Comparison of myocardial flow, hemodynamic changes, and lactate metabolism during isoproterenol stress in patients with coronary heart disease and severe aortic stenosis

Changes in phasic coronary blood flow velocity profile in relation to changes in hemodynamic parameters during stress in patients with aortic valve stenosis

BACKGROUND

Alterations in phasic coronary flow profile have been demonstrated at rest in patients with aortic valve stenosis (AVS) but have never been studied under conditions of hemodynamic stress.

METHODS AND RESULTS

Thirty-four patients with significant pure AVS (21 with exertional symptoms [group 1], 13 asymptomatic [group 2]) and 9 control subjects (group 3), all with normal coronary arteries, were studied successively at rest, during rapid atrial pacing, and after dobutamine infusion (5 to 30 micrograms.kg-1.min-1 i.v.) by proximal left anterior descending (LAD) intracoronary Doppler flow velocimetry concomitant with hemodynamic measurements. Systolic retrograde coronary flow velocity (CFV) was recorded only in patients with AVS, and its resting peak value was positively correlated with peak aortic pressure gradient (APG) (r = .63, P < .001). In group 1, there was lower aortic valve area (0.58 +/- 0.10 versus 0.75 +/- 0.08 cm2, P < .001) and higher resting APG and peak systolic retrograde CFV than in group 2, and also higher resting peak diastolic and mean CFV than in groups 2 and 3. In the two AVS groups, there were no changes from rest in APG and retrograde CFV at peak pacing rate; however, these parameters increased concomitantly and significantly at peak dobutamine stress. The ratio of the resting systolic to diastolic CFV curve area was inversely correlated with mean APG (r = -.54, P < .001); it was significantly lower in group 1 than in groups 2 and 3 (0.19 +/- 0.07 versus 0.29 +/- 0.10 and 0.30 +/- 0.04, respectively, both P < .005) and increased at peak pacing (group 1, to 0.29 +/- 0.14; group 2, to 0.39 +/- 0.12; group 3, to 0.38 +/- 0.07; all P < .001). At peak dobutamine stress, it decreased in patients with AVS (group 1, to 0.05 +/- 0.05; group 2, to 0.08 +/- 0.03; both P < .001) but did not change in group 3 (0.25 +/- 0.05). From rest to peak dobutamine stress, in both AVS groups there was increased retrograde systolic (group 1, 441 +/- 483%; group 2, 681 +/- 356%; both P < .001), decreased total systolic (group 1, -66 +/- 25%, P < .001; group 2, -19 +/- 24%; P = NS), and increased diastolic (group 1, 33.4 +/- 31.7%; group 2, 197.7 +/- 105.1%; both P < .001; group 1 versus group 2, P < .001) CFV curve area. In contrast, group 3 showed comparable increases in both systolic (143.5 +/- 44.4%) and diastolic (197.1 +/- 75.2%) CFV area (both P < .001). The stress-induced increases in the mean CFV and blood flow exceeded or were comparable with the concomitant increases in the estimated myocardial metabolic demand in groups 2 and 3 but were significantly lower in group 1.

CONCLUSIONS

Stress-induced changes in LAD phasic CFV profile differ significantly between patients with and without AVS. In AVS, these changes are closely related to the concomitant stress-induced changes in hemodynamic parameters.

Coronary flow reserve

The ability of the coronary circulation to autoregulate is essential for the heart to respond to metabolic demands. Several alterations in function may limit maximal coronary perfusion including atherosclerosis, structural abnormalities of small coronary vessels, extravascular compressive forces, thrombosis, abnormal endothelial regulatory function, and the effect of abnormal myocardium on the coronary circulation. Coronary flow reserve is a unifying concept that examines the limitation in myocardial perfusion that certain disease states impose. At present, even with state-of-the-art technology, the measurement of coronary flow reserve is difficult in routine clinical situations. As the ability to measure regional myocardial perfusion improves, coronary flow reserve may gain more widespread clinical use with perhaps as yet undiscovered therapeutic implications.

Preoperative left ventricular wall stress, ejection fraction, and aortic valve gradient as prognostic indicators in aortic valve stenosis

Patients with aortic valve stenosis (AS) and left ventricular (LV) dysfunction may dramatically improve after aortic valve replacement, but operative risk is high. In an earlier study, all patients with low preoperative wall stress and low ejection fraction, or with low aortic valve gradient, died or had persistent heart failure after operation. Because wall stress is difficult to calculate, we reassessed its effect and the effect of other preoperative characteristics on outcome in 66 consecutive catheterization patients with predominant aortic stenosis referred for valve replacement. Despite ejection fraction that was inordinately low compared with afterloading wall stress in nine patients, seven patients improved with surgery. All three patients with ejection fraction less than 20% improved after surgery. Two of three patients with mean aortic valve gradients of less than 30 mm Hg improved. Mortality was 33% in patients with mean gradient less than 30 mm Hg and 19% with mean gradient less than 50 mm Hg. In the 54 patients with calculated aortic valve areas of less than or equal to 0.8 cm2, 1 (2%) had continuing heart failure, while 6 of 12 (50%, P less than .01) patients with aortic valve areas of 0.9-1.2 cm2 had continued symptoms of or died of heart failure. Patients who died or failed to improve after operation were older (71 +/- 9 years) than those who improved (65 +/- 9 years, P = .02). We conclude that wall stress calculations do not predict which patients with aortic stenosis will benefit from aortic valve replacement and that poor left ventricular function and low mean aortic valve gradient do not absolutely preclude operation. On the other hand, low gradient, non-critical valve area, and advanced age are all relative contraindications to aortic valve replacement in aortic stenosis.

