Relations between myocardial blood flow and postextrasystolic potentiation in epicardial and endocardial left ventricular regions early after coronary occlusion in dogs

Postextrasystolic potentiation. Do we really know what it means and how to use it?

Postextrasystolic potentiation (PESP), the increase in contractility that follows an extrasystole, is an interesting phenomenon that has been known for almost 100 years. The literature on this effect is reviewed. It is found that there is significant evidence that the phenomenon is independent of muscle loading and represents a distinct property of the myocardium. Examination of the literature pertaining to the cause of the effect suggests that calcium shifts within the sarcoplasmic reticulum are responsible, although there are some conflicts with this conclusion. Regarding the utility of PESP as a diagnostic test of latent viability of ischemic myocardium, the literature review reveals contradictions and conflicts with several methodological problems of the experiments. Finally, concerning the utility of continuous PESP (paired-pacing) to augment ventricular function in the failing ventricle, the studies again are inconclusive and methodologically suspect. Conditions for the proper analysis of the PESP response are reported, and suggestions for future studies are introduced.

Postextrasystolic potentiation does not distinguish ischaemic from stunned myocardium

Myocardial function is impaired by ischaemia, and it remains depressed during reperfusion following short periods of ischaemia (stunned myocardium). We tested whether ischaemic and reperfusion dysfunction, in particular the time course of its recovery, can be distinguished by postextrasystolic potentiation (PESP). In eight open-chest dogs, posterior systolic wall thickening (sonomicrometry) was reduced by graded occlusion of the left circumflex coronary artery (LCX) from 17.4 +/- 6.8% (SD) during control conditions to 10.7 +/- 1.3% (mild ischaemic dysfunction), 7.2 +/- 2.3% (moderate ischaemic dysfunction), 3.6 +/- 1.4% (severe ischaemic dysfunction), and -4.4 +/- 3.6% (complete coronary occlusion). Extrasystoles with constant prematurity and a fully compensated postextrasystolic interval were induced after at least 4 min steady-state ischaemia. After each ischaemic period full recovery of posterior systolic wall thickening was assured. During 8 h of reperfusion following a 15-min LCX occlusion, extrasystoles were induced when posterior systolic wall thickening was comparable to one degree of the preceding ischaemic dysfunction. The increases in posterior systolic wall thickening induced by PESP were 10.5 +/- 5.8% during control conditions, during ischaemia they were 11.5 +/- 3.5% (mild dysfunction), 12.3 +/- 4.6% (moderate dysfunction), 12.6 +/- 4.1% (severe dysfunction) and 10.4 +/- 4.4% (complete coronary occlusion), and during reperfusion they were 12.8 +/- 8.2% (severe dysfunction), 13.0 +/- 9.7% (moderate dysfunction) and 10.7 +/- 2.2% (mild dysfunction).(ABSTRACT TRUNCATED AT 250 WORDS)

Effects of ischemia on epicardial segment shortening

To evaluate the effects of nontransmural ischemia on epicardial contractile function, we implanted sonomicrometers in 15 open-chest, anesthetized (halothane) dogs. One cylindrical crystal (radiating ultrasound 360 degrees) was used as a transmitter for three conventional flat plate crystals arrayed to measure epicardial segment shortening along three different axes that were deviated 0 degree (parallel), 45 degrees (oblique), and 90 degrees (perpendicular) from surface fiber orientation in the anteroapical or posterior-basal left ventricle. During baseline conditions, epicardial shortening was maximal parallel with fiber orientation. Shortening decreased in a non-linear manner as deviation from fiber orientation increased, but there were significant differences between the two left ventricular regions suggesting that more substantial lateral strain occurs in the anterior-apical than the posterior-basal area. During coronary inflow restriction, changes in epicardial segment shortening also varied greatly depending on location and alignment. At levels of wall thickening impairment associated with normal subepicardial perfusion, changes in epicardial function were restricted to the segments aligned perpendicular to fiber orientation whereas the parallel and oblique segments displayed moderate dysfunction or none at all. Thus, transmural tethering modifies epicardial segmental motion during coronary inflow restriction, but the severity of the influence depends on the alignment and location of the epicardial measurements.

