intervention (PCI) with ongoing CPR. • Recommendations for administration of fibrinolytics when pulmonary embolism is the suspected cause of cardiac arrest remain unchanged. K.G. Monsieurs et al. / Resuscitation 95 (2015) 1–80 3 Special environments The special environments section includes recommendations for the treatment of cardiac arrest occurring in specific locations. These locations are specialised healthcare facilities (e.g. operating theatre, cardiac surgery, catheterisation laboratory, dialysis unit, dental surgery), commercial airplanes or air ambulances, field of play, outside environment (e.g. drowning, difficult terrain, high altitude, avalanche burial, lightning strike and electrical injuries) or the scene of a mass casualty incident. • A new section covers the common causes and relevant modification to resuscitative procedures in patients undergoing surgery. • In patients following major cardiac surgery, key to successful resuscitation is recognising the need to perform immediate emergency resternotomy, especially in the context of tamponade or haemorrhage, where external chest compressions may be inef- fective. • Cardiac arrest from shockable rhythms (ventricular fibrillation (VF) or pulseless ventricular tachycardia (pVT)) during cardiac catheterisation should immediately be treated with up to three stacked shocks before starting chest compressions. Use of mechanical chest compression devices during angiography is recommended to ensure high-quality chest compressions and to reduce the radiation burden to personnel during angiography with ongoing CPR. • AEDs and appropriate CPR equipment should be mandatory on board of all commercial aircraft in Europe, including regional and low-cost carriers. Consider an over-the-head technique of CPR if restricted access precludes a conventional method. • Sudden and unexpected collapse of an athlete on the field of play is likely to be cardiac in origin and requires rapid recognition and early defibrillation. • Submersion exceeding 10 min is associated with poor outcome. Bystanders play a critical role in early rescue and resuscitation. Resuscitation strategies for those in respiratory or cardiac arrest continue to prioritise oxygenation and ventilation. • The chances of good outcome from cardiac arrest in difficult terrain or mountains may be reduced because of delayed access and prolonged transport. There is a recognised role of air rescue and availability of AEDs in remote but often-visited locations. • The cut-off criteria for prolonged CPR and extracorporeal rewarming of avalanche victims in cardiac arrest have become more stringent to reduce the number of futile cases treated with extracorporeal life support (ECLS). • Safety measures are emphasised when providing CPR to the victim of an electrical injury. • During mass casualty incidents (MCIs), if the number of casualties overwhelms healthcare resources, withhold CPR for those without signs of life. Special patients The section on special patients gives guidance for CPR in patients with severe comorbidities (asthma, heart failure with ventricular assist devices, neurological disease, obesity) and those with specific physiological conditions (pregnancy, elderly people). • In patients with ventricular assist devices (VADs), confirmation of cardiac arrest may be difficult. If during the first 10 days after surgery, cardiac arrest does not respond to defibrillation, perform resternotomy immediately. • Patients with subarachnoid haemorrhage may have ECG changes that suggest an acute coronary syndrome (ACS). Whether a computed tomography (CT) brain scan is done before or after coronary angiography will depend on clinical judgement. • No changes to the sequence of actions are recommended in resuscitation of obese patients, but delivery of effective CPR may be challenging. Consider changing rescuers more frequently than the standard 2-min interval. Early tracheal intubation is recom- mended. • For the pregnant woman in cardiac arrest, high-quality CPR with manual uterine displacement, early ALS and delivery of the foetus if early return of spontaneous circulation (ROSC) is not achieved remain key interventions. Post-resuscitation care This section is new to the European Resuscitation Council Guidelines; in 2010 the topic was incorporated into the section on ALS.12 The ERC has collaborated with the European Society of Intensive Care Medicine to produce these post-resuscitation care guidelines, which recognise the importance of high-quality post-resuscitation care as a vital link in the Chain of Survival.13 The most important changes in post-resuscitation care since 2010 include: • There is a greater emphasis on the need for urgent coronary catheterisation and percutaneous coronary intervention (PCI) following out-of-hospital cardiac arrest of likely cardiac cause. • Targeted temperature management remains important but there is now an option to target a temperature of 36 ◦C instead of the previously recommended 32–34 ◦C. The prevention of fever remains very important. • Prognostication is now undertaken using a multimodal strategy and there is emphasis on allowing sufficient time for neurological recovery and to enable sedatives to be cleared. • A novel section has been added which addresses rehabilitation after survival from a cardiac arrest. Recommendations include the systematic organisation of follow-up care, which should include screening for potential cognitive and emotional impairments and provision of information. Paediatric life support Guideline changes have been made in response to convincing new scientific evidence and, by using clinical, organisational and educational findings, they have been adapted to promote their use and ease for teaching. Basic life support • The duration of delivering a breath is about 1 s, to coincide with adult practice. • For chest compressions, the lower sternum should be depressed by at least one third the anterior-posterior diameter of the chest (4 cm for the infant and 5 cm for the child). Managing the seriously ill child • If there are no signs of septic shock, then children with a febrile illness should receive fluid with caution and reassessment following its administration. In some forms of septic shock, restricting fluids with isotonic crystalloid may be of benefit as compared to liberal use of fluids. • For cardioversion of a supraventricular tachycardia (SVT), the initial dose has been revised to 1 J kg-1. Paediatric cardiac arrest algorithm • Many of the features are common with adult practice. Post-resuscitation care • Prevent fever in children who have return of spontaneous circulation (ROSC) from an out-of-hospital setting. 4 K.G. Monsieurs et al. / Resuscitation 95 (2015) 1–80 • Targeted temperature management of children post-ROSC should be either normothermia or mild hypothermia. • There is no single predictor for when to stop resuscitation. Resuscitation and support of transition of babies at birth The following are the main changes that have been made to the ERC guidelines for resuscitation at birth in 2015: • Support of transition: Recognising the unique situation of the baby at birth, who rarely requires resuscitation but sometimes needs medical help during the process of postnatal transition. The term support of transition has been introduced to better distinguish between interventions that are needed to restore vital organ functions (resuscitation) or to support transition. • Cord clamping: For uncompromised babies, a delay in cord clamping of at least 1 min from the complete delivery of the infant, is now recommended for term and preterm babies. As yet there is insufficient evidence to recommend an appropriate time for clamping the cord in babies who require resuscitation at birth. • Temperature: The temperature of newly born non-asphyxiated infants should be maintained between 36.5 ◦C and 37.5 ◦C after birth. The importance of achieving this has been highlighted and reinforced because of the strong association with mortality and morbidity. The admission temperature should be recorded as a predictor of outcome as well as a quality indicator. • Maintenance of temperature: At <32 weeks gestation, a combination of interventions may be required in addition to maintain the temperature between 36.5 ◦C and 37.5 ◦C after delivery through admission and stabilisation. These may include warmed humidified respiratory gases, increased room temperature plus plastic wrapping of body and head, plus thermal mattress or a thermal mattress alone, all of which have been effective in reducing hypothermia. • Optimal assessment of heart rate: It is suggested in babies requiring resuscitation that the ECG can be used to provide a rapid and accurate estimation of heart rate. • Meconium: Tracheal intubation should not be routine in the presence of meconium and should only be performed for suspected tracheal obstruction. The emphasis should be on initiating ventilation within the first minute of life in non-breathing or ineffectively breathing infants and this should not be delayed. • Air/oxygen: Ventilatory support of term infants should start with air. For preterm infants, either air or a low concentration of oxygen (up to 30%) should be used initially. If, despite effective ventilation, oxygenation (ideally guided by oximetry) remains unacceptable, use of a higher concentration of oxygen should be considered. • CPAP: Initial respiratory support of spontaneously breathing preterm infants with respiratory distress may be provided by CPAP rather than intubation. Acute coronary syndromes The following is a summary of the most important new views and changes in recommendations for the diagnosis and treatment of acute coronary syndromes (ACS). Diagnostic Interventions in ACS • Pre-hospital recording of a 12-lead electrocardiogram (ECG) is recommended in patients with suspected ST segment elevation acute myocardial infarction (STEMI). For those with STEMI this expedites pre-hospital and in-hospital reperfusion and reduces mortality. • Non-physician ECG STEMI interpretation with or without the aid of computer ECG STEMI interpretation is suggested if adequate diagnostic performance can be maintained through carefully monitored quality assurance programmes. • Pre-hospital STEMI activation of the catheterisation laboratory may not only reduce treatment delays but may also reduce patient mortality. • The use of negative high-sensitivity cardiac troponins (hs-cTn) during initial patient evaluation cannot be used as a standalone measure to exclude an ACS, but in patients with very low risk scores may justify early discharge. Therapeutic Interventions in ACS • Adenosine diphosphate (ADP) receptor antagonists (clopidogrel, ticagrelor, or prasugrel-with specific restriction), may be given either pre-hospital or in the ED for STEMI patients planned for primary PCI. • Unfractionated heparin (UFH) can be administered either in the pre-hospital or in-hospital setting in patients with STEMI and a planned primary PCI approach. • Pre-hospital enoxaparin may be used as an alternative to prehospital UFH for STEMI. • Patients with acute chest pain with presumed ACS do not need supplemental oxygen unless they present with signs of hypoxia, dyspnoea, or heart failure. Reperfusion decisions in STEMI Reperfusion decisions have been reviewed in a variety of possible local situations. • When fibrinolysis is the planned treatment strategy, we recommend using pre-hospital fibrinolysis in comparison to in-hospital fibrinolysis for STEMI where transport times are >30 min and pre-hospital personnel are well trained. • In geographic regions where PCI facilities exist and are available, direct triage and transport for PCI is preferred to pre-hospital fibrinolysis for STEMI. • Patients presenting with STEMI in the emergency department (ED) of a non-PCI capable hospital should be transported immediately to a PCI centre provided that treatment delays for PPCI are less than 120 min (60–90 min for early presenters and those with extended infarctions), otherwise patients should receive fibrinolysis and be transported to a PCI centre. • Patients who receive fibrinolytic therapy in the emergency department of a non-PCI centre should be transported if possible for early routine angiography (within 3–24 h from fibrinolytic therapy) rather than be transported only if indicated by the presence of ischaemia. • PCI in less than 3 h following administration of fibrinolytics is not recommended and can be performed only in case of failed fibrinolysis. Hospital reperfusion decisions after return of spontaneous circulation • We recommend emergency cardiac catheterisation lab evaluation (and immediate PCI if required), in a manner similar to patients with STEMI without cardiac arrest, in selected adult patients with ROSC after out-of-hospital cardiac arrest (OHCA) of suspected cardiac origin with ST-elevation on ECG. • In patients who are comatose and with ROSC after OHCA of suspected cardiac origin without ST-elevation on ECG It is reasonable K.G. Monsieurs et al. / Resuscitation 95 (2015) 1–80 5 to consider an emergency cardiac catheterisation lab evaluation in patients with the highest risk of coronary cause cardiac arrest. First aid A section on first aid is included for the first time in the 2015 ERC Guidelines. Principles of education in resuscitation The following is a summary of the most important new views or changes in recommendations for education in resuscitation since the last ERC guidelines in 2010. Training • In centres that have the resources to purchase and maintain high fidelity manikins, we recommend their use. The use of lower fidelity manikins however is appropriate for all levels of training on ERC courses. • Directive CPR feedback devices are useful for improving compression rate, depth, release, and hand position. Tonal devices improve compression rates only and may have a detrimental effect on compression depth while rescuers focus on the rate. • The intervals for retraining will differ according to the characteristics of the participants (e.g. lay or healthcare). It is known that CPR skills deteriorate within months of training and therefore annual retraining strategies may not be frequent enough. Whilst optimal intervals are not known, frequent ‘low dose’ retraining may be beneficial. • Training in non-technical skills (e.g. communication skills, team leadership and team member roles) is an essential adjunct to the training of technical skills. This type of training should be incorporated into life support courses. • Ambulance service dispatchers have an influential role to play in guiding lay rescuers how to deliver CPR. This role needs specific training in order to deliver clear and effective instructions in a stressful situation. Implementation • Data-driven performance-focused debriefing has been shown to improve performance of resuscitation teams. We highly recommend its use for teams managing patients in cardiac arrest. • Regional systems including cardiac arrest centres are to be encouraged, as there is an association with increased survival and improved neurological outcome in victims of out-of-hospital cardiac arrest. • Novel systems are being developed to alert bystanders to the location of the nearest AED. Any technology that improves the delivery of swift bystander CPR with rapid access to an AED is to be encouraged. • “It takes a system to save a life” [http://www. resuscitationacademy.com/]. Healthcare systems with a responsibility for the management of patients in cardiac arrest (e.g. EMS organisations, cardiac arrest centres) should evaluate their processes to ensure that they are able to deliver care that ensures the best achievable survival rates. The ethics of resuscitation and end-of-life decisions The 2015 ERC Guidelines include a detailed discussion of the ethical principles underpinning cardiopulmonary resuscitation. The international consensus on cardiopulmonary resuscitation science The International Liaison Committee on Resuscitation (ILCOR, www.ilcor.org) includes representatives from the American Heart Association (AHA), the European Resuscitation Council (ERC), the Heart and Stroke Foundation of Canada (HSFC), the Australian and New Zealand Committee on Resuscitation (ANZCOR), the Resuscitation Council of Southern Africa (RCSA), the Inter-American Heart Foundation (IAHF), and the Resuscitation Council of Asia (RCA). Since 2000, researchers from the ILCOR member councils have evaluated resuscitation science in 5-yearly cycles. The most recent International Consensus Conference was held in Dallas in February 2015 and the published conclusions and recommendations from this process form the basis of these ERC Guidelines 2015.14 In addition to the six ILCOR task forces from 2010 (basic life support (BLS); advanced life support (ALS); acute coronary syndromes (ACS); paediatric life support (PLS); neonatal life support (NLS); and education, implementation and teams (EIT)) a First Aid task force was created. The task forces identified topics requiring evidence evaluation and invited international experts to review them. As in 2010, a comprehensive conflict of interest (COI) policy was applied.14 For each topic, two expert reviewers were invited to undertake independent evaluations. Their work was supported by a new and unique online system called SEERS (Scientific Evidence Evaluation and Review System), developed by ILCOR. To assess the quality of the evidence and the strength of the recommendations, ILCOR adopted the GRADE (Grading of Recommendations Assessment, Development and Evaluation) methodology.15 The ILCOR 2015 Consensus Conference was attended by 232 participants representing 39 countries; 64% of the attendees came from outside the United States. This participation ensured that this final publication represents a truly international consensus process. During the three years leading up to this conference, 250 evidence reviewers from 39 countries reviewed thousands of relevant, peer-reviewed publications to address 169 specific resuscitation questions, each in the standard PICO (Population, Intervention, Comparison, Outcome) format. Each science statement summarised the experts’ interpretation of all relevant data on the specific topic and the relevant ILCOR task force added consensus draft treatment recommendations. Final wording of science statements and treatment recommendations was completed after further review by ILCOR member organisations and by the editorial board, and published in Resuscitation and Circulation as the 2015 Consensus on Science and Treatment Recommendations (CoSTR).16,17 The member organisations forming ILCOR will publish resuscitation guidelines that are consistent with this CoSTR document, but will also consider geographic, economic and system differences in practice, and the availability of medical devices and drugs. From science to guidelines These ERC Guidelines 2015 are based on the 2015 CoSTR document and represent consensus among the members of the ERC General Assembly. New to the ERC Guidelines 2015 are the First Aid Guidelines, created in parallel with the First Aid Task Force of ILCOR, and guidelines on post-resuscitation care. For each section of the ERC Guidelines 2015, a writing group was assigned that drafted and agreed on the manuscript prior to approval by the General Assembly and the ERC Board. In areas where ILCOR had not conducted a systematic review, the ERC writing group undertook focused literature reviews. The ERC considers these new guidelines to be the most effective and easily learned interventions that can be supported by current knowledge, research and experience. Inevitably, even 6 K.G. Monsieurs et al. / Resuscitation 95 (2015) 1–80 within Europe, differences in the availability of drugs, equipment, and personnel will necessitate local, regional and national adaptation of these guidelines. Some of the recommendations made in the ERC Guidelines 2010 remain unchanged in 2015, either because no new studies have been published or because new evidence since 2010 has merely strengthened the evidence that was already avail- able. Adult basic life support and automated external defibrillation The basic life support (BLS) and automated external defibrillation (AED) chapter contains guidance on the techniques used during the initial resuscitation of an adult cardiac arrest victim. This includes BLS (airway, breathing and circulation support without the use of equipment other than a protective device) and the use of an AED. In addition, simple techniques used in the management of choking (foreign body airway obstruction) are included. Guidelines for the use of manual defibrillators and starting in-hospital resuscitation are found in section 3.2 A summary of the recovery position is included, with further information provided in the First Aid Chapter. The guidelines are based on the ILCOR 2015 Consensus on Science and Treatment Recommendations (CoSTR) for BLS/AED.18 The ILCOR review focused on 23 key topics leading to 32 Treatment Recommendations in the domains of early access and cardiac arrest prevention, early, high-quality CPR, and early defibrillation. Cardiac arrest Sudden cardiac arrest (SCA) is one of the leading causes of death in Europe. On initial heart-rhythm analysis, about 25–50% of SCA victims have ventricular fibrillation (VF)19–21 but when the rhythm is recorded soon after collapse, in particular by an on-site AED, the proportion of victims in VF can be as high as 76%.22,23 The recommended treatment for VF cardiac arrest is immediate bystander CPR and early electrical defibrillation. Most cardiac arrests of noncardiac origin have respiratory causes, such as drowning (among them many children) and asphyxia. Rescue breaths as well as chest compressions are critical for successful resuscitation of these vic- tims. The chain of survival The Chain of Survival summarises the vital links needed for successful resuscitation (Fig. 1.2). Most of these links apply to victims of both primary cardiac and asphyxial arrest.13 1: Early recognition and call for help Recognising the cardiac origin of chest pain, and calling the emergency services before a victim collapses, enables the emergency medical service to arrive sooner, hopefully before cardiac arrest has occurred, thus leading to better survival.24–26 Once cardiac arrest has occurred, early recognition is critical to enable rapid activation of the EMS and prompt initiation of bystander CPR. The key observations are unresponsiveness and not breathing normally. 2: Early bystander CPR The immediate initiation of CPR can double or quadruple survival after cardiac arrest.27–29 If able, bystanders with CPR training should give chest compressions together with ventilations. When a bystander has not been trained in CPR, the emergency medical dispatcher should instruct him or her to give chest-compression-only CPR while awaiting the arrival of professional help.30–32 3: Early defibrillation Defibrillation within 3–5 min of collapse can produce survival rates as high as 50–70%. This can be achieved by public access and onsite AEDs.21,23,33 4: Early advanced life support and standardised post-resuscitation care Advanced life support with airway management, drugs and correcting causal factors may be needed if initial attempts at resuscitation are un-successful. The critical need for bystanders to act In most communities, the median time from emergency call to emergency medical service arrival (response interval) is 5–8 min,22,34–36 or 8–11 min to a first shock.21,28 During this time the victim’s survival depends on bystanders who initiate CPR and use an automated external defibrillator (AED).22,37 Fig. 1.2. The Chain of Survival. K.G. Monsieurs et al. / Resuscitation 95 (2015) 1–80 7 Recognition of cardiac arrest Recognising cardiac arrest can be challenging. Both bystanders and emergency call handlers (emergency medical dispatchers) have to diagnose cardiac arrest promptly in order to activate the chain of survival. Checking the carotid pulse (or any other pulse) has proved to be an inaccurate method for confirming the presence or absence of circulation.38–42 Agonal breathing may be present in up to 40% of victims in the first minutes after cardiac arrest, and if responded to as a sign of cardiac arrest, is associated with higher survival rates.43 The significance of agonal breathing should be emphasised during basic life support training.44,45 Bystanders should suspect cardiac arrest and start CPR if the victim is unresponsive and not breathing normally. Bystanders should be suspicious of cardiac arrest in any patient presenting with seizures.46,47 Role of the emergency medical dispatcher Dispatcher recognition of cardiac arrest Patients who are unresponsive and not breathing normally should be presumed to be in cardiac arrest. Agonal breathing is often present, and callers may mistakenly believe the victim is still breathing normally.48–57 Offering dispatchers additional education, specifically addressing the identification and significance of agonal breathing, can improve cardiac arrest recognition, increase the provision of telephone-CPR,55,57 and reduce the number of missed cardiac arrest cases.52 If the initial emergency call is for a person suffering seizures, the call taker should be highly suspicious of cardiac arrest, even if the caller reports that the victim has a prior history of epilepsy.49,58 Dispatcher-assisted CPR Bystander CPR rates are low in many communities. Dispatcherassisted CPR (telephone-CPR) instructions improve bystander CPR rates,56,59–62 reduce the time to first CPR,57,59,62–64 increase the number of chest compressions delivered60 and improve patient outcomes following out-of-hospital cardiac arrest (OHCA) in all patient groups.30–32,56,61,63,65 Dispatchers should provide telephone-CPR instructions in all cases of suspected cardiac arrest unless a trained provider is already delivering CPR. Where instructions are required for an adult victim, dispatchers should provide chest-compression-only CPR instructions. If the victim is a child, dispatchers should instruct callers to provide both ventilations and chest compressions. Adult BLS sequence Fig. 1.3 presents the step-by-step sequence for the trained provider. It continues to highlight the importance of ensuring rescuer, victim and bystander safety. Calling for additional help (if required) is incorporated in the alerting emergency services step below. For clarity the algorithm is presented as a linear sequence of steps. It is recognised that the early steps of checking response, opening the airway, checking for breathing and calling the emergency medical dispatcher may be accomplished simultaneously or in rapid succession. Those who are not trained to recognise cardiac arrest and start CPR would not be aware of these guidelines and therefore require dispatcher assistance whenever they make the decision to call 112 (Fig. 1.4). Unresponsive and not breathing normally Call Emergency Services Give 30 chest compressions Give 2 rescue breaths Continue CPR 30:2 As soon as AED arrives - switch it on and follow instructions Fig. 1.3. The basic life support/automated external defibrillation (BLS/AED) algo- rithm. Opening the airway and checking for breathing The trained provider should assess the collapsed victim rapidly to determine if they are responsive and breathing normally. Open the airway using the head tilt and chin lift technique whilst assessing whether the person is breathing normally. Alerting emergency services 112 is the European emergency phone number, available everywhere in the EU, free of charge. It is possible to call 112 from fixed and mobile phones to contact any emergency service: an ambulance, the fire brigade or the police. Early contact with the emergency services will facilitate dispatcher assistance in the recognition of cardiac arrest, telephone instruction on how to perform CPR, emergency medical service/first responder dispatch, and on locating and dispatching of an AED.66–69 Starting chest compressions In adults needing CPR, there is a high probability of a primary cardiac cause. When blood flow stops after cardiac arrest, the blood in the lungs and arterial system remains oxygenated for some minutes. To emphasise the priority of chest compressions, it is recommended that CPR should start with chest compressions rather than initial ventilations. When providing manual chest compressions: 1. Deliver compressions ‘in the centre of the chest’ 2. Compress to a depth of at least 5 cm but not more than 6 cm 3. Compress the chest at a rate of 100–120 min−1 with as few interruptions as possible 4. Allow the chest to recoil completely after each compression; do not lean on the chest Hand position Experimental studies show better haemodynamic responses when chest compressions are performed on the lower half of the 8 K.G. Monsieurs et al. / Resuscitation 95 (2015) 1–80 Fig. 1.4. Step by step sequence of actions for use by the BLS/AED trained provider to treat the adult cardiac arrest victim. K.G. Monsieurs et al. / Resuscitation 95 (2015) 1–80 9 Fig. 1.4. (Continued ) 10 K.G. Monsieurs et al. / Resuscitation 95 (2015) 1–80 Fig. 1.4. (Continued ) K.G. Monsieurs et al. / Resuscitation 95 (2015) 1–80 11 Fig. 1.4. (Continued ) sternum.70–72 It is recommended that this location be taught in a simplified way, such as, “place the heel of your hand in the centre of the chest with the other hand on top”. This instruction should be accompanied by a demonstration of placing the hands on the lower half of the sternum.73,74 Chest compressions are most easily delivered by a single CPR provider kneeling by the side of the victim, as this facilitates movement between compressions and ventilations with minimal interruptions. Over-the-head CPR for single CPR providers and straddle-CPR for two CPR providers may be considered when it is not possible to perform compressions from the side, for example when the victim is in a confined space.75,76 Compression depth Data from four recent observational studies suggest that a compression depth range of 4.5–5.5 cm in adults leads to better outcomes than all other compression depths during manual CPR.77–80 One of these studies found that a compression depth of 46 mm was associated with the highest survival rate.79 The ERC, therefore, endorses the ILCOR recommendation that it is reasonable to aim for a chest compression depth of approximately 5 cm but not more than 6 cm in the average sized adult.81 In line with the ILCOR recommendation, the ERC decided to retain the 2010 guidance to compress the chest at least 5 cm but not more than 6 cm. Compression rate Two studies found higher survival among patients who received chest compressions at a rate of 100–120 min−1. Very high chest compression rates were associated with declining chest compression depths.82,83 The ERC recommends, therefore, that chest compressions should be performed at a rate of 100–120 min−1. Minimising pauses in chest compressions Pre- and post-shock pauses of less than 10 s, and chest compression fractions >60% are associated with improved outcomes.84–88 Pauses in chest compressions should be minimised. Firm surface CPR should be performed on a firm surface whenever possible. Air-filled mattresses should be routinely deflated during CPR.89 The evidence for the use of backboards is equivocal.90–94 If a backboard is used, take care to avoid interrupting CPR and dislodging intravenous lines or other tubes during board placement. Chest wall recoil Allowing complete recoil of the chest after each compression results in better venous return to the chest and may improve the effectiveness of CPR.95–98 CPR providers should, therefore, take care to avoid leaning after each chest compression. Duty cycle There is very little evidence to recommend any specific duty cycle and, therefore, insufficient new evidence to prompt a change from the currently recommended ratio of 50%. Feedback on compression technique None of the studies on feedback or prompt devices has demonstrated improved survival to discharge with feedback.99 The use of CPR feedback or prompt devices during CPR should only be considered as part of a broader system of care that should include comprehensive CPR quality improvement initiatives,99,100 rather than as an isolated intervention. 