The Human Body

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This article explains the genesis of and normal values for the individual components of the wave forms that are seen in an electrocardiogram. To recognise electrocardiographic abnormalities the range of normal wave patterns must be understood.

P wave
The sinoatrial node lies high in the wall of the right atrium and initiates atrial depolarisation, producing the P wave on the electrocardiogram. Although the atria are anatomically two
distinct chambers, electrically they act almost as one. They have relatively little muscle and generate a single, small P wave. P wave amplitude rarely exceeds two and a half small squares
(0.25 mV). The duration of the P wave should not exceed three small squares (0.12 s).

The wave of depolarisation is directed inferiorly and towards the left, and thus the P wave tends to be upright in leads I and II and inverted in lead aVR. Sinus P waves are usually most prominently seen in leads II and V1. A negative P wave in lead I may be due to incorrect recording of the electrocardiogram (that is, with transposition of the left and right arm electrodes), dextrocardia, or abnormal atrial rhythms.

The P wave in V1 is often biphasic. Early right atrial forces are directed anteriorly, giving rise to an initial positive deflection; these are followed by left atrial forces travelling posteriorly, producing a later negative deflection. A large negative deflection (area of more than one small square) suggests left atrial enlargement.

Normal P waves may have a slight notch, particularly in the precordial (chest) leads. Bifid P waves result from slight asynchrony between right and left atrial depolarisation. A pronounced notch with a peak­to­peak interval of > 1 mm (0.04 s) is usually pathological, and is seen in association with a left atrial abnormality—for example, in mitral stenosis.

PR interval
After the P wave there is a brief return to the isoelectric line, resulting in the “PR segment.” During this time the electrical impulse is conducted through the atrioventricular node, the
bundle of His and bundle branches, and the Purkinje fibres.

The PR interval is the time between the onset of atrial depolarisation and the onset of ventricular depolarisation, and it is measured from the beginning of the P wave to the first
deflection of the QRS complex (see next section), whether this be a Q wave or an R wave.The normal duration of the PR interval is three to five small squares (0.12­0.20 s). Abnormalities of the conducting system may lead to transmission delays, prolonging the PR interval.

QRS complex
The QRS complex represents the electrical forces generated by ventricular depolarisation. With normal intraventricular conduction, depolarisation occurs in an efficient, rapid fashion.The duration of the QRS complex is measured in the lead with the widest complex and should not exceed two and a half small squares (0.10 s). Delays in ventricular depolarisation—for
example, bundle branch block—give rise to abnormally wide QRS complexes (>0.12 s).

The depolarisation wave travels through the interventricular septum via the bundle of His and bundle branches and reaches the ventricular myocardium via the Purkinje fibre network. The
left side of the septum depolarises first, and the impulse then spreads towards the right. Lead V1 lies immediately to the right of the septum and thus registers an initial small positive
deflection (R wave) as the depolarisation wave travels towards this lead.

When the wave of septal depolarisation travels away from the recording electrode, the first deflection inscribed is negative. Thus small “septal” Q waves are often present in the lateral
leads, usually leads I, aVL, V5, and V6.

These non­pathological Q waves are less than two small squares deep and less than one small square wide, and should be < 25% of the amplitude of the corresponding R wave. The wave of depolarisation reaches the endocardium at the apex of the ventricles, and then travels to the epicardium, spreading outwards in all directions. Depolarisation of the right and left ventricles produces opposing electrical vectors, but the left ventricle has the larger muscle mass and its depolarization dominates the electrocardiogram. In the precordial leads, QRS morphology changes depending on whether the depolarisation forces are moving towards or away from a lead. The forces generated by the free wall of the left ventricle predominate, and therefore in lead V1 a small R wave is followed by a large negative deflection (S wave). The R wave in the precordial leads steadily increases in amplitude from lead V1 to V6, with a corresponding decrease in S wave depth, culminating in a predominantly positive complex in V6. Thus, the QRS complex gradually changes from being predominantly negative in lead V1 to being predominantly positive in lead V6. The lead with an equiphasic QRS complex is located over the transition zone; this lies between leads V3 and V4, but shifts towards the left with age. The height of the R wave is variable and increases progressively across the precordial leads; it is usually < 27 mm in leads V5 and V6. The R wave in lead V6, however, is often smaller than the R wave in V5, since the V6 electrode is further from the left ventricle. The S wave is deepest in the right precordial leads; it decreases in amplitude across the precordium, and is often absent in leads V5 and V6. The depth of the S wave should not exceed 30 mm in a normal individual, although S waves and R waves > 30 mm are occasionally recorded in normal young male adults.