Demonstration of an imbalance between coronary perfusion and excessive load as a mechanism of ischemia during stress in patients with aortic stenosis

Patients with aortic stenosis are susceptible to myocardial ischemia during hemodynamic stress, which may be caused by two mechanisms. First, vascular abnormalities inherent in myocardial hypertrophy may impair coronary vasodilation, limiting the ability to increase coronary blood flow to meet increased metabolic demands. Second, aortic stenosis itself may cause an imbalance between oxygen supply and demand during hemodynamic stress by decreasing aortic pressure (decreasing coronary perfusion or oxygen supply) and increasing left ventricular pressure (increasing oxygen demand). By decreasing aortic valve gradient without immediately altering ventricular hypertrophy, aortic balloon valvuloplasty offers the opportunity to distinguish these mechanisms. We hypothesized that aortic valvuloplasty would improve the balance between myocardial oxygen supply and demand, especially during isoproterenol infusion. Nine patients undergoing aortic balloon valvuloplasty were assessed at baseline and during isoproterenol infusion (5 +/- 2 micrograms/min, mean +/- SD) before and after valvuloplasty. Valvuloplasty increased myocardial oxygen supply. After valvuloplasty, isoproterenol decreased diastolic pressure time index (DPTI) less and increased coronary sinus blood flow more than before valvuloplasty (-630 +/- 367 vs. -292 +/- 224 mm Hg.sec/min, p = 0.02 and 53 +/- 137 vs. 179 +/- 145 ml/min, p = 0.001, respectively). Valvuloplasty also decreased oxygen demand, decreasing systolic pressure time index (SPTI) from 4,135 +/- 511 to 3,021 +/- 492 mm Hg.sec/min (p = 0.0002). Valvuloplasty improved the balance between myocardial oxygen supply and demand, increasing baseline DPTI:SPTI, decreasing aortocoronary sinus oxygen content difference (0.51 +/- 0.15 to 0.68 +/- 0.14, p = 0.005 and 96 +/- 14 to 78 +/- 15 ml O2/l, p = 0.002, respectively), and decreasing myocardial lactate production during isoproterenol infusion (mean lactate extraction fraction, -0.26 +/- 0.40 to 0.14 +/- 0.17; p = 0.01). We conclude that aortic valvuloplasty improves the balance between myocardial oxygen supply and demand during hemodynamic stress induced by isoproterenol infusion. We speculate that the clinical improvement, which often occurs in these patients after valvuloplasty despite persistence of hemodynamically "critical" aortic stenosis, is in part attributable to immediate improvement in the myocardial oxygen supply:demand ratio.

Effect of aortocoronary bypass surgery on coronary circulation and myocardial metabolism during atrial pacing

Eleven patients with coronary heart disease, in whom at least one of several bypass grafts to the left coronary artery was patent, were selected for the study. The hemodynamics, coronary sinus blood flow, myocardial oxygen consumption, and myocardial lactate metabolism were evaluated at rest and during atrial pacing stress test before and after surgery. There were no significant improvements in the cardiac index, pulmonary arterial end-diastolic pressure, and left ventricular ejection fraction after aortocoronary bypass surgery. However, significant improvement of coronary sinus blood flow, myocardial oxygen consumption, and myocardial lactate extraction and consumption were found during postoperative atrial pacing compared with the preoperative findings. These results suggest that successful bypass grafting may improve myocardial lactate metabolism in ischemic lesions and contribute to the postoperative relief of angina.

Hemodynamic and myocardial energetic changes induced by the new cardiotonic agent, AR-L 115, in patients with coronary artery disease

AR-L 115 has been shown to improve left ventricular (LV) pump function in patients with advanced congestive cardiomyopathy by the intravenous and oral routes. Since AR-L 115 effects on myocardial oxygen consumption (MVO2) and coronary blood flow (CSF) are unknown, the hemodynamic, myocardial metabolic, and ECG responses to AR-L 115 (2 mg/kg bolus) were monitored at 9-, 14-, and 9-minute intervals in seven patients with coronary disease, exhibiting ischemia during pacing stress only. Maximal responses occurred at the fourteenth minute after AR-L 115. There were (average) increases in cardiac index by 30%, heart rate by 19%, CSF by 39%, MVO2 by 34%, and LV dp/dt max by 27%. There were (average) decreases in peak LV systolic pressure by 13%, LV end-diastolic pressure by 42%, systemic vascular resistance by 34%, and in coronary vascular resistance by 37%. All changes were significant (p less than 0.05). Myocardial lactate extraction, stroke work index, and stroke index remained unchanged (p greater than 0.05). The modest increase in MVO2 is possibly explained by the increase in contractility being partially offset by reductions in LV preload and afterload. AR-L 115-improved LV pump function was accompanied by moderate increases in MVO2 and CSF but without evidence of myocardial ischemia.

