Correlation between intracellular and surface electrograms in acute myocardial ischemia

Solid-angle theory and heart rate adjustment of ST-segment depression for the identification and quantification of coronary artery disease

Determinants of the ST-segment response to exercise can be mathematically modeled by solid-angle theory, and heart rate adjustment of the magnitude of exercise-induced ST-segment depression can remodel the solid-angle relationship to provide a theoretic and practical basis for application of heart rate-adjusted indexes of ST depression in exercise electrocardiography. Solid-angle theory indicates that the magnitude of ST depression recorded at a surface electrode (epsilon) can be described as the product of spatial and nonspatial determinants: epsilon = (omega/4 pi).(delta Vm).K (equation 1), where omega is the solid angle subtending the boundary of the ischemic territory, delta Vm is the difference in transmembrane voltage between the ischemic and adjacent nonischemic regions, and K is a term correcting for differences in intracellular and extracellular conductivity and changes in end-plate conductance. As a consequence, the magnitude of ST depression recorded by a surface electrode will be proportional both to the area of ischemic territory subtended by the recording electrode, which reflects the solid angle, and to the local transmembrane potential difference, which in turn reflects the electric consequences of the metabolic severity of ischemia at the level of the myocardial cell. It follows from equation 1 that the amplitude of ST depression can accurately reflect the area of ischemic boundary only when the severity of ischemia is constant or otherwise controlled, and differences in ST depression will only reflect varying areas of underlying ischemia when similar severity of ischemia is present. During exercise the severity of ischemia is directly proportional to changes in myocardial oxygen demand and coronary blood flow, which in turn are directly related to increasing heart rate (delta HR). Because the change in transmembrane voltage across the ischemic boundary is linearly proportional to delta HR, delta Vm/delta HR remains constant as ischemia develops. Dividing the solid-angle relationship in equation 1 by delta HR and making the appropriate substitution for a constant delta Vm/delta HR then indicates that epsilon/delta HR = (omega/4 pi).(c . K) [equation 2], where c is the new constant. Under conditions where changes in conductance are proportional or small, this simplified relationship reduces to delta ST/delta HR = c'.omega [equation 3], where delta ST reflects the magnitude of ST depression recorded by the surface electrode, delta HR the change in heart rate during developing ischemia, and c' the resulting empiric constant.

Clinical and pathophysiologic correlates of ST-T-wave abnormalities in coronary artery disease

Clinical, hemodynamic and coronary angiographic data from 9,801 patients were evaluated to determine the correlates of ST-segment depression, with or without T-wave inversion, on the resting routine electrocardiogram. The relative risk (RR) of having a measured clinical or angiographic variable was computed whether or not ST-T-wave abnormalities were observed. ST-segment depression was seen significantly more often in subjects greater than 55 years of age (RR = 1.4) who were women (RR = 1.3) or nonwhite (RR = 1.5), were hypertensive (RR = 1.8), had diabetes mellitus (RR = 1.6) or who smoked cigarettes (RR = 1.5). Angiographic findings related to presence of ST-T-wave abnormalities included severe coronary obstruction (less than 70%), higher number of diseased vessels, and the presence of obstruction in the left anterior descending coronary artery. In a multivariate model, the most significant correlates of ST-T-wave abnormalities were presence of left ventricular contraction abnormality, followed by age, gender, presence of left anterior descending coronary artery disease, elevated end-systolic volume index, and a diagnosis of hypertension. Thus, electrocardiographic ST-T abnormalities has specific and significant clinical and pathophysiologic correlates.

Significance of ST segment depression during paroxysmal supraventricular tachycardia

During paroxysmal supraventricular tachycardia, patients frequently experience chest pain and marked ST segment depression suggesting acute myocardial ischemia. The purpose of this study was to assess whether ST depression during supraventricular tachycardia is caused by myocardial ischemia as reflected by net myocardial lactate production. Twenty-five patients (14 men, 11 women) who had a history of paroxysmal supraventricular tachycardia and a mean age (+/- SD) of 38 +/- 14 years underwent electrophysiologic testing. Twenty-four of these patients had no evidence of coronary disease, whereas one patient had undergone previous coronary bypass surgery. Nineteen patients had orthodromic and six patients had atrioventricular node reentrant tachycardias. A 12 lead electrocardiogram and simultaneous femoral artery and coronary sinus blood samples for lactate determinations were obtained at baseline and at 5 and 10 min of supraventricular tachycardia. Mean baseline heart rate of 83 +/- 12 beats/min increased to 180 +/- 25 beats/min during supraventricular tachycardia. All patients had 1 to 8 mm of ST segment depression in 1 to 9 of the 12 leads. Chest pain occurred in 64% of patients during supraventricular tachycardia. Baseline myocardial lactate extraction was 28 +/- 13% with no significant change at 5 or 10 min of tachycardia. In contrast, in a comparison group of seven patients with known coronary artery disease, atrial pacing at 168 +/- 26 beats/min in five patients resulted in greater than or equal to 1 mm ST depression in 2 to 7 of the 12 leads and a change in lactate extraction from a baseline of 29 +/- 13% to -27 +/- 20% (p less than 0.05) indicating net myocardial lactate production.(ABSTRACT TRUNCATED AT 250 WORDS)