Recruitment of a time-dependent inotropic reserve by postextrasystolic potentiation in normal and reperfused myocardium

Impaired excitation-contraction coupling has been suggested as the underlying mechanism of postischemic contractile dysfunction of reperfused myocardium in in-vitro studies. To test this hypothesis in situ, postextrasystolic potentiation (PESP) following an extrasystole with constant prematurity and three different postextrasystolic time intervals (compensated, regular, abbreviated) was analyzed in 12 anesthetized dogs. Changes in regional inotropic state were assessed by comparison of end-systolic wall thickness (sonomicrometry) during PESP to the respective pressure-matched values of an end-systolic pressure/wall-thickness relationship established during brief manual clamping of the aorta. Before ischemia, posterior end-systolic wall-thickness was increased by 0.19 +/- 0.35 (SD) mm during PESP with an abbreviated, by 0.36 +/- 0.42 mm with a regular, and by 0.60 +/- 0.42 mm with a compensated postextrasystolic interval. Baseline systolic wall thickening was decreased from 16.2 +/- 5.4% (before ischemia) to -3.0 +/- 3.4% at the end of 15 min left circumflex coronary occlusion, and to 2.8 +/- 7.5% at 10 min, 7.2 +/- 3.9% at 4 h, and 7.9 +/- 4.1% at 8 h reperfusion. Stepwise increases in regional inotropic state during PESP with increasing postextrasystolic intervals were not different in normal and reperfused myocardium. Thus, excitation-contraction coupling appears not to be impaired during inotropic stimulation of reperfused myocardium in situ.

Abnormal subendocardial blood flow in pressure overload hypertrophy is associated with pacing-induced subendocardial dysfunction

To detect the functional significance of subendocardial hypoperfusion in the pressure-overloaded left ventricle, we studied subendocardial and subepicardial function and subendocardial and subepicardial blood flow simultaneously in seven dogs with left ventricular hypertrophy (left ventricle/body weight ratio, 7.2 g/kg) produced by chronic aortic banding. Seven normal dogs served as controls. Subendocardial and subepicardial segment lengths were measured by ultrasonic dimension gauges, and myocardial blood flow was measured with radioactive microspheres. Atrial pacing (180-200 beats/min for 5 minutes) was used to produce a chronotropic stress. In dogs with left ventricular hypertrophy, the subendocardial blood flow failed to increase during pacing compared with the baseline state (1.21 +/- 0.17 vs. 1.22 +/- 0.17 ml/min/g). Subendocardial shortening fraction deteriorated with pacing stress (before pacing, 30.6 +/- 3.9%; after pacing, 24.2 +/- 3.7%; p less than 0.001). In controls, subendocardial blood flow increased from 1.32 +/- 0.19 to 1.80 +/- 0.19 ml/min/g during pacing, and shortening fraction was preserved (before pacing, 25.5 +/- 3.9%; after pacing, 25.9 +/- 3.3%). Subepicardial blood flow in dogs with hypertrophy increased from 1.54 +/- 0.24 to 2.32 +/- 0.34 ml/min/g, and subepicardial shortening fraction was maintained (before pacing, 10.4 +/- 1.0%; after pacing, 10.5 +/- 1.2%) as it was in controls (subepicardial blood flow, from 1.27 +/- 0.18 to 2.12 +/- 0.17 ml/min/g; shortening fraction, from 16.6 +/- 2.5% to 15.5 +/- 2.2%). We conclude that, with pacing stress in pressure-overload hypertrophy, subendocardial blood flow failed to increase. This abnormality corresponded with a deterioration in subendocardial contractile function.

Regional work of the human left ventricle calculated by wall stress and the natural logarithm of reciprocal of wall thickness

Regional left ventricular work is a more precise indicator of function than is simple shortening fraction. Regional work of the ventricle normalized to a unit volume of myocardium (RWM) is given by the following equation: RWM = - intergral of sigma d[ln(1/H)], where sigma is the mean wall stress and ln(1/H) is the natural logarithm of reciprocal of wall thickness. This method has been previously validated in animal experiments and it is now extended to the clinical setting for the first time. In 10 normal subjects and 6 patients with anteroseptal myocardial infarction, ventricular minor axis and wall thickness were measured by echocardiography and recorded simultaneously with high fidelity left ventricular pressure. Then, regional work of the interventricular septum and of the posterior wall of the left ventricle was calculated from the measured pressure and dimension data. In normal subjects, regional work of the septum and posterior wall was 6.1 +/- 1.7 and 7.0 +/- 1.8 mJ/cm3, respectively; the average of the septal and posterior wall regional work multiplied by the left ventricular myocardial volume correlated well (r = 0.93) with the total mechanical work done by the entire left ventricle. In patients with anteroseptal infarction, septal regional work was greatly reduced (0.6 +/- 1.7 mJ/cm3), compared with posterior wall regional work in the same patients (6.1 +/- 1.8 mJ/cm3). This simple method can be applied clinically in assessing the functional state of different regions of the myocardium.

