ELECTROCARDIOGRAPHY (ECG)

The heart is a muscular organ, which pumps blood through the blood vessels of the circulatory
system. Blood provides the body with oxygen and nutrients, as well as assists in the removal of
metabolic wastes. The heart is located in the middle compartment of the chest.

In humans the heart is divided into four chambers: upper left and right atria; and lower left and
right ventricles. Commonly the right atrium and ventricle are referred together as the right heart
and their left counterparts as the left heart. The heart is enclosed in a protective sac, the
pericardium, which also contains a small amount of fluid. The wall of the heart is made up of three
layers: epicardium, myocardium, and endocardium.

The heart pumps blood with a rhythm determined by a group of pacemaking cells in the sinoatrial
node. These generate a current that causes contraction of the heart, traveling through the
atrioventricular node and along the conduction system of the heart. The heart receives blood low in
oxygen from the systemic circulation, which enters the right atrium from the superior and inferior
venae cavae and passes to the right ventricle. From here it is pumped into the pulmonary
circulation, through the lungs where it receives oxygen and gives off carbon dioxide. Oxygenated
blood then returns to the left atrium, passes through the left ventricle and is pumped out through
the aorta to the systemic circulation−where the oxygen is used and metabolized to carbon dioxide.

Effective blood flow with minimal demand for energy requires synchronized cardiac cycles. The
impulse for the contraction of heart cells (cardiomyocytes) is the formation of action potential
(excitation) on the cell’s plasma membrane. Cardiomyocytes create functional syncytium, this means
that the cells are electrically connected (not isolated). Action potential formed in a certain part
of the myocardium extends to the whole heart.

There are two types of cells within the heart:

-         the cardiomyocytes

-         the cardiac pacemaker cells.

Cardiomyocytes make up the atria (the chambers in which blood enters the heart) and the ventricles
(the chambers where blood is collected and pumped out of the heart). These cells are responsible
for contraction. The cardiac pacemaker cells ensure the formation of action potential and its
extension in the heart to the cardiomyocytes. The cardiac pacemaker cells are determined by three
basic characteristics of heart activity:

1. Automaticity. Some cardiac fibers have the capability of self-excitation, a process that can
cause automatic rhythmical discharge and contraction. This is especially true of the fibers of the
heart’s specialized conducting system, including the fibers of the sinus node. For this reason, the
sinus node ordinarily controls the rate of beat of the entire heart.

2. Autonomy. Impulses for contraction produced in the heart itself. Nervous or humoral mechanisms
of regulation may regulate only frequency and cardiac contractility. Heart is able to work even
outside the organism in case of constant nutrients and oxygen supply.

3. Rhytmicity. Impulses are generated regularly with a certain frequency.


SPECIALIZED EXCITATORY AND CONDUCTIVE SYSTEM OF THE HEART

Figure shows the specialized excitatory and conductive system of the heart that controls cardiac
contractions. The figure shows the sinus node (also called sinoatrial or S-A node), in which the
normal rhythmical impulse is generated; the internodal pathways that conduct the impulse from the
sinus node to the atrioventricular (A-V) node; the A-V node, in which the impulse from the atria is
delayed before passing into the ventricles; the A-V bundle, which conducts the impulse from the
atria into the ventricles; and the left and right bundle branches of Purkinje fibers, which conduct
the cardiac impulse to all parts of the ventricles.

ACTION POTENTIAL OF CARDIAC CELLS

Textové pole: mV Excitable cells respond to adequate stimulus stereotypical electrical responses
that we call action potential. Action potential varies according to the type of heart cells and its
localization. The action potential is the result of a fine balance between the flowing ion
currents.

ACTION POTENTIAL OF CARDIOMYOCYTE

Textové pole: µA

time, ms

Myocardial fibers have a resting membrane potential of approximately –80 mV.

The transmembrane action potential of single cardiac muscle cells is characterized by:

·        rapid depolarization (phase 0),

·        an initial rapid repolarization (phase 1),

·        a plateau (phase 2),

·        a slow repolarization (phase 3),

·

time, ms

resting membrane potential (phase 4).