12 K.G. Monsieurs et al. / Resuscitation 95 (2015) 1–80 Rescue breaths We suggest that during adult CPR tidal volumes of approximately 500–600 ml (6–7 ml kg−1) are delivered. Practically, this is the volume required to cause the chest to rise visibly.101 CPR providers should aim for an inflation duration of about 1 s, with enough volume to make the victim’s chest rise, but avoid rapid or forceful breaths. The maximum interruption in chest compression to give two breaths should not exceed 10 s.102 Compression–ventilation ratio A ratio of 30:2 was recommended in ERC Guidelines 2010 for the single CPR provider attempting resuscitation of an adult. Several observational studies have reported slightly improved outcomes after implementation of the guideline changes, which included switching from a compression ventilation ratio of 15:2 to 30:2.103–106 The ERC continues, therefore, to recommend a compression to ventilation ratio of 30:2. Compression-only CPR Observational studies, classified mostly as very low-quality evidence, have suggested equivalence of chest-compression-only CPR and chest compressions combined with rescue breaths in adults with a suspected cardiac cause for their cardiac arrest.27,107–118 Our confidence in the equivalence between chest-compressiononly and standard CPR is not sufficient to change current practice. The ERC, therefore, endorses the ILCOR recommendations that all CPR providers should perform chest compressions for all patients in cardiac arrest. CPR providers trained and able to perform rescue breaths should perform chest compressions and rescue breaths as this may provide additional benefit for children and those who sustain an asphyxial cardiac arrest111,119,120 or where the EMS response interval is prolonged.115 Use of an automated external defibrillator AEDs are safe and effective when used by laypeople with minimal or no training.121 AEDs make it possible to defibrillate many minutes before professional help arrives. CPR providers should continue CPR with minimal interruption of chest compressions while attaching an AED and during its use. CPR providers should concentrate on following the voice prompts immediately when they are spoken, in particular resuming CPR as soon as instructed, and minimising interruptions in chest compression. Standard AEDs are suitable for use in children older than 8 years.122–124 For children between 1 and 8 years use paediatric pads, together with an attenuator or a paediatric mode if available. CPR before defibrillation Continue CPR while a defibrillator or AED is being brought onsite and applied, but defibrillation should not be delayed any longer. Interval between rhythm checks Pause chest compressions every 2 min to assess the cardiac rhythm. Voice prompts It is critically important that CPR providers pay attention to AED voice prompts and follow them without any delay. Voice prompts are usually programmable, and it is recommended that they be set in accordance with the sequence of shocks and timings for CPR given above. Devices measuring CPR quality may in addition provide real-time CPR feedback and supplemental voice/visual prompts. In practice, AEDs are used mostly by trained rescuers, where the default setting of AED prompts should be for a compression to ventilation ratio of 30:2. If (in an exception) AEDs are placed in a setting where such trained rescuers are unlikely to be available or present, the owner or distributor may choose to change the settings to compression only. Public access defibrillation (PAD) programmes Placement of AEDs in areas where one cardiac arrest per 5 years can be expected is considered cost-effective and comparable to other medical interventions.125–127 Registration of AEDs for public access, so that dispatchers can direct CPR providers to a nearby AED, may also help to optimise response.128 The effectiveness of AED use for victims at home is limited.129 The proportion of patients found in VF is lower at home than in public places, however the absolute number of potentially treatable patients is higher at home.129 Public access defibrillation (PAD) rarely reaches victims at home.130 Dispatched lay CPR providers, local to the victim and directed to a nearby AED, may improve bystander CPR rates33 and help reduce the time to defibrillation.37 Universal AED signage ILCOR has designed a simple and clear AED sign that may be recognised worldwide and this is recommended to indicate the location of an AED.131 In-hospital use of AEDs There are no published randomised trials comparing in-hospital use of AEDs with manual defibrillators. Three observational studies showed no improvements in survival to hospital discharge for inhospital adult cardiac arrest when using an AED compared with manual defibrillation.132–134 Another large observational study showed that in-hospital AED use was associated with a lower survival-to-discharge rate compared with no AED use.135 This suggests that AEDs may cause harmful delays in starting CPR, or interruptions in chest compressions in patients with non-shockable rhythms.136 We recommend the use of AEDs in those areas of the hospital where there is a risk of delayed defibrillation,137 because it will take several minutes for a resuscitation team to arrive, and first responders do not have skills in manual defibrillation. The goal is to attempt defibrillation within 3 min of collapse. In hospital areas where there is rapid access to manual defibrillation, either from trained staff or a resuscitation team, manual defibrillation should be used in preference to an AED. Hospitals should monitor collapseto-first shock intervals and audit resuscitation outcomes. Risks to the CPR provider and recipients of CPR In victims who are eventually found not to be in cardiac arrest, bystander CPR extremely rarely leads to serious harm. CPR providers should not, therefore, be reluctant to initiate CPR because of concern of causing harm. Foreign body airway obstruction (choking) Foreign body airway obstruction (FBAO) is an uncommon but potentially treatable cause of accidental death.138 As victims initially are conscious and responsive, there are often opportunities for early interventions which can be life saving. K.G. Monsieurs et al. / Resuscitation 95 (2015) 1–80 13 Recognition FBAO usually occurs while the victim is eating or drinking. Fig. 1.5 presents the treatment algorithm for the adult with FBAO. Foreign bodies may cause either mild or severe obstruction. It is important to ask the conscious victim “Are you choking?”. The victim that is able to speak, cough and breathe has mild obstruction. The victim that is unable to speak, has a weakening cough, is struggling or unable to breathe, has severe airway obstruction. Treatment for mild airway obstruction Encourage the victim to cough as coughing generates high and sustained airway pressures and may expel the foreign body. Fig. 1.5. Step by step sequence of actions for the treatment of the adult victim with foreign body airway obstruction. 14 K.G. Monsieurs et al. / Resuscitation 95 (2015) 1–80 Fig. 1.5. (Continued ) Treatment for severe airway obstruction For conscious adults and children over one year of age with complete FBAO, case reports have demonstrated the effectiveness of back blows or ‘slaps’, abdominal thrusts and chest thrusts.139 The likelihood of success is increased when combinations of back blows or slaps, and abdominal and chest thrusts are used.139 Treatment of foreign body airway obstruction in an unresponsive victim A randomised trial in cadavers140 and two prospective studies in anaesthetised volunteers141,142 showed that higher airway pressures can be generated using chest thrusts compared with abdominal thrusts. Chest compressions should, therefore, be started promptly if the victim becomes unresponsive or unconscious. After 30 compressions attempt 2 rescue breaths, and continue CPR until the victim recovers and starts to breathe nor- mally. Victims with a persistent cough, difficulty swallowing or the sensation of an object being still stuck in the throat should be referred for a medical opinion. Abdominal thrusts and chest compressions can potentially cause serious internal injuries and all victims successfully treated with these measures should be examined afterwards for injury. Resuscitation of children (see also section 6) and victims of drowning (see also section 4) Many children do not receive resuscitation because potential CPR providers fear causing harm if they are not specifically trained in resuscitation for children. This fear is unfounded: it is far better to use the adult BLS sequence for resuscitation of a child than to do nothing. For ease of teaching and retention, laypeople should be taught that the adult sequence may also be used for children who are not responsive and not breathing normally. The following minor modifications to the adult sequence will make it even more suitable for use in children: • Give 5 initial rescue breaths before starting chest compressions • Give CPR for 1 min before going for help in the unlikely event the CPR provider is alone • Compress the chest by at least one third of its depth; use 2 fingers for an infant under one year; use 1 or 2 hands for a child over 1 year as needed to achieve an adequate depth of compression The same modifications of 5 initial breaths and 1 min of CPR by the lone CPR provider before getting help, may improve outcome for victims of drowning. This modification should be taught only to those who have a specific duty of care to potential drowning victims (e.g. lifeguards). Adult advanced life support Guidelines for prevention of in-hospital cardiac arrest Early recognition of the deteriorating patient and prevention of cardiac arrest is the first link in the chain of survival.13 Once cardiac arrest occurs, only about 20% of patients who have an in-hospital cardiac arrest will survive to go home.143,144 Hospitals should provide a system of care that includes: (a) educating staff about the signs of patient deterioration and the rationale for rapid response to illness, (b) appropriate, and frequent monitoring of patients’ vital signs, (c) clear guidance (e.g. via calling criteria or early warning scores) to assist staff in the early detection of patient deterioration, (d) a clear, uniform system of calling for assistance, and (e) an appropriate and timely clinical response to calls for help.145 Prevention of sudden cardiac death (SCD) out-of-hospital Most SCD victims have a history of cardiac disease and warning signs, most commonly chest pain, in the hour before cardiac arrest.146 Apparently healthy children and young adults who suffer SCD can also have signs and symptoms (e.g. syncope/pre-syncope, chest pain and palpitations) that should alert healthcare professionals to seek expert help to prevent cardiac arrest.147–151 Screening programmes for athletes vary between countries.152,153 Identification of individuals with inherited conditions and screening of family members can help prevent deaths in young people with inherited heart disorders.154–156 Prehospital resuscitation CPR versus defibrillation first for out-of-hospital cardiac arrest EMS personnel should provide high-quality CPR while a defibrillator is retrieved, applied and charged. Defibrillation should not be delayed longer than needed to establish the need for defibrillation and charging. Termination of resuscitation rules The ‘basic life support termination of resuscitation rule’ is predictive of death when applied by defibrillation-only emergency medical technicians.157 The rule recommends termination when there is no ROSC, no shocks are administered and EMS personnel did not witness the arrest. Several studies have shown external generalisability of this rule.158–164 More recent studies show that EMS systems providing ALS interventions can also use this BLS rule and therefore termed it the ‘universal’ termination of resuscitation rule.159,165,166 In-hospital resuscitation After in-hospital cardiac arrest, the division between BLS and ALS is arbitrary; in practice, the resuscitation process is a K.G. Monsieurs et al. / Resuscitation 95 (2015) 1–80 15 Collapsed / sick patient Shout for HELP & assess patient Signs of life?No Yes Call resuscitation team CPR 30:2 with oxygen and airway adjuncts Apply pads/monitor Attempt defibrillation if appropriate Advanced Life Support when resuscitation team arrives Assess ABCDE Recognise & treat Oxygen, monitoring, IV access Call resuscitation team if appropriate Handover to resuscitation team In-hospital Resuscitation Fig. 1.6. In-hospital resuscitation algorithm. ABCDE – Airway, Breathing Circulation, Disability, Exposure IV – intravenous; CPR – cardiopulmonary resuscitation. continuum and is based on common sense. An algorithm for the initial management of in-hospital cardiac arrest is shown in Fig. 1.6. • Ensure personal safety. • When healthcare professionals see a patient collapse or find a patient apparently unconscious in a clinical area, they should first summon help (e.g. emergency bell, shout), then assess if the patient is responsive. Gently shake the shoulders and ask loudly: ‘Are you all right?’ • If other members of staff are nearby, it will be possible to undertake actions simultaneously. The responsive patient Urgent medical assessment is required. Depending on the local protocols, this may take the form of a resuscitation team (e.g. Medical Emergency Team, Rapid Response Team). While awaiting this team, give oxygen, attach monitoring and insert an intravenous cannula. The unresponsive patient The exact sequence will depend on the training of staff and experience in assessment of breathing and circulation. Trained healthcare staff cannot assess the breathing and pulse sufficiently reliably to confirm cardiac arrest.39,40,42,44,167–172 Agonal breathing (occasional gasps, slow, laboured or noisy breathing) is common in the early stages of cardiac arrest and is a sign of cardiac arrest and should not be confused as a sign of life.43,53,54,56 Agonal breathing can also occur during chest compressions as cerebral perfusion improves, but is not indicative of ROSC. Cardiac arrest can cause an initial short seizure-like episode that can be confused with epilepsy46,47 Finally changes in skin colour, notably pallor and bluish changes associated with cyanosis are not diagnostic of cardiac arrest.46 16 K.G. Monsieurs et al. / Resuscitation 95 (2015) 1–80 • Shout for help (if not already) Turn the victim on to his back and then open the airway: • Open airway and check breathing: ◦ Open the airway using a head tilt chin lift ◦ Keeping the airway open, look, listen and feel for normal breathing (an occasional gasp, slow, laboured or noisy breathing is not normal): • Look for chest movement • Listen at the victim’s mouth for breath sounds • Feel for air on your cheek • Look, listen and feel for no more than 10 seconds to determine if the victim is breathing normally. • Check for signs of a circulation: ◦ It may be difficult to be certain that there is no pulse. If the patient has no signs of life (consciousness, purposeful movement, normal breathing, or coughing), or if there is doubt, start CPR immediately until more experienced help arrives or the patient shows signs of life. ◦ Delivering chest compressions to a patient with a beating heart is unlikely to cause harm.173 However, delays in diagnosing cardiac arrest and starting CPR will adversely effect survival and must be avoided. ◦ Only those experienced in ALS should try to assess the carotid pulse whilst simultaneously looking for signs of life. This rapid assessment should take no more than 10 s. Start CPR if there is any doubt about the presence or absence of a pulse. • If there are signs of life, urgent medical assessment is required. Depending on the local protocols, this may take the form of a resuscitation team. While awaiting this team, give the patient oxygen, attach monitoring and insert an intravenous cannula. When a reliable measurement of oxygen saturation of arterial blood (e.g. pulse oximetry (SpO2)) can be achieved, titrate the inspired oxygen concentration to achieve a SpO2 of 94–98%. • If there is no breathing, but there is a pulse (respiratory arrest), ventilate the patient’s lungs and check for a circulation every 10 breaths. Start CPR if there is any doubt about the presence or absence of a pulse. Starting in-hospital CPR The key steps are listed here. Supporting evidence can be found in the sections on specific interventions that follow. • One person starts CPR as others call the resuscitation team and collect the resuscitation equipment and a defibrillator. If only one member of staff is present, this will mean leaving the patient. • Give 30 chest compressions followed by 2 ventilations. • Compress to a depth of at least 5 cm but no more than 6 cm. • Chest compressions should be performed at a rate of 100–120 min−1. • Allow the chest to recoil completely after each compression; do not lean on the chest. • Minimise interruptions and ensure high-quality compressions. • Undertaking high-quality chest compressions for a prolonged time is tiring; with minimal interruption, try to change the person doing chest compressions every 2 min. • Maintain the airway and ventilate the lungs with the most appropriate equipment immediately to hand. Pocket mask ventilation or two-rescuer bag-mask ventilation, which can be supplemented with an oral airway, should be started. Alternatively, use a supraglottic airway device (SGA) and self-inflating bag. Tracheal intubation should be attempted only by those who are trained, competent and experienced in this skill. • Waveform capnography must be used for confirming tracheal tube placement and monitoring ventilation rate. Waveform capnography can also be used with a bag-mask device and SGA. The further use of waveform capnography to monitor CPR quality and potentially identify ROSC during CPR is discussed later in this section.174 • Use an inspiratory time of 1 s and give enough volume to produce a normal chest rise. Add supplemental oxygen to give the highest feasible inspired oxygen as soon as possible.175 • Once the patient’s trachea has been intubated or a SGA has been inserted, continue uninterrupted chest compressions (except for defibrillation or pulse checks when indicated) at a rate of 100–120 min−1 and ventilate the lungs at approximately 10 breaths min−1. Avoid hyperventilation (both excessive rate and tidal volume). • If there is no airway and ventilation equipment available, consider giving mouth-to-mouth ventilation. If there are clinical reasons to avoid mouth-to-mouth contact, or you are unable to do this, do chest compressions until help or airway equipment arrives. • When the defibrillator arrives, apply self-adhesive defibrillation pads to the patient whilst chest compressions continue and then briefly analyse the rhythm. If self-adhesive defibrillation pads are not available, use paddles. Pause briefly to assess the heart rhythm. With a manual defibrillator, if the rhythm is VF/pVT charge the defibrillator while another rescuer continues chest compressions. Once the defibrillator is charged, pause the chest compressions and then give one shock, and immediately resume chest compressions. Ensure no one is touching the patient during shock delivery. Plan and ensure safe defibrillation before the planned pause in chest compressions. • If using an automated external defibrillator (AED) follow the AED’s audio-visual prompts, and similarly aim to minimise pauses in chest compressions by rapidly following prompts. • In some settings where self-adhesive defibrillation pads are not available, alternative defibrillation strategies using paddles are used to minimise the preshock pause. • In some countries a defibrillation strategy that involves charging the defibrillator towards the end of every 2 min cycle of CPR in preparation for the pulse check is used.176,177 If the rhythm is VF/pVT a shock is given and CPR resumed. Whether this leads to any benefit is unknown, but it does lead to defibrillator charging for non-shockable rhythms. • Restart chest compressions immediately after the defibrillation attempt. Minimise interruptions to chest compressions. When using a manual defibrillator it is possible to reduce the pause between stopping and restarting of chest compressions to less than five seconds. • Continue resuscitation until the resuscitation team arrives or the patient shows signs of life. Follow the voice prompts if using an AED. • Once resuscitation is underway, and if there are sufficient staff present, prepare intravenous cannulae and drugs likely to be used by the resuscitation team (e.g. adrenaline). • Identify one person to be responsible for handover to the resuscitation team leader. Use a structured communication tool for handover (e.g. SBAR, RSVP).178,179 Locate the patient’s records. • The quality of chest compressions during in-hospital CPR is frequently sub-optimal.180,181 The importance of uninterrupted chest compressions cannot be over emphasised. Even short interruptions to chest compressions are disastrous for outcome and every effort must be made to ensure that continuous, effective chest compression is maintained throughout the resuscitation attempt. Chest compressions should commence at the beginning of a resuscitation attempt and continue uninterrupted unless they are paused briefly for a specific intervention (e.g. rhythm K.G. Monsieurs et al. / Resuscitation 95 (2015) 1–80 17 check). Most interventions can be performed without interruptions to chest compressions. The team leader should monitor the quality of CPR and alternate CPR providers if the quality of CPR is poor. • Continuous EtCO2 monitoring during CPR can be used to indicate the quality of CPR, and a rise in EtCO2 can be an indicator of ROSC during chest compressions.174,182–184 • If possible, the person providing chest compressions should be changed every 2 min, but without pauses in chest compressions. ALS treatment algorithm Although the ALS cardiac arrest algorithm (Fig. 1.7) is applicable to all cardiac arrests, additional interventions may be indicated for cardiac arrest caused by special circumstances (see Section 4).3 The interventions that unquestionably contribute to improved survival after cardiac arrest are prompt and effective bystander basic life support (BLS), uninterrupted, high-quality chest compressions and early defibrillation for VF/pVT. The use of adrenaline has been shown to increase ROSC but not survival to discharge. Furthermore there is a possibility that it causes worse longterm neurological survival. Similarly, the evidence to support the use of advanced airway interventions during ALS remains limited.175,185–192 Thus, although drugs and advanced airways are still included among ALS interventions, they are of secondary importance to early defibrillation and high-quality, uninterrupted chest compressions. As with previous guidelines, the ALS algorithm distinguishes between shockable and non-shockable rhythms. Each cycle is broadly similar, with a total of 2 min of CPR being given before assessing the rhythm and where indicated, feeling for a pulse. Adrenaline 1 mg is injected every 3–5 min until ROSC is achieved – the timing of the initial dose of adrenaline is described below. In VF/pVT, a single dose of amiodarone 300 mg is indicated after a total of three shocks and a further dose of 150 mg can be considered after five shocks. The optimal CPR cycle time is not known and algorithms for longer cycles (3 min) exist which include different timings for adrenaline doses.193 Shockable rhythms (ventricular fibrillation/pulseless ventricular tachycardia) Having confirmed cardiac arrest, summon help (including the request for a defibrillator) and start CPR, beginning with chest compressions, with a compression: ventilation (CV) ratio of 30:2. When the defibrillator arrives, continue chest compressions while applying the defibrillation electrodes. Identify the rhythm and treat according to the ALS algorithm. • If VF/pVT is confirmed, charge the defibrillator while another rescuer continues chest compressions. Once the defibrillator is charged, pause the chest compressions, quickly ensure that all rescuers are clear of the patient and then give one shock. • Defibrillation shock energy levels are unchanged from the 2010 guidelines.194 For biphasic waveforms, use an initial shock energy of at least 150 J. With manual defibrillators it is appropriate to consider escalating the shock energy if feasible, after a failed shock and for patients where refibrillation occurs.195,196 • Minimise the delay between stopping chest compressions and delivery of the shock (the preshock pause); even a 5–10 s delay will reduce the chances of the shock being successful.84,85,197,198 • Without pausing to reassess the rhythm or feel for a pulse, resume CPR (CV ratio 30:2) immediately after the shock, starting with chest compressions to limit the post-shock pause and the total peri-shock pause.84,85 • Continue CPR for 2 min, then pause briefly to assess the rhythm; if still VF/pVT, give a second shock (150–360 J biphasic). Without pausing to reassess the rhythm or feel for a pulse, resume CPR (CV ratio 30:2) immediately after the shock, starting with chest compressions. • Continue CPR for 2 min, then pause briefly to assess the rhythm; if still VF/pVT, give a third shock (150–360 J biphasic). Without reassessing the rhythm or feeling for a pulse, resume CPR (CV ratio 30:2) immediately after the shock, starting with chest com- pressions. • If IV/IO access has been obtained, during the next 2 min of CPR give adrenaline 1 mg and amiodarone 300 mg.199 • The use of waveform capnography may enable ROSC to be detected without pausing chest compressions and may be used as a way of avoiding a bolus injection of adrenaline after ROSC has been achieved. Several human studies have shown that there is a significant increase in EtCO2 when ROSC occurs.174,182–184,200,201 If ROSC is suspected during CPR withhold adrenaline. Give adrenaline if cardiac arrest is confirmed at the next rhythm check. • If ROSC has not been achieved with this 3rd shock, the adrenaline may improve myocardial blood flow and increase the chance of successful defibrillation with the next shock. • Timing of adrenaline dosing can cause confusion amongst ALS providers and this aspect needs to be emphasised during training.202 Training should emphasise that giving drugs must not lead to interruptions in CPR and delay interventions such as defibrillation. Human data suggests drugs can be given without affecting the quality of CPR.186 • After each 2-min cycle of CPR, if the rhythm changes to asystole or PEA, see ‘non-shockable rhythms’ below. If a non-shockable rhythm is present and the rhythm is organised (complexes appear regular or narrow), try to feel a pulse. Ensure that rhythm checks are brief, and pulse checks are undertaken only if an organised rhythm is observed. If there is any doubt about the presence of a pulse in the presence of an organised rhythm, immediately resume CPR. If ROSC has been achieved, begin post-resuscitation care. During treatment of VF/pVT, healthcare providers must practice efficient coordination between CPR and shock delivery whether using a manual defibrillator or an AED. Reduction in the peri-shock pause (the interval between stopping compressions to resuming compressions after shock delivery) by even a few seconds can increase the probability of shock success.84,85,197,198 Highquality CPR may improve the amplitude and frequency of the VF and improve the chance of successful defibrillation to a perfusing rhythm.203–205 Regardless of the arrest rhythm, after the initial adrenaline dose has been given, give further doses of adrenaline 1 mg every 3–5 min until ROSC is achieved; in practice, this will be about once every two cycles of the algorithm. If signs of life return during CPR (purposeful movement, normal breathing or coughing), or there is an increase in EtCO2, check the monitor; if an organised rhythm is present, check for a pulse. If a pulse is palpable, start post-resuscitation care. If no pulse is present, continue CPR. Witnessed, monitored VF/pVT. If a patient has a monitored and witnessed cardiac arrest in the catheter laboratory, coronary care unit, a critical care area or whilst monitored after cardiac surgery, and a manual defibrillator is rapidly available: • Confirm cardiac arrest and shout for help. • If the initial rhythm is VF/pVT, give up to three quick successive (stacked) shocks. • Rapidly check for a rhythm change and, if appropriate, ROSC after each defibrillation attempt. • Start chest compressions and continue CPR for 2 min if the third shock is unsuccessful. 18 K.G. Monsieurs et al. / Resuscitation 95 (2015) 1–80 Fig. 1.7. Advanced Life Support algorithm. CPR – cardiopulmonary resuscitation; VF/Pulseless VT – ventricular fibrillation/pulseless ventricular tachycardia; PEA – pulseless electrical activity; ABCDE – Airway, Breathing Circulation, Disability, Exposure; SaO2 – oxygen saturation; PaCO2 – partial pressure carbon dioxide in arterial blood; ECG – electrocardiogram. K.G. Monsieurs et al. / Resuscitation 95 (2015) 1–80 19 This three-shock strategy may also be considered for an initial, witnessed VF/pVT cardiac arrest if the patient is already connected to a manual defibrillator. Although there are no data supporting a three-shock strategy in any of these circumstances, it is unlikely that chest compressions will improve the already very high chance of ROSC when defibrillation occurs early in the electrical phase, immediately after onset of VF. Airway and ventilation. During the treatment of persistent VF, ensure good-quality chest compressions between defibrillation attempts. Consider reversible causes (4 Hs and 4 Ts) and, if identified, correct them. Tracheal intubation provides the most reliable airway, but should be attempted only if the healthcare provider is properly trained and has regular, ongoing experience with the technique. Tracheal intubation must not delay defibrillation attempts. Personnel skilled in advanced airway management should attempt laryngoscopy and intubation without stopping chest compressions; a brief pause in chest compressions may be required as the tube is passed through the vocal cords, but this pause should be less than 5 s. Alternatively, to avoid any interruptions in chest compressions, the intubation attempt may be deferred until ROSC. No RCTs have shown that tracheal intubation increases survival after cardiac arrest. After intubation, confirm correct tube position and secure it adequately. Ventilate the lungs at 10 breaths min−1; do not hyperventilate the patient. Once the patient’s trachea has been intubated, continue chest compressions, at a rate of 100–120 min−1 without pausing during ventilation. In the absence of personnel skilled in tracheal intubation, a supraglottic airway (SGA) (e.g. laryngeal mask airway, laryngeal tube or i-gel) is an acceptable alternative. Once a SGA has been inserted, attempt to deliver continuous chest compressions, uninterrupted by ventilation.206 If excessive gas leakage causes inadequate ventilation of the patient’s lungs, chest compressions will have to be interrupted to enable ventilation (using a CV ratio of 30:2). Intravenous access and drugs. Establish intravenous access if this has not already been achieved. Peripheral venous cannulation is quicker, easier to perform and safer than central venous cannulation. Drugs injected peripherally must be followed by a flush of at least 20 ml of fluid and elevation of the extremity for 10–20 s to facilitate drug delivery to the central circulation. If intravenous access is difficult or impossible, consider the IO route. This is now established as an effective route in adults.207–210 Intraosseous injection of drugs achieves adequate plasma concentrations in a time comparable with injection through a vein.211,212 Non-shockable rhythms (PEA and asystole) Pulseless electrical activity (PEA) is defined as cardiac arrest in the presence of electrical activity (other than ventricular tachyarrhythmia) that would normally be associated with a palpable pulse.213 Survival following cardiac arrest with asystole or PEA is unlikely unless a reversible cause can be found and treated effec- tively. If the initial monitored rhythm is PEA or asystole, start CPR 30:2. If asystole is displayed, without stopping CPR, check that the leads are attached correctly. Once an advanced airway has been sited, continue chest compressions without pausing during ventilation. After 2 min of CPR, recheck the rhythm. If asystole is present, resume CPR immediately. If an organised rhythm is present, attempt to palpate a pulse. If no pulse is present (or if there is any doubt about the presence of a pulse), continue CPR. Give adrenaline 1 mg as soon as venous or intraosseous access is achieved, and repeat every alternate CPR cycle (i.e. about every 3–5 min). If a pulse is present, begin post-resuscitation care. If signs of life return during CPR, check the rhythm and check for a pulse. If ROSC is suspected during CPR withhold adrenaline and continue CPR. Give adrenaline if cardiac arrest is confirmed at the next rhythm check. Whenever a diagnosis of asystole is made, check the ECG carefully for the presence of P waves, because this may respond to cardiac pacing. There is no benefit in attempting to pace true asystole. In addition, if there is doubt about whether the rhythm is asystole or extremely fine VF, do not attempt defibrillation; instead, continue chest compressions and ventilation. Continuing highquality CPR however may improve the amplitude and frequency of the VF and improve the chance of successful defibrillation to a perfusing rhythm.203–205 The optimal CPR time between rhythm checks may vary according to the cardiac arrest rhythm and whether it is the first or subsequent loop.214 Based on expert consensus, for the treatment of asystole or PEA, following a 2-min cycle of CPR, if the rhythm has changed to VF, follow the algorithm for shockable rhythms. Otherwise, continue CPR and give adrenaline every 3–5 min following the failure to detect a palpable pulse with the pulse check. If VF is identified on the monitor midway through a 2-min cycle of CPR, complete the cycle of CPR before formal rhythm and shock delivery if appropriate – this strategy will minimise interruptions in chest compressions. Potentially reversible causes Potential causes or aggravating factors for which specific treatment exists must be considered during any cardiac arrest. For ease of memory, these are divided into two groups of four, based upon their initial letter: either H or T. More details on many of these conditions are covered in Section 4 (Special Circumstances).3 Use of ultrasound imaging during advanced life support. Several studies have examined the use of ultrasound during cardiac arrest to detect potentially reversible causes.215–217 Although no studies have shown that use of this imaging modality improves outcome, there is no doubt that echocardiography has the potential to detect reversible causes of cardiac arrest. The integration of ultrasound into advanced life support requires considerable training if interruptions to chest compressions are to be minimised. Monitoring during advanced life support There are several methods and emerging technologies to monitor the patient during CPR and potentially help guide ALS interventions. These include: • Clinical signs such as breathing efforts, movements and eye opening can occur during CPR. These can indicate ROSC and require verification by a rhythm and pulse check, but can also occur because CPR can generate a sufficient circulation to restore signs of life including consciousness.218 • The use of CPR feedback or prompt devices during CPR is addressed in Section 2 Basic Life Support.1 The use of CPR feedback or prompt devices during CPR should only be considered as part of a broader system of care that should include comprehensive CPR quality improvement initiatives. 