Postsystolic shortening of acutely ischemic canine myocardium predicts early and late recovery of function after coronary artery reperfusion

Postsystolic shortening and thickening of ischemic and postischemic myocardium are well-recognized phenomena, but their significance is controversial. To discover whether postsystolic shortening and thickening might represent an active process and to establish their place as possible predictors of functional recovery during and after recovery from ischemia, we examined correlations in severely ischemic dyskinetic myocardial segments in 14 open-chest anesthetized dogs (90 minutes' ischemia, n = 9; 180 minutes' ischemia, n = 5) between the magnitudes of postsystolic shortening and thickening during ischemia and either the magnitudes of systolic shortening and thickening in the same segments before coronary occlusion or the magnitudes of shortening and thickening at 30-60 minutes and at 2-3 weeks after reperfusion. We found positive correlations between preocclusion shortening and postsystolic shortening (r = 0.44, n = 33 myocardial segments; p less than 0.02) and between preocclusion thickening and postsystolic thickening (r = 0.73, n = 13 segments; p less than 0.01), both measured at 5 minutes after onset of ischemia. Strong correlations were found also between postsystolic shortening and thickening measured immediately before reperfusion and systolic shortening and thickening measured after recovery at 2-3 weeks (r = 0.73, n = 28; p less than 0.001 for shortening; r = 0.79, n = 12; p less than 0.01 for thickening). Significant but less-exact correlations were found between postsystolic shortening and thickening measured immediately before reperfusion and early recovery of shortening and thickening at 30-60 minutes after reperfusion (during the "stunned myocardium" period). Postsystolic shortening and thickening persisted early after reperfusion in dogs that had had 90 minutes of ischemia, and this predicted further significant return of function at 2-3 weeks. However, dogs that had had 180 minutes of ischemia did not have postsystolic shortening or thickening during early recovery and showed no further return of function at 2-3 weeks. The magnitudes of postsystolic shortening and thickening immediately before reperfusion were better predictors of late return of function than the histological appearance of the ischemic segments at 2-3 weeks or the magnitude of their blood flow during ischemia (15 +/- 3 micron microspheres). From correlations made immediately before reperfusion with those at functional recovery after reperfusion, we conclude that postsystolic shortening and thickening of dyskinetic myocardial segments are markers of their potential for recovery.(ABSTRACT TRUNCATED AT 400 WORDS)

Postextrasystolic potentiation: analysis of methods of induction

Studies were conducted in 15 patients with coronary artery disease to determine if the type of pacing used to induce an extrasystole had a bearing on subsequent postextrasystolic potentiation (PESP) and if the fact that these were evaluated in jeopardized or nonjeopardized portions of the ventricle altered the ability to assess PESP. Two types of pacing were used. In the first group, all beats in the test sequence (basic heart rate, extrasystole, and postextrasystole) were delivered from a programmed external pacemaker. This group was termed the "all-paced" (AP) group, and the postextrasystole was introduced before a compensatory pause could occur, so that loading conditions within the ventricle at the last regular beat and after the extrasystole were not different. In the second group, the extrasystole was coupled to the sensed intrinsic heart rate of the patient, and the postextrasystole was allowed to occur spontaneously. This group was termed the "sensed-paced" (SP) group. Despite differences in basic heart rates and postextrasystolic intervals between the two groups, comparable results were obtained with the two techniques. However, the postextrasystole in the SP group occurred much earlier than expected, probably due to intrinsic cardioacceleration during ventriculography. The net result was that loading conditions in this group before and after the extrasystole were also not different from each other. Results from the pacing techniques were not influenced by whether they were obtained from jeopardized or nonjeopardized segments.(ABSTRACT TRUNCATED AT 250 WORDS)

Postextrasystolic potentiation: regional wall motion before and after revascularization

We evaluated the augmentation of contractility which follows an extrasystole (postextrasystolic potentiation: PESP) in patients before and after coronary revascularization surgery for angina pectoris. PESP was induced by methods which result in essentially identical loading conditions of the ventricle for the beat before the extrasystole and the beat after the extrasystole. We evaluated regional ventricular function before and after revascularization in "jeopardized" segments (supplied by a coronary vessel with significant coronary disease) and "nonjeopardized" segments (supplied by a vessel without significant disease). All coronary lesions were proximal to all three anterior or all posterior segments. Those jeopardized segments with patent grafts which had augmented with PESP improved their baseline function following revascularization. Conversely, those jeopardized segments which failed to augment with PESP decreased their basic function following revascularization. Those segments in which the grafts were occluded failed to augment with PESP after attempted revascularization. Perioperative myocardial infarction resulted in a drop in ejection fraction and a failure to augment with PESP. The nonjeopardized segments responded to PESP similarly to the ischemic augmenting segments. The results of this study suggest that PESP does detect ventricular segments which will improve basic function following revascularization. Those segments which fail to augment with PESP are most likely more ischemic than the augmenting segments, will not improve, and may even decrease function following revascularization.