The initial depolarization is due to Na ^+ influx through rapidly opening Na ^+ channels (the Na ^+
current, I Na). The inactivation of Na ^+ channels, activation of K^+ channels and efflux of K^+
ions contributes to the rapid repolarization phase. Ca ^2+ influx through more slowly opening Ca
^2+ channels (the Ca ^2+ current, I Ca) and balance between Ca ^2+ and K^+ ions produce the plateau
phase. Repolarization is due to net K ^+ efflux through multiple types of K ^+ channels.

ACTION POTENTIAL OF THE CARDIAC PACEMAKER CELLS

Textové pole: mV

Morphology of the action potential SA and AV node differs from the action potential of
cardiomyocytes. The most striking difference is the inability to maintain a stable resting membrane
potential and significantly slower depolarization.

Textové pole: µA

time, ms

Slow diastolic depolarization. Nodal cells are unable to maintain a constant value of the resting
membrane potential. The main reason is the absence of I K (the K^+ current), and a relatively high
background sodium current. The maximum value of membrane voltage, which cells are able to achieve,
is called as the maximum diastolic potential (MDP) and its value is about -50 mV. After reaching
the maximum diastolic potential the potassium channels, that responsible for repolarization, are
closing and also the calcium channels of T-type are opening. This increases flow of cations into
the cell and cause a gradual shift membrane voltage to more positive values - slow diastolic
depolarization (SDD).


time, ms

Depolarization and repolarization. SDD shifts a membrane voltage of nodal cells to electric zero
until it reaches a value about -40 mV. At this membrane voltage value calcium L-type channels are
opening. This leads to Ca ^2+ influx and to the rapid depolarization. Follow inactivating calcium
channels with the opening of fast and slow delayed potassium current cause l repolarization of the
nodal cells.

THE ELECTROCARDIOGRAM

The electrocardiogram (ECG) is a continuous record of cardiac electrical activity obtained by
placing sensing electrodes on the surface of the body and recording the voltage differences
generated by the heart. The ECG may be recorded by using an active or exploring electrode connected
to an indifferent electrode at zero potential (unipolar recording) or by using two active
electrodes (bipolar recording).

Three bipolar limb leads.

Bipolar leads give the potential difference between two active electrodes placed at different
sites. Electrodes of the traditional bipolar limb leads are placed on the left arm, right arm, and
left leg. The potential difference between each combination of two of these electrodes give leads
I, II, and III.

Lead I. To recording limb lead I, the negative terminal of the electrocardiograph is connected to
the right arm and the positive terminal to the left arm.

Lead II. To record limb lead II, the negative terminal of the electrocardiograph is connected to
the right arm and the positive terminal to the left leg.

Lead III. To record limb lead III, the negative terminal of the electrocardiograph is connected to
the left arm and the positive terminal to the left leg.

Einthoven’s Triangle. In image, the triangle, called Einthoven’s triangle, is drawn around the area
of the heart. This illustrates that the two arms and the left leg form apices of a triangle
surrounding the heart. The two apices at the upper part of the triangle represent the points at
which the two arms connect electrically with the fluids around the heart, and the lower apex is the
point at which the left leg connects with the fluids.

Einthoven’s Law. Einthoven’s law states that if the electrical potentials of any two of the three
bipolar limb electrocardiographic leads are known at any given instant, the third one can be
determined  mathematically by simply summing the first two (but note that the positive and negative
signs of the different leads must be observed when making this summation).

Unipolar lead

Unipolar lead is the pair of electrical conductors giving the potential difference between an
exploring electrode and a reference input, sometimes called the indifferent electrode. The
reference input comes from a combination of electrodes at different sites, which is supposed to
give roughly zero potential throughout excitation of the heart. Assuming this to be the case, the
recorded electrical activity is the result of the influence of cardiac electrical activity on the
exploring electrode. By convention, when the exploring electrode is positive relative to the
reference input, an upward deflection is recorded.