ST segment
The QRS complex terminates at the J point or ST junction. The ST segment lies between the J point and the beginning of the T wave, and represents the period between the end of ventricular
depolarisation and the beginning of repolarisation. The ST segment should be level with the subsequent “TP segment” and is normally fairly flat, though it may slope upwards slightly before merging with the T wave.

In leads V1 to V3 the rapidly ascending S wave merges directly with the T wave, making the J point indistinct and the ST segment difficult to identify. This produces elevation of the ST segment, and this is known as “high take­off.”

Non­pathological elevation of the ST segment is also associated with benign early repolarisation (see article on acute myocardial infarction later in the series), which is particularly common in young men, athletes, and black people. Interpretation of subtle abnormalities of the ST segment is one of the more difficult areas of clinical electrocardiography; nevertheless, any elevation or depression of the ST segment must be explained rather than dismissed.

T wave
Ventricular repolarisation produces the T wave. The normal Twave is asymmetrical, the first half having a more gradual slope than the second half.

T wave orientation usually corresponds with that of the QRS complex, and thus is inverted in lead aVR, and may be inverted in lead III. T wave inversion in lead V1 is also common. It is occasionally accompanied by T wave inversion in lead V2, though isolated T wave inversion in lead V2 is abnormal. T wave inversion in two or more of the right precordial leads is known as a persistent juvenile pattern; it is more common in black people. The presence of symmetrical, inverted T waves is highly suggestive of myocardial ischaemia, though asymmetrical inverted T waves are frequently a non­specific finding.

No widely accepted criteria exist regarding T wave amplitude. As a general rule, T wave amplitude corresponds with the amplitude of the preceding R wave, though the tallest T waves are seen in leads V3 and V4. Tall T waves may be seen in acute myocardial ischaemia and are a feature of hyperkalaemia.

QT interval
The QT interval is measured from the beginning of the QRS complex to the end of the T wave and represents the total time taken for depolarisation and repolarisation of the ventricles.

The QT interval lengthens as the heart rate slows, and thus when measuring the QT interval the rate must be taken into account. As a general guide the QT interval should be 0.35­ 0.45 s, and should not be more than half of the interval between adjacent R waves (R­R interval). The QT interval increases slightly with age and tends to be longer in women than in men. Bazett's correction is used to calculate the QT interval corrected for heart rate (QTc): QTc = QT/R­R (seconds).

Prominent U waves can easily be mistaken for T waves, leading to overestimation of the QT interval. This mistake can be avoided by identifying a lead where U waves are not prominent—for example, lead aVL.

U wave
The U wave is a small deflection that follows the T wave. It is generally upright except in the aVR lead and is often most prominent in leads V2 to V4. U waves result from repolarisation of the mid­myocardial cells—that is, those between the endocardium and the epicardium—and the
His­Purkinje system. Many electrocardiograms have no discernible U waves. Prominent U waves may be found in athletes and are associated with hypokalaemia and hypercalcaemia.


Electrocardiography is a fundamental part of cardiovascular assessment. It is an essential tool for investigating cardiac arrhythmias and is also useful in diagnosing cardiac disorders such as myocardial infarction. Familiarity with the wide range of

patterns seen in the electrocardiograms of normal subjects and an understanding of the effects of non­cardiac disorders on the trace are prerequisites to accurate interpretation.


The contraction and relaxation of cardiac muscle results

from the depolarisation and repolarisation of myocardial cells. These electrical changes are recorded via electrodes placed on the limbs and chest wall and are transcribed on to graph paper to produce an electrocardiogram (commonly known as an

ECG).




















The sinoatrial node acts as a natural pacemaker and initiates atrial depolarisation. The impulse is propagated to the ventricles by the atrioventricular node and spreads in a coordinated fashion throughout the ventricles via the specialised conducting tissue of the His­Purkinje system. Thus, after delay in the atrioventricular mode, atrial contraction is followed by rapid and coordinated contraction of the ventricles.


The electrocardiogram is recorded on to standard paper

travelling at a rate of 25 mm/s. The paper is divided into large squares, each measuring 5 mm wide and equivalent to 0.2 s. Each large square is five small squares in width, and each small square is 1 mm wide and equivalent to 0.04 s.

The electrical activity detected by the electrocardiogram

machine is measured in millivolts. Machines are calibrated so that a signal with an amplitude of 1 mV moves the recording stylus vertically 1 cm. Throughout this text, the amplitude of waveforms will be expressed as: 0.1 mV = 1 mm = 1 small square.