99,219 • Pulse checks when there is an ECG rhythm compatible with an output can be used to identify ROSC, but may not detect pulses in those with low cardiac output states and a low blood pressure.220 The value of attempting to feel arterial pulses during chest compressions to assess the effectiveness of chest compressions is unclear. There are no valves in the inferior vena cava and retrograde blood flow into the venous system can produce femoral vein pulsations.221 Carotid pulsation during CPR 20 K.G. Monsieurs et al. / Resuscitation 95 (2015) 1–80 does not necessarily indicate adequate myocardial or cerebral perfusion. • Monitoring the heart rhythm through pads, paddles or ECG electrodes is a standard part of ALS. Motion artefacts prevent reliable heart rhythm assessment during chest compressions forcing rescuers to stop chest compressions to assess the rhythm, and preventing early recognition of recurrent VF/pVT. Some modern defibrillators have filters that remove artefacts from compressions but there are no human studies showing improvements in patient outcomes from their use. We suggest against the routine use of artefact-filtering algorithms for analysis of ECG rhythm during CPR unless as part of a research programme.18 • The use of waveform capnography during CPR has a greater emphasis in Guidelines 2015 and is addressed in more detail below. • Blood sampling and analysis during CPR can be used to identify potentially reversible causes of cardiac arrest. Avoid finger prick samples in critical illness because they may not be reliable; instead, use samples from veins or arteries. • Blood gas values are difficult to interpret during CPR. During cardiac arrest, arterial gas values may be misleading and bear little relationship to the tissue acid–base state.222 Analysis of central venous blood may provide a better estimation of tissue pH. Central venous oxygen saturation monitoring during ALS is feasible but its role in guiding CPR is not clear. • Invasive arterial pressure monitoring will enable the detection of low blood pressure values when ROSC is achieved. Consider aiming for an aortic diastolic pressure of greater than 25 mmHg during CPR by optimising chest compressions.223 In practice this would mean measuring an arterial diastolic pressure. Although haemodynamic-directed CPR showed some benefit in experimental studies 224–227 there is currently no evidence of improvement in survival with this approach in humans.175 • Ultrasound assessment is addressed above to identify and treat reversible causes of cardiac arrest, and identify low cardiac output states (‘pseudo-PEA’). Its use has been discussed above. • Cerebral oximetry using near-infrared spectroscopy measures regional cerebral oxygen saturation (rSO2) non-invasively.228–230 This remains an emerging technology that is feasible during CPR. Its role in guiding CPR interventions including prognostication during and after CPR is yet to be established.231 Waveform capnography during advanced life support. Waveform capnography enables continuous real-time EtCO2 to be monitored during CPR. During CPR, EtCO2 values are low, reflecting the low cardiac output generated by chest compression. There is currently no evidence that use of waveform capnography during CPR improves patient outcomes, although the prevention of unrecognised oesophageal intubation is clearly beneficial. The role of waveform capnography during CPR includes: • Ensuring tracheal tube placement in the trachea (see below for further details). • Monitoring ventilation rate during CPR and avoiding hyperven- tilation. • Monitoring the quality of chest compressions during CPR. EtCO2 values are associated with compression depth and ventilation rate and a greater depth of chest compression will increase the value.232 Whether this can be used to guide care and improve outcome requires further study.174 • Identifying ROSC during CPR. An increase in EtCO2 during CPR may indicate ROSC and prevent unnecessary and potentially harmful dosing of adrenaline in a patient with ROSC.174,182,200,201 If ROSC is suspected during CPR withhold adrenaline. Give adrenaline if cardiac arrest is confirmed at the next rhythm check. • Prognostication during CPR. Lower EtCO2 values may indicate a poor prognosis and less chance of ROSC;175 however, we recommend that a specific EtCO2 value at any time during CPR should not be used alone to stop CPR efforts. End-tidal CO2 values should be considered only as part of a multi-modal approach to decisionmaking for prognostication during CPR. Extracorporeal Cardiopulmonary Resuscitation (eCPR) Extracorporeal CPR (eCPR) should be considered as a rescue therapy for those patients in whom initial ALS measures are unsuccessful and, or to facilitate specific interventions (e.g. coronary angiography and percutaneous coronary intervention (PCI) or pulmonary thrombectomy for massive pulmonary embolism).233,234 There is an urgent need for randomised studies of eCPR and large eCPR registries to identify the circumstances in which it works best, establish guidelines for its use and identify the benefits, costs and risks of eCPR.235,236 Defibrillation The defibrillation strategy for the ERC Guidelines 2015 has changed little from the former guidelines: • The importance of early, uninterrupted chest compressions remains emphasised throughout these guidelines, together with minimising the duration of pre-shock and post-shock pauses. • Continue chest compressions during defibrillator charging, deliver defibrillation with an interruption in chest compressions of no more than 5 s and immediately resume chest compressions following defibrillation. • Self-adhesive defibrillation pads have a number of advantages over manual paddles and should always be used in preference when they are available. • CPR should be continued while a defibrillator or automated external defibrillator (AED) is retrieved and applied, but defibrillation should not be delayed longer than needed to establish the need for defibrillation and charging. • The use of up to three-stacked shocks may be considered if initial VF/pVT occurs during a witnessed, monitored arrest with a defibrillator immediately available, e.g. cardiac catheteri- sation. • Defibrillation shock energy levels are unchanged from the 2010 guidelines.194 For biphasic waveforms deliver the first shock with an energy of at least 150 J, the second and subsequent shocks at 150–360 J. The shock energy for a particular defibrillator should be based on the manufacturer’s guidance. It is appropriate to consider escalating the shock energy if feasible, after a failed shock and for patients where refibrillation occurs.195,196 Strategies for minimising the pre-shock pause The delay between stopping chest compressions and delivery of the shock (the pre-shock pause) must be kept to an absolute minimum; even 5–10 s delay will reduce the chances of the shock being successful.84,85,87,197,198,237 The pre-shock pause can be reduced to less than 5 s by continuing compressions during charging of the defibrillator and by having an efficient team coordinated by a leader who communicates effectively.176,238 The safety check to avoid rescuer contact with the patient at the moment of defibrillation should be undertaken rapidly but efficiently. The post-shock pause is minimised by resuming chest compressions immediately after shock delivery (see below). The entire process of manual defibrillation K.G. Monsieurs et al. / Resuscitation 95 (2015) 1–80 21 should be achievable with less than a 5 second interruption to chest compressions. Airway management and ventilation The optimal strategy for managing the airway has yet to be determined. Several observational studies have challenged the premise that advanced airway interventions (tracheal intubation or supraglottic airways) improve outcomes.239 The ILCOR ALS Task Force has suggested using either an advanced airway (tracheal intubation or supraglottic airway (SGA)) or a bag-mask for airway management during CPR.175 This very broad recommendation is made because of the total absence of high quality data to indicate which airway strategy is best. In practice a combination of airway techniques will be used stepwise during a resuscitation attempt.240 The best airway, or combination of airway techniques will vary according to patient factors, the phase of the resuscitation attempt (during CPR, after ROSC), and the skills of rescuers.192 Confirmation of correct placement of the tracheal tube Unrecognised oesophageal intubation is the most serious complication of attempted tracheal intubation. Routine use of primary and secondary techniques to confirm correct placement of the tracheal tube should reduce this risk. The ILCOR ALS Task Force recommends using waveform capnography to confirm and continuously monitor the position of a tracheal tube during CPR in addition to clinical assessment (strong recommendation, low quality evidence). Waveform capnography is given a strong recommendation as it may have other potential uses during CPR (e.g. monitoring ventilation rate, assessing quality of CPR). The ILCOR ALS Task Force recommends that if waveform capnography is not available, a non-waveform carbon dioxide detector, oesophageal detector device or ultrasound in addition to clinical assessment is an alternative. Drugs and fluids for cardiac arrest Vasopressors Despite the continued widespread use of adrenaline and the use of vasopressin during resuscitation in some countries, there is no placebo-controlled study that shows that the routine use of any vasopressor during human cardiac arrest increases survival to hospital discharge, although improved short-term survival has been documented.186,187,189 Our current recommendation is to continue the use of adrenaline during CPR as for Guidelines 2010. We have considered the benefit in short-term outcomes (ROSC and admission to hospital) and our uncertainty about the benefit or harm on survival to discharge and neurological outcome given the limitations of the observational studies.175,241,242 We have decided not to change current practice until there is high-quality data on long-term out- comes. A series of randomised controlled trials243–247 demonstrated no difference in outcomes (ROSC, survival to discharge, or neurological outcome) with vasopressin versus adrenaline as a first line vasopressor in cardiac arrest. Other studies comparing adrenaline alone or in combination with vasopressin also demonstrated no difference in ROSC, survival to discharge or neurological outcome.248–250 We suggest vasopressin should not be used in cardiac arrest instead of adrenaline. Those healthcare professionals working in systems that already use vasopressin may continue to do so because there is no evidence of harm from using vasopressin when compared to adrenaline.175 Anti-arrhythmics As with vasopressors, the evidence that anti-arrhythmic drugs are of benefit in cardiac arrest is limited. No anti-arrhythmic drug given during human cardiac arrest has been shown to increase survival to hospital discharge, although amiodarone has been shown to increase survival to hospital admission.251,252 Despite the lack of human long-term outcome data, the balance of evidence is in favour of the use anti-arrhythmic drugs for the management of arrhythmias in cardiac arrest. Following three initial shocks, amiodarone in shock-refractory VF improves the short-term outcome of survival to hospital admission compared with placebo251 or lidocaine.252 Amiodarone also appears to improve the response to defibrillation when given to humans or animals with VF or haemodynamically unstable ventricular tachycardia.253–257 There is no evidence to indicate the optimal time at which amiodarone should be given when using a single-shock strategy. In the clinical studies to date, the amiodarone was given if VF/pVT persisted after at least three shocks. For this reason, and in the absence of any other data, amiodarone 300 mg is recommended if VF/pVT persists after three shocks. Lidocaine is recommended for use during ALS when amiodarone is unavailable.252 Do not use magnesium routinely for the treatment of cardiac arrest. Other drug therapy Do not give sodium bicarbonate routinely during cardiac arrest and CPR or after ROSC. Consider sodium bicarbonate for lifethreatening hyperkalaemia, for cardiac arrest associated with hyperkalaemia and for tricyclic overdose. Fibrinolytic therapy should not be used routinely in cardiac arrest. Consider fibrinolytic therapy when cardiac arrest is caused by proven or suspected acute pulmonary embolism. Following fibrinolysis during CPR for acute pulmonary embolism, survival and good neurological outcome have been reported in cases requiring in excess of 60 min of CPR. If a fibrinolytic drug is given in these circumstances, consider performing CPR for at least 60–90 min before termination of resuscitation attempts.258–260 Ongoing CPR is not a contraindication to fibrinolysis. Intravenous fluids Hypovolaemia is a potentially reversible cause of cardiac arrest. Infuse fluids rapidly if hypovolaemia is suspected. In the initial stages of resuscitation there are no clear advantages to using colloid, so use balanced crystalloid solutions such as Hartmann’s solution or 0.9% sodium chloride. Avoid dextrose, which is redistributed away from the intravascular space rapidly and causes hyperglycaemia, and may worsen neurological outcome after cardiac arrest.261 CPR techniques and devices Although manual chest compressions are often performed very poorly,262–264 no adjunct has consistently been shown to be superior to conventional manual CPR. Mechanical chest compression devices Since Guidelines 2010 there have been three large RCTs enrolling 7582 patients that have shown no clear advantage from the routine use of automated mechanical chest compression devices for OHCA.36,265,266 We suggest that automated mechanical chest compression devices are not used routinely to replace manual chest compressions. We suggest that automated mechanical chest compression devices are a reasonable alternative to high-quality manual chest compressions in situations where sustained highquality manual chest compressions are impractical or compromise provider safety, such as CPR in a moving ambulance, prolonged CPR 22 K.G. Monsieurs et al. / Resuscitation 95 (2015) 1–80 (e.g. hypothermic arrest), and CPR during certain procedures (e.g. coronary angiography or preparation for extracorporeal CPR.175 Interruptions to CPR during device deployment should be avoided. Healthcare personnel who use mechanical CPR should do so only within a structured, monitored programme, which should include comprehensive competency-based training and regular opportunities to refresh skills. Impedance threshold device (ITD) An RCT of the ITD with standard CPR compared to standard CPR alone with 8718 OHCA patients failed to show any benefit with ITD use in terms of survival and neurological outcome.267 We therefore recommend that the ITD is not used routinely with standard CPR. Two RCTs did not show a benefit in terms of survival to hospital discharge of the ITD with active compression decompression CPR when compared with active compression decompression CPR alone.268,269 Results of a large trial of a combination of ITD with active compression decompression CPR (ACD CPR) compared to standard CPR were reported in two publications.270,271 There was no difference for survival to discharge and neurologically favourable survival at 12 months, and after consideration of the number needed to treat a decision was made not to recommend the routine use of the ITD and ACD.175 Peri-arrest arrhythmias The correct identification and treatment of arrhythmias in the critically ill patient may prevent cardiac arrest from occurring or reoccurring after successful initial resuscitation. The initial assessment and treatment of a patient with an arrhythmia should follow the ABCDE approach. The assessment and treatment of all arrhythmias addresses two factors: the condition of the patient (stable versus unstable), and the nature of the arrhythmia. Anti-arrhythmic drugs are slower in onset and less reliable than electrical cardioversion in converting a tachycardia to sinus rhythm; thus, drugs tend to be reserved for stable patients without adverse signs, and electrical cardioversion is usually the preferred treatment for the unstable patient displaying adverse signs. Algorithms for the treatment of tachycardia and bradycardia are unchanged from 2010 and are show in Figs. 1.8 and 1.9. The presence or absence of adverse signs or symptoms will dictate the appropriate treatment for most arrhythmias. The following adverse factors indicate a patient who is unstable because of the arrhythmia. 1. Shock – this is seen as pallor, sweating, cold and clammy extremities (increased sympathetic activity), impaired consciousness (reduced cerebral blood flow), and hypotension (e.g. systolic blood pressure <90 mmHg). 2. Syncope – loss of consciousness, which occurs as a consequence of reduced cerebral blood flow 3. Heart failure – arrhythmias compromise myocardial performance by reducing coronary artery blood flow. In acute situations this is manifested by pulmonary oedema (failure of the left ventricle) and/or raised jugular venous pressure, and hepatic engorgement (failure of the right ventricle). 4. Myocardial ischaemia – this occurs when myocardial oxygen consumption exceeds delivery. Myocardial ischaemia may present with chest pain (angina) or may occur without pain as an isolated finding on the 12 lead ECG (silent ischaemia). The presence of myocardial ischaemia is especially important if there is underlying coronary artery disease or structural heart disease because it may cause further life-threatening complications including cardiac arrest. Having determined the rhythm and the presence or absence of adverse signs, the options for immediate treatment are categorised as: • Electrical (cardioversion, pacing). • Pharmacological (anti-arrhythmic (and other) drugs). Cardiac arrest in special circumstances Special causes Hypoxia Cardiac arrest caused by hypoxaemia is usually a consequence of asphyxia, which accounts for most of the non-cardiac causes of cardiac arrest. Survival after cardiac arrest from asphyxia is rare and most survivors sustain severe neurological injury. Those who are unconscious but have not progressed to a cardiac arrest are much more likely to make a good neurological recovery.272,273 Hypo-/hyperkalaemia and other electrolyte disorders Electrolyte abnormalities can cause cardiac arrhythmias or cardiac arrest. Life-threatening arrhythmias are associated most commonly with potassium disorders, particularly hyperkalaemia. Hypothermia (accidental) Accidental hypothermia is defined as an involuntary drop of the body core temperature <35 ◦C. Cooling of the human body decreases cellular oxygen consumption by about 6% per 1 ◦C decrease in core temperature.274 At 18 ◦C the brain can tolerate cardiac arrest for up to 10 times longer than at 37 ◦C. This results in hypothermia exerting a protective effect on the brain and heart,275 and intact neurological recovery may be possible even after prolonged cardiac arrest if deep hypothermia develops before asphyxia. If an ECLS centre is not available, rewarming may be attempted in hospital using a combination of external and internal rewarming techniques (e.g. forced warm air, warm infusions, forced peritoneal lavage).276 Hyperthermia Hyperthermia occurs when the body’s ability to thermoregulate fails and core temperature exceeds that normally maintained by homeostatic mechanisms. Hyperthermia is a continuum of heat-related conditions, starting with heat stress, progressing to heat exhaustion, heat stroke and finally multiple organ dysfunction and cardiac arrest.277 The mainstay of treatment is supportive therapy and rapidly cooling the patient.278–280 Start cooling in the prehospital setting if possible. Aim to rapidly reduce the core temperature to approximately 39 ◦C. If cardiac arrest occurs, follow standard guidelines and continue cooling the patient. Use the same cooling techniques as for targeted temperature management after cardiac arrest Hypovolaemia Hypovolaemia is a potentially treatable cause of cardiac arrest that usually results from a reduced intravascular volume (i.e. haemorrhage), but relative hypovolaemia may also occur in patients with severe vasodilation (e.g. anaphylaxis, sepsis). Depending on the suspected cause, initiate volume therapy with warmed blood products and/or crystalloids, in order to rapidly restore intravascular volume. At the same time, initiate immediate intervention to control haemorrhage, e.g. surgery, endoscopy, endovascular techniques,281 or treat the primary cause (e.g. anaphylactic shock). K.G. Monsieurs et al. / Resuscitation 95 (2015) 1–80 23 Fig. 1.8. Tachycardia algorithm. ABCDE – Airway, Breathing Circulation, Disability, Exposure; IV – intravenous; SpO2 – oxygen saturation measured by pulse oximetry; BP – blood pressure; ECG – electrocardiogram; DC – direct current; AF – atrial fibrillation; VT – ventricular tachycardia; SVT – supraventricular tachycardia; PSVT – paroxysmal supraventricular tachycardia. Anaphylaxis. Anaphylaxis is a severe, life-threatening, generalised or systemic hypersensitivity reaction. This is characterised by rapidly developing life-threatening airway and/or breathing and/or circulation problems usually associated with skin and mucosal changes.282–285 Adrenaline is the most important drug for the treatment of anaphylaxis.286,287 The treatment algorithm for anaphylaxis, including the correct doses for adrenaline, is shown in Fig. 1.10. Adrenaline is most effective when given early after the onset of the reaction,288 and adverse effects are extremely rare with correct IM doses. Repeat the IM adrenaline dose if there is no improvement in the patient’s condition within 5 min. IV adrenaline should only be used by those experienced in the use and titration of vasopressors in their normal clinical practice. Traumatic cardiac arrest. Traumatic cardiac arrest (TCA) carries a very high mortality, but in those where ROSC can be achieved, neurological outcome in survivors appears to be much better than in other causes of cardiac arrest.289,290 It is vital that a medical cardiac arrest is not misdiagnosed as a TCA as it must be treated with the universal ALS algorithm. In cardiac arrest caused by hypovolaemia, cardiac tamponade or tension pneumothorax, chest compressions are unlikely to be as effective as in normovolaemic cardiac arrest.291,292 For this reason, chest compressions take a lower priority than the immediate treatment of reversible causes, e.g. thoracotomy, controlling haemorrhage etc. (Fig. 1.11) Tension pneumothorax The incidence of tension pneumothorax is approximately 5% in major trauma patients treated in the prehospital setting (13% of 24 K.G. Monsieurs et al. / Resuscitation 95 (2015) 1–80 Fig. 1.9. Bradycardia algorithm. ABCDE – Airway, Breathing Circulation, Disability, Exposure; IV – intravenous; SpO2 – oxygen saturation measured by pulse oximetry; BP – blood pressure; ECG – electrocardiogram; AV – atrioventricular. those developing TCA).293–295 Needle chest decompression is rapid and within the skill set of most ambulance personnel but is of limited value.296,297 Simple thoracostomy is easy to perform and used routinely by several prehospital physician services.298,299 This consists of the first stage of standard chest tube insertion – a simple incision and rapid dissection into the pleural space in the positive pressure ventilated patient Tamponade (cardiac) The mortality after cardiac tamponade is high and immediate decompression of the pericardium is required to give any chance of survival. If thoracotomy is not possible, consider ultrasound-guided pericardiocentesis to treat cardiac arrest associated with suspected traumatic or non-traumatic cardiac tamponade. Non-image guided pericardiocentesis is an alternative, only if ultrasound is not avail- able. Thrombosis Pulmonary embolism. Cardiac arrest from acute pulmonary embolism is the most serious clinical presentation of venous thromboembolism.300 The reported incidence of cardiac arrest caused by pulmonary embolism is 2–9% of all OHCAs,183,301–303 and 5–6% of all in-hospital cardiac arrests.304,305 Diagnosis of acute pulmonary embolism during cardiac arrest is difficult. Clinical history and assessment, capnography and echocardiography (if available) can all assist in the diagnosis of acute pulmonary embolism during CPR with varying degrees of specificity and sensitivity. Consider administration of fibrinolytic therapy when acute pulmonary embolism is a known or suspected cause of cardiac arrest. Ongoing CPR is not a contraindication to fibrinolysis. The potential benefit of fibrinolysis in terms of improved survival outweighs potential risks in a location where no alternative exists, e.g. in the prehospital setting.258 Once a fibrinolytic drug is administered, continue CPR for at least 60–90 min before terminating resuscitation attempts.258,259 Coronary thrombosis. Although proper diagnosis of the cause of cardiac arrest may be difficult in a patient already in cardiac arrest, if the initial rhythm is VF it is most likely that the cause is coronary artery disease with an occluded large coronary vessel. In these cases, transport with ongoing CPR and immediate access to the catheterisation laboratory may be considered if a prehospital and in-hospital infrastructure is available with teams experienced in mechanical haemodynamic support and primary percutaneous coronary intervention (PPCI) with ongoing CPR. A decision to transport with ongoing CPR should take into consideration a realistic chance of survival (e.g. witnessed cardiac arrest with initial shockable rhythm (VF/pVT) and bystander CPR). Intermittent ROSC also strongly favours a decision to transport.306 Toxins Overall, poisoning rarely causes cardiac arrest or death.307 There are few specific therapeutic measures for poisoning that improve outcomes: decontamination, enhancing elimination, and the use of specific antidotes.308–310 The preferred method of gastrointestinal decontamination in patients with an intact or protected airway is activated charcoal. It is most effective if given within 1 h of ingestion.311 Special environments Perioperative cardiac arrest The commonest cause of anaesthesia-related cardiac arrest involves airway management.312,313 Cardiac arrest caused by bleeding had the highest mortality in non-cardiac surgery, with only 10.3% of these patients surviving to hospital discharge.314 Patients in the operating room are normally fully monitored and, as such, there should be little or no delay in diagnosing cardiac arrest. Cardiac arrest following cardiac surgery Cardiac arrest following major cardiac surgery is relatively common in the immediate post-operative phase, with a reported incidence of 0.7–8%.315,316 Emergency resternotomy is an integral part of resuscitation after cardiac surgery, once all other reversible causes have been excluded. Once adequate airway and ventilation has been established, and if three attempts at defibrillation have failed in VF/pVT, undertake resternotomy without delay. Emergency resternotomy is also indicated in asystole or PEA, when other K.G. Monsieurs et al. / Resuscitation 95 (2015) 1–80 25 Fig. 1.10. Anaphylaxis treatment algorithm.282 Reproduced with permission from Elsevier Ireland Ltd. 26 K.G. Monsieurs et al. / Resuscitation 95 (2015) 1–80 Fig. 1.11. Traumatic cardiac arrest algorithm. treatments have failed, and should be performed within 5 min of the cardiac arrest by anyone with appropriate training. Cardiac arrest in a cardiac catheterisation laboratory Cardiac arrest (commonly VF) may occur during percutaneous coronary intervention (PCI) for ST-elevation myocardial infarction (STEMI) or non-STEMI, but it may also be a complication of angiography. In this special setting with immediate response to monitored VF, defibrillation without preceding chest compressions is recommended. If needed for failed defibrillation or immediately recurring VF, immediate defibrillation may be repeated up to two times. If VF persists after the initial three shocks or ROSC not immediately established with certainty, chest compressions and ventilations must be initiated without further delay and a cause for the unresolved problem sought with further coronary angiography. On an angiography table with the image intensifier above the patient, delivering chest compressions with adequate depth and rate is almost impossible and exposes the rescuers to dangerous radiation. Therefore, early transition to the use of a mechanical chest compression device is strongly recommended.317,318 If the problem is not rapidly resolved, very low quality evidence suggests that the use of extracorporeal life support (ECLS) can be considered as K.G. Monsieurs et al. / Resuscitation 95 (2015) 1–80 27 Fig. 1.12. Drowning chain of survival.337 Reproduced with permission from Elsevier Ireland Ltd. a rescue strategy if the infrastructure is available, and probably to be preferred over intra-aortic balloon pump (IABP).319 Cardiac arrest in a dialysis unit Sudden cardiac death is the most common cause of death in haemodialysis patients and is usually preceded by ventricular arrhythmias.320 Hyperkalaemia contributes to 2–5% of deaths amongst haemodialysis patients 321 A shockable rhythm (VF/pVT) is more common in patients undergoing haemodialysis. 320,322,323 Most haemodialysis machine manufacturers recommend disconnection from the dialysis equipment prior to defibrillation.324 Cardiac arrest in transportation vehicles In-flight emergencies aboard airplanes. Cardiac arrest on board has an incidence of 1 per 5–10 million passenger flights. An initial shockable rhythm is present in 25–31% patients,325–328 and the in-flight use of an AED can result in 33–50% survival to hospital discharge.325,328,329 Cardiac arrest in HEMS and air ambulances. Air ambulance services operate either a helicopter emergency medical service (HEMS) or fixed-wing air ambulances that routinely transport critically ill patients. Cardiac arrest may occur in flight, both in patients being transported from an accident site and also critically ill patients being transported between hospital.330,331 If a shockable rhythm (VF/pVT) is recognised in a monitored patient and defibrillation can be accomplished rapidly, immediately give up to three-stacked shocks before starting chest compressions. Mechanical chest compression devices enable delivery of high quality chest compressions in the confined space of an air ambulance and their use should be considered.332,333 If a cardiac arrest during flight is thought to be a possibility, consider fitting the patient within a mechanical chest compression device during packaging before flight.334,335 Cardiac arrest during sports activities The sudden and unexpected collapse, not associated with contact or trauma, of an athlete on the field of play is probably cardiac in origin and requires rapid recognition and effective treatment if the victim is to survive. If there is no immediate response to treatment and there is an organised medical team, consider moving the patient to an area shielded from media and spectators. If the patient is in VF/pVT, delay moving them until after the first three defibrillation attempts (defibrillation is most likely to be successful in the first three shocks). Water rescue and drowning Drowning is a common cause of accidental death.336 The Drowning Chain of Survival 337 describes five critical links for improving survival from drowning (Fig. 1.12). Bystanders play a critical role in initial attempts at rescue and resuscitation.338–340 ILCOR reviewed specific prognostic indicators and noted that submersion durations of less than 10 min were associated with a very high chance of favourable outcome.18 Age, emergency medical services (EMS) response time, fresh or salt water, water temperature, and witness status were not useful for predicting survival. Submersion in ice-cold water may prolong the window of survival and justify extended search and rescue activities.341–343 The BLS sequence in drowning (Fig. 1.13) reflects the critical importance of rapid alleviation of hypoxia. Wilderness and environmental emergencies Difficult terrain and remote areas. Compared to urban areas some terrains will be more difficult to access and are remote from organised medical care. The chances of a good outcome from cardiac arrest may be reduced due to delayed access and prolonged trans- port. Whenever possible, transport the patient with air rescue.344,345 The organisation of the helicopter emergency medical service (HEMS) affects the outcome.346–348 High altitude illness. Given the increasing popularity of travel at altitude, an increasing number of tourists at altitude have Attach AED and follow instructions Give 5 rescue breaths / ventilations supplemented with oxygen if possible Signs of life? Start CPR 30:2 Open airway Shout for help and call emergency services Unresponsive and not breathing normally? Fig. 1.13. Drowning treatment algorithm for rescuers with a duty to respond. 