Augmented unipolar limb leads

The exploratory electrode for an augmented limb lead is an electrode on a single limb. The
reference input is the two other limb electrodes connected together. Lead aVR gives the potential
difference between the right arm (exploring electrode) and the combination of the left arm and the
left leg (reference). Lead aVL gives the potential difference between the left arm and the
combination of the right arm and left leg. Lead aVF gives the potential difference between the left
leg and the combination of the left arm and right arm.

Chest leads (precordial leads)

The exploring electrode for the precordial or chest leads is the single electrode placed on the
anterior and left lateral chest wall. For the chest leads, the reference input is obtained by
connecting the three limb electrodes. The observed ECGs recorded from the chest leads are each the
result of voltage changes at a specified point on the surface of the chest. Unipolar chest leads
are designated V1 to V6 and are placed over the areas of the chest.


V[1] – V[6]

ECG CURVE

A standard 12-lead ECG, including six limb leads and six chest leads, it means that we use 10
electrodes (3 limb electrodes, 6 chest electrodes and 1 grounding electrode). Whole measurements in
healthy person are provided at the II lead.


                                            the T wave

The T wave represents the repolarization of the ventricles.

It is generally upright in all leads except aVR and lead V1.



                                            QRS complex


The QRS complex represents the rapid depolarization of the right and left ventricles. The
ventricles have a large muscle mass compared to the atria, so the QRS complex usually has a much
larger amplitude than the P-wave.




                                            the P wave

The p-wave represents depolarization of the atria. Atrial depolarization spreads from the SA node
towards the AV node, and from the right atrium to the left atrium.



AIM:

Practically acquire ECG recording, its evaluation for clinical practice.

EQUIPMENT:

Set of standard limb electrodes, 6 chest single-use electrodes with connectors to cables or
electrodes with fastening belt, connecting cables, PC, ECG gel, cotton-wool, examination bed, ECG
ruler.

PROCEDURE:

Clean the skin of the examined subject with the alcohol and spread ECG contact gel on the
electrodes. Place the single-use electrodes on the corresponding places. Connect all electrodes by
connecting cables, which are marked with respective letter and – in case of limb electrodes – by
respective color.

The places for fixing the electrodes

Limb leads:      red electrode:              right hand wrist

                        yellow electrode:       left hand wrist

                        green electrode:         left foot

                        black electrode:         right foot

Chest leads:     V[1]                               4^th intercostal space right from the sternum

                        V[2]                               4^th intercostal space left from the
sternum

                        V[4]                               5^th intercostal space in the left
medioclavicular line

                        V[3]                               between V[2] a V[4]

                        V[5]                               5^th intercostal space in the left front
axillar line

                        V[6]                               5^th intercostal space in the left
medial axillar line

Working with PC:

1. Start program ECG-Seiva (icon with heart)

2. Press button Ins and set name and surname of experimental subject; other values are not relevant
for practical. Confirm by pressing CTRL+Enter. Press twice “Beru na vědomí”.

3. By pressing F[4][ ]activate ECG recording.

4. Press F[4] to start 10 sec ECG recording; it is necessary for experimental subject to stay calm.
Registration will terminate automatically.

5. Print the record by pressing F[6].

6. To return to the main menu, press Alt+F[4]. For examination of next experimental subject, repeat
the procedure from step 2.

7. Terminate the program by repeated pressing of Alt+F[4]

EVALUATION OF ECG RECORD:

1. Heart rhythm: is heart rhythm regular?   YES (heart rhythm is regular)

                                                                       NO (heart rhythm is
irregular)


Rhythm source: is each QRS complex preceded by P wave?   YES (sinus rhythm)


    NO (idiopathic rhythm)

2. Heart rate: from PC:…………………………………………………………..

calculation from paper peed (25mm/s)……………………………

evaluation according to ECG ruler………………………………..

3. Duration of: RR interval…………………………………

 PQ interval………………………………….

 QRS complex……………………………….

  QT interval………………………………….

Interesting task: estimate Sokolow - Lyon index [S wave (V[1] or V[2)] + R (V5 or V6)]:
….……………………………………………………………………………………………….

(> 35 mm = left ventricle hypertrophy)

Construct electrical axis of the heart from two limb leads into the Einthoven triangle and measure
its angle in frontal plane. Assess its angle in horizontal plane from chest leads.


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