Effect of intracoronary nitroglycerin administration on phasic pattern and transmural distribution of flow during coronary artery stenosis.

BACKGROUND. Nitroglