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An
Electrocardiogram (abbreviated as either ECG or EKG (from
German, Elektrokardiogramm)) is a graphic produced by an
electrocardiograph, which records the electrical voltage in the
heart in the form of a continuous strip graph. The ECG results
provide the following:
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Determine
whether the heart is performing normally or suffering from
abnormalities (eg extra or skipped heartbeats - Cardiac
arrhythmia).
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May indicate
coronary artery blockages (during or after a heart attack).
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Can be used for
detecting calcium, magnesium and other electrolyte
disturbances.
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Allows the
detection of conduction abnormalities (heart blocks).
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Indicates the
physical shape of a patient during stress tests.
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Can provide
information on the physical condition of the heart (ie: left
ventricular hypertrophy).
A typical ECG
tracing of a normal heartbeat consists of a P wave, a QRS
complex and a T wave. The P wave is the electrical signature of
the current that causes atrial contraction. Both the left and
right atria contract simultaneously. The QRS complex corresponds
to the current that causes contraction of the left and right
ventricles, which is much more forceful than that of the atria
and involves more muscle, mass, thus resulting in a greater ECG
deflection. The T wave represents the repolarization of the
ventricles. The QRS complex usually obscures the atrial
repolarization wave so that it is not usually seen.
Electrically, the cardiac muscle cells are like loaded springs.
A small impulse sets them off, they depolarize and contract.
Setting the spring up again is repolarization (more at action
potential).
Q.A. Interval
The
QT interval is measured from the beginning of the QRS complex to
the end of the T wave. The QT interval as well as the corrected
QT interval are important in the diagnosis of long QT syndrome
and short QT syndrome. The QT interval varies based on the heart
rate, and various correction factors have been developed to
correct the QT interval for the heart rate.
The most commonly used method for correcting the QT interval for
rate is the one formulated by Bazett. Bazett's formula is <math>QTc
= \frac{QT}{\sqrt {RR} }<math>, where QTc is the QT interval
corrected for rate, and RR is the interval from the onset of one
QRS complex to the onset of the next QRS complex, measured in
seconds. However, this formula tends to not be accurate, and
over-corrects at high heart rates and under-corrects at low
heart rates.
A more accurate method to correct the QT interval for the rate
was developed by Rautaharju et al., who developed the formula
<math>QTp=\frac{656}{1+\frac{heart rate}{100}}<math>. This
method is not widely used by clinicians.
E.K.G Lead Placement
A
typical ECG report shows the cardiac cycle from 12 different
vantage points (I, II, III, aVR, aVL, aVF, V1-V6), like viewing
the event electrically from 12 different locations.
Understanding the usual and abnormal directions, or vectors, of
depolarization and repolarization yields important diagnostic
information. The directions, or vectors, are known as leads. aVR
is placed on the right arm (or shoulder), aVL is placed on the
left arm (or shoulder), and aVF is placed on the left leg (or
hip). Lead I represents activity that is going from the right
arm to the left arm. Lead II represents activity that is going
from the right arm to the left leg. Lead III represents activity
that is going from the left arm to the left leg.
Electrical
vectors and how they apply to the heart
The
inferior leads (leads II, III and aVF) look at electrical
activity from the vantage point of the inferior region (wall) of
the heart. The lateral leads (I, aVL, V5 and V6) look at the
electrical activity from the vantage point of the lateral wall
of the heart. The anterior leads, V1 through V6, and represent
the anterior wall of the heart. aVR is rarely used for
diagnostic information, but indicates if the ECG leads were
placed correctly on the patient.
The inferior leads record events from the apex of the left
ventricle. The lateral and anterior leads record events from the
left wall and front walls of the left ventricle, respectively.
The right ventricle has very little muscle mass. It leaves only
a small imprint on the ECG, making it more difficult to diagnose
than changes in the left ventricle.
The
leads measure the average electrical activity generated by the
summation of the action potentials of the heart at a particular
moment in time. For instance, during normal atrial systole, the
summation of the electrical activity produces an electrical
vector that is directed from the SA node towards the AV node,
and spreads from the right atrium to the left atrium (since the
SA node resides in the right atrium). This turns into the P wave
on the EKG, which is upright in II, III, and a VF (since the
general electrical activity is going towards those leads), and
inverted in a VR (since it is going away from that lead).
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