Dissociation between epicardial and transmural function during acute myocardial ischemia

The relationship between epicardial and transmural function (measured with sonomicrometers) was examined in 13 anesthetized open-chest dogs. Systolic wall thickening was used as a standard of integrated transmural function to compare with epicardial function measured as segment shortening parallel to surface fibers. Three levels of coronary inflow restriction were produced by using decrements in systolic wall thickening as an index of changes in the transmural distribution of myocardial blood flow (microspheres) in myocardium perfused by the left anterior descending artery (anterior-apical group, n = 7) or circumflex artery (posterior-basal group, n = 6). Levels 1 and 2 were characterized by reductions in systolic wall thickening of 35% and 80%, respectively, and marked decreases in deep myocardial blood flow. In the subepicardium, myocardial blood flow was minimally affected at levels 1 and 2 and there was no change in posterior-basal epicardial segment shortening, but anterior segment shortening decreased significantly (by 21% and 37%, respectively). At level 3 myocardial blood flow was reduced transmurally, producing systolic wall thinning and marked epicardial dysfunction in both groups. Parallel epicardial segment shortening underestimated the extent of transmural dysfunction in both groups at levels 1 and 2 but the degree of underestimation was greatest in the posterior-basal group. Anterior-apical segment shortening was impaired at levels 1 and 2, whereas posterior-basal segment shortening was unaffected, suggesting that significant regional variability exists in the epicardial response to nontransmural ischemia.

Early loss of postextrasystolic potentiation in acutely ischemic myocardium: evaluation by contrast two-dimensional echocardiography

Studies in animals with acutely ischemic hearts have suggested that postextrasystolic potentiation (PESP) may predict the viability of dysfunctional myocardium. Most of these data have been obtained with sonomicrometers and therefore the presence and extent of PESP throughout the entire region at risk has not been defined. In this study we used contrast two-dimensional echocardiography (2DE) to define region at risk in vivo, and then with quantitative 2DE we examined the proportion of the region at risk that demonstrated PESP, the degree of the potentiation, and the time course of this response. The region at risk was divided into a central (inner 50%) and two peripheral (25% each) ischemic zones. Adjacent contrast-enhanced myocardium was divided into near and far border zones that were equal in size to the adjacent peripheral ischemic zone. Systolic thickening was analyzed within each zone along multiple radii at 5, 30, and 120 min after coronary occlusion. PESP was absent in the central ischemic zone at all three times. In the peripheral ischemic zone at 5 min, a small amount of PESP was detected (-4.1% vs + 3.1% for nonpotentiated and potentiated thickening, respectively; p less than .01). At 30 min after occlusion, no potentiation was seen in the region at risk and PESP was confined to the contrast-enhanced near and far border zones. These findings persisted at 120 min. These data indicate that the response to PESP is localized to perfused myocardium by 30 min after acute occlusion. PESP is therefore of limited value in predicting the presence of ischemic, potentially viable myocardium early in the course of acute infarction.

Assessment of potentially salvageable myocardium during acute myocardial infarction: use of postextrasystolic potentiation

Twenty-three patients with evolving acute myocardial infarction (AMI) undergoing catheterization for thrombolytic therapy had interventional contrast ventriculography using programmed atrial stimulation. Postextrasystolic (PES) potentiation was present in 67% of infarct-related segments up to 9 hours after the onset of AMI. The presence of segmental potentiation was not related to time from onset of pain to ventriculography, initial ejection fraction, presence of collaterals, left ventricular end-diastolic pressure or the PES delay. In 18 patients reperfusion was successful using intracoronary streptokinase an average of 6.2 hours after the onset of AMI; in these patients repeat contrast ventriculography was performed an average of 11 days after AMI. Improved chronic segmental ventricular function was predicted by the presence of collaterals to the infarct-related artery at the time of acute catheterization (p = 0.02), but was best predicted by analysis of acute PES potentiation (p less than 0.0001). The predictive value of PES analysis was highest in segments without collaterals. Thus, atrial stimulation is safe during AMI and analysis of segmental ventricular function shows potentially viable myocardium up to 9 hours after the onset of AMI. In addition, analysis of PES segmental function can predict chronic function if reperfusion is successful, especially in segments without collaterals. PES ventriculographic analysis may allow prospective determination of which patients during AMI are most likely to benefit from acute thrombolytic therapy.