28 K.G. Monsieurs et al. / Resuscitation 95 (2015) 1–80 cardiovascular and metabolic risk factors for cardiac arrest. Resuscitation at high altitude does not differ from standard CPR. With the lower pO2, CPR is more exhausting for the rescuer than at sea level, and the average number of effective chest compressions may decrease within the first minute.349–351 Use mechanical chest compression devices whenever possible. In situations where transport is not possible, and correction of reversible causes is not possible, further resuscitation is futile and CPR should be terminated. Avalanche burial. In Europe and North America together, there are about 150 snow avalanche deaths each year. Fatalities are mainly due to asphyxia, sometimes associated with trauma and hypothermia. Prognostic factors are severity of injury, duration of complete burial, airway patency, core temperature and serum potassium.352 The cut-off criteria for prolonged CPR and extracorporeal rewarming of avalanche victims in cardiac arrest have become more stringent to reduce the number of futile cases treated with extracorporeal life support (ECLS). An algorithm for the management of the buried avalanche victim is shown in Fig. 1.14. Lightning strike and electrical injuries. Electrical injury is a relatively infrequent but potentially devastating multisystem injury with high morbidity and mortality, causing 0.54 deaths per 100,000 people each year. Ensure that any power source is switched off and do not approach the casualty until it is safe. Electrocution from lightning strikes is rare, but worldwide it causes 1000 deaths each year.353 Unconscious patients with linear or punctuate burns (feathering) should be treated as victims of lightning strike.354 Severe burns (thermal or electrical), myocardial necrosis, the extent of central nervous system injury, and secondary multisystem organ failure determine the morbidity and long-term prognosis. Mass casualty incidents Use a triage system to prioritise treatment. The decision to use a mass casualty incident (MCI) triage sieve, and withhold CPR to those with imminent death, (including victims without signs of life), is the responsibility of a medical commander who is usually the most experienced EMS clinician on scene. Training allows fast and correct recognition of those needing life-saving procedures, and reduces the risk of inappropriate care given to futile cases. Special patients Cardiac arrest associated with concomitant diseases Asthma. The majority of asthma-related deaths occur before admission to hospital.355 Cardiac arrest in a person with asthma is often a terminal event after a period of hypoxaemia. Modifications to standard ALS guidelines include considering the need for early tracheal intubation. If dynamic hyperinflation of the lungs is suspected during CPR, compression of the chest while disconnecting tracheal tube may relieve air trapping. Patients with ventricular assist devices. Confirming cardiac arrest in these patients may be difficult. A patient with invasive monitoring should be considered to have arrested if the arterial line reads the same as the central venous pressure (CVP) line. In patients without invasive monitoring, if the patient has no signs of life and is not breathing, then they should be considered to have suffered a cardiac arrest. Patients with an implantable left ventricular assist device (LVAD) should have the same algorithm followed as the algorithm for arrest after cardiac surgery. In pulseless electrical activity (PEA), turn the pacing off and verify there is no underlying VF, which must be treated by defibrillation. External chest compressions should be performed if immediate resuscitative efforts fail. Importantly, the airway and breathing checks should always be performed. It is possible for a patient to have asystole or VF, but still have adequate cerebral blood flow due to adequate and continued pump flow. If the patient is conscious and responding then you will have more time in which to resolve this arrhythmia and external chest compressions will not be needed. Resternotomy should be performed in an established cardiac arrest within 10 days of surgery. Cardiac arrest associated with neurological disease. Cardiac arrest associated with acute neurological disease is relatively uncommon and can occur with subarachnoid haemorrhage, intracerebral haemorrhage, epileptic seizures, and ischaemic stroke.356 Cardiac or respiratory arrest occurs in between 3 and 11% of patents with subarachnoid haemorrhage,357 and the initial rhythm is usually non-shockable. However, patients with subarachnoid haemorrhage may have ECG changes that suggest an acute coronary syndrome.358 Individuals with neurological prodromal symptoms who achieve ROSC may be considered for CT brain scan. Whether this is done before or after coronary angiography will depend on clinical judgement with consideration of the likelihood of a subarachnoid haemorrhage versus an acute coronary syndrome.4 Obesity. In 2014, more than 1.9 billion (39%) adults were overweight, and of these over 600 million (13%) were obese. Traditional cardiovascular risk factors (hypertension, diabetes, lipid profile, prevalent coronary heart disease, heart failure, and left ventricular hypertrophy) are common in obese patients. Obesity is associated with increased risk of sudden cardiac death.359 No changes to the sequence of actions are recommended in resuscitation of obese patients, but delivery of effective CPR may be challenging. Cardiac arrest associated with pregnancy From 20 weeks’ gestation, the uterus can compress both the inferior vena cava (IVC) and aorta, impeding venous return and cardiac output. The hand position for chest compressions may need to be slightly higher on the sternum for patients with advanced pregnancy e.g. third trimester.360 Manually displace the uterus to the left to reduce IVC compression. Add left lateral tilt if this is feasible and ensure the chest remains supported on a firm surface (e.g. in the operating room). Consider the need for an emergency hysterotomy or Caesarean section as soon as a pregnant woman goes into cardiac arrest. The best survival rate for infants over 24–25 weeks’ gestation occurs when delivery of the infant is achieved within 5 min after the mother’s cardiac arrest.361 Elderly people More than 50% of people resuscitated from OHCA are aged 65 years or older.362 No modifications of standard resuscitation protocols are needed when managing aged patients in cardiac arrest. Rescuers, however, should be aware that the risk of both sternal and rib fractures is higher in elderly.363–365 The incidence of CPR-related injuries increases with duration of CPR.365 Post-resuscitation care Successful return of spontaneous circulation (ROSC) is the first step towards the goal of complete recovery from cardiac arrest. The complex pathophysiological processes that occur following whole body ischaemia during cardiac arrest and the subsequent reperfusion response during CPR and following successful resuscitation have been termed the post-cardiac arrest syndrome.366 K.G. Monsieurs et al. / Resuscitation 95 (2015) 1–80 29 Fig. 1.14. Avalanche accident algorithm. 30 K.G. Monsieurs et al. / Resuscitation 95 (2015) 1–80 Fig. 1.15. Post resuscitation care algorithm. SBP – systolic blood pressure; PCI – percutaneous coronary intervention; CTPA – computed tomography pulmonary angiogram; ICU – intensive care unit; MAP – mean arterial pressure; ScvO2 – central venous oxygenation; CO/CI – cardiac output/cardiac index; EEG – electroencephalography; ICD – implanted cardioverter defibrillator. K.G. Monsieurs et al. / Resuscitation 95 (2015) 1–80 31 Depending on the cause of the arrest, and the severity of the post-cardiac arrest syndrome, many patients will require multiple organ support and the treatment they receive during this post-resuscitation period influences significantly the overall outcome and particularly the quality of neurological recovery.367–373 The post-resuscitation care algorithm (Fig. 1.15) outlines some of the key interventions required to optimise outcome for these patients. Post-cardiac arrest syndrome The post-cardiac arrest syndrome comprises post-cardiac arrest brain injury, post-cardiac arrest myocardial dysfunction, the systemic ischaemia/reperfusion response, and the persistent precipitating pathology.366,374,375 The severity of this syndrome will vary with the duration and cause of cardiac arrest. It may not occur at all if the cardiac arrest is brief. Cardiovascular failure accounts for most deaths in the first three days, while brain injury accounts for most of the later deaths.376–378 Withdrawal of life sustaining therapy (WLST) is the most frequent cause of death (approximately 50%) in patients with a prognosticated bad outcome,378,379 emphasising the importance of the prognostication plan (see below). Post-cardiac arrest brain injury may be exacerbated by microcirculatory failure, impaired autoregulation, hypotension, hypercarbia, hypoxaemia, hyperoxaemia, pyrexia, hypoglycaemia, hyperglycaemia and seizures. Significant myocardial dysfunction is common after cardiac arrest but typically starts to recover by 2–3 days, although full recovery may take significantly longer.380–382 The whole body ischaemia/reperfusion of cardiac arrest activates immune and coagulation pathways contributing to multiple organ failure and increasing the risk of infection.383 Thus, the post-cardiac arrest syndrome has many features in common with sepsis, including intravascular volume depletion, vasodilation, endothelial injury and abnormalties of the microcirculation.384–390 Airway and breathing Hypoxaemia and hypercarbia both increase the likelihood of a further cardiac arrest and may contribute to secondary brain injury. Several animal studies indicate that hyperoxaemia early after ROSC causes oxidative stress and harms post-ischaemic neurones.391 Virtually all human data is derived from intensive care unit registries and they have produced conflicting results on the potential impact of hyperoxaemia after resuscitation from cardiac arrest.392 A recent study of air versus supplemental oxygen in ST-elevation myocardial infarction showed that supplemental oxygen therapy increased myocardial injury, recurrent myocardial infarction and major cardiac arrhythmia and was associated with larger infarct size at 6 months.393 Given the evidence of harm after myocardial infarction and the possibility of increased neurological injury after cardiac arrest, as soon as arterial blood oxygen saturation can be monitored reliably (by blood gas analysis and/or pulse oximetry), titrate the inspired oxygen concentration to maintain the arterial blood oxygen saturation in the range of 94–98%. Avoid hypoxaemia, which is also harmful – ensure reliable measurement of arterial oxygen saturation before reducing the inspired oxygen concentration. Consider tracheal intubation, sedation and controlled ventilation in any patient with obtunded cerebral function. After cardiac arrest, hypocapnia induced by hyperventilation causes cerebral ischaemia.394–396 Observational studies using cardiac arrest registries document an association between hypocapnia and poor neurological outcome.397,398 Until prospective data are available, it is reasonable to adjust ventilation to achieve normocarbia and to monitor this using the end-tidal CO2 and arterial blood gas values. Circulation Acute coronary syndrome (ACS) is a frequent cause of outof-hospital cardiac arrest (OHCA): in a recent meta-analysis, the prevalence of an acute coronary artery lesion ranged from 59% to 71% in OHCA patients without an obvious non-cardiac aetiology.399 Many observational studies have shown that emergent cardiac catheterisation laboratory evaluation, including early percutaneous coronary intervention (PCI), is feasible in patients with ROSC after cardiac arrest.400,401 The invasive management (i.e. early coronary angiography followed by immediate PCI if necessary) of these patients, particularly those having prolonged resuscitation and nonspecific ECG changes, has been controversial because of the lack of specific evidence and significant implications on use of resources (including transfer of patients to PCI centres). Percutaneous coronary intervention following ROSC with ST-Elevation Based on available data, emergent cardiac catheterisation laboratory evaluation (and immediate PCI if required) should be performed in adult patients with ROSC after OHCA of suspected cardiac origin with STE on the ECG. This recommendation is based on low quality of evidence from selected populations. Observational studies also indicate that optimal outcomes after OHCA are achieved with a combination of TTM and PCI, which can be included in a standardised post–cardiac arrest protocol as part of an overall strategy to improve neurologically intact survival.401–403 Percutaneous coronary intervention following ROSC without ST-Elevation In contrast to the usual presentation of ACS in non-cardiac arrest patients, the standard tools to assess coronary ischaemia in cardiac arrest patients are less accurate. The sensitivity and specificity of the usual clinical data, ECG and biomarkers to predict an acute coronary artery occlusion as the cause of OHCA are unclear.404–407 Several large observational series showed that absence of STE may also be associated with ACS in patients with ROSC following OHCA.408–411 In these non-STE patients, there are conflicting data from observational studies on the potential benefit of emergent cardiac catheterization laboratory evaluation.410,412,413 It is reasonable to discuss and consider emergent cardiac catheterisation laboratory evaluation after ROSC in patients with the highest risk of a coronary cause for their cardiac arrest. Factors such as patient age, duration of CPR, haemodynamic instability, presenting cardiac rhythm, neurological status upon hospital arrival, and perceived likelihood of cardiac aetiology can influence the decision to undertake the intervention in the acute phase or to delay it until later on in the hospital stay. Indications and timing of computed tomography (CT) scanning Cardiac causes of OHCA have been extensively studied in the last few decades; conversely, little is known about non-cardiac causes. Early identification of a respiratory or neurological cause would enable transfer of the patient to a specialised ICU for optimal care. Improvedknowledgeof prognosisalsoenablesdiscussionaboutthe appropriateness of specific therapies, including TTM. Early identification of a respiratory or neurological cause can be achieved by performing a brain and chest CT-scan at hospital admission, before or after coronary angiography. In the absence of signs or symptoms suggesting a neurological or respiratory cause (e.g. headache, seizures or neurological deficits for neurological causes, shortness of breath or documented hypoxia in patients suffering from 32 K.G. Monsieurs et al. / Resuscitation 95 (2015) 1–80 a known and worsening respiratpry disease) or if there is clinical or ECG evidence of myocardial ischaemia, coronary angiography is undertaken first, followed by CT scan in the absence of causative lesions. Several case series showed that this strategy enables diagnosis of non-cardiac causes of arrest in a substantial proportion of patients.358,414 Haemodynamic management Post-resuscitation myocardial dysfunction causes haemodynamic instability, which manifests as hypotension, low cardiac index and arrhythmias.380,415 Perform early echocardiography in all patients in order to detect and quantify the degree of myocardial dysfunction.381,416 Post-resuscitation myocardial dysfunction often requires inotropic support, at least transiently. Treatment may be guided by blood pressure, heart rate, urine output, rate of plasma lactate clearance, and central venous oxygen saturation. Serial echocardiography may also be used, especially in haemodynamically unstable patients. In the ICU an arterial line for continuous blood pressure monitoring is essential. Similarly to the early goal-directed therapy that is recommended in the treatment of sepsis, 417 although challenged by several recent studies,418–420 a bundle of therapies, including a specific blood pressure target, has been proposed as a treatment strategy after cardiac arrest.370 In the absence of definitive data, target the mean arterial blood pressure to achieve an adequate urine output (1 ml kg−1 h−1) and normal or decreasing plasma lactate values, taking into consideration the patient’s normal blood pressure, the cause of the arrest and the severity of any myocardial dysfunction.366 These targets may vary depending on individual physiology and co-morbid status. Importantly, hypothermia may increase urine output421 and impair lactate clearance.415 Implantable cardioverter defibrillators Consider insertion of an implantable cardioverter defibrillator (ICD) in ischaemic patients with significant left ventricular dysfunction, who have been resuscitated from a ventricular arrhythmia that occurred later than 24–48 h after a primary coronary event.422–424 Disability (optimising neurological recovery) Cerebral perfusion Animal studies show that immediately after ROSC there is a short period of multifocal cerebral no-reflow followed by transient global cerebral hyperaemia lasting 15–30 min.425–427 This is followed by up to 24 h of cerebral hypoperfusion while the cerebral metabolic rate of oxygen gradually recovers. After asphyxial cardiac arrest, brain oedema may occur transiently after ROSC but it is rarely associated with clinically relevant increases in intracranial pressure.428,429 In many patients, autoregulation of cerebral blood flow is impaired (absent or right-shifted) for some time after cardiac arrest, which means that cerebral perfusion varies with cerebral perfusion pressure instead of being linked to neuronal activity.430,431 Thus, after ROSC, maintain mean arterial pressure near the patient’s normal level.12 Sedation Although it has been common practice to sedate and ventilate patients for at least 24 h after ROSC, there are no high-level data to support a defined period of ventilation, sedation and neuromuscular blockade after cardiac arrest. Control of seizures Seizures are common after cardiac arrest and occur in approximately one-third of patients who remain comatose after ROSC. Myoclonus is most common and occurs in 18–25%, the remainder having focal or generalised tonic–clonic seizures or a combination of seizure types.376,432–434 Clinical seizures, including myoclonus may or may not be of epileptic origin. Other motor manifestations could be mistaken for seizures and there are several types of myoclonus, the majority being non-epileptic.435,436 Use intermittent electroencephalography (EEG) to detect epileptic activity in patients with clinical seizure manifestations. Consider continuous EEG to monitor patients with a diagnosed status epilepticus and effects of treatment. Seizures may increase the cerebral metabolic rate437 and have the potential to exacerbate brain injury caused by cardiac arrest: treat with sodium valproate, levetiracetam, phenytoin, benzodiazepines, propofol, or a barbiturate. Myoclonus can be particularly difficult to treat; phenytoin is often ineffective. Propofol is effective to suppress post-anoxic myoclonus.438 Clonazepam, sodium valproate and levetiracetam are antimyoclonic drugs that may be effective in post-anoxic myoclonus.436 Glucose control There is a strong association between high blood glucose after resuscitation from cardiac arrest and poor neurological outcome.261,439,440 Based on the available data, following ROSC maintain the blood glucose at ≤10 mmol l−1 (180 mg dl−1) and avoid hypoglycaemia.441 Do not implement strict glucose control in adult patients with ROSC after cardiac arrest because it increases the risk of hypoglycaemia. Temperature control A period of hyperthermia (hyperpyrexia) is common in the first 48 h after cardiac arrest.261,442–445 Several studies document an association between post-cardiac arrest pyrexia and poor outcomes.261,442,444–447 Although the effect of elevated temperature on outcome is not proven, it seems reasonable to treat hyperthermia occurring after cardiac arrest with antipyretics and to consider active cooling in unconscious patients. Animal and human data indicate that mild induced hypothermia is neuroprotective and improves outcome after a period of global cerebral hypoxia-ischaemia.448,449 All studies of post-cardiac arrest mild induced hypothermia have included only patients in coma. One randomised trial and a pseudo-randomised trial demonstrated improved neurological outcome at hospital discharge or at 6 months in comatose patients after out-of-hospital VF cardiac arrest.450,451 Cooling was initiated within minutes to hours after ROSC and a temperature range of 32–34 ◦C was maintained for 12–24 h. In the Targeted Temperature Management (TTM) trial, 950 allrhythm OHCA patients were randomised to 36 h of temperature control (comprising 28 h at the target temperature followed by slow rewarm) at either 33 ◦C or 36 ◦C.376 Strict protocols were followed for assessing prognosis and for withdrawal of life-sustaining treatment (WLST). There was no difference in the primary outcome – all cause mortality, and neurological outcome at 6 months was also similar (hazard ratio (HR) for mortality at end of trial 1.06, 95% CI 0.89–1.28; relative risk (RR) for death or poor neurological outcome at 6 months 1.02, 95% CI 0.88–1.16). Detailed neurological outcome at 6 months was also similar.452,453 Importantly, patients in both arms of this trial had their temperature well controlled so that fever was prevented in both groups. The term targeted temperature management or temperature control is now preferred over the previous term therapeutic hypothermia. The ALS Task Force of the International Liaison Committee on Resuscitation made several treatment recommendations on targeted temperature management175 and these are reflected in these ERC guidelines: • Maintain a constant, target temperature between 32 ◦C and 36 ◦C for those patients in whom temperature control is used (strong recommendation, moderate-quality evidence). K.G. Monsieurs et al. / Resuscitation 95 (2015) 1–80 33 • Whether certain subpopulations of cardiac arrest patients may benefit from lower (32–34 ◦C) or higher (36 ◦C) temperatures remains unknown, and further research may help elucidate this. • TTM is recommended for adults after OHCA with an initial shockable rhythm who remain unresponsive after ROSC (strong recommendation, low-quality evidence). • TTM is suggested for adults after OHCA with an initial nonshockable rhythm who remain unresponsive after ROSC (weak recommendation, very low-quality evidence). • TTM is suggested for adults after IHCA with any initial rhythm who remain unresponsive after ROSC (weak recommendation, very low-quality evidence). • If targeted temperature management is used, it is suggested that the duration is at least 24 h (as undertaken in the two largest previous RCTs376,450) (weak recommendation, very low-quality evidence). When to control temperature?. Whichever target temperature is selected, active temperature control is required to achieve and maintain the temperature in this range. Prior recommendations suggest that cooling should be initiated as soon as possible after ROSC, but this recommendation was based only on preclinical data and rational conjecture.454 Animal data indicate that earlier cooling after ROSC produces better outcomes.455,456 Observational studies are confounded by the fact that there is an association between patients who cool faster spontaneously and worse neurological outcome.457–459 It is hypothesised that those with the most severe neurological injury are more prone to losing their ability to control body temperature. A randomised trial of prehospital cooling using a rapid infusion of large volumes of cold intravenous fluid immediately after ROSC versus cooling delayed until hospital admission showed increased rates of re-arrest during transport and pulmonary oedema.460 Although uncontrolled prehospital infusion of cold fluid is not recommended, it may still be reasonable to infuse cold intravenous fluid where patients are well monitored and a lower target temperature (e.g. 33 ◦C) is the goal. Early cooling strategies, other than rapid infusion of large volumes of cold intravenous fluid, and cooling during cardiopulmonary resuscitation in the prehospital setting have not been studied adequately. How to control temperature?. As yet, there are no data indicating that any specific cooling technique increases survival when compared with any other cooling technique; however, internal devices enable more precise temperature control compared with external techniques.461,462 Rebound hyperthermia is associated with worse neurological outcome.463,464 Thus, rewarming should be achieved slowly: the optimal rate is not known, but the consensus is currently about 0.25–0.5 ◦C of rewarming per hour.465 Prognostication This section on prognostication has been adapted from the Advisory Statement on Neurological Prognostication in comatose survivors of cardiac arrest,466 written by members of the ERC ALS Working Group and of the Trauma and Emergency Medicine (TEM) Section of the European Society of Intensive Care Medicine (ESICM), in anticipation of the 2015 Guidelines. Hypoxic-ischaemic brain injury is common after resuscitation from cardiac arrest.467 Two thirds of those dying after admission to ICU following out-of-hospital cardiac arrest die from neurological injury; this has been shown both before468 and after376–378 the implementation of target temperature management (TTM) for post-resuscitation care. Most of these deaths are due to active withdrawal of life sustaining treatment (WLST) based on prognostication of a poor neurological outcome.377,378 For this reason, when dealing with patients who are comatose after resuscitation from cardiac arrest minimising the risk of a falsely pessimistic prediction is essential. Ideally, when predicting a poor outcome the false positive rate (FPR) should be zero with the narrowest possible confidence interval (CI). However, most prognostication studies include so few patients that even if the FPR is 0%, the upper limit of the 95% CI is often high.469,470 Moreover, many studies are confounded by self-fulfilling prophecy, which is a bias occurring when the treating physicians are not blinded to the results of the outcome predictor and use it to make a decision on WLST.469,471 Finally, both TTM itself and sedatives or neuromuscular blocking drugs used to maintain it may potentially interfere with prognostication indices, especially those based on clinical examination.472 A multimodal approach to prognostication is essential and includes: clinical examination, electrophysiology, biomarkers and imaging. A careful clinical neurological examination remains the foundation for prognostication of the comatose patient after cardiac arrest.473 Perform a thorough clinical examination daily to detect signs of neurological recovery such as purposeful movements or to identify a clinical picture suggesting that brain death has occurred. The process of brain recovery following global post-anoxic injury is completed within 72 h from arrest in most patients.474,475 However, in patients who have received sedatives ≤12 h before the 72 h post-ROSC neurological assessment, the reliability of clinical examination may be reduced.472 Before decisive assessment is performed, major confounders must be excluded;476,477 apart from sedation and neuromuscular blockade, these include hypothermia, severe hypotension, hypoglycaemia, and metabolic and respiratory derangements. Suspend sedatives and neuromuscular blocking drugs for long enough to avoid interference with clinical examination. Short-acting drugs are preferred whenever possible. When residual sedation/paralysis is suspected, consider using antidotes to reverse the effects of these drugs. The prognostication strategy algorithm (Fig. 1.16) is applicable to all patients who remain comatose with an absent or extensor motor response to pain at ≥72 h from ROSC. Results of earlier prognostic tests are also considered at this time point. Evaluate the most robust predictors first. These predictors have the highest specificity and precision (FPR <5% with 95% CIs <5% in patients treated with controlled temperature) and have been documented in several studies from at least three different groups of investigators. They include bilaterally absent pupillary reflexes at ≥72 h from ROSC and bilaterally absent somatosensory evoked potential (SSEP) N20 wave after rewarming (this last sign can be evaluated at ≥24 h from ROSC in patients who have not been treated with controlled temperature). Based on expert opinion, we suggest combining the absence of pupillary reflexes with those of corneal reflexes for predicting poor outcome at this time point. Ocular reflexes and SSEPs maintain their predictive value irrespective of target temperature.478,479 If none of the signs above is present to predict a poor outcome, a group of less accurate predictors can be evaluated, but the degree of confidence in their prediction will be lower. These have FPR < 5% but wider 95% CIs than the previous predictors, and/or their definition/threshold is inconsistent in prognostication studies. These predictors include the presence of early status myoclonus (within 48 h from ROSC), high values of serum neuron specific enolase (NSE) at 48–72 h after ROSC, an unreactive malignant EEG pattern (burstsuppression, status epilepticus) after rewarming, the presence of a marked reduction of the grey matter to white matter (GM/WM) ratio or sulcal effacement on brain CT within 24 h after ROSC or the presence of diffuse ischaemic changes on brain magnetic resonance imaging (MRI) at 2–5 days after ROSC. Based on expert opinion, we suggest waiting at least 24 h after the first prognostication assessment and confirming unconsciousness with a Glasgow motor score 34 K.G. Monsieurs et al. / Resuscitation 95 (2015) 1–80 Fig. 1.16. Prognostication strategy algorithm. EEG – electroencephalography; NSE – neuron specific enolase; SSEP – somatosensory evoked potentials; ROSC – return of spontaneous circulation; M – Motor score of Glasgow Coma Scale. of 1–2 before using this second set of predictors. We also suggest combining at least two of these predictors for prognostication. No specific NSE threshold for prediction of poor outcome with 0% FPR can be recommended at present. Ideally, every hospital laboratory assessing NSE should create its own normal values and cut-off levels based on the test kit used. Sampling at multiple timepoints is recommended to detect trends in NSE levels and to reduce the risk of false positive results.480 Although the most robust predictors showed no false positives in most studies, none of them singularly predicts poor outcome with absolute certainty. Moreover, those predictors have often been used for WLST decisions, with the risk of a self-fulfilling prophecy. For this reason, we recommend that prognostication should be multimodal whenever possible, even in presence of one of these predictors. Apart from increasing safety, limited evidence also suggests that multimodal prognostication increases sensitivity.481–484 When dealing with an uncertain outcome, clinicians should consider prolonged observation. Absence of clinical improvement over time suggests a worse outcome. Although awakening has been described as late as 25 days after arrest,485–487 most survivors will recover consciousness within one week.376,488–491 In a recent observational study,490 94% of patients awoke within 4.5 days from rewarming and the remaining 6% awoke within ten days. Even those awakening late can still have a good neurological outcome.490 Rehabilitation Although neurological outcome is considered to be good for the majority of cardiac arrest survivors, cognitive and emotional problems and fatigue are common.452,492–494 Long-term cognitive impairments, mostly mild, are present in half of survivors.453,495,496 Mild cognitive problems are often not recognised by health care professionals and cannot be detected with standard outcome scales such as the Cerebral Performance Categories (CPC) or the Mini-Mental State Examination (MMSE).452,497 Both cognitive and emotional problems have significant impact and can affect a patient’s daily functioning, return to work and quality of life.494,498,499 after hospital discharge should be organised systematically and can be provided by a physician or specialised nurse. It should at least include screening for cognitive impairments and for emotional problems, and the provision of information. Organ donation Organ donation should be considered in those who have achieved ROSC and who fulfil criteria for death using neurological criteria.500 In those comatose patients in whom a decision is made to withdraw life-sustaining therapy, organ donation should be considered after circulatory death occurs. Organ donation can also be K.G. Monsieurs et al. / Resuscitation 95 (2015) 1–80 35 considered in individuals where CPR is not successful in achieving ROSC. All decisions concerning organ donation must follow local legal and ethical requirements, as these vary in different settings. Screening for inherited disorders Many sudden death victims have silent structural heart disease, most often coronary artery disease, but also primary arrhythmia syndromes, cardiomyopathies, familial hypercholesterolaemia and premature ischaemic heart disease. Screening for inherited disorders is crucial for primary prevention in relatives as it may enable preventive antiarrhythmic treatment and medical follow- up.154,155,501 Cardiac arrest centres There is wide variability in survival among hospitals caring for patients after resuscitation from cardiac arrest.261,371,502–506 Many studies have reported an association between survival to hospital discharge and transport to a cardiac arrest centre but there is inconsistency in the hospital factors that are most related to patient outcome.368,371,504,507,508 There is also inconsistency in the services that together define a cardiac arrest centre. Most experts agree that such a centre must have a cardiac catheterisation laboratory that is immediately accessible 24/7 and the facility to provide targeted temperature management. Paediatric life support This section of the ERC GL 2015 on Paediatric Life Support includes: • Basic life support • Management of foreign bodies in the airway • Prevention of cardiac arrest • Advanced life support during cardiac arrest • Post-resuscitation care Paediatric basic life support From the ILCOR CoSTR statement on the sequence for manoeuvres in BLS, there was found to be equipoise between the CAB sequence (compression for circulation, airway and breathing) and the ABC sequence (airway, breathing and compression for circulation).509–511 Given that the ABC sequence has become an established and well recognised method for the delivery of CPR to children in Europe, the ERC PLS Writing Group determined that the use of this sequence should continue, particularly as the previous guidelines have led to its instruction to many hundreds of thousands of healthcare providers and lay people. Sequence of actions in basic life support Rescuers who have been taught adult BLS or the chest compression-only sequence and have no specific knowledge of paediatric resuscitation may use this, as the outcome is worse if they do nothing. However, it is better to provide rescue breaths as part of the resuscitation sequence when applied to children as the asphyxial nature of most paediatric cardiac arrests necessitates ventilation as part of effective CPR.119,120 Non-specialists who wish to learn paediatric resuscitation because they have responsibility for children (e.g. teachers, school nurses, lifeguards), should be taught that it is preferable to modify adult BLS and perform five initial breaths followed by 1 min of CPR before they go for help (see adult BLS guidelines). Not breathing normally? 