Decreased coronary reserve: a mechanism for angina pectoris in patients with aortic stenosis and normal coronary arteries

The pathogenesis of angina pectoris in patients with aortic stenosis and normal coronary arteries remains uncertain. Using a specially designed Doppler probe, we measured the maximal velocity of coronary blood flow in the left-anterior descending coronary artery at the time of elective open-heart surgery in 14 patients with aortic stenosis and left ventricular hypertrophy (13 had angina) and in 8 controls without left ventricular hypertrophy. The ratio peak velocity of coronary blood flow, after a 20-second occlusion, to resting velocity was decreased by more than 50 per cent (P less than 0.05) in the patients with aortic stenosis. In 7 of the patients this ratio was decreased by more than 75 per cent. Studies of the velocity of coronary blood flow in vessels perfusing the right ventricle in these patients showed only mild abnormalities. These data demonstrate a selective and marked decrease in coronary reserve to the hypertrophied left ventricle in patients with severe aortic stenosis. The impairment in coronary reserve is probably an important contributor to the pathogenesis of angina pectoris in these patients.

Hemodynamics alterations induced by isoproterenol and pacing after aortic valve replacement with the Björk-Shiley or St. Jude medical prosthesis

Stress evaluation was carried out in 26 patients approximately 7 months after aortic valve replacement with Björk-Shiley valves (13 patients) and St. Jude medical valves (13 patients). During isoproterenol infusion (0.3 micrograms/kg/min), cardiac output increased by a factor of 1.5 and aortic valve area decreased by 50% for both valve groups, while transvalvular gradients (rest: 7 +/- 2 vs 10 +/- 5 mm Hg, p greater than 0.05) increased by 42 +/- 18 vs 51 +/- 18 mm Hg (p greater than 0.05), i.e., to levels of moderate aortic stenosis. However, during pacing stress these values progressively decreased with rising heart rates. In other postoperative evaluations that included ergometric stress with isoproterenol and pacing, induced hemodynamic changes after aortic valve replacement were predictable and consistent with regard to both direction and magnitude, and they differed characteristically according to the type of stress used. We conclude that no functional differences between Björk-Shiley and St. Jude medical valves can be claimed. Standardized evaluation with isoproterenol is a sensitive stress test of prosthetic valvular hemodynamics. Because of the apparent magnification of residual obstruction after aortic valve replacement, it has advantages over pacing.

Coronary flow studies in patients with left ventricular hypertrophy of the hypertensive type. Evidence for an impaired coronary vascular reserve

Increased myocardial blood flow occurs in ventricular hypertrophy, but flow per 100 grams of myocardium remains normal. The increase in flow may be obtained at the expense of the existing coronary vascular reserve or by an increase in the vascular bed. The coronary vascular reserve was studied by analyzing the hyperemic reaction to selective injection of contrast agent into the coronary arteries in 25 patients: a control group (9 patients) with chest pain syndrome, normal coronary arteries and a normal left ventricle (Group I) and 16 patients with aortic stenosis, left ventricular hypertrophy and normal coronary arteries (Group II). The hyperemic response in Groups I and II was 73.3 +/- 2.2 and 65.8 +/- 9.1 percent, respectively (difference not significant). Group II was subdivided into two groups: Group IIA had five patients with a left ventricular mass of less than 200 g (mean 158.8 +/- 25.9); this group had a hyperemic response of 102.3 +/- 9.9 percent. Group IIB had 11 patients with a left ventricular mass of more than 200 g (mean 308.9 +/- 22.5) and a hyperemic response of 49.27 +/- 10.42 percent. The hyperemic response was correlated with the diastolic left ventricular-aortic gradient (r = +0.64, p less than 0.001), left ventricular mass (r = -0.51, p less than 0.01) and aortic diastolic pressure (r = +0.636, p less than 0.001). Group I had a left ventricular mass similar to that of Group IIA (124.9 +/- 9 and 158.8 +/- 26 g, respectively) but a lower hyperemic response (73.3 +/- 2 and 102.3 +/- 10 percent, respectively). These data suggest that severe left ventricular hypertrophy is associated with a reduction in coronary vascular reserve; it is speculated that this decrease in the vascular reserve capacity may be related to the ischemic component of hypertrophic heart disease.