Electrocardiography A recording of the electrical activity of the heart over time Gold standard for diagnosis of cardiac arrhythmias Helps detect electrolyte disturbances (hyper- & hypokalemia) Allows for detection of conduction abnormalities Screening tool for ischemic heart disease during stress tests Helpful with non-cardiac diseases (e.g. pulmonary embolism or hypothermia
Electrocardiogram (ECG/EKG) Is a recording of electrical activity of heart conducted thru ions in body to surface Fig 13.22a 13-60
ECG Graph Paper Runs at a paper speed of 25 mm/sec Each small block of ECG paper is 1 mm2 At a paper speed of 25 mm/s, one small block equals 0.04 s Five small blocks make up 1 large block which translates into 0.20 s (200 msec) Hence, there are 5 large blocks per second Voltage: 1 mm = 0.1 mV between each individual block vertically
Normal conduction pathway: SA node -> atrial muscle -> AV node -> bundle of His -> Left and Right Bundle Branches -> Ventricular muscle
Recording of the ECG: Leads used: Limb leads are I, II, II. So called because at one time subjects had to literally place arms and legs in buckets of salt water. Each of the leads are bipolar; i.e., it requires two sensors on the skin to make a lead. If one connects a line between two sensors, one has a vector. There will be a positive end at one electrode and negative at the other. The positioning for leads I, II, and III were first given by Einthoven. Form the basis of Einthoven’s triangle.
Types of ECG Recordings Bipolar leads record voltage between electrodes placed on wrists & legs (right leg is ground) Lead I records between right arm & left arm Lead II: right arm & left leg Lead III: left arm & left leg Fig 13.23 13-61
Fig. 13.22b
ECG 3 distinct waves are produced during cardiac cycle P wave caused by atrial depolarization QRS complex caused by ventricular depolarization T wave results from ventricular repolarization Fig 13.24 13-63
Elements of the ECG: P wave: Depolarization of both atria; Relationship between P and QRS helps distinguish various cardiac arrhythmias Shape and duration of P may indicate atrial enlargement PR interval: from onset of P wave to onset of QRS Normal duration = 0.12-2.0 sec (120-200 ms) (3-4 horizontal boxes) Represents atria to ventricular conduction time (through His bundle) Prolonged PR interval may indicate a 1st degree heart block QRS complex: Ventricular depolarization Larger than P wave because of greater muscle mass of ventricles Normal duration = 0.08-0.12 seconds Its duration, amplitude, and morphology are useful in diagnosing cardiac arrhythmias, ventricular hypertrophy, MI, electrolyte derangement, etc. Q wave greater than 1/3 the height of the R wave, greater than 0.04 sec are abnormal and may represent MI
ST segment: Connects the QRS complex and T wave Duration of 0.08-0.12 sec (80-120 msec T wave: Represents repolarization or recovery of ventricles Interval from beginning of QRS to apex of T is referred to as the absolute refractory period QT Interval Measured from beginning of QRS to the end of the T wave Normal QT is usually about 0.40 sec QT interval varies based on heart rate
Fig. 13.24b
Fig. 13.24c
Fig. 13.24d
P wave Elements of the ECG: Depolarization of both atria; Relationship between P and QRS helps distinguish various cardiac arrhythmias Shape and duration of P may indicate atrial enlargement
QRS complex: Represents ventricular depolarization Larger than P wave because of greater muscle mass of ventricles Normal duration = 0.08-0.12 seconds Its duration, amplitude, and morphology are useful in diagnosing cardiac arrhythmias, ventricular hypertrophy, MI, electrolyte derangement, etc. Q wave greater than 1/3 the height of the R wave, greater than 0.04 sec are abnormal and may represent MI
PR interval: From onset of P wave to onset of QRS Normal duration = 0.12-2.0 sec (120-200 ms) (3-4 horizontal boxes) Represents atria to ventricular conduction time (through His bundle) Prolonged PR interval may indicate a 1st degree heart block
Fig. 13.24g
T wave: Represents repolarization or recovery of ventricles Interval from beginning of QRS to apex of T is referred to as the absolute refractory period
ST segment: QT Interval Connects the QRS complex and T wave Duration of 0.08-0.12 sec (80-120 msec QT Interval Measured from beginning of QRS to the end of the T wave Normal QT is usually about 0.40 sec QT interval varies based on heart rate
Ischemic Heart Disease Is most commonly due to atherosclerosis in coronary arteries Ischemia occurs when blood supply to tissue is deficient Causes increased lactic acid from anaerobic metabolism Often accompanied by angina pectoris (chest pain) Click here to play Myocardial Infarction RealMedia Movie 13-78
Ischemic Heart Disease Detectable by changes in S-T segment of ECG Myocardial infarction (MI) is a heart attack Diagnosed by high levels of creatine phosphate (CPK) & lactate dehydrogenase (LDH) Fig 13.34 13-79
Arrhythmias Detected on ECG Arrhythmias are abnormal heart rhythms Heart rate <60/min is bradycardia; >100/min is tachycardia Fig 13.35 13-80
Arrhythmias Detected on ECG continued In flutter contraction rates can be 200-300/min In fibrillation contraction of myocardial cells is uncoordinated & pumping ineffective Ventricular fibrillation is life-threatening Electrical defibrillation resynchronizes heart by depolarizing all cells at same time Fig 13.35 13-81
Arrhythmias Detected on ECG continued AV node block occur when node is damaged First–degree AV node block is when conduction through AV node > 0.2 sec Causes long P-R interval Second-degree AV node block is when only 1 out of 2-4 atrial APs can pass to ventricles Causes P waves with no QRS In third-degree or complete AV node block no atrial activity passes to ventricles Ventricles driven slowly by bundle of His or Purkinjes 13-82
Arrhythmias Detected on ECG continued AV node block occurs when node is damaged First–degree AV node block is when conduction thru AV node > 0.2 sec Causes long P-R interval Fig 13.36 13-83
Arrhythmias Detected on ECG continued Second-degree AV node block is when only 1 out of 2-4 atrial APs can pass to ventricles Causes P waves with no QRS Fig 13.36 13-84
Arrhythmias Detected on ECG continued In third-degree or complete AV node block, no atrial activity passes to ventricles Ventricles are driven slowly by bundle of His or Purkinjes Fig 13.36 13-85
Representation in culture In TV medical dramas, an isoelectric ECG (no cardiac electrical activity, aka, flatline, is used as a symbol of death or extreme medical peril. Technically, this is known as asystole, a form of cardiac arrest, with a partcularly bad prognosis. Defibrillation, which can be used to correct arrythmias such as ventricular fibrillation and pulseless ventricular tachycardia, cannot correct asystole.