5 rescue breaths 15 chest compressions 2 rescue breaths 15 compressions Call cardiac arrest team or Paediatric ALS team after 1 minute of CPR No signs of life? Open airway Shout for help Unresponsive? Paediatric basic life support Fig. 1.17. Paediatric basic life support algorithm. Basic life support for those with a duty to respond The following sequence is to be followed by those with a duty to respond to paediatric emergencies (usually health professionals) (Fig. 1.17). Although the following sequence describes expired air ventilation, health professionals with a responsibility for treating children will usually have access to, and training in the use of bag mask ventilation (BMV), and these should be used to provide rescue breaths. 1. Ensure the safety of rescuer and child 2. Check the child’s responsiveness • Stimulate the child and ask loudly: Are you all right? 3A. If the child responds by answering, crying or moving: • Leave the child in the position in which you find him (provided he is not in further danger). • Check his condition and call for help. • Reassess him regularly. 3B. If the child does not respond: • Shout for help. • Turn the child carefully on his back. • Open the child’s airway by tilting the head and lifting the chin. ◦ Place your hand on his forehead and gently tilt his head back. ◦ At the same time, with your fingertip(s) under the point of the child’s chin, lift the chin. Do not push on the soft tissues under 36 K.G. Monsieurs et al. / Resuscitation 95 (2015) 1–80 Fig. 1.18. Mouth-to-mouth-and-nose ventilation – infant. the chin as this may obstruct the airway. This is especially important in infants. ◦ If you still have difficulty in opening the airway, try a jaw thrust: place the first two fingers of each hand behind each side of the child’s mandible and push the jaw forward. Have a low threshold for suspecting an injury to the neck; if so, try to open the airway by jaw thrust alone. If jaw thrust alone does not enable adequate airway patency, add head tilt a small amount at a time until the airway is open. 4. Keeping the airway open, look, listen and feel for normal breathing by putting your face close to the child’s face and looking along the chest: • Look for chest movements • Listen at the child’s nose and mouth for breath sounds • Feel for air movement on your cheek. In the first few minutes after a cardiac arrest a child may be taking slow infrequent gasps. Look, listen and feel for no more than 10 s before deciding – if you have any doubt whether breathing is normal, act as if it is not normal: 5A. If the child is breathing normally: • Turn the child on his side into the recovery position (see below). If there is a history of trauma, cervical spine injury should be considered. • Send or go for help – call the emergency services. • Check for continued breathing. 5B. If breathing is not normal or absent: • Carefully remove any obvious airway obstruction. • Give five initial rescue breaths. • While performing the rescue breaths note any gag or cough response to your action. These responses or their absence will form part of your assessment of ‘signs of life’, which will be described later. Rescue breaths for an infant • Ensure a neutral position of the head as an infant’s head is usually flexed when supine, this may require some extension (a rolled towel/blanket under the upper part of the body may help to maintain the position) and a chin lift. • Take a breath and cover the mouth and nose of the infant with your mouth, making sure you have a good seal. If the nose and mouth cannot be covered in the older infant, the rescuer may attempt to seal only the infant’s nose or mouth with his mouth (if the nose is used, close the lips to prevent air escape) (Fig. 1.18). • Blow steadily into the infant’s mouth and nose for about 1 s, sufficient to make the chest visibly rise. Fig. 1.19. Mouth-to-mouth ventilation – child. • Maintain head position and chin lift, take your mouth away from the victim and watch for his chest to fall as air comes out. • Take another breath and repeat this sequence five times. Rescue breaths for a child over 1 year of age • Ensure head tilt and chin lift. • Pinch the soft part of the nose closed with the index finger and thumb of your hand on his forehead. • Allow the mouth to open, but maintain chin lift. • Take a breath and place your lips around the mouth, making sure that you have a good seal (Fig. 1.19). • Blow steadily into the mouth for about 1 s, watching for chest rise. • Maintain head tilt and chin lift, take your mouth away from the victim and watch for his chest to fall as air comes out. • Take another breath and repeat this sequence five times. Identify effectiveness by seeing that the child’s chest has risen and fallen in a similar fashion to the movement produced by a normal breath. For both infants and children, if you have difficulty achieving an effective breath, the airway may be obstructed: • Open the child’s mouth and remove any visible obstruction. Do not perform a blind finger sweep. • Reposition the head. Ensure that there is adequate head tilt and chin lift but also that the neck is not over-extended. • If head tilt and chin lift has not opened the airway, try the jaw thrust method. • Make up to five attempts to achieve effective breaths, if still unsuccessful, move on to chest compressions. 6. Assess the child’s circulation Take no more than 10 s to: Look for signs of life – this includes any movement, coughing or normal breathing (gasps or infrequent, irregular breaths are abnormal). If you check the pulse, ensure that you take no more than 10 s. Pulse check is unreliable and therefore the complete picture of how the patient appears must guide whether BLS is required, i.e. if there are no signs of life, start BLS.40,41 7A. If you are confident that you can detect signs of life within 10 s • Continue rescue breathing, if necessary, until the child starts breathing effectively on his own • Turn the child on his side (into the recovery position, with caution if there is a history of trauma) if he remains unconscious. • Re-assess the child frequently. 7B. If there are no signs of life • Start chest compressions. K.G. Monsieurs et al. / Resuscitation 95 (2015) 1–80 37 Xiphoid process Sternum (lower half) Fig. 1.20. Chest compression – infant. • Combine rescue breathing and chest compressions at a ratio of 15 compressions to 2 ventilations. Chest compressions. For all children, compress the lower half of the sternum. The compression should be sufficient to depress the sternum by at least one third of the anterior-posterior diameter of the chest. Release the pressure completely and repeat at a rate 100–120 min−1. After 15 compressions, tilt the head, lift the chin, and give two effective breaths. Continue compressions and breaths in a ratio of 15:2. Chest compression in infants. The lone rescuer compresses the sternum with the tips of two fingers (Fig. 1.20). If there are two or more rescuers, use the encircling technique. Place both thumbs flat side by side on the lower half of the sternum (as above) with the tips pointing towards the infant’s head. Spread both hands with the fingers together to encircle the lower part of the infant’s rib cage. The fingers should support the infant’s back. For both methods, depress the lower sternum by at least one third the anterior-posterior dimension of the infant’s chest or by 4 cm.512 Chest compression in children over 1 year of age. To avoid compressing the upper abdomen, locate the xiphisternum by finding the angle where the lowest ribs join in the middle. Place the heel of one hand on the sternum one finger’s breadth above this. Lift the fingers to ensure that pressure is not applied onto the child’s ribs. Position yourself above the victim’s chest and, with your arm straight, compress the sternum to at least one third of the anteriorposterior dimension of the chest or by 5 cm (Fig. 1.21).512,513 In larger children or for small rescuers, this is achieved most easily by using both hands, with the rescuer’s fingers interlocked (Fig. 1.22). 8. Do not interrupt resuscitation until: • The child shows signs of life (starts to wake up, to move, opens eyes and to breathe normally). • More healthcare workers arrive and can either assist or take over. • You become exhausted. When to call for assistance It is vital for rescuers to get help as quickly as possible when a child collapses. • When more than one rescuer is available, one starts resuscitation while another rescuer goes for assistance. Fig. 1.21. Chest compression with one hand – child. • If only one rescuer is present, undertake resuscitation for about 1 min or 5 cycles of CPR before going for assistance. To minimise interruption in CPR, it may be possible to carry an infant or small child whilst summoning help. • If you are on your own, witness a child suddenly collapse and you suspect a primary cardiac arrest, call for help first and then start CPR as the child will likely need urgent defibrillation. This is an uncommon situation. Fig. 1.22. Chest compression with two hands – child. 38 K.G. Monsieurs et al. / Resuscitation 95 (2015) 1–80 Table 1.1 Signs of foreign body airway obstruction. General signs of FBAO Witnessed episode Coughing/choking Sudden onset Recent history of playing with/eating small objects Ineffective cough Effective cough Unable to vocalise Crying or verbal response to questions Quiet or silent cough Loud cough Unable to breathe Able to take a breath before coughing Cyanosis Fully responsive Decreasing level of consciousness Automated external defibrillation and basic life support Continue with CPR until the AED arrives. Attach the AED and follow the instructions. For 1–8 year old, use attenuated pads if available, as explained in the section on Adult Basic Life Support and Automated External Defibrillation.1 Recovery position An unconscious child whose airway is clear, and who is breathing normally, should be turned on his side into the recovery position. There are several recovery positions; they all aim to prevent airway obstruction and reduce the likelihood of fluids such as saliva, secretions or vomit from entering into the upper airway. Foreign body airway obstruction (FBAO) Suspect FBAO if the onset was very sudden and there are no other signs of illness; there may be clues to alert the rescuer, e.g. a history of eating or playing with small items immediately before the onset of symptoms (Table 1.1) Back blows, chest thrusts and abdominal thrusts all increase intra-thoracic pressure and can expel foreign bodies from the airway. If one is unsuccessful, try the others in rotation until the object is cleared (Fig. 1.23). The most significant difference from the adult algorithm is that abdominal thrusts should not be used for infants. Although abdominal thrusts have caused injuries in all age groups, the risk is particularly high in infants and very young children. For this reason, the guidelines for the treatment of FBAO are different between infants and children. Recognition of foreign body airway obstruction Active interventions to relieve FBAO are required only when coughing becomes ineffective, but they then need to be commenced rapidly and confidently Relief of FBAO 1. Safety and summoning assistance. The principle of do no harm should be applied, i.e. if the child is able to breathe and cough, even with difficulty, encourage these spontaneous efforts. Do not intervene at this point as this may move the foreign body and worsen the problem, e.g. by causing full airway obstruction. • If the child is coughing effectively, no manoeuvre is necessary. Encourage the child to cough and continue monitoring the child’s condition. • If the child’s coughing is (or is becoming) ineffective, shout for help immediately and determine the child’s conscious level. 2. Conscious child with FBAO. • If the child is still conscious but has absent or ineffective coughing, give back blows. • If back blows do not relieve the FBAO, give chest thrusts to infants or abdominal thrusts to children. These manoeuvres create an artificial cough, increasing intrathoracic pressure and dislodging the foreign body. If back blows fail to dislodge the object, and the child is still conscious, use chest thrusts for infants or abdominal thrusts for children. Do not use abdominal thrusts (Heimlich manoeuvre) in infants. Following the chest or abdominal thrusts, reassess the child. If the object has not been expelled and the victim is still conscious, continue the sequence of back blows and chest (for Paediatric Foreign Body Airway Obstruction Treatment Assess severity Unconscious Open airway 5 breaths Start CPR Conscious 5 back blows 5 thrusts (chest only for infants) (alternative abdominal and chest for child >1 year) Encourage cough Continue to check for deterioration until obstruction relieved Fig. 1.23. Paediatric foreign body airway obstruction algorithm. K.G. Monsieurs et al. / Resuscitation 95 (2015) 1–80 39 infant) or abdominal (for children) thrusts. Call out, or send, for help if it is still not available. Do not leave the child at this stage. If the object is expelled successfully, assess the child’s clinical condition. It is possible that part of the object may remain in the respiratory tract and cause complications. If there is any doubt, seek medical assistance. Abdominal thrusts may cause internal injuries and all victims treated with abdominal thrusts should be examined by a doctor.514 3. Unconscious child with FBAO. If the child with FBAO is, or becomes, unconscious, place him on a firm, flat surface. Call out, or send, for help if it is still not available. Do not leave the child at this stage; proceed as follows. Airway opening. Open the mouth and look for any obvious object. If one is seen, make an attempt to remove it with a single finger sweep. Do not attempt blind or repeated finger sweeps – these could push the object deeper into the pharynx and cause injury. Rescue breaths. Open the airway using a head tilt/chin lift and attempt five rescue breaths. Assess the effectiveness of each breath: if a breath does not make the chest rise, reposition the head before making the next attempt. Chest compressions and CPR. • Attempt five rescue breaths and if there is no response (moving, coughing, spontaneous breaths) proceed to chest compressions without further assessment of the circulation. • Follow the sequence for single rescuer CPR for approximately a minute or 5 cycles of 15 compressions to 2 ventilations before summoning the EMS (if this has not already been done by someone else). • When the airway is opened for attempted delivery of rescue breath, check if the foreign body can be seen in the mouth. • If an object is seen and can be reached, attempt to remove it with a single finger sweep. • If it appears the obstruction has been relieved, open and check the airway as above; deliver rescue breaths if the child is not breathing. • If the child regains consciousness and exhibits spontaneous effective breathing, place him in a safe position on his side (recovery position) and monitor breathing and the level of consciousness whilst awaiting the arrival of the EMS. Paediatric advanced life support Assessment of the seriously ill or injured child – the prevention of cardiopulmonary arrest In children, secondary cardiopulmonary arrests, caused by either respiratory or circulatory failure, are more frequent than primary arrests caused by arrhythmias.147,515–524 So-called asphyxial arrests or respiratory arrests are also more common in young adulthood (e.g. trauma, drowning and poisoning).119,525 As the outcome from cardiopulmonary arrest in children is poor, identifying the preceding stages of circulatory or respiratory failure is a priority as effective early intervention in these stages may be lifesaving. The order of assessment and intervention for any seriously ill child follows the ABCDE principles. • A indicates airway. • B indicates breathing. • C indicates circulation. • D indicates disability. • E indicates exposure. The topics of D and E are beyond the remit of these guidelines but are taught in paediatric life support courses. Summoning a paediatric rapid response team or medical emergency team may reduce the risk of respiratory and/or cardiac arrest in hospitalised children outside the intensive care setting but the evidence is limited on this point as the literature tends not to separate out the team response alone from the other systems in place to identify early deterioration.526–529 Processes to detect the early deterioration are key in reducing the morbidity and mortality of seriously ill and injured children. Specific scores can be used (e.g. the paediatric early warning score, PEWS),530 but there is no evidence that these improve the decision making process, or the clinical outcome.512,531 Diagnosing respiratory failure: assessment of A and B. The assessment of a potentially critically ill child starts with the assessment of airway (A) and breathing (B). The signs of respiratory failure may include: • Respiratory rate outside the normal range for the child’s age – either too fast or too slow.532 • Initially increased work of breathing, which may progress to inadequate/decreased work of breathing as the child tires or compensatory mechanisms fail. • Additional noises such as stridor, wheeze, crackles, grunting, or the loss of breath sounds. • Decreased tidal volume marked by shallow breathing, decreased chest expansion or decreased air entry at auscultation. • Hypoxaemia (without/with supplemental oxygen) generally identified by cyanosis but it is often detectable prior to this by pulse oximetry. There may be associated signs in other organ systems. Even though the primary problem is respiratory, other organ systems will be involved to try to ameliorate the overall physiological dis- turbance. These are detectable in step C of the assessment and include: • Increasing tachycardia (compensatory mechanism to increase tissue oxygen delivery). • Pallor. • Bradycardia (an ominous indicator of the loss of compensatory mechanisms). • Alteration in the level of consciousness (a sign that compensatory mechanisms are failing) owing to poor perfusion of the brain. Diagnosing circulatory failure: assessment of C. Circulatory failure is characterised by a mismatch between the metabolic demand by the tissues, and the delivery of oxygen and nutrients by the circulation.532,533 Signs of circulatory failure might include: • Increased heart rate (bradycardia is an ominous sign of physiological decompensation).532 • Decreased systemic blood pressure. • Decreased peripheral perfusion (prolonged capillary refill time, decreased skin temperature, pale or mottled skin) – signs of increased vascular resistance. • Bounding pulses, vasodilation with widespread erythema may be seen in conditions with decreased vascular resistance. • Weak or absent peripheral pulses. • Decreased intravascular volume. • Decreased urine output. The transition from a compensatory state to decompensation may occur in an unpredictable way. Therefore, the child should be 40 K.G. Monsieurs et al. / Resuscitation 95 (2015) 1–80 monitored, to detect and correct any deterioration in their physiological parameters promptly. Diagnosing cardiopulmonary arrest Signs of cardiopulmonary arrest include: • Unresponsiveness to pain (coma) • Apnoea or gasping respiratory pattern • Absent circulation • Pallor or deep cyanosis Palpation of a pulse is not reliable as the sole determinant of the need for chest compressions.40,169,534,535 In the absence of signs of life, rescuers (lay and professional) should begin CPR unless they are certain that they can feel a central pulse within 10 seconds (infants – brachial or femoral artery; children – carotid or femoral artery). If there is any doubt, start CPR.42,169,170,536 If personnel skilled in echocardiography are available, this investigation may help to detect cardiac activity and potentially treatable causes for the arrest.534 Management of respiratory and circulatory failure Airway and breathing. • Open the airway. • Optimise ventilation. • Ensure adequate oxygenation, start with 100% oxygen. • Establish respiratory monitoring (first line – pulse oximetry/peripheral oxygen saturation – SpO2). • Achieving adequate ventilation and oxygenation – this may require the use of airway adjuncts +/− bag-mask ventilation (BMV), the use of a laryngeal mask airway or other supraglottic airway, securing a definitive airway by tracheal intubation and positive pressure ventilation. • For intubated children, it is standard practice that their end tidal carbon dioxide levels are monitored. End tidal carbon dioxide monitoring can also be used in non-intubated critically ill patients. • Very rarely, a surgical airway may be required. Circulation. • Establish cardiac monitoring (first line – pulse oximetry/SpO2, electrocardiography (ECG) and non-invasive blood pressure (NIBP)). • Secure intravascular access. This may be achieved by peripheral intravenous (IV) or by intraosseous (IO) route. If already in situ, a central intravenous catheter should be used. • Give a fluid bolus (20 ml kg−1) and/or drugs (e.g., inotropes, vasopressors, anti-arrhythmics) to treat circulatory failure due to hypovolaemia, e.g. from fluid loss or maldistribution, as seen in septic shock and anaphylaxis. • Consider carefully the use of fluid bolus in primary cardiac functioning disorders, e.g. myocarditis, cardiomyopathy. • Do not give a fluid bolus in severe febrile illness when circulatory failure is absent.512,537–539 • Isotonic crystalloids are recommended as initial resuscitation fluid in infants and children with any type of shock, including septic shock.512,540–545 • Assess and re-assess the child repeatedly, beginning each time with the airway before proceeding to breathing and then the circulation. Blood gas and lactate measurement may be helpful. • During treatment, capnography, invasive monitoring of arterial blood pressure, blood gas analysis, cardiac output monitoring, echocardiography and central venous oxygen saturation (ScvO2) Table 1.2 Paediatric tracheal tube size in internal diameters (ID) based on age. This is a guide only and tubes one size larger and smaller should always be available. Tracheal tube size can also be estimated from the length of the child’s body, as indicated by resuscitation tapes. Uncuffed Cuffed Premature neonates Gestational age in weeks/10 Not used Full term neonates 3.5 Not usually used Infants 3.5–4.0 3.0–3.5 Child 1–2 years 4.0–4.5 3.5–4.0 Child >2 years Age/4 + 4 Age/4 + 3.5 may be useful to guide the treatment of respiratory and/or circulatory failure.225,226 Whilst the evidence for the use of these techniques is of low quality, the general principles of monitoring and assessing the impact of any interventions and those responses are key in managing seriously ill children. Airway. Open the airway by using basic life support techniques. Oropharyngeal and nasopharyngeal airway adjuncts can help maintain the airway. Supraglottic airways devices (SADs) (including LMA). Although bag-mask ventilation (BMV) remains the recommended first line method for achieving airway control and ventilation in children, the SADs represent a range of acceptable airway devices that may assist providers trained in their use.546,547 Tracheal intubation. Tracheal intubation is the most secure and effective way to establish and maintain the airway. The oral route for tracheal intubation is preferable during resuscitation. In the conscious child, the judicious use of anaesthetics, sedatives and neuromuscular blocking drugs is essential to avoid multiple intubation attempts or intubation failure.548,549 Only skilled and experienced practitioners should perform intubation. Clinical examination and capnography should be used to ensure that the tracheal tube remains secured and vital signs should be monitored.550 Intubation during cardiopulmonary arrest. The child who is in cardiopulmonary arrest does not require sedation or analgesia to be intubated. Appropriate tracheal tube sizes are shown in Table 1.2. A correctly sized cuffed tracheal tube is as safe as an uncuffed tube for infants and children (not for neonates) provided attention is paid to its placement, size and cuff inflation pressure.551–553 As excessive cuff pressure may lead to ischaemic damage to the surrounding laryngeal tissue and stenosis, cuff inflation pressure should be monitored and maintained at less than 25 cm H2O.553 Confirmation of correct tracheal tube placement. Displaced, misplaced or obstructed tubes occur frequently in the intubated child and are associated with an increased risk of death.554,555 No single technique is 100% reliable for distinguishing oesophageal from tracheal intubation. If the child is in cardiopulmonary arrest and exhaled CO2 is not detected despite adequate chest compressions, or if there is any doubt as to the tube position, confirm the placement of the tracheal tube by direct laryngoscopy. After correct placement and confirmation, secure the tracheal tube and reassess its position. Maintain the child’s head in the neutral position as flexion of the head will drive the tube further into the trachea whereas extension may pull it out of the airway.556 Breathing. Oxygenation. Give oxygen at the highest concentration (i.e. 100%) during initial resuscitation. Once the child is stabilised and/or there is ROSC, titrate the fraction of inspired oxygen (FiO2) to achieve normoxaemia, or at least (if arterial blood gas is not available), maintain SpO2 in the range of 94–98%.557,558 K.G. Monsieurs et al. / Resuscitation 95 (2015) 1–80 41 Ventilation. Healthcare providers commonly provide excessive ventilation during CPR and this may be harmful. A simple guide to deliver an appropriate tidal volume is to achieve normal chest wall rise. Use a ratio of 15 chest compressions to 2 ventilations and a compression rate of 100–120 min−1. Once the airway is protected by tracheal intubation, continue positive pressure ventilation at 10 breaths min−1 without interrupting the chest compressions. Take care to ensure that lung inflation is adequate during chest compressions. Once ROSC has been achieved, provide normal ventilation (rate/volume) based on the child’s age, and by monitoring end-tidal CO2 and blood gas values, to achieve a normal arterial carbon dioxide tension (PaCO2) and arterial oxygen levels. Both hypocarbia and hypercarbia are associated with poor outcomes following cardiac arrest.559 This means that the child with ROSC should usually be ventilated at 12–24 breaths min−1, according to their age normal values. Bag mask ventilation. Bag mask ventilation (BMV) is effective and safe for a child requiring assisted ventilation for a short period.560,561 Assess the effectiveness of BMV by observing adequate chest rise, monitoring heart rate and auscultating for breath sounds, and measuring SpO2. Any healthcare provider with a responsibility for treating children must be able to deliver BMV effectively. Monitoring of breathing and ventilation. End-tidal CO2. Monitoring end-tidal CO2 (EtCO2) with a colorimetric detector or capnometer confirms tracheal tube placement in the child weighing more than 2 kg, and may be used in preand in-hospital settings, as well as during any transportation of a child.562–565 A colour change or the presence of a capnographic waveform for more than four ventilated breaths indicates that the tube is in the tracheobronchial tree both in the presence of a perfusing rhythm and during cardiopulmonary arrest. The absence of exhaled CO2 during cardiopulmonary arrest does not guarantee tube misplacement since a low or absent EtCO2 may reflect low or absent pulmonary blood flow.200,566–568 Although an EtCO2 higher than 2 kPa (15 mmHg) may be an indicator of adequate resuscitation, current evidence does not support the use of a threshold EtCO2 value as an indicator for the quality of CPR or for the discontinuation of resuscitation.512 Peripheral pulse oximetry. Clinical evaluation to determine the degree of oxygenation in a child is unreliable; therefore, monitor the child’s peripheral oxygen saturation continuously by pulse oximetry. Pulse oximetry can be unreliable under certain conditions, e.g. if the child is in circulatory failure, in cardiopulmonary arrest or has poor peripheral perfusion. Circulation. Vascular access. Vascular access is essential to enable drugs and fluids to be given, and blood samples obtained. Venous access can be difficult to establish during resuscitation of an infant or child. In critically ill children, if attempts at establishing intravenous (IV) access are unsuccessful after one minute, insert an intra-osseous (IO) needle.208,569 Intraosseous access. Intraosseous (IO) access is a rapid, safe, and effective route to give drugs, fluids and blood products.570,571 The onset of action and time to achieve adequate plasma drug concentrations are similar to that achieved via the central venous route.212,572–574 Bone marrow samples can be used to cross match for blood type or group for chemical analysis575–577 and for blood gas measurement (the values may be comparable to central venous blood gases if no drug has been injected in the cavity).212 Inject large boluses of fluid using manual pressure or a pressure bag.578 Maintain IO access until definitive IV access has been established. Intravenous access and other routes. Central venous lines provide more secure long-term access but, compared with IO or peripheral IV access, offer no advantages during resuscitation.209 The tracheal route for the administration of drugs is no longer recommended.579 Fluids and drugs. Isotonic crystalloids are recommended as the initial resuscitation fluid for infants and children with any type of circulatory failure.580,581 If there are signs that the systemic perfusion is inadequate, give a bolus of 20 ml kg−1 of an isotonic crystalloid even if the systemic blood pressure is normal. Following each bolus, re-assess the child’s clinical state, using the ABCDE system of assessment, to decide whether a further bolus or other treatment is required. In some children, early inotropic or vasopressor support may be needed.582,583 There is growing evidence to prefer the use of balanced crystalloids as these induce less hyperchloraemic acidosis.584–587 In life-threatening hypovolaemic shock, as may be seen in rapid blood loss in trauma, limiting the use of crystalloids in favour of a regime of massive blood transfusion may be required. There are varying regimes of combining plasma, platelets and other blood products in delivering massive blood transfusion,588,589 so the regime used should be according to local protocols. Adrenaline. Adrenaline (epinephrine) plays a central role in the cardiac arrest treatment algorithms for non-shockable and shockable rhythms. For cardiopulmonary resuscitation, the recommended IV/IO dose of adrenaline in children for the first and for subsequent doses is 10 ␮g kg−1. The maximum single dose is 1 mg. If needed, give further doses of adrenaline every 3–5 min. The use of single higher doses of adrenaline (above 10 ␮g