Regional myocardial blood flow in experimental myocardial infarction after pretreatment with aspirin

The effects of aspirin on myocardial blood flow in an area of ischemia were studied in 12 baboons. In each, a diagonal branch of the left anterior descending coronary artery was ligated. Six of the baboons received aspirin (2 X 600 mg orally, 12 hours and 1 hour before ligation); the other six did not receive aspirin and served as a control group. The extent of myocardial ischemia was delineated with an electrode wire grid on the surface of the anterior left ventricular wall. The maximal area circumscribed by electrodes with 2 mV or more ST segment elevation was compared with the area of reduced myocardial blood flow. Myocardial blood flow was measured with the radioactive microspheres method using strontium-85-labeled carbonized spheres. Two areas of reduced myocardial blood flow were noted, one with severely reduced flow in the center of the myocardial infarct (0 to 49% of noninfarcted myocardium) and another with mild to moderately reduced myocardial blood flow at the border of the myocardial infarct (50 to 90% of noninfarcted myocardium). Myocardial blood flow in the border area (margins of ST elevation area) for the total wall was 85 +/- 8% of normal in the aspirin-treated animals and 40 +/- 4% in the control group (p less than 0.01); for the epicardium it was 67 +/- 10% of normal in noninfarcted myocardium after aspirin and 37 +/- 5% for the control group (p less than 0.05); and for the endocardium it was 78 +/- 8% of normal in noninfarcted myocardium after aspirin and 39 +/- 6% in the control group (p less than 0.01).(ABSTRACT TRUNCATED AT 250 WORDS)

An electrocardiographic model of myocardial ischemic injury

Previous electrocardiographic models of myocardial ischemic injury have assumed that transmembrane potential changes are uniform throughout a region of ischemia such that injury currents arise exclusively at the boundary between normal and ischemic myocardium. In such models, the distribution and amplitude of ST segment deflections are considered to arise from a polarized surface interfacing normal and ischemic myocardium. This concept in modeling ischemic injury was derived from the application of principles of electric field theory which had been successfully applied previously to ventricular activation in which QRS potentials are considered to arise from polarized surfaces representing the relatively narrow interfaces between depolarized and nondepolarized myocardium. The present paper outlines the limitations of modeling ischemic injury as a polarized surface in terms of the failure of the predictions of such a model to be supported by the experimentally observed: 1) distribution and relative amplitude of epicardial ST segment elevation overlying a region of ischemia; 2) directional changes in epicardial ST segment elevation that occur with changes in the size of an ischemic region; and 3) nonuniform distribution of transmembrane potential changes which occur within a region of ischemia. A new electrocardiographic model of ischemic injury is formulated which accounts for the nonuniform distribution of transmembrane potential changes which occur throughout a region of ischemia. The model accurately describes experimental observations regarding ST segment deflections which had remained inconsistent with previous models.

Epicardial mapping and electrocardiographic models of myocardial ischemic injury

The amplitude and distribution of epicardial ST-segment elevation (ST) were examined for an 8-hour period after coronary occlusion in eight baboons and five pigs. ST was determined from unipolar epicardial electrograms obtained from a high-resolution matrix of fixed electrodes overlying a transmural region of ischemia. A relatively uniform degree of ST was observed overlying the ischemic region for 20 minutes after coronary occlusion. A gradient in ST from the periphery to the center of the ischemic region was documented after 20 minutes of ischemia. In 10 other pigs, change in the degree of ST was examined contingent on either an increase (five pigs) or decrease (five pigs) in the size of the ischemic region after 1 hour of preexisting ischemia. An abrupt increase in the number of electrodes that showed ST (NST) from 7.8 +/- 1.24 (SEM) to 14.8 +/- 1.35 (90%) was associated with an increase in mean ST of 58% from 4.28 +/- 0.61 mV to 6.78 +/- 0.84 (p less than 0.05). An abrupt decrease in NST from 25.2 +/- 2.63 to 14.6 +/- 2.22 (42%) was associated with a decrease in mean ST of 24%, from 8.2 +/- 0.36 mV to 6.3 +/- 0.30 mV (p less than 0.01). The results during early ischemia (less than 20 minutes of ischemia) are accurately represented by a model of ischemia in which injury current arises only at the ischemic boundary. The results during later ischemia (after 20 minutes of ischemia) may be represented by a model in which ST is considered dependent on injury currents generated throughout the ischemic region.

