Respiratory system



Anat dých sys Kiss



Regulation of breathing



Control of ventilation
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•Breathing is an automatic process that takes place unconsciously. Automaticity of breathing comes
from regular (rhythmic) activity of groups of neurons anatomically localized in the medulla and its
vicinity.

•They can be divided into three main groups:
•
•dorsal respiratory group – placed bilaterally on the dorsal side of the medulla oblongata, only
inspiratory neurons, sending axons to motoneurons of inspiratory muscles (diaphragm, external
intercostal muscles; their activation=inspiration, their relaxation=expiration; participates on
inspiration at rest and forced inspiration
•
•ventral respiratory group - located on the ventrolateral part of the medulla oblongata, the upper
part: neurons whose axons of motor neurons activate the main and auxiliary inspiratory muscles; the
lower part: expiratory neurons which innervate expiratory muscles (internal intercostal muscles).
Neurons in this group operate only during forced inspiration and forced expiration.
•
•Pontine respiratory group - pneumotaxic center - dorsally placed on top of the pont, contributes
to the frequency and depth of breathing; affects the activity of respiratory neurons in the medulla
oblongata.

Chemical factors affecting the respiratory center:
•Central chemoreceptors
-on the front side of the medulla
-sensitive only to increase of arterial pCO2 (by increasing H+ )
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-Notice:
-central chemoreceptor are stimulated by other types of acidosis (lactate acidosis, ketoacidosis)

•Peripheral chemoreceptors
•– located in the aortic and carotid bodies
•-primarily sensitive to decrease in arterial pO2, particularly to decrease of O2 under 10-13 kPa
in the arterial blood.
•They convey their sensory information to the medulla via the  vagus nerve and glossopharyngeal
nerve.
•
•Mechanism of action: Decreased  ATP production in mitochondria leads to depolarization of
receptors membrane and to excitation of chemoreceptor
http://www.medicine.mcgill.ca/physio/resp-web/sect8.htm,







Modulation of respiratory output
Major parameters for feedback control – classical gases:pO2, pCO2, pH
In additin to these, the respiratory system receives input from two other major sources:
1. variety of stretch and chemical/irritant receptors  that monitor the size of airways and the
presence of noxious agentsreceptors in respiratory system
2. Higher CNS centers that modulate respiratory activity for the sake of nonrespiratory activities
Irritants receptors on mucose of  respiratory system – rapidly adapting
Stimulus:  agens - chemical substances (histamin, serotonin, prostaglandins, ammonia, cigarette
smoke).
Respons: increase mucus secretion, constriction of larynx and brochus
C-fibre receptors (juxtacapillary=J receptors)– free nerve ending of n.vagus (unmyelinated axon) in
intersticium of bronchus and alveolus;
Stimulus: Mechanical irritans (pulmonary hypertension, pulmonary oedema)+chemical
Response: hypopnoe, rapid shallow breathing, bronchoconstriction, cough
Stretch receptors  slowly adapting (mechanoreceptors in tracheobronchial tree that detect the
changes in lung volume by sensing the stretch receptors of the airway wall), inform to brain about
the lung volume to optimize respiratory; its irritants triggered decrese activity of respiratory
centre – Hering-Breuer´s  reflexes. (protecting the lungs from overinflation/deflation)

Baroreceptors – suppresses activity of  respiratory centre
Irritants of proprioreceptors of muscles, tendons during active and pasive movements of limbs
Influenced activity of respiratory neurons  (increase minute ventilation during work load)
Limbic system, hypothalamus – strong pain, emotion
Tractus corticospinalis =cortex – activated RC during work load
temperature

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•Types of anesthaesia in animal experiments
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inhalation
Intra-muscular application
= i.m.

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Upraveno dle: Poopesko Peter a kol. (1990)
•Anatomy of neck in laboratory rat
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TRACHEA
N. VAGUS
A. CAROTIS
ENDOTRACHEAL CANNULA

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HERING-BREUER „inflation“ REFLEX
HB před vagotomií001
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REFLEX STOP BREATHING
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ARTIFACTS
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ARTIFACTS
Breathing at rest
Breathing at rest

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Changes of breathing after VAGOTOMY
klidové dých po vagotomii004
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One-side  VAGOTOMY
Both-side VAGOTOMY
inspirium
expirium

Periodic breathing
•It is not regular, rhythmic, but respiration occurs in periods ("a moment to breathe, take a
moment to not breathe„)
•
•CHEYNE-STOKES
•BIOT‘S
•„gasping“
•KUSSMAUL




Hypoxia, hypoxemia
•Hypoxia is a general name for a lack of oxygen in the body or individual tissues.
•Hypoxemia is lack of oxygen in arterial blood.
•Complete lack of oxygen is known as anoxia.
The most common types of hypoxia:
1.Hypoxic - physiological: stay at higher altitudes, pathological: hypoventilation during lung or
neuromuscular diseases
2.Transport (anemic) - reduced transport capacity of blood for oxygen (anemia, blood loss, CO
poisoning)
3.Ischemic (stagnation) - restricted blood flow to tissue (heart failure, shock states, obstruction
of an artery)
4.Histotoxic - cells are unable to utilize oxygen (cyanide poisoning - damage to the respiratory
chain)

S02401-002-f007
pO2  =  1 mmHg


Hypercapnia
• Hypercapnia - increase of concentration of carbon dioxide in the blood or in tissues that is
caused by retention of CO2 in the body
•  possible causes: total alveolar hypoventilation (decreased respiration or extension of dead
space)
•  mild hypercapnia (5 -7 kPa) causes stimulation of the respiratory center (therapeutic use:
pneumoxid = mixture of oxygen + 2-5% CO2)
•  hypercapnia around 10 kPa - CO2 narcosis - respiratory depression (preceded by headache,
confusion, disorientation, a feeling of breathlessness)
•hypercapnia over 12 kPa - significant respiratory depression - coma and death.




Travelling by aircraft
(On board aicraft is pressure as on 2000 m above sea level)
High risk for patients with diseases:
- concentration of hemoglobin  lower than 60 %
- severe step of atherosclerosis
- cardial insuficiency
- respiratory insuficiency
- non-treated hypertension (BP ower 200/100mmHg)

Toxicity of oxygen
The toxicity seems to be due to the production of the superoxid anion and H2O2
Causes: - lost of possibility binding CO2 in venous blood
- in lungs – pulmonary edoema – decrease CO2 expenditure
Critical values > 40 kPa (300 mmHg) –dependence on time

Toxicity of oxygen
Exposure – 8 hours:- respiratory passages became irritated
   - Substernal distress
   - Nasal congestion
   - Sore throat
   - Cough
- 24-48 hours:
- damage of lungs – decrease production of surfactant

Recommendation:
100 % - give discontinuosly


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