kg−1) is not recommended because it does not improve survival or neurological outcome after cardiopulmonary arrest.590–594 Amiodarone for shock-resistant paediatric VF/pulseless VT. Amiodarone can be used to treat paediatric shock-resistant VF/pulseless VT (pVT). It is given after the third shock as a 5 mg kg−1 bolus (and can be repeated following the fifth shock). When treating other cardiac rhythm disturbances, amiodarone must be injected slowly (over 10–20 min) with systemic blood pressure and ECG monitoring to avoid causing hypotension.595 This side effect is less common with the aqueous solution.257 Atropine. Atropine is recommended only for bradycardia caused by increased vagal tone or cholinergic drug toxicity.596–598 The commonly used dose is 20 ␮g kg−1. In bradycardia with poor perfusion unresponsive to ventilation and oxygenation, the first line drug is adrenaline, not atropine. Calcium. Calcium is essential for myocardial function,599 but the routine use of calcium does not improve the outcome from cardiopulmonary arrest.600,601 Calcium is indicated in the presence of hypocalcaemia, calcium channel blocker overdose, hypermagnesaemia and hyperkalaemia.602 Glucose. Data from neonates, children and adults indicate that both hyper- and hypo-glycaemia are associated with poor outcome after cardiopulmonary arrest,603 but it is uncertain if this is causative or merely an association. Check blood or plasma glucose concentration and monitor closely in any ill or injured child, including after cardiac arrest. Do not give glucose-containing fluids during CPR unless hypoglycaemia is present.604 Avoid hyper- and hypoglycaemia following ROSC.605 Magnesium. There is no evidence for giving magnesium routinely during cardiopulmonary arrest.606,607 Magnesium treatment is indicated in the child with documented hypomagnesaemia or with torsade de pointes VT (50 mg kg−1), regardless of the cause.608 Sodium bicarbonate. There is no evidence for giving sodium bicarbonate routinely during cardiopulmonary arrest.609–611 Sodium bicarbonate may be considered for the child with prolonged cardiopulmonary arrest and/or severe metabolic acidosis. Sodium bicarbonate may also be considered in case of 42 K.G. Monsieurs et al. / Resuscitation 95 (2015) 1–80 Fig. 1.24. Paddle positions for defibrillation – child. haemodynamic instability and co-existing hyperkalaemia, or in the management of tricyclic antidepressant drug overdose. Vasopressin–terlipressin. There is currently insufficient evidence to support or refute the use of vasopressin or terlipressin as an alternative to, or in combination with, adrenaline in any cardiac arrest rhythm in adults or children.246,248,249,612–616 Defibrillators Manual defibrillators capable of delivering the full energy requirements from neonates upwards must be available within hospitals and in other healthcare facilities caring for children at risk of cardiopulmonary arrest. Automated external defibrillators (AEDs) are pre-set for all variables including the energy dose. Pad/paddle size for defibrillation Select the largest possible available paddles to provide good contact with the chest wall. The ideal size is unknown but there should be good separation between the pads.617,618 Recommended sizes are 4.5 cm diameter for infants and children weighing <10 kg, and 8–12 cm diameter for children weighing >10 kg (older than one year). Self-adhesive pads facilitate continuous good quality CPR. Position of the paddles Apply the paddles firmly to the bare chest in the antero-lateral position, one paddle placed below the right clavicle and the other in the left axilla (Fig. 1.24). If the paddles are too large and there is a danger of charge arcing across the paddles, one should be placed on the upper back, below the left scapula and the other on the front, to the left of the sternum. Energy dose in children. In Europe we continue to recommend a dose of 4 J kg−1 for initial and subsequent defibrillation. Doses higher than 4 J kg−1 (as much as 9 J kg−1) have defibrillated children effectively with negligible side effects.619,620 If no manual defibrillator is available, use an AED that can recognise paediatric shockable rhythms.621–623 The AED should be equipped with a dose attenuator that decreases the delivered energy to a value more suitable for children aged 1–8 years (50–75 J).624,625 If such an AED in not available, use a standard adult AED and the pre-set adult energy levels. For children older than 8 years, use a standard AED with standard paddles. Experience with the use of AEDs (preferably with dose attenuator) in children younger than 1 year is limited; their use is acceptable if no other option is available. Advanced management of cardiopulmonary arrest The paediatric advanced life support algorithm is shown in Fig. 1.25. More detailed algorithms for the treatment of nonshockable (Fig. 1.26) and shockable rhythms (Fig. 1.27) also shown. Cardiac monitoring. Position the cardiac monitor leads or selfadhesive pads as soon as possible to enable differentiation between a shockable and a non-shockable cardiac rhythm. Non-shockable rhythms are pulseless electrical activity (PEA), bradycardia (<60 min−1 with no signs of circulation) and asystole. PEA and bradycardia often have wide QRS complexes. Shockable rhythms are pVT and VF. These rhythms are more likely after sudden collapse in children with heart disease or in adolescents. Non-shockable rhythms. Most cardiopulmonary arrests in children and adolescents are of respiratory origin.626 A period of immediate CPR is therefore mandatory in this age group before searching for an AED or manual defibrillator, as its immediate availability will not improve the outcome of a respiratory arrest. The most common ECG patterns in infants, children and adolescents with cardiopulmonary arrest are asystole and PEA. PEA is characterised by electrical activity on the ECG, and absent pulses. It commonly follows a period of hypoxia or myocardial ischaemia, but occasionally can have a reversible cause (i.e., one of the 4 Hs and 4 Ts) that led to a sudden impairment of cardiac output. Shockable rhythms. Primary VF occurs in 3.8–19% of cardiopulmonary arrests in children, the incidence of pVT/VF increases as the age increases.123,340,627–634 The primary determinant of survival from VT/pVT cardiopulmonary arrest is the time to defibrillation. Pre-hospital defibrillation within the first 3 min of witnessed adult VF arrest results in >50% survival. However, the success of defibrillation decreases dramatically the longer the time until defibrillation: for every minute delay in defibrillation (without any CPR), survival decreases by 7–10%. Secondary VF is present at some point in up to 27% of in-hospital resuscitation events. It has a much poorer prognosis than primary VF.635 Extracorporeal life support. Extracorporeal life support should be considered for children with cardiac arrest refractory to conventional CPR with a potentially reversible cause, if the arrest occurs where expertise, resources and system are available to rapidly initiate extracorporeal life support (ECLS). Arrhythmias Unstable arrhythmias Check for signs of life and the central pulse of any child with an arrhythmia; if signs of life are absent, treat as for cardiopulmonary arrest. If the child has signs of life and a central pulse, evaluate the haemodynamic status. Whenever the haemodynamic status is compromised, the first steps are: 1. Open the airway 2. Give oxygen and assist ventilation as necessary 3. Attach ECG monitor or defibrillator and assess the cardiac rhythm 4. Evaluate if the rhythm is slow or fast for the child’s age 5. Evaluate if the rhythm is regular or irregular 6. Measure QRS complex (narrow complexes: <0.08 s duration; wide complexes: >0.08 s) 7. The treatment options are dependent on the child’s haemodynamic stability. K.G. Monsieurs et al. / Resuscitation 95 (2015) 1–80 43 Fig. 1.25. Paediatric advanced life support algorithm. 44 K.G. Monsieurs et al. / Resuscitation 95 (2015) 1–80 CARDIAC ARREST: NON SHOCKABLE RHYTHM 2 min 2 min 2 min 2 min 2 min 1° 2° 3° 4° 5° Adrenaline 0.01 mg/kg Adrenaline 0.01 mg/kg Adrenaline 0.01 mg/kg CPR ROSC Ventilate / Oxygenate Vascular Access IO / IV Medications Intubation Fig. 1.26. Paediatric algorithm for non-shockable rhythm. CARDIAC ARREST – SHOCKABLE RHYTHM CPR ROSC 2 min 2 min 2 min 2 min 2 min 2 min 2 min 1° 2° 3° 4° 5° 6° 7° Shock 4J/kg Shock 4J/kg Shock 4J/kg Shock 4J/kg Shock 4J/kg Shock 4J/kg Shock 4J/kg Shock 4J/kg Adrenaline 0.01 mg/kg Adrenaline 0.01 mg/kg Adrenaline 0.01 mg/kg Ventilate / Oxygenate Vascular Access IO / IV Medications Intubation Amiodarone 5 mg/kg Amiodarone 5 mg/kg Fig. 1.27. Paediatric algorithm for shockable rhythm. K.G. Monsieurs et al. / Resuscitation 95 (2015) 1–80 45 Bradycardia Bradycardia is caused commonly by hypoxia, acidosis and/or severe hypotension; it may progress to cardiopulmonary arrest. Give 100% oxygen, and positive pressure ventilation if required, to any child presenting with bradyarrhythmia and circulatory failure. If a child with decompensated circulatory failure has a heart rate <60 beats min−1, and they do not respond rapidly to ventilation with oxygen, start chest compressions and give adrenaline. Cardiac pacing (either transvenous or external) is generally not useful during resuscitation. It may be considered in cases of AV block or sinus node dysfunction unresponsive to oxygenation, ventilation, chest compressions and other medications; pacing is not effective in asystole or arrhythmias caused by hypoxia or ischaemia.636 Tachycardia Narrow complex tachycardia. If supraventricular tachycardia (SVT) is the likely rhythm, vagal manoeuvres (Valsalva or diving reflex) may be used in haemodynamically stable children. They can also be used in haemodynamically unstable children, but only if they do not delay chemical or electrical cardioversion. Adenosine is usually effective in converting SVT into sinus rhythm. It is given by rapid, intravenous injection as close as practicable to the heart, and followed immediately by a bolus of normal saline. If the child has signs of decompensated shock with depressed conscious level, omit vagal manoeuvres and adenosine and attempt electrical cardioversion immediately. Electrical cardioversion (synchronised with R wave) is also indicated when vascular access is not available, or when adenosine has failed to convert the rhythm. The first energy dose for electrical cardioversion of SVT is 1 J kg−1 and the second dose is 2 J kg−1. If unsuccessful, give amiodarone or procainamide under guidance from a paediatric cardiologist or intensivist before the third attempt. Verapamil may be considered as an alternative therapy in older children but should not be routinely used in infants. Wide complex tachycardia. In children, wide-QRS complex tachycardia is uncommon and more likely to be supraventricular than ventricular in origin.637 Nevertheless, in haemodynamically unstable children, it must be considered to be VT until proven otherwise. Ventricular tachycardia occurs most often in the child with underlying heart disease (e.g., after cardiac surgery, cardiomyopathy, myocarditis, electrolyte disorders, prolonged QT interval, central intracardiac catheter). Synchronised cardioversion is the treatment of choice for unstable VT with signs of life. Consider anti-arrhythmic therapy if a second cardioversion attempt is unsuccessful or if VT recurs. Stable arrhythmias Whilst maintaining the child’s airway, breathing and circulation, contact an expert before initiating therapy. Depending on the child’s clinical history, presentation and ECG diagnosis, a child with stable, wide-QRS complex tachycardia may be treated for SVT and be given vagal manoeuvres or adenosine. Special circumstances Life support for blunt or penetrating trauma Cardiac arrest from major (blunt or penetrating) trauma is associated with a very high mortality.292,638–643 Consider the 4Ts and 4Hs as potentially reversible causes. There is little evidence to support any additional specific interventions that are different from the routine management of cardiac arrest; however, the use of resuscitative thoracotomy may be considered in children with penetrating injuries.644,645 Extracorporeal membrane oxygenation (ECMO) For infants and children with a cardiac diagnosis and an inhospital arrest, ECMO should be considered as a useful rescue strategy if expertise, adequate resources and systems are equally available. There is insufficient evidence to suggest for or against the use of ECMO in non-cardiac arrest or for children with myocarditis or cardiomyopathy who are not in arrest.512 Pulmonary hypertension There is an increased risk of cardiac arrest in children with pulmonary hypertension.646,647 Follow routine resuscitation protocols in these patients with emphasis on high FiO2 and alkalosis/hyperventilation because this may be as effective as inhaled nitric oxide in reducing pulmonary vascular resistance.648 Post resuscitation care Post cardiac arrest care must be a multidisciplinary activity and include all the treatments needed for complete neurological recov- ery. Myocardial dysfunction Myocardial dysfunction is common after cardiopulmonary resuscitation.366,649–652 Parenteral fluids and vasoactive drugs (adrenaline, dobutamine, dopamine and noradrenaline) may improve the child’s post-arrest haemodynamic status and should be titrated to maintain a systolic blood pressure of at least >5th centile for age.512 Goals for oxygenation and ventilation Aim for a normal PaO2 range (normoxaemia) post-ROSC once a patient is stabilised.559,653–655 There is insufficient paediatric evidence to suggest a specific PaCO2 target, however, PaCO2 should be measured post-ROSC and adjusted according to patient characteristics and needs.397,512,559,656 It is sensible to aim in general for normocapnia, although this decision might be in part influenced by context and disease. Temperature control and management post ROSC Mild hypothermia has an acceptable safety profile in adults446,450 and neonates.657 Recently the THAPCA out of hospital study showed that both hypothermia (32–34 ◦C) and controlled normothermia (36–37.5 ◦C) could be used in children.658 The study did not show a significant difference for the primary outcome (neurologic status at one year) with either approach. After ROSC, a strict control of the temperature must be maintained to avoid hyperthermia (>37.5 ◦C) and severe hypothermia (<32 ◦C).512 Glucose control Both hyper- and hypoglycaemia may impair outcome of critically ill adults and children and should be avoided,659–661 but tight glucose control may also be harmful.662 Monitor blood glucose and avoid hypoglycaemia and hyperglycaemia.366,663,664 Prognosis of cardiopulmonary arrest Although several factors are associated with outcome after cardiopulmonary arrest and resuscitation there are no simple guidelines to determine when resuscitative efforts become futile.512,656 The relevant considerations in the decision to continue the resuscitation include the duration of CPR, cause of arrest, preexisting medical conditions, age, site of arrest, whether the arrest was witnessed,519,665 the duration of untreated cardiopulmonary arrest (‘no flow’ time) the presence of a shockable rhythm as the first or subsequent rhythm, and associated special circumstances (e.g., icy water drowning666,667 exposure to toxic drugs). The role 46 K.G. Monsieurs et al. / Resuscitation 95 (2015) 1–80 of the EEG as a prognostic factor is still unclear. Guidance on the termination of resuscitation attempts is discussed in the chapter on ethics in resuscitation and end-of-life decisions.10 Parental presence In some Western societies, the majority of parents want to be present during the resuscitation of their child. Families who are present at their child’s death show better adjustment and undergo a better grieving process.668 Evidence about parental presence during resuscitation comes from selected countries and can probably not be generalised to all of Europe, where there may be different socio-cultural and ethical considerations.669,670 Resuscitation and support of transition of babies at birth The guidelines that follow do not define the only way that resuscitation at birth should be achieved; they do, however, represent a widely accepted view of how resuscitation at birth can be carried out both safely and effectively. Preparation A minority of infants require resuscitation at birth, but a few more have problems with this perinatal transition, which, if no support is given, might subsequently result in a need for resuscitation. Of those needing any help, the overwhelming majority will require only assisted lung aeration. A tiny minority may need a brief period of chest compressions in addition to lung aeration.671–673 In deliveries with a known increased risk of problems, specially trained personnel should be present with at least one person experienced in tracheal intubation. Each institution should have a protocol in place for rapidly mobilising a team with competent resuscitation skills for any birth. Planned home deliveries Recommendations as to who should attend a planned home delivery vary from country to country, but the decision to undergo a planned home delivery, once agreed with medical and midwifery staff, should not compromise the standard of initial assessment, stabilisation or resuscitation at birth. Ideally, two trained professionals should be present at all home deliveries; one of these must be fully trained and experienced in providing mask ventilation and chest compressions in the newborn. Equipment and environment When a birth takes place in a non-designated delivery area, the recommended minimum set of equipment includes a device for safe assisted lung aeration and subsequent ventilation of an appropriate size for the newborn, warm dry towels and blankets, a sterile instrument for cutting and clamping the umbilical cord and clean gloves for the attendant and assistants. Timing of clamping the umbilical cord A systematic review on delayed cord clamping and cord milking in preterm infants found improved stability in the immediate postnatal period, including higher mean blood pressure and haemoglobin on admission, compared to controls.674 Delaying umbilical cord clamping for at least one minute is recommended for newborn infants not requiring resuscitation. A similar delay should be applied to preterm babies not requiring immediate resuscitation after birth. Until more evidence is available, infants who are not breathing or crying may require the umbilical cord to be clamped, so that resuscitation measures can commence promptly. Temperature control Naked, wet, newborn babies cannot maintain their body temperature in a room that feels comfortably warm for adults. The association between hypothermia and mortality has been known for more than a century,675 and the admission temperature of newborn non-asphyxiated infants is a strong predictor of mortality at all gestations and in all settings.676 Preterm infants are especially vulnerable. Maintain the temperature of newly born non-asphyxiated infants at between 36.5 ◦C and 37.5 ◦C after birth. Whilst maintenance of a baby’s temperature is important, this should be monitored in order to avoid hyperthermia (>38.0 ◦C). Initial assessment The Apgar score was not designed to be assembled and ascribed in order to then identify babies in need of resuscitation.677,678 However, individual components of the score, namely respiratory rate, heart rate and tone, if assessed rapidly, can identify babies needing resuscitation.677 Repeated assessment particularly of heart rate and, to a lesser extent breathing, can indicate whether the baby is responding or whether further efforts are needed. Breathing Check whether the baby is breathing. If so, evaluate the rate, depth and symmetry of breathing together with any evidence of an abnormal breathing pattern such as gasping or grunting. Heart rate Immediately after birth the heart rate is assessed to evaluate the condition of the baby and subsequently is the most sensitive indicator of a successful response to interventions. Heart rate is initially most rapidly and accurately assessed by listening to the apex beat with a stethoscope679 or by using an electrocardiograph.680–682 Feeling the pulse in the base of the umbilical cord is often effective but can be misleading, cord pulsation is only reliable if found to be more than 100 beats per minute (bpm)679 and clinical assessment may underestimate the heart rate.679,683,684 For babies requiring resuscitation and/or continued respiratory support, a modern pulse oximeter can give an accurate heart rate.681 Colour Colour is a poor means of judging oxygenation,685 which is better assessed using pulse oximetry if possible. A healthy baby is born blue but starts to become pink within 30 s of the onset of effective breathing. If a baby appears blue check preductal oxygenation with a pulse oximeter. Tone A very floppy baby is likely to be unconscious and will need ventilatory support. Tactile stimulation Drying the baby usually produces enough stimulation to induce effective breathing. Avoid more vigorous methods of stimulation. If the baby fails to establish spontaneous and effective breaths following a brief period of stimulation, further support will be required. Classification according to initial assessment On the basis of the initial assessment, the baby can be placed into one of three groups: 1. Vigorous breathing or crying, good tone, heart rate higher than 100 min−1 K.G. Monsieurs et al. / Resuscitation 95 (2015) 1–80 47 Fig. 1.28. Newborn life support algorithm (SpO2: transcutaneous pulse oximetry, ECG: electrocardiograph, PPV: positive pressure ventilation). 48 K.G. Monsieurs et al. / Resuscitation 95 (2015) 1–80 Fig. 1.29. Newborn with head in neutral position. There is no need for immediate clamping of the cord. This baby requires no intervention other than drying, wrapping in a warm towel and, where appropriate, handing to the mother. 2. Breathing inadequately or apnoeic, normal or reduced tone, heart rate less than 100 min−1 Dry and wrap. This baby will usually improve with mask inflation but if this does not increase the heart rate adequately, may rarely also require ventilations. 3. Breathing inadequately or apnoeic, floppy, low or undetectable heart rate, often pale suggesting poor perfusion Dry and wrap. This baby will then require immediate airway control, lung inflation and ventilation. Once this has been successfully accomplished the baby may also need chest compressions, and perhaps drugs. Preterm babies may be breathing and showing signs of respiratory distress in which case they should be supported initially with CPAP. Newborn life support Commence newborn life support if initial assessment shows that the baby has failed to establish adequate regular normal breathing, or has a heart rate of less than 100 min−1. Opening the airway and aerating the lungs is usually all that is necessary. Furthermore, more complex interventions will be futile unless these two first steps have been successfully completed. Airway Place the baby on his or her back with the head in a neutral position (Fig. 1.29). A 2 cm thickness of the blanket or towel placed under the baby’s shoulder may be helpful in maintaining proper head position. In floppy babies application of jaw thrust or the use of an appropriately sized oropharyngeal airway may be essential in opening the airway. The supine position for airway management is traditional but side-lying has also been used for assessment and routine delivery room management of term newborns.686 There is no need to remove lung fluid from the oropharynx routinely.687 Suction is needed only if the airway is obstructed. Meconium Lightly meconium stained liquor is common and does in general not give rise to much difficulty with transition. The much less common finding of very thick meconium stained liquor at birth is an indicator of perinatal distress and should alert to the potential need for resuscitation. Intrapartum suctioning and routine intubation and suctioning of vigorous infants born through meconium stained liquor are not recommended. The presence of thick, viscous meconium in a non-vigorous baby is the only indication for initially considering visualising the oropharynx and suctioning material, which might obstruct the airway. Tracheal intubation should not be routine in the presence of meconium and should only be performed for suspected tracheal obstruction.688–692 The emphasis Fig. 1.30. Mask ventilation of newborn. should be on initiating ventilation within the first minute of life in non-breathing or ineffectively breathing infants and this should not be delayed. Initial breaths and assisted ventilation After initial steps at birth, if breathing efforts are absent or inadequate, lung aeration is the priority and must not be delayed (Figs. 1.28 and 1.30). In term babies, respiratory support should start with air.693 The primary measure of adequate initial lung inflation is a prompt improvement in heart rate. If the heart rate is not improving assess the chest wall movement. For the first five positive pressure inflations maintain the initial inflation pressure for 2–3 s. This will usually help lung expansion.694,695 Most babies needing respiratory support at birth will respond with a rapid increase in heart rate within 30 s of lung inflation. If the heart rate increases but the baby is not breathing adequately, ventilate at a rate of about 30 breaths min−1 allowing approximately one second for each inflation, until there is adequate spontaneous breathing. Without adequate lung aeration, chest compressions will be ineffective; therefore, confirm lung aeration and ventilation before progressing to circulatory support. Some practitioners will ensure airway control by tracheal intubation, but this requires training and experience. If this skill is not available and the heart rate is decreasing, re-evaluate the airway position and deliver inflation breaths while summoning a colleague with intubation skills. Continue ventilatory support until the baby has established normal regular breathing. Air/oxygen Term babies. In term infants receiving respiratory support at birth with positive pressure ventilation (PPV), it is best to begin with air (21%) as opposed to 100% oxygen. If, despite effective ventilation, there is no increase in heart rate or oxygenation (guided by oximetry wherever possible) remains unacceptable, use a higher concentration of oxygen to achieve an adequate preductal oxygen saturation.696,697 High concentrations of oxygen are associated with an increased mortality and delay in time of onset of spontaneous breathing,698 therefore, if increased oxygen concentrations are used they should be weaned as soon as possible.693,699 Preterm babies. Resuscitation of preterm infants less than 35 weeks gestation at birth should be initiated in air or low concentration oxygen (21–30%).6,693,700,701 Titrate the administered oxygen concentration to achieve acceptable pre-ductal oxygen saturations K.G. Monsieurs et al. / Resuscitation 95 (2015) 1–80 49 Table 1.3 Oral tracheal tube lengths by gestation. Gestation (weeks) ETT at lips (cm) 23–24 5.5 25–26 6.0 27–29 6.5 30–32 7.0 33–34 7.5 35–37 8.0 38–40 8.5 41–43 9.0 approximating to the 25th percentile in healthy term babies immediately after birth.696,697 Pulse oximetry Modern pulse oximetry, using neonatal probes, provides reliable readings of heart rate and transcutaneous oxygen saturation within 1–2 min of birth.702,703 Uncompromised babies born at term at sea level have SpO2 ∼60% during labour,704 which increases to >90% by 10 min.696 The 25th percentile is approximately 40% at birth and increases to ∼80% at 10 min.697 Use pulse oximetry to avoid excessive use of oxygen (Fig. 1.28). Transcutaneous oxygen saturations above the acceptable levels should prompt weaning of any supplemental oxygen. Positive end expiratory pressure All term and preterm babies who remain apnoeic despite initial steps must receive positive pressure ventilation after initial lung inflation. Provide positive end expiratory pressure (PEEP) of ∼5 cm H2O for preterm newborn babies receiving PPV.676 Assisted ventilation devices Effective ventilation can be achieved with a self-inflating bag or with a T-piece mechanical device designed to regulate pressure.705,706 However, self-inflating bags are the only devices, which can be used in the absence of compressed gas but cannot deliver continuous positive airway pressure (CPAP) and may not be able to achieve PEEP even with a PEEP valve in place.707 Laryngeal mask airway The LMA may be considered as an alternative to a facemask or to tracheal intubation for positive pressure ventilation among newborns weighing more than 2000 g or delivered ≥34 weeks gestation.708,709 The laryngeal mask airway has not been evaluated in the setting of meconium stained fluid, during chest compressions, or for the administration of emergency intra-tracheal medications. Tracheal tube placement Tracheal intubation may be considered at several points during neonatal resuscitation: • When suctioning the lower airways to remove a presumed tracheal blockage • When, after correction of mask technique and/or the baby’s head position, bag-mask ventilation is ineffective or prolonged • When chest compressions are performed • Special circumstances (e.g. congenital diaphragmatic hernia or to give tracheal surfactant) The use and timing of tracheal intubation will depend on the skill and experience of the available resuscitators. Appropriate tube lengths based on gestation are shown in Table 1.3.710 It should be recognised that vocal cord guides, as marked on tracheal Fig. 1.31. Ventilation and chest compression of newborn. tubes by different manufacturers to aid correct placement, vary considerably.711 Tracheal tube placement must be assessed visually during intubation, and positioning confirmed. Following tracheal intubation and intermittent positive-pressure, a prompt increase in heart rate is a good indication that the tube is in the tracheobronchial tree.712 Exhaled CO2 detection is effective for confirmation of tracheal tube placement in infants, including VLBW infants713–716 and neonatal studies suggest that it confirms tracheal intubation in neonates with a cardiac output more rapidly and more accurately than clinical assessment alone.715–717 Failure to detect exhaled CO2 strongly suggests oesophageal intubation713,715 but false negative readings have been reported during cardiac arrest 713 and in VLBW infants.718 Detection of exhaled carbon dioxide in addition to clinical assessment is recommended as the most reliable method to confirm tracheal placement in neonates with spontaneous circula- tion. Continuous positive airways pressure Initial respiratory support of all spontaneously breathing preterm infants with respiratory distress may be provided by continuous positive airways pressure (CPAP), rather than intubation.719–721 There are few data to guide the appropriate use of CPAP in term infants at birth and further clinical studies are required.722,723 Circulatory support Give chest compressions if the heart rate is less than 60 beats min−1 despite adequate ventilation. As ventilation is the most effective and important intervention in newborn resuscitation, and may be compromised by compressions, it is vital to ensure that effective ventilation is occurring before commencing chest compressions. The most effective technique for providing chest compressions is with two thumbs over the lower third of the sternum with the fingers encircling the torso and supporting the back (Fig. 1.31).724 This technique generates higher blood pressures and coronary artery perfusion with less fatigue than the previously used two-finger technique.725–728 The sternum is compressed to a depth of approximately one-third of the anterior–posterior diameter of the chest allowing the chest wall to return to its relaxed position between compressions.729–732 50 K.G. Monsieurs et al. / Resuscitation 95 (2015) 1–80 2 umbilical arteries 1 umbilical vein LEGS HEAD Fig. 1.32. Newborn umbilical cord showing the arteries and veins. Use a 3:1 compression to ventilation ratio, aiming to achieve approximately 120 events per minute, i.e. approximately 90 compressions and 30 ventilations.733–738 Co-ordinate compressions and ventilations to avoid simultaneous delivery.739 A 3:1 compression to ventilation ratio is used for resuscitation at birth where compromise of gas exchange is nearly always the primary cause of cardiovascular collapse, but rescuers may consider using higher ratios (e.g., 15:2) if the arrest is believed to be of cardiac origin. When delivering chest compressions it would appear sensible to increase the supplementary oxygen concentration towards 100%. Check the heart rate after about 30 s and periodically thereafter. Discontinue chest compressions when the spontaneous heart rate is faster than 60 beats min−1. Drugs Drugs are rarely indicated in resuscitation of the newly born infant. Bradycardia in the newborn infant is usually caused by inadequate lung inflation or profound hypoxia, and establishing adequate ventilation is the most important step to correct it. However, if the heart rate remains less than 60 beats min−1 despite adequate ventilation and chest compressions, it is reasonable to consider the use of drugs. These are best given via a centrally positioned umbilical venous catheter (Fig. 1.32). Adrenaline. Despite the lack of human data it is reasonable to use adrenaline when adequate ventilation and chest compressions have failed to increase the heart rate above 60 beats min−1. If adrenaline is used, give an initial dose of 10 micrograms kg−1 (0.1 ml kg−1 of 1:10,000 adrenaline) intravenously as soon as possible with subsequent intravenous doses of 10–30 micrograms kg−1 (0.1–0.3 ml kg−1 of 1:10,000 adrenaline) if required.6,693,700 Do not use the tracheal route. Bicarbonate. There are insufficient data to recommend routine use of bicarbonate in resuscitation of the newly born. If it is used during prolonged arrests unresponsive to other therapy, give a dose of 1–2 mmol kg−1 by slow intravenous injection after adequate ventilation and perfusion have been established. Fluids If there has been suspected blood loss or the infant appears to be in shock (pale, poor perfusion, weak pulse) and has not responded adequately to other resuscitative measures then consider giving fluid.740 This is a rare event. In the absence of suitable blood, give a bolus of isotonic crystalloid of 10 ml kg−1 initially. If successful it may need to be repeated to maintain an improvement. When resuscitating preterm infants volume is rarely needed and has been associated with intraventricular and pulmonary haemorrhages when large volumes are infused rapidly. Withholding or discontinuing resuscitation Mortality and morbidity for newborns varies according to region and to availability of resources.741 Opinions vary amongst providers, parents and societies about the balance of benefits and disadvantages of using aggressive therapies in such babies.742,743 Discontinuing resuscitation Local and national committees will define recommendations for stopping resuscitation. If the heart rate of a newly born baby is not detectable and remains undetectable for 10 min, it may be appropriate to consider stopping resuscitation. The decision should be individualised. In cases where the heart rate is less than 60 min−1 at birth and does not improve after 10 or 15 min of continuous and apparently adequate resuscitative efforts, the choice is much less clear and firm guidance cannot be given. Withholding resuscitation It is possible to identify conditions associated with high mortality and poor outcome, where withholding resuscitation may be considered reasonable, particularly when there has been the opportunity for discussion with parents.744–746 There is no evidence to support the prospective use of any particular delivery room prognostic score presently described, over gestational age assessment alone, in preterm infants <25 weeks gestation. When withdrawing or withholding resuscitation, care should be focused on the comfort and dignity of the baby and family. Communication with the parents It is important that the team caring for the newborn baby informs the parents of the baby’s progress. At delivery, adhere to the routine local plan and, if possible, hand the baby to the mother at the earliest opportunity. If resuscitation is required inform the parents of the procedures undertaken and why they were required. Parents’ wishes to be present during resuscitation should be supported where possible.747 Post-resuscitation care Babies who have required resuscitation may later deteriorate. Once adequate ventilation and circulation are established, the infant should be maintained in or transferred to an environment in which close monitoring and anticipatory care can be provided. Glucose The range of blood glucose concentration that is associated with the least brain injury following asphyxia and resuscitation cannot be defined based on available evidence. Infants who require significant resuscitation should be monitored and treated to maintain glucose in the normal range. Induced hypothermia Newly born infants born at term or near-term with evolving moderate to severe hypoxic – ischaemic encephalopathy should, where possible, be offered therapeutic hypothermia.748,749 Whole body cooling and selective head cooling are both appropriate strategies. There is no evidence in human newborns that cooling is effective if started more than 6 h after birth. Prognostic tools Although widely used in clinical practice, for research purposes and as a prognostic tool,750 the applicability of the APGAR score has been questioned due to large inter- and intra-observer variations. These are partly explained by a lack of agreement on how to score infants receiving medical interventions or being born K.G. Monsieurs et al. / Resuscitation 95 (2015) 1–80 51 Fig. 1.33. Definitions of acute coronary syndromes (ACS); ECG, electrocardiogram; LBBB, left bundle branch block; STEMI, ST-elevation myocardial infarction; NSTEMI, non-ST-elevation acute myocardial infarction; c troponin, cardiac troponin; UAP, unstable angina pectoris; TIMI, thrombolysis in acute myocardial infarction; GRACE, global registry of acute coronary events. preterm. Therefore a development of the score was recommended as follows: all parameters are scored according to the conditions regardless of the interventions needed to achieve the condition and considering whether being appropriate for gestational age. In addition, the interventions needed to achieve the condition have to be scored as well. This Combined-Apgar has been shown to predict outcome in preterm and term infants better than the conventional score.751,752 Briefing/debriefing Prior to resuscitation it is important to discuss the responsibilities of each member of the team. After the management in the delivery room a team debrief of the event using positive and constructive critique techniques should be conducted and personal bereavement counselling offered to those with a particular need. Initial management of acute coronary syndromes The term acute coronary syndrome (ACS) encompasses three different entities of the acute manifestation of coronary heart disease (Fig. 1.33): ST elevation myocardial infarction (STEMI), non-ST elevation myocardial infarction and unstable angina pectoris (UAP). Non-ST elevation myocardial infarction and UAP are usually combined in the term non-STEMI-ACS. The common pathophysiology of ACS is a ruptured or eroded atherosclerotic plaque.753 Electrocardiographic (ECG) characteristics (absence or presence of ST elevation) differentiate STEMI from non-STEMI ACS. The latter may present with ST segment depression, nonspecific ST segment wave abnormalities, or even a normal ECG. In the absence of ST elevation, an increase in the plasma concentration of cardiac biomarkers, particularly troponin T or I as the most specific markers of myocardial cell necrosis, indicates non-STEMI. Acute coronary syndromes are the commonest cause of malignant arrhythmias leading to sudden cardiac death. The therapeutic goals are to treat acute life-threatening conditions, such as ventricular fibrillation (VF) or extreme bradycardia, and to preserve left ventricular function and prevent heart failure by minimising the extent of myocardial damage. The current guidelines address the first hours after onset of symptoms. Out-of-hospital treatment and initial therapy in the emergency department (ED) may vary according to local capabilities, resources and regulations. These recommendations are consistent with the guidelines for the diagnosis and treatment of ACS with and without ST elevation published by the European Society of Cardiology and the American College of Cardiology/American Heart Association.424,754 Diagnosis and risk stratification in acute coronary syndromes Signs and symptoms of ACS Typically ACS appears with symptoms such as radiating chest pain, shortness of breath and sweating; however, atypical symptoms or unusual presentations may occur in the elderly, in females, and in diabetics. None of these signs and symptoms of ACS can be used alone for the diagnosis of ACS. A reduction in chest pain after nitroglycerin administration can be misleading and is not recommended as a diagnostic manoeuvre.755 Symptoms may be more intense and last longer in patients with STEMI but are not reliable for discriminating between STEMI and non-STEMI-ACS.424,756–758 12-lead ECG When an ACS is suspected, a 12-lead-ECG should be acquired and interpreted as soon as possible after first patient contact, to facilitate early diagnosis and triage.754,756,758 STEMI is typically diagnosed when, ST-segment elevation, measured at the J point, fulfilling specific voltage criteria in the absence of left ventricular (LV) hypertrophy or left bundle branch block (LBBB).424 In patients with clinical suspicion of ongoing myocardial ischaemia with new or presumed new LBBB, consider prompt reperfusion therapy, preferably using primary PCI (PPCI). Right precordial leads should be recorded in all patients with inferior STEMI in order to detect right ventricular MI. Recording of a 12-lead ECG out-of-hospital enables advanced notification to the receiving facility and expedites treatment decisions after hospital arrival. In many studies, using pre-hospital 12-lead ECG, the time from hospital admission to initiating reperfusion therapy is reduced by 10 to 60 minutes. This is associated with shorter times to reperfusion and improved patient survival in both patients with PCI and those undergoing fibrinolysis.759–767 Trained EMS personnel (emergency physicians, paramedics and nurses) can identify STEMI with a high specificity and sensitivity comparable to diagnostic accuracy in the hospital.768,769 It is thus reasonable that paramedics and nurses be trained to diagnose STEMI without direct medical consultation, as long as there is strict concurrent provision of quality assurance. If interpretation of the pre-hospital ECG is not available on-site, computer interpretation770,771 or field transmission of the ECG is reasonable.762,770–777 Biomarkers, rules for early discharge and chest pain observation protocols In the absence of ST elevation on the ECG, the presence of a suggestive history and elevated concentrations of biomarkers (troponins, CK and CKMB) characterise non-STEMI and distinguish it from STEMI and unstable angina respectively. Highly sensitive 52 K.G. Monsieurs et al. / Resuscitation 95 (2015) 1–80 (ultrasensitive) cardiac troponin assays can increase sensitivity and accelerate diagnosis of MI in patients with symptoms suspicious of cardiac ischaemia.778 Cardiac biomarker testing should be part of the initial evaluation of all patients presenting to the ED with symptoms suggestive of cardiac ischaemia. However, the delay in release of biomarkers from damaged myocardium prevents their use in diagnosing myocardial infarction in the first hours after the onset of symptoms. For patients who present within 6 h of symptom onset, and have an initial negative cardiac troponin, biomarkers should be measured again between 2–3 and up to 6 h later for hs-cTn (12 h with regular troponin). In patients suspected of an ACS the combination of an unremarkable past history and physical examination with negative initial ECG and biomarkers cannot be used to exclude ACS reliably. Therefore a follow up period is mandatory in order to reach a diagnosis and make therapeutic decisions. At some point after AMI is excluded, the evaluation of the patient should be complemented by either a non-invasive evaluation for anatomical coronary disease or provocative testing for inducible myocardial ischaemia. Imaging techniques Effective screening of patients with suspected ACS, but with negative ECG and negative cardiac biomarkers, remains challenging. Non invasive imaging techniques (CT angiography,779 cardiac magnetic resonance, myocardial perfusion imaging,780 and echocardiography781) have been evaluated as means of screening these low-risk patients and identifying subgroups that can be discharged home safely.782–785 Echocardiography should be routinely available in the ED, and used in all patients with suspected ACS. Multi-detector computer tomography coronary angiography (MDCTCA) has been recently proposed in the management acute chest pain in the ED. In a recent meta-analysis, MDCTCA demonstrated a high sensitivity and a low negative likelihood ratio of 0.06, and was effective in ruling out the presence of ACS in low to intermediate risk patients presenting to the ED with acute chest pain.786 But the inability of anatomical findings to prove the presence of ischaemia, the cancer risk induced by radiation exposure and potential overuse still raise concerns about the relevance of this strategy. Treatment of acute coronary syndromes – symptoms Nitrates Glyceryl trinitrate may be considered if the systolic blood pressure (SBP) is above 90 mmHg and the patient has ongoing ischaemic chest pain (Fig. 1.34). Glyceryl trinitrate can also be useful in the treatment of acute pulmonary congestion. Do not use nitrates in patients with hypotension (SBP ≤ 90 mmHg), particularly if combined with bradycardia, and in patients with inferior infarction and suspected right ventricular involvement. Give glyceryl trinitrate 0.4 mg sublingual or equivalent every 5 min up to 3 doses as SBP allows. Begin IV dosing at 10 ␮g min−1 for persistent pain or pulmonary oedema; titrate to desired BP effect. Analgesia Morphine is the analgesic of choice for nitrate-refractory pain and also has calming effects on the patient making sedatives unnecessary in most cases. Since morphine is a dilator of venous capacitance vessels, it may have additional benefit in patients with pulmonary congestion. Give morphine in initial doses of 3–5 mg intravenously and repeat every few minutes until the patient is pain-free. Avoid non-steroidal anti-inflammatory drugs (NSAIDs) for analgesia because they have pro-thrombotic effects.787 Oxygen Evidence is accumulating about the questionable role of supplemental oxygen in cardiac arrest, after ROSC and in ACS. Patients with acute chest pain with presumed ACS do not need supplemental oxygen unless they present with signs of hypoxia, dyspnoea or heart failure. There is increasing evidence suggesting that hyperoxia may be harmful in patients with uncomplicated myocardial infarction.393,788–790 During cardiac arrest, use 100% oxygen. After ROSC, titrate the inspired oxygen concentration to achieve arterial blood oxygen saturation in the range of 94–98%, or 88–92 in chronic obstructive pulmonary disease.424,791 Treatment of acute coronary syndromes – cause Inhibitors of platelet aggregation Platelet activation and aggregation following atherosclerotic plaque rupture are central pathophysiologic mechanisms of acute coronary syndromes and antiplatelet therapy is a pivotal treatment of ACS whether with or without ST segment elevation, with or without reperfusion and with or without revascularisation. Acetylsalicylic acid (ASA). Large randomised controlled trials indicate decreased mortality when ASA (75–325 mg) is given to hospitalised patients with ACS independent of the reperfusion or revascularisation strategy. ADP receptor inhibitors. The inhibition of the platelet ADP receptor by the thienopyridines clopidogrel and prasugrel (irreversible inhibition) and the cyclo-pentyl-triazolo-pyrimidine ticagrelor (reversible inhibition) leads to further inhibition of platelet aggregation in addition to that produced by ASA. Glycoprotein (Gp) IIB/IIIA inhibitors. Glycoprotein (Gp) IIB/IIIA receptor activation is the common final link of platelet aggregation. Eptifibatide and tirofiban lead to reversible inhibition, while abciximab leads to irreversible inhibition of the Gp IIB/IIIA receptor. There are insufficient data to support routine pre-treatment with Gp IIB/IIIA receptor blockers in patients with STEMI or non-STEMIACS. Do not give Gp IIB/IIIA receptor blockers before coronary anatomy is known. Antithrombins Unfractionated heparin (UFH) is an indirect inhibitor of thrombin, which in combination with ASA is used as an adjunct with fibrinolytic therapy or PPCI and is an important part of treatment of unstable angina and STEMI. Alternatives are characterised by a more specific factor Xa activity (low molecular weight heparins [LMWH], fondaparinux) or are direct thrombin inhibitors (bivalirudin). Rivaroxaban, apixaban and other oral direct thrombin antagonists may have an indication after stabilisation in specific patient groups but not in the initial treatment of ACS.792 Details on the use of antithrombins are given in Section 8 Initial Management of Acute Coronary Syndromes.7 Reperfusion strategy in patients presenting with STEMI Reperfusion therapy in patients with STEMI is the most important advance in the treatment of myocardial infarction in the last 30 years. Reperfusion may be achieved with fibrinolysis, with PPCI, or a combination of both. Efficacy of reperfusion therapy is profoundly dependent on the time interval from symptom onset to reperfusion. Fibrinolysis is effective specifically in the first 2–3 h after symptom onset; PPCI is less time sensitive. K.G. Monsieurs et al. / Resuscitation 95 (2015) 1–80 53 Fig. 1.34. Treatment algorithm for acute coronary syndromes; ECG, electrocardiogram; SBP, systolic blood pressure; STEMI, ST-elevation myocardial infarction; non-STEMIACS, non-ST-elevation acute coronary syndrome; PCI, percutaneous coronary intervention. Fibrinolysis Giving fibrinolytics to out-of-hospital to patients with STEMI or signs and symptoms of an ACS with presumed new LBBB is beneficial. The efficacy is greatest early after onset of symptoms. Patients with symptoms of ACS and ECG evidence of STEMI (or presumably new LBBB or true posterior infarction) presenting directly to the ED should be given fibrinolytic therapy as soon as possible unless there is timely access to PPCI. The real advantage of prehospital fibrinolysis is where there are long transport times, i.e. >30–60 min. Healthcare professionals who give fibrinolytic therapy must be aware of its contraindications and risks. Patients with large AMIs (e.g. indicated by extensive ECG changes) are likely to gain most from fibrinolytic therapy. Benefits of fibrinolytic therapy are less impressive in inferior wall infarctions than in anterior infarctions. Primary percutaneous intervention Coronary angioplasty with or without stent placement has become the first-line treatment for patients with STEMI. PPCI performed with a limited delay to first balloon inflation after first medical contact, at a high-volume centre, by an experienced operator who maintains an appropriate expert status, is the preferred treatment as it improves morbidity and mortality as compared with immediate fibrinolysis.793 Fibrinolysis versus primary PCI Primary PCI has been limited by access to catheter laboratory facilities, appropriately skilled clinicians and delay to first balloon inflation. Fibrinolysis therapy is a widely available reperfusion strategy. Both treatment strategies are well established and have been the subject of large randomised multicentre trials over the last decades. Time from onset of symptoms and PPCI related delay (diagnosis to balloon interval minus the diagnosis to needle interval) are key in selecting the most appropriate revascularisation strategy. Fibrinolytic therapy is most effective in patients presenting within 2–3 h from onset of ischaemic symptoms. It compares favourably with PPCI when started within 2 h from symptom onset and is combined with rescue or delayed PCI. In early presenters, patients of younger age and large anterior infarctions, PPCI related delays of 60 min may be unacceptable while in late presenters (>3 h from the onset of symptoms) PPCI related delays of up to 120 min may be acceptable.794 Improving the systems of care may significantly shorten time delay to PPCI795,796: • A pre-hospital ECG should be acquired as soon as possible and interpreted for the diagnosis of STEMI. This can reduce mortality in both patients planned for PPCI and fibrinolytic therapy. • STEMI recognition may be accomplished by ECG transmission or onsite interpretation by physicians, or highly trained nurses or paramedics, with or without the aid of computer ECG interpreta- tion. • When PPCI is the planned strategy, pre-hospital activation of catheterisation laboratory for PPCI will contribute to a mortality benefit.797 Additional elements for an effective system of care include: • Requiring the catheterisation laboratory to be ready within 20 min available 24/7. • Providing real-time data feedback on the real time course from symptom onset to PCI For those patients with a contraindication to fibrinolysis, PCI should still be pursued despite the delay, rather than not providing reperfusion therapy at all. For those STEMI patients presenting in shock, primary PCI (or coronary artery bypass surgery) is the 54 K.G. Monsieurs et al. / Resuscitation 95 (2015) 1–80 preferred reperfusion treatment. Fibrinolysis should only be considered if there is a substantial delay to PCI. Triage and inter-facility transfer for primary PCI The majority of patients with an ongoing STEMI will be first diagnosed either in the pre-hospital environment or in the setting of the ED of a non-PCI capable hospital. When PCI can be performed within a time limit of 60–90 min, then direct triage and transport for PCI is preferred to pre-hospital fibrinolysis.797–801 For adult patients presenting with STEMI in the ED of a non-PCI capable hospital emergent transfer without fibrinolysis to a PCI centre should be considered provided that PPCI can be performed within acceptable time delays. It is less clear whether immediate fibrinolytic therapy (in- or out-of-hospital) or transfer for PPCI is superior for younger patients presenting with anterior infarction and within a short duration of <2–3 h.794 Transfer of STEMI patients for PPCI is reasonable for those presenting more than 3 h but less than 12 h after the onset of symptoms, provided that the transfer can be achieved rapidly. Combination of fibrinolysis and percutaneous coronary intervention Fibrinolysis and PCI may be used in a variety of combinations to restore and maintain coronary blood flow and myocardial perfusion. Routine immediate angiography post fibrinolytic therapy is associated with increased ICH and major bleeding without offering any benefit in terms of mortality or reinfarction.802–806 It is reasonable to perform angiography and PCI in patients with failed fibrinolysis according to clinical signs and/or insufficient ST-segment resolution.807 In case of clinically successful fibrinolysis (evidenced by clinical signs and ST-segment resolution >50%), angiography delayed by several hours after fibrinolysis (the pharmaco-invasive approach) has been shown to improve outcome. This strategy includes early transfer for angiography and PCI if necessary after fibrinolytic treatment. Special situations Cardiogenic shock. Acute coronary syndrome (ACS) is the most common cause of cardiogenic shock, mainly through a large zone of myocardial ischaemia or a mechanical complication of myocardial infarction. Although uncommon, the short-term mortality of cardiogenic shock is up to 40%808 contrasting with a good quality of life in patients discharged alive. An early invasive strategy (i.e. primary PCI, PCI early after fibrinolysis) is indicated for those patients who are suitable for revascularisation.809 Observational studies suggest that this strategy could be also beneficial in elderly patients (over 75 years). Even if commonly used in clinical practice, there is no evidence supporting the use of IABP in cardiogenic shock.808 Suspect right ventricular infarction in patients with inferior infarction, clinical shock and clear lung fields. ST segment elevation ≥1 mm in lead V4R is a useful indicator of right ventricular infarction. These patients have an in-hospital mortality of up to 30% and many benefit greatly from reperfusion therapy. Avoid nitrates and other vasodilators, and treat hypotension with intravenous fluids. Reperfusion after successful CPR. The invasive management of patients with return of spontaneous circulation (ROSC) after cardiac arrest (i.e. early coronary angiography (CAG) followed by immediate PCI if deemed necessary), particularly patients after prolonged resuscitation and having nonspecific ECG changes, has been controversial due to the lack of specific evidence and significant implications on resource utilisation (including transfer of patients to PCI centres). PCI following ROSC with ST-elevation. The highest prevalence of acute coronary lesion is observed in patients with ST segment elevation (STE) or left bundle branch block (LBBB) on post-ROSC electrocardiogram (ECG). There is no randomised study but as many observational studies reported a benefit regarding survival and neurological outcome, it is highly probable that this early invasive management is a strategy associated with a clinically relevant benefit in patients with ST segment elevation. A recent meta-analysis indicates that early angiography is associated with reduction of hospital mortality [OR 0.35 (0.31–0.41)] and increased neurologically favourable survival [OR 2.54 (2.17–2.99)].797 Based on the available data, emergent cardiac catheterisation lab evaluation (and immediate PCI if required) should be performed in selected adult patients with ROSC after OHCA of suspected cardiac origin with ST segment elevation on ECG.810 Observational studies also indicate that optimal outcomes after OHCA are achieved with a combination of targeted temperature management and PCI, which can be combined in a standardised post-cardiac-arrest protocol as part of an overall strategy to improve neurologically intact survival in this patient group. PCI following ROSC without ST-elevation. In patients with ROSC after cardiac arrest but without ST elevation, data are conflicting regarding the potential benefit of an emergent cardiac catheterisation lab evaluation, all coming from observational studies,410,412 or subgroup analysis.413 It is reasonable to discuss an emergent cardiac catheterisation lab evaluation after ROSC in patients with the highest risk of coronary cause of CA. A variety of factors such as patient age, duration of CPR, haemodynamic instability, presenting cardiac rhythm, neurologic status upon hospital arrival, and perceived likelihood of cardiac aetiology can influence the decision to undertake the intervention. In patients who present in a nonPCI centre transfer for angiography and PPCI if indicated should be considered on an individual basis, weighing the expected benefits from early angiography against the risks from patient transport. First aid First aid is defined as the helping behaviours and initial care provided for an acute illness or injury. First aid can be initiated by anyone in any situation. A first aid provider is defined as someone trained in first aid who should: • recognise, assess and prioritise the need for first aid • provide care using appropriate competencies • recognise limitations and seek additional care when needed The goals of first aid are to preserve life, alleviate suffering, prevent further illness or injury, and promote recovery. This 2015 definition for first aid, as created by the ILCOR First Aid Task Force, addresses the need to recognise injury and illness, the requirement to develop a specific skill base and the need for first aid providers to simultaneously provide immediate care and to activate emergency medical services or other medical care as required.811 First aid assessments and interventions should be medically sound and based on scientific evidence-based medicine or, in the absence of such evidence, on expert medical consensus. The scope of first aid is not purely scientific, as both training and regulatory requirements will influence it. Because the scope of first aid varies between countries, states and provinces, the guidelines contained herein may need to be refined according to circumstances, need, and regulatory constraints. First aid for medical emergencies Positioning of a breathing but unresponsive victim Several different side-lying recovery positions have been compared but overall no significant differences between the positions have been identified.812–814 K.G. Monsieurs et al. / Resuscitation 95 (2015) 1–80 55 Position individuals who are unresponsive but breathing normally into a lateral, side-lying recovery position as opposed to leaving them supine (lying on back). In certain situations such as resuscitation-related agonal respirations or trauma, it may not be appropriate to move the individual into a recovery position. Optimal position for a shock victim Place individuals with shock into the supine (lying on back) position. Where there is no evidence of trauma use passive leg raising to provide a further transient improvement in vital signs815–817; the clinical significance of this transient improvement is uncertain. Oxygen administration for first aid There are no direct indications for the use of supplemental oxygen by first aid providers.818–821 Supplemental oxygen might have potential adverse effects that complicate the disease course or even worsen clinical outcomes. If used, supplemental oxygen should be administered only by first aid providers who have been properly trained in its use and if they can monitor its effects. Bronchodilator administration The administration of a bronchodilator in asthma has been shown to decrease the time to resolution of symptoms in children and to reduce the time for the subjective improvement of dyspnoea in young adult asthma sufferers.822,823 Assist individuals with asthma who are experiencing difficulty in breathing with their bronchodilator administration. First aid providers must be trained in the various methods of administering a bronchodilator.824–826 Stroke recognition Stroke is a non-traumatic, focal vascular-induced injury of the central nervous system and typically results in permanent damage in the form of cerebral infarction, intracerebral haemorrhage and/or subarachnoid haemorrhage.827 Early admission to a stroke centre and early treatment greatly improves stroke outcome and highlights the need for first aid providers to quickly recognise stroke symptoms.828,829 There is good evidence that the use of a strokescreening tool improves the time to definitive treatment.830–833 Use a stroke assessment system to decrease the time to recognition and definitive treatment for individuals with suspected acute stroke. First aid providers must be trained in the use of FAST (Face, Arm, Speech Tool) or CPSS (Cincinnati Pre-hospital Stroke Scale) to assist in the early recognition of stroke. Aspirin administration for chest pain The early administration of aspirin in the pre-hospital environment, within the first few hours of the onset of chest pain due to suspected myocardial infarction, reduces cardiovascular mortality.834,835 In the pre-hospital environment, administer 150-300 mg chewable aspirin early to adults with chest pain due to suspected myocardial infarction (ACS/AMI). There is a relatively low risk of complications particularly anaphylaxis and serious bleeding.836–840 Aspirin should not be administered to patients who have a known allergy or contraindication to aspirin. Do not administer aspirin to adults with chest pain of unclear aetiology. The early administration of aspirin should never delay the transfer of the patient to a hospital for definitive care. Second dose of adrenaline for anaphylaxis Anaphylaxis is a potentially fatal, allergic reaction that requires immediate recognition and intervention. Adrenaline reverses the pathophysiological manifestations of anaphylaxis and remains the most important drug, especially if it is given within the first few minutes of a severe allergic reaction.287,841,842 In the pre-hospital setting, adrenaline is administered via prefilled auto-injectors, which contain one dose of 300 ␮g of adrenaline (adult dose) for intramuscular self-administration or assisted by a trained first aid provider. Administer a second intramuscular dose of adrenaline to individuals in the pre-hospital environment with anaphylaxis that has not been relieved within 5–15 minutes by an initial intramuscular auto-injector dose of adrenaline.843–852 A second intramuscular dose of adrenaline may also be required if symptoms re-occur. Hypoglycaemia treatment Hypoglycaemia in diabetes patients is usually a sudden and life-threatening event with the typical symptoms of hunger, headache, agitation, tremor, sweating, psychotic behaviour (frequently resembling drunkenness) and loss of consciousness. It is most important that these symptoms are recognised as hypoglycaemia as the victim requires rapid first aid treatment. Treat conscious patients with symptomatic hypoglycaemia with glucose tablets equating to glucose 15–20 g. If glucose tablets are not available, use other dietary forms of sugar.853–855 If the patient is unconscious or unable to swallow then oral treatment should be withheld due to the risk of aspiration, and the emergency medical services should be called. Exertion-related dehydration and rehydration therapy First aid providers are often called upon to assist at “hydration stations” for sporting events. Use 3–8% oral carbohydrate–electrolyte (CE) beverages for rehydration of individuals with simple exercise-induced dehydration.856–864 Alternative acceptable beverages for rehydration include water, 12% CE solution,856 coconut water,857,863,864 2% milk,861 or tea with or without carbohydrate electrolyte solution added.858,865 Oral hydration may not be appropriate for individuals with severe dehydration associated with hypotension, hyperpyrexia or mental status changes. Such individuals should receive care by an advanced medical provider capable of administering intravenous fluids. Eye injury from chemical exposure For an eye injury due to exposure to a chemical substance, take immediate action by irrigating the eye using continuous, large volumes of clean water. Irrigation with large volumes of water was more effective at improving corneal pH as compared to using low volumes or saline irrigation.866 Refer the individual for emergency professional review. First aid for trauma emergencies Control of bleeding Apply direct pressure, with or without a dressing, to control external bleeding where possible. Do not try to control major external bleeding by the use of proximal pressure points or elevation of an extremity. However it may be beneficial to apply localised cold therapy, with or without pressure, for minor or closed extremity bleeding.867,868 Where bleeding cannot be controlled by direct pressure it may be possible to control bleeding by the use of a haemostatic dressing or a tourniquet (see below). Haemostatic dressings Haemostatic dressings are commonly used to control bleeding in the surgical and military settings especially when the wound is in a non-compressible area such as the neck, abdomen, or groin.869–873 Use a haemostatic dressing when direct pressure cannot control severe external bleeding or the wound is in a position where direct pressure is not possible.874–877 Training is required to ensure the safe and effective application of these dressings. 