The amplitude of the waveform recorded in any lead maybe influenced by the myocardial mass, the net vector of depolarisation, the thickness and properties of the interveningtissues, and the distance between the electrode and the myocardium. Patients with ventricular hypertrophy have a relatively large myocardial mass and are therefore likely to have

high amplitude waveforms. In the presence of pericardial fluid, pulmonary emphysema, or obesity, there is increased resistance to current flow, and thus waveform amplitude is reduced.


The direction of the deflection on the electrocardiogram

depends on whether the electrical impulse is travelling towards

or away from a detecting electrode. By convention, an electrical

impulse travelling directly towards the electrode produces an

upright (“positive”) deflection relative to the isoelectric baseline,

whereas an impulse moving directly away from an electrode

produces a downward (“negative”) deflection relative to the

baseline. When the wave of depolarisation is at right angles to

the lead, an equiphasic deflection is produced.


The six chest leads (V1 to V6) “view” the heart in the

horizontal plane. The information from the limb electrodes is

combined to produce the six limb leads (I, II, III, aVR, aVL, and

aVF), which view the heart in the vertical plane. The

information from these 12 leads is combined to form a

standard electrocardiogram.


The arrangement of the leads produces the following

anatomical relationships: leads II, III, and aVF view the inferior

surface of the heart; leads V1 to V4 view the anterior surface;

leads I, aVL, V5, and V6 view the lateral surface; and leads V1

and aVR look through the right atrium directly into the cavity

of the left ventricle.


Rate

The term tachycardia is used to describe a heart rate greater than 100 beats/min. A bradycardia is defined as a rate less than 60 beats/min (or < 50 beats/min during sleep). One large square of recording paper is equivalent to 0.2 seconds; there are five large squares per second and 300 per minute. Thus when the rhythm is regular and the paper speed is running at the standard rate of 25 mm/s, the heart rate can be calculated by counting the number of large squares between two consecutive R waves, and dividing this number into 300.

Alternatively, the number of small squares between two consecutive R waves may be divided into 1500.


Some countries use a paper speed of 50 mm/s as standard; the heart rate is calculated by dividing the number of large squares between R waves into 600, or the number of small squares into 3000.


“Rate rulers” are sometimes used to calculate heart rate; these are used to measure two or three consecutive R­R intervals, of which the average is expressed as the rate equivalent. When using a rate ruler, take care to use the correct scale according to paper speed (25 or 50 mm/s); count the correct numbers of beats (for example, two or three); and restrict the technique to regular rhythms.


When an irregular rhythm is present, the heart rate may be calculated from the rhythm strip (see next section). It takes one second to record 2.5 cm of trace. The heart rate per minute can be calculated by counting the number of intervals between QRScomplexes in 10 seconds (namely, 25 cm of recording paper)

and multiplying by six.


Rhythm

To assess the cardiac rhythm accurately, a prolonged

recording from one lead is used to provide a rhythm strip. Lead II, which usually gives a good view of the P wave, is most commonly used to record the rhythm strip.


The term “sinus rhythm” is used when the rhythm originates in the sinus node and conducts to the ventricles.


Young, athletic people may display various other rhythms, particularly during sleep. Sinus arrhythmia is the variation in the heart rate that occurs during inspiration and expiration.


There is “beat to beat” variation in the R­R interval, the rate

increasing with inspiration. It is a vagally mediated response to

the increased volume of blood returning to the heart during

inspiration.


Cardiac axis

The cardiac axis refers to the mean direction of the wave of

ventricular depolarisation in the vertical plane, measured from a zero reference point. The zero reference point looks at the heart from the same viewpoint as lead I. An axis lying above this line is given a negative number, and an axis lying below the line is given a positive number. Theoretically, the cardiac axis may lie anywhere between 180 and - 180°. The normal range for the cardiac axis is between - 30° and 90°. An axis lying beyond - 30° is termed left axis deviation, whereas an axis > 90° is termed right axis deviation.

Several methods can be used to calculate the cardiac

axis, though occasionally it can prove extremely difficult to

determine. The simplest method is by inspection of leads I, II,

and III.





A more accurate estimate of the axis can be achieved if all

six limb leads are examined. The hexaxial diagram shows each lead's view of the heart in the vertical plane.


The direction of current flow is towards leads with a positive deflection, away from leads with a negative deflection, and at 90° to a lead with an equiphasic QRS complex. The axis is determined as follows:

1. Choose the limb lead closest to being equiphasic. The axis lies about 90° to the right or left of this lead

2. With reference to the hexaxial diagram, inspect the QRS complexes in the leads adjacent to the equiphasic lead. If the

lead to the left side is positive, then the axis is 90° to the

equiphasic lead towards the left. If the lead to the right side is

positive, then the axis is 90° to the equiphasic lead towards the

right.