Electrocardiographic QRS changes induced by acute coronary ligation in the isolated rabbit heart

The electrical fields associated with augmented R- and decreased S-wave amplitudes during acute, severe myocardial ischemia were studied in fifteen isolated rabbit heart preparations. Hearts were suspended in a spherical tank and perfused with oxygenated electrolyte solution. Electrocardiographic signals were recorded from electrodes on the tank's surface and processed by computerized methods. Fifteen minutes after suture ligation of the left anterior descending coronary artery, records from electrodes overlying the lesion demonstrated increased R-wave amplitude and ST-segment elevation. Fitting a single moving dipole to pre- and post-ligation potentials demonstrated that the ligation increased the dipolarity of the field and shifted the terminal QRS dipole to a position topographically related to the location of the ischemic lesion. The effects of injury were further assessed by study of fields computed by subtracting control from post-ligation data. This generated a dipolar field at the instant of maximal dipole moment whose strength directly correlated (r=0.74) with the area of non-perfused epicardium, as determined by post-ligation methylene blue infusion. These results suggest that the electrical fields generated during mid to late dipolarization by coronary ligation are qualitatively similar to those generated during repolarization, and may therefore be of similar clinical and/or experimental value.

Magnetic determination of the relationship between the S-T segment shift and the injury current produced by coronary artery occlusion

Both the S-T segment shift and the injury current were measured using the direct-current magnetocardiogram (d-c MCG) in seven dogs undergoing coronary artery occlusion. The purpose of the measurements was to clarify the origin of the S-T shift in acute ischemia and infarction. Previous measurements, consisting of d-c electrograms recorded from the exposed epicardial surface in situ, are partially inconsistent; also, they are not necessarily representative of the surface electrocardiogram (ECG), which sums broadly over the myocardium. The d-c MCG allows steady myocardial currents in the intact torso to the measured externally; because the d-c MCG sums broadly over these currents, conclusions drawn from it are applicable to the ECG. Coronary artery occlusion was produced by inflating a tube which, about 1 week earlier, had been surgically installed around the artery and exteriorized. During occlusions carried out in the MIT magnetically shielded room, a sensitive magnetometer recorded the d-c MCG at various locations around the torso. Within 20 seconds after occlusion, equal and opposite S-T segment and base-line (d-c) shifts appeared on the d-c MCG; these shifts were maintained for at least 15 minutes, after which they slowly decreased. Therefore, during the acute ischemia produced by these occlusions, the S-T shift is a secondary result of a primary injury current that is interrupted during the S-T interval.

A mechanism for the electrocardiogram response to left ventricular hypertrophy and acute ischemia

A proposed mechanism for explaining the electrocardiographic response in left ventricular hypertrophy and in subendocardial and epicardial acute ischemia was incorporated in a mathematical model of electrical heart activity. The model of hypertrophy was simply an increase in cell size, and the principal effect on the computer-generated 12-lead electrocardiograms (ECGs) was an increase in R-wave amplitude and ventricular activation time and a flattening or polarity reversal of the T wave. The model of acute ischemia was a reduction between plateau and resting potential of the transmembrane action potential. The principal effect on the computer-generated 12-lead ECGs was an S-T segment displacement up or down depending on the location of the lesion. This shift was linearly proportional to the severity of the ischemia, i.e., the reduction in electrical activity of the ischemic cell, and for a lesion of given severity the S-T segment shift was a measure of the area, not the volume, of ischemic tissue. Therefore, this model suggests that a direct correlation does not necessarily exist between volume-measuring tests such as serum enzyme values in the case of necrosis and S-T segment shifts.

Spontaneous and induced cardiac arrhythmias in subendocardial Purkinje fibers surviving extensive myocardial infarction in dogs