56 K.G. Monsieurs et al. / Resuscitation 95 (2015) 1–80 Use of a tourniquet Haemorrhage from vascular injured extremities may result in life-threatening exsanguination and is one of the leading causes of preventable death on the battlefield and in the civilian setting.878,879 Tourniquets have been used in military settings for severe external limb bleeding for many years.880,881 The application of a tourniquet has resulted in a decrease in mortality.880–889 Use a tourniquet when direct wound pressure cannot control severe external bleeding in a limb. Training is required to ensure the safe and effective application of a tourniquet. Straightening an angulated fracture Fractures, dislocations, sprains and strains are extremity injuries commonly cared for by first aid providers. Do not straighten an angulated long bone fracture. Protect the injured limb by splinting the fracture. Realignment of fractures should only be undertaken by those specifically trained to perform this procedure. First aid treatment for an open chest wound The correct management of an open chest wound is critical, as the inadvertent sealing of these wounds by the incorrect use of occlusive dressings or device or the application of a dressing that becomes occlusive may result in the potential life-threatening complication of a tension pneumothorax.890 Leave an open chest wound exposed to freely communicate with the external environment without applying a dressing, or cover the wound with a non-occlusive dressing if necessary. Control localised bleeding with direct pressure. Spinal motion restriction In suspected cervical spine injury it has been routine to apply cervical collars to the neck, in order to avoid further injury from spinal movement. However, this intervention has been based on consensus and opinion rather than on scientific evidence.891,892 Furthermore, clinically significant adverse effects such as raised intracranial pressure have been shown to occur following the application of a cervical collar.893–897 The routine application of a cervical collar by a first aid provider is no longer recommended. In suspected cervical spine injury, manually support the head in a position limiting angular movement until experienced healthcare provision is available. Recognition of concussion Although a concussion scoring system would greatly assist first aid providers in the recognition of concussion,898 there is no simple validated scoring system in use in current practice. An individual with a suspected concussion should be evaluated by a professional. Cooling of burns Immediate active cooling of thermal burns, defined as any method undertaken to decrease local tissue temperature, is a common first aid recommendation for many years. Cooling thermal burns will minimise the resulting depth of the burn899,900 and possibly decrease the number of patients that will eventually require hospital admission for treatment.901 The other perceived benefits of cooling are pain relief and reduction of oedema, reduced infection rates and a faster wound healing process. Actively cool thermal burns as soon as possible for a minimum of 10 min duration using water. Care must be taken when cooling large thermal burns or burns in infants and small children so as not to induce hypothermia. Burn dressings A broad range of burn wound dressings are available,902 but no scientific evidence was found to determine which type of dressings, wet or dry, is most effective. Subsequent to cooling, burns should be dressed with a loose sterile dressing. Dental avulsion Following a fall or accident involving the face, a tooth can be injured or avulsed. Immediate re-implantation is the intervention of choice but it is often not possible for first aid providers to reimplant the tooth due to a lack of training or skills in that procedure. If a tooth cannot be immediately re-implanted, store it in Hank’s BalancedSaltSolution.If thisis notavailableusePropolis,eggwhite, coconut water, ricetral, whole milk, saline or Phosphate Buffered Saline (in order of preference) and refer the individual to a dentist as soon as possible. Education in first aid First aid education programmes, public health campaigns and formal first aid training are recommended in order to improve prevention, recognition and management of injury and illness.901,903,904 Principles of education in resuscitation The chain of survival13 was extended to the formula of survival11 because it was realised that the goal of saving more lives relies not only on solid and high quality science but also on the effective education of lay people and healthcare professionals.905 Ultimately, those who are engaged in the care of cardiac arrest victims should be able to implement resource efficient systems that can improve survival after cardiac arrest. Basic level training Who to train and how to train Basic life support (BLS) is the cornerstone of resuscitation and it is well established that bystander CPR is critical to survival in out-of-hospital cardiac arrests. Chest compressions and early defibrillation are the main determinants of survival from outof-hospital cardiac arrest and there is some evidence that the introduction of training for lay people has improved survival at 30 days and 1 year.906,907 There is evidence that training lay people in BLS is effective in improving the number of people willing to undertake BLS in a real situation.908–910 For high-risk populations (e.g. areas where there is high risk of cardiac arrest and low bystander response), recent evidence shows that specific factors can be identified which will enable targeted training based on the community’s unique characteristics.911,912 There is evidence that likely rescuers in these populations are unlikely to seek training on their own but that they gain competency in BLS skills and/or knowledge after training.913–915 They are willing to be trained and are likely to share training with others.913,914,916–918 One of the most important steps in increasing the rate of bystander resuscitation and improving survival worldwide is to educate all school children. This can be achieved easily by teaching children for just two hours per year, beginning at the age of 12 years old.919 At that age, school children have a positive attitude towards learning resuscitation and both medical professionals and teachers require special training to achieve these results with children.920 It has been shown that well trained EMS dispatchers are able to improve bystander CPR and patient outcomes.921 However there are concerns with their ability to recognise cardiac arrest particularly in relation to agonal breathing.50 Consequently training of EMS dispatchers should include a focus on the identification and the significance of agonal breathing,52 and the importance of K.G. Monsieurs et al. / Resuscitation 95 (2015) 1–80 57 seizures as aspects of cardiac arrest. In addition EMS dispatchers need to be taught simplified scripts for instructing bystanders in CPR.52 BLS/AED curricula should be tailored to the target audience and kept as simple as possible. Increasing access to different modalities of training (e.g. the use of digital media, on-line, instructor-led teaching) and self-directed learning, offer alternative means of teaching both lay and professional providers. Self-instruction programmes with synchronous or asynchronous hands-on practice (e.g., video, DVD, on-line training, computer giving feedback during training) appear to be an effective alternative to instructorled courses for laypeople and healthcare providers learning BLS skills.922–926 All citizens should be taught how to perform chest compressions as a minimum requirement. Ideally, full CPR skills (compressions and ventilation using a 30:2 ratio) should be taught to all citizens. When training is time-limited or opportunistic (e.g., EMS telephone instructions to a bystander, mass events, public campaigns, internet-based viral videos), it should focus on compression-only CPR. Local communities may want to consider their approach based on their local population epidemiology, cultural norms and bystander response rates. For those initially trained in compression-only CPR, ventilation may be covered in subsequent training. Ideally these individuals should be trained in compression-only CPR and then offered training in chest compressions with ventilation at the same training session. Those laypersons with a duty of care, such as first aid workers, lifeguards, and carers, should be taught standard CPR i.e. chest compressions and ventilation. Most studies show that CPR skills decay within three to six months after initial training.924,927–930 AED skills are retained for longer than BLS skills alone.931,932 There is some evidence that higher frequency, short burst training could potentially enhance BLS training and reduce skill decay.928,930–932 A systematic appraisal of the literature determined that audiovisual feedback devices during resuscitation resulted in rescuers providing chest compression parameters closer to recommendations but no evidence was found that this translates into improved patient outcomes.933 Advanced level training Advanced level courses cover the knowledge, skills and attitudes needed to function as part of (and ultimately lead) a resuscitation team. Supportive evidence has emerged for blended learning models (independent electronic learning coupled with a reduced duration instructor-led course). Simulation training is an integral part of resuscitation training and showed improvement in knowledge and skill performance compared to training without simulation.934 Evidence that participants in ALS courses learn more or better CPR by using high-fidelity manikins is lacking. With this in mind, high-fidelity manikins can be used but if they are not available, the use of low-fidelity manikins is acceptable for standard advanced life support training. Training of non-technical skills (NTS) including leadership and team training to improve CPR outcome An increase in hospital survival from paediatric cardiac arrest and in surgical patients was found after implementation of team training programmes.935,936 Resuscitation team performance has been shown to improve in actual cardiac arrest or simulated inhospital advanced life support scenarios, when specific team or leadership training is added to advanced level courses.937–941 If the simulated scenario training is followed by debriefing then learning will occur, as opposed to scenario training without debriefing.942 Studies have failed to show a difference between debriefing with and without the use of video clips.943,944 There is emerging evidence that frequent manikin-based refresher training in the form of low-dose in-situ training may save costs, reduce the total time for retraining, and it seems to be preferred by the learners.945,946 Refresher training is invariably required to maintain knowledge and skills; however, the optimal frequency for refresher training is unclear.945,947–949 Implementation and change management The formula for survival concludes with ‘local implementation’.11 The combination of medical science and educational efficiency is not sufficient to improve survival if there is poor or absent implementation. Impact of guidelines In each country, resuscitation practice is largely based on the implementation of internationally agreed resuscitation guidelines. Studies about the impact of international resuscitation guidelines suggest a positive effect on CPR performance,906,950 return of spontaneous circulation105,906,950–953 and survival to hospital discharge.105,906,950–954 Use of technology and social media The prevalence of smartphones and tablet devices has led to the generation of numerous approaches to implementation through the use of ‘apps’ and also social media. Measuring performance of resuscitation systems As systems evolve to improve the outcomes from cardiac arrest, we need to accurately assess their impact. Measuring performance and implementing quality improvement initiatives will further enhance systems to deliver optimal results.939,955–960 Debriefing after resuscitation in the clinical setting Feedback to members of an in-hospital cardiac arrest team about their performance in an actual cardiac arrest (as opposed to the training environment) can lead to improved outcomes. This can either be real-time and data-driven (e.g. use of feedback devices on cardiac compression metrics) or in a structured post-event performance focused debriefing.939,961 Medical emergency teams (MET) for adults When considering the chain of survival for cardiac arrest,13 the first link is the early recognition of the deteriorating patient and prevention of cardiac arrest. We recommend the use of a MET because they have been associated with a reduced incidence of cardiac/respiratory arrest962–968 and improved survival rates.963,965–968,962,969 The MET is one part of a rapid response system (RRS), which includes staff education about the signs of patient deterioration, appropriate and regular vital signs monitoring of patients, clear guidance (e.g. via calling criteria or early warning scores) to assist staff in the early detection of patient deterioration, a clear uniform system of calling for assistance and a clinical response to calls for assistance. Training in resource limited settings There are many different techniques for teaching ALS and BLS in resource limited settings. These include simulation, multimedia learning, self-directed learning, limited instruction, and 58 K.G. Monsieurs et al. / Resuscitation 95 (2015) 1–80 self-directed computer-based learning. Some of these techniques are less expensive and require less instructor resources enabling wider dissemination of ALS and BLS training. The ethics of resuscitation and end-of-life decisions The principle of patient autonomy Respect for autonomy refers to a physician’s obligation to respect a patient’s preferences and to make decisions that accord with a patient’s values and beliefs. Patient-centred healthcare places the patient at the centre of the decision-making process, rather than as a recipient of a medical decision. Applying this principle during cardiac arrest where the patient is often unable to communicate preferences is challenging.970–973 The principle of beneficence Beneficence implies that interventions must benefit the patient after assessing relevant risk and benefit. Evidence-based clinical guidelines exist to assist healthcare professionals in deciding which treatment approaches are most appropriate.11,974,975 The principle of non-maleficence CPR has become the norm for most patients with acute, life-threatening conditions.976,977 CPR is, however, an invasive procedure with a low likelihood of success. CPR should, therefore, not be performed in futile cases. It is difficult to define futility in a way that is precise, prospective and applicable to the majority of cases. The principle of justice and equitable access Justice implies that health resources are distributed equally and fairly, irrespective of the patient’s social status, in the absence of discrimination, with the right for each individual to receive the current standard of care. Medical futility Resuscitation is considered futile when the chances of good quality survival are minimal.978 The decision not to attempt resuscitation does not require the consent of the patient or of those close to him, who often have unrealistic expectations.979,980 Decision makers have a duty to consult the patient or a representative if the patient lacks capacity, in accordance with a “clear and accessible policy”.981–983 Some countries allow prospective decisions to withhold CPR whilst in others countries or religions withholding CPR is not allowed or considered illegal. There is a lack of consistency in terms such as ‘do not attempt resuscitation (DNAR)’, ‘do not attempt cardiopulmonary resuscitation (DNACPR)’ or ‘allow natural death (AND)’. This confusing use of acronyms may generate misunderstandings in national legislation and jurisdiction.984,985 Advance directives Advance directives are decisions about treatment provided prospectively by an individual in case they are unable to participate directly in medical decision-making at some point in the future.986 Periodic reviews of directives are required to ensure patients’ current wishes and circumstances are accurately reflected.979,987,988 The legal status of advance directives in the national legislation of European countries is very disparate.989 Patient-centred care The increasing centricity of the patient within healthcare demands that we seek to understand the perspective of the survivor of cardiac arrest. This requires a further commitment to work together with the public, with the survivors of cardiac arrest and their families as partners in this process.990 In-hospital cardiac arrest Following in-hospital cardiac arrest (IHCA), the default position is to start resuscitation unless a decision was made to withhold CPR. Resuscitation decisions should be reviewed. Determining when CPR is likely to be unsuccessful or futile, is difficult. Prediction studies are particularly dependent on system factors such as time to start of CPR and time to defibrillation. The total study cohort but may not be applicable to an individual case. Decisions should not be made based on a single element, such as age.991 There will remain grey areas where judgement is required for individual patients. Out-of-hospital cardiac arrest The decision to start or discontinue CPR is challenging outside a hospital because of the lack of sufficient information about a patient’s wishes and values, comorbidities and baseline health status.992,993 Withholding or withdrawing CPR Transport to hospital with ongoing CPR Healthcare professionals should consider withholding or withdrawing CPR in children and adults when: • the safety of the provider can no be assured; • there is obvious mortal injury or irreversible death; • a valid advance directive becomes available; • there is other strong evidence that further CPR would be against patient’s values and preferences or is considered futile; • asystole for more than 20 min despite ongoing ALS, in the absence of a reversible cause. After stopping CPR, the possibility of ongoing support of the circulation and transport to a dedicated centre with the perspective of organ donation should be considered. Healthcare professionals should consider transport to hospital with ongoing CPR when, in the absence of the above CPR withdrawal criteria, there is one or more of the following present: • EMS witnessed arrest • ROSC at any moment • VT/VF as presenting rhythm • Presumed reversible cause (e.g. cardiac, toxic, hypothermia) This decision should be considered early in the process e.g. after 10 min of ALS without ROSC and in view of the circumstances e.g. distance, CPR delay and presumed CPR quality in view of patient characteristics Paediatric cardiac arrest Despite differences in pathophysiology and aetiology, the ethical framework for decision-making in paediatric cardiac arrest does not differ much. In most countries, legal authorities are involved in cases of sudden unexplained or accidental death. In some countries systematic K.G. Monsieurs et al. / Resuscitation 95 (2015) 1–80 59 review of all child deaths is organised to get a better understanding and knowledge for the prevention of future children’s deaths.994 Provider safety Infectious disease epidemics have raised concerns about the safety of healthcare providers involved in the care of cardiac arrest patients. When attempting CPR in infectious patients healthcare professionals must use proper protective equipment and be sufficiently trained in its use.995,996 Organ donation The primary goal of resuscitation is to save the patient’s life.997 Nonetheless, resuscitation efforts may result in brain death. In these cases, the aim of resuscitation could change to the preservation of organs for possible donation.998 The duty of resuscitation teams for the living patient should not be confused with the duty of physicians for the dead donors, where the organs are preserved to save other people’s lives. All European countries should enhance their efforts to maximise the possibility of organ donation from cardiac arrest patients who became brain dead or after stopping resuscitation in case of CPR failure.999 Variability in ethical CPR practices in Europe Representatives of 32 European countries where the activities of the European Resuscitation Council are organised, have responded to questions regarding local ethical legislation and practice of resuscitation, and organisation of out-of-hospital and in-hospital resuscitation services. Equal access to emergency care and to early defibrillation is now well established. The principle of patient autonomy is now legally supported in the majority of countries. However in less than half the countries are family members usually allowed to be present during CPR. At this time euthanasia and physician-assisted suicide are controversial subjects in many European countries and the discussion is ongoing in several European countries. Healthcare professionals should know and apply the established national and local legislation and policies. Family presence during resuscitation The ERC supports relatives being offered the choice of being present during a resuscitation attempt whilst cultural and social variations must be understood and appreciated with sensitivity. DNAR decisions and discussions relating to DNAR should be recorded clearly in the patient’s notes.1001–1004 Over time the situation or the perspectives of patients might change and DNAR orders should be revised accordingly.1005 Training health care professionals about DNAR issues Healthcare professionals should receive training about the legal and ethical basis of DNAR decisions and about how to communicate effectively with patients, relatives or next of kin. Quality of life, supportive care and end-of-life decisions need to be explained as an integrative part of the medical and nursing practice.1006 Practicing procedures on the recently dead As there is wide diversity in opinion about practicing procedures on the recently dead, healthcare students and teaching professionals are advised to learn and follow the established legal, regional and local hospital policies. Research and informed consent Research in the field of resuscitation is necessary to test commonly interventions with uncertain efficacy or new potentially beneficial treatments.1007,1008 To include participants in a study, informed consent must be obtained. In emergencies, there is often insufficient time to obtain informed consent. Deferred consent or exception to informed consent with prior community consultation, are considered ethically acceptable alternatives for respecting autonomy.1009,1010 Following 12 years of ambiguity, a new European Union (EU) Regulation permitting deferred consent is expected to harmonise and foster emergency research across Member States.1008,1009,1011,1012 Audit of in-hospital cardiac arrests and registry analyses Local CPR management can be improved through post-CPR debriefing to ensure a PDCA (plan-do-check-act) circle of quality improvement. Debriefing enables identification of CPR quality errors and prevents their repetition.939,961,1013 Resuscitation teambased infrastructure and multilevel institutional audit,1014 accurate reporting1015 of resuscitation attempts at national audit level and/or multinational registry level, and subsequent data analysis and feedback from reported results may contribute to continuous improvement of in-hospital CPR quality and cardiac arrest outcomes.362,1016–1019 Conflict of interest policy for the 2015 ERC Guidelines All authors of these ERC Guidelines 2015 have signed COI declarations (Appendix 2). Acknowledgements Many individuals have supported the authors in the preparation of these guidelines. We particularly thank An De Waele, Annelies Pické, Hilary Phelan and Bart Vissers from the ERC Office for their administrative support and for co-ordinating much of the work on the algorithms and on the illustrations. We are also indebted to Rosette Vanlangendonck and to Luke Nolan for their contribution to editing the references. Appendix 1. The ERC Guidelines 2015 Writing Group. Gamal Eldin Abbas Khalifa, Annette Alfonzo, Hans-Richard Arntz, Helen Askitopoulou, Abdelouahab Bellou, Farzin Beygui, Dominique Biarent, Robert Bingham, Joost J.L.M. Bierens, Bernd W. Böttiger, Leo L. Bossaert, Guttorm Brattebø, Hermann Brugger, Jos Bruinenberg, Alain Cariou, Pierre Carli, Pascal Cassan, Maaret Castrén, Athanasios F. Chalkias, Patricia Conaghan, Charles D. Deakin, Emmy D.J. De Buck, Joel Dunning, Wiebe De Vries, Thomas R. Evans, Christoph Eich, Jan-Thorsten Gräsner, Robert Greif, Christina M. Hafner, Anthony J. Handley, Kirstie L. Haywood, Silvija Hunyadi-Antiˇcevi´c, Rudolph W. Koster, Anne Lippert, David J. Lockey, Andrew S. Lockey, Jesús López-Herce, Carsten Lott, Ian K. Maconochie, Spyros D. Mentzelopoulos, Daniel Meyran, Koenraad G. Monsieurs, Nikolaos I. Nikolaou, Jerry P. Nolan, Theresa Olasveengen, Peter Paal, Tommaso Pellis, Gavin D. Perkins, Thomas Rajka, Violetta I. Raffay, Giuseppe Ristagno, Antonio RodríguezNú˜nez, Charles Christoph Roehr, Mario Rüdiger, Claudio Sandroni, Susanne Schunder-Tatzber, Eunice M. Singletary, Markus B. Skrifvars, Gary B. Smith, Michael A. Smyth, Jasmeet Soar, Karl-Christian Thies, Daniele Trevisanuto, Anatolij Truhláˇr, Philippe G. Vandekerckhove, Patrick Van de Voorde, Kjetil Sunde, Berndt Urlesberger, Volker Wenzel, Jonathan Wyllie, Theodoros T. Xanthos, David A. Zideman. 60 K.G. Monsieurs et al. / Resuscitation 95 (2015) 1–80 Appendix 2. Conflicts of interest Author Section number Guideline Declared conflict of interest Koen Monsieurs Section 1 Executive summary No conflict of interest reported Jerry P. Nolan Editor-in-Chief Resuscitation Leo Bossaert No conflict of interest reported Robert Greif Editor Trends in Anesthesia and Critical Care Ian Maconochie No conflict of interest reported Nikolaos Nikolaou Research grant Fourier trial-AMGEN Gavin D. Perkins Editor Resuscitation Jasmeet Soar Editor Resuscitation Anatolij Truhlar No conflict of interest reported Jonathan Wyllie No conflict of interest reported David Zideman No conflict of interest reported Gavin D. Perkins Section 2 Adult basic life support and automated external defibrillation Editor Resuscitation Anthony J. Handley Medical advisor BA, Virgin, Places for people, Life saving Societies, Trading Company Secretary RCUK Giuseppe Ristagno Expert advice ZOLL: ECG interpretation Jan-Thorsten Grasner No conflict of interest reported Jasmeet Soar Editor Resuscitation Koen Monsieurs No conflict of interest reported Maaret Castren Medical advisory Board Falck Foundation Michael Smyth No conflict of interest reported Ruud Koster Medical advisor Physio Control and HeartSine; Research grants Physio Control, Philips, Zoll, Cardiac Science, Defibtech, Jolife Theresa Mariero Olasveengen No conflict of interest reported Violetta Raffay No conflict of interest reported Volker Wenzel Research grants, Medical advisor, Speakers honorarium “AOP Orphan” Pharma Jasmeet Soar Section 3 Adult advanced life support Editor Resuscitation Bernd Böttiger No conflict of interest reported Carsten Lott No conflict of interest reported Charles Deakin Director Prometheus Medical Ltd Claudio Sandroni No conflict of interest reported Gavin D. Perkins Editor Resuscitation Gary B. Smith The Learning Clinic company (VitalPAC): research advisor, family shareholder Jerry P. Nolan Editor-in-Chief Resuscitation Kjetil Sunde No conflict of interest reported Markus Skrifvars No conflict of interest reported Pierre Carli No conflict of interest reported Thomas Pellis Speakers honorarium BARD Medica Anatolij Truhlar Section 4 Cardiac arrest in special circumstances No conflict of interest reported Annette Alfonzo No conflict of interest reported Carsten Lott No conflict of interest reported Charles D. Deakin Director Prometheus Medical Ltd Claudio Sandroni No conflict of interest reported David A. Zideman No conflict of interest reported David J. Lockey No conflict of interest reported Gamal Eldin Abbas Khalifa No conflict of interest reported Gavin D. Perkins Editor Resuscitation Guttorm Brattebo Chair BEST foundation Hermann Brugger Medical advisor EURAC/ICAR alpine medicine Jasmeet Soar Editor Resuscitation Jerry P. Nolan Editor-in-Chief Resuscitation Joel Dunning Speakers honorarium CARDICA Joost J.L.M. Bierens Board member/Advisor KNRM; KNRD; Life Saving societies K.G. Monsieurs et al. / Resuscitation 95 (2015) 1–80 61 Author Section number Guideline Declared conflict of interest Karl-Christian Thies Chair European Trauma Course Organisation ETCO Peter Paal Speakers honorarium Vidacare, Zoll Ruud Koster Medical advisor Physio Control and HeartSine; Research grants Physio Control, Philips, Zoll, Cardiac Science, Defibtech, Jolife Silvija Hunyadi-Anticevic No conflict of interest reported Jerry P. Nolan Section 5 Post-resuscitation care Editor-in-Chief Resuscitation Alain Cariou Speakers honorarium BARD-France Bernd Böttiger No conflict of interest reported Charles Deakin Director Prometheus Medical Ltd Claudio Sandroni No conflict of interest reported Hans Friberg Speakers honorarium Bard Medical-Natus Inc Jas Soar Editor Resuscitation Kjetil Sunde No conflict of interest reported Tobias Cronberg No conflict of interest reported Veronique Moulaert No conflict of interest reported Ian Maconochie Section 6 Paediatric life support No conflict of interest reported Antonio Rodriguez-Nunez No conflict of interest reported Christoph Eich No conflict of interest reported David Zideman No conflict of interest reported Dominique Biarent Board member SME “Souvez mon Enfant” charity Jesus Lopez-Herce No conflict of interest reported Patrick Van de Voorde No conflict of interest reported Robert Bingham No conflict of interest reported Thomas Rajka No conflict of interest reported Jonathan Wyllie Section 7 Resuscitation and support of transition of babies at birth No conflict of interest reported Berndt Urlesberger No conflict of interest reported Charles Christoph Rohr Educational grant Fischer&Paykel and Medical advisor STEPHAN company Daniele Trevisanuto No conflict of interest reported Jos Bruinenberg No conflict of interest reported Mario Rüdiger Speakers honorarium Chiesi, Lyomark; Research grant SLE device Nikolaos Nikolaou Section 8 Initial management of acute coronary syndromes Research grant Fourier trial-AMGEN Abdel Bellou No conflict of interest reported Alain Cariou Speakers honorarium BARD-France Farzin Beygui Speakers honorarium Astra Zeneca, Lilly, Daichi-Sankyo Hans-Richard Arntz No conflict of interest reported Leo Bossaert No conflict of interest reported David Zideman Section 9 First aid No conflict of interest reported Anthony J. Handley Medical advisor BA, Virgin, Places for people, Life saving Societies, Trading Company Secretary RCUK Christina Hafner No conflict of interest reported Daniel Meyran French Red Cross: Medical advisor Emmy De Buck Belgian Red Cross-Flanders: employee Eunice Singletary American Red Cross Advisory Council member Pascal Cassan French Red Cross Head Global First Aid Defence Center Philippe Vandekerckhove Red Cross Belgium: employee Susanne Schunder-Tatzber OMV Austrian Oil&Gas company: Health Manager Thanos Chalkias No conflict of interest reported Tom Evans No conflict of interest reported Robert Greif Section 10 Principles of education in resuscitation Editor Trends in Anesthesia and Critical Care Andy Lockey Medical advisor “First on Scene First Aid” company Anne Lippert No conflict of interest reported 62 K.G. Monsieurs et al. / Resuscitation 95 (2015) 1–80 Author Section number Guideline Declared conflict of interest Koen Monsieurs No conflict of interest reported Patricia Conoghan No conflict of interest reported Wiebe De Vries Training organisation ACM employee Leo Bossaert Section 11 The ethics of resuscitation and end-of-life decisions No conflict of interest reported Gavin D. Perkins Editor Resuscitation Helen Askitopoulou No conflict of interest reported Jerry P. Nolan Editor-in-Chief Resuscitation Kirstie L. Haywood No conflict of interest reported Patrick Van de Voorde No conflict of interest reported Robert Greif Editor Trends in Anaesthesia and Critical Care Spyros Mentzelopoulos No conflict of interest reported Theodoros Xanthos President Hellenic Society CPR www.ekab.gr, Lab research grants ELPEN Pharma Violetta Raffay No conflict of interest reported References 1. Perkins GD, Handley AJ, Koster KW, et al. 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