The cellular electrophysiological mechanisms underlying the ventricular arrhythmias that accompany myocardial infarction were studied in isolated, superfused infarcted myocardium excised from dogs previously subjected to a two-stage ligation of the anterior descending coronary artery. Ventricular arrhythmias frequently occurred in the intact heart 24 hours after coronary occlusion. Surviving subendocardial Purkinje fibers in infarcts excised at this time were highly arrhythmic when they were studied with intracellular microelectrodes in vitro. These arrhythmias consisted of rapid, repetitive depolarizations and occurred spontaneously or could be induced by premature electrical stimulation. Premature stimulation also resulted in single unstimulated responses. In such instances, premature impulses conducted extremely slowly through the infarcted region where surviving Purkinje fiber action potential durations were extraordinarily prolonged. Conduction block at some sites in the infarct caused phenomena which were interpreted as reentrant beats. Some surviving subendocardial Purkinje fibers in the infarct demonstrated spontaneous diastolic depolarization and appeared to function as pacemakers in the absence of electrical stimulation. In some instances, these fibers constituted typical parasystolic foci, demonstrating both entrance and exit block. These results suggest that subendocardial Purkinje fibers which survive in an infarct may be the site of origin of some of the ventricular arrhythmias that accompany myocardial infarction.

Survival of subendocardial Purkinje fibers after extensive myocardial infarction in dogs

Alterations in cardiac electrophysiology that accompany myocardial infarction were studied in dogs subjected to a two-stage ligation of the anterior descending coronary artery. A multipolar transmural needle electrode was used to record electrical activity from the in situ infarcted heart 24 hours after coronary occlusion. Bipolar electrograms recorded from subendocardial regions of infarcted myocardium demonstrated the persistence of early, rapid deflections suggesting Purkinje fiber activity; evidence of ventricular muscle activity in the infarct was absent in both subendocardial and intramural electrograms. The infarcted myocardium and the adjacent non-infarcted tissue were then excised and studied with intracellular microelectrodes in vitro. Transmembrane action potentials could be recorded from one or two cell layers of subendocardial Purkinje fibers at all sites within the infarcted region, but no ventricular muscle action potentials were found. Subendocardial Purkinje fibers which survived in the infarct had reduced maximum diastolic potentials, action potential amplitudes, and maximum depolarization velocities compared with normal subendocardial Purkinje fibers; also, action potential durations in these surviving fibers were extraordinarily prolonged. Spontaneous diastolic depolarization was evident in some surviving fibers. Since subendocardial Purkinje fibers that generate abnormal action potentials survive in an infarct, these fibers may participate in the genesis of ventricular arrhythmias that accompany infarction.

Effect of inhibition of lipolysis on infarct size after experimental coronary artery occlusion

Recent studies have demonstrated a depressant effect of increased delivery of FFA to the hypoxic heart. Because catecholamines are released in acute myocardial infarction, it is likely that lipolytic activity is increased. The purpose of this study was to determine whether inhibition of hormone-sensitive lipases influence the extent and severity of myocardial ischemic injury produced by coronary occlusion. Myocardial infarction was produced by occlusion of the left anterior descending coronary artery in open-chest dogs. 15 min later a surface map of S-T segments was obtained with the use of 10-14 epicardial leads in the distribution area of the occluded artery. Average S-T segment elevation of all sites was used as an index of myocardial ischemic injury. Before coronary occlusion, the average S-T segment elevation was 0.3+/-0.2, which increased to 4.1+/-0.7 mV (SEM, 12 dogs) after occlusion. Inhibition of lipolytic activity by beta-pyridyl-carbinol before repeated coronary occlusion reduced the occlusion-induced S-T segment elevation to 2.1+/-0.6 mV (P < 0.001). When arterial concentrations of FFA were raised by i.v. infusion of a triglyceride emulsion and heparin, average S-T segment elevation after coronary occlusion increased from 1.2+/-0.7 to 2.2+/-0.8 mV (P < 0.05) in animals treated with beta-pyridyl-carbinol, which suggests an unfavorable effect of circulating FFA in this setting. Isoproterenol given before a repeated occlusion increased the severity and extent of the ischemic injury. The effect of isoproterenol on the occlusion-induced S-T segment elevation was reduced, however, when the lipolytic effect of the drug was inhibited by beta-pyridyl-carbinol. Our study suggests that beta-pyridyl-carbinol during acute coronary artery occlusion may be of importance in reducing the extent and severity of myocardial ischemic injury.

Magnetocardiography of direct currents: S-T segment and baseline shifts during experimental myocardial infarction

Magnetocardiograms with a bandwidth of 0 to 40 hertz were recorded from intact dogs undergoing myocardial infarction. This was done with a superconducting magnetometer in a magnetically shielded room. The purpose was to look for the steady currents of injury from the heart which supposedly produce much of the S-T segment shifts during infarction. These heart currents cannot be measured with surface electrodes because of direct-current interference from other sources, such as from the contact potential between electrode and skin. The magnetocardiograms showed both S-T segment shifts and direct currents as a result of infarction. However, they also showed that the S-T segment shifts were not produced by the direct currents. It is unlikely that these direct currents originated from the infarcted area, and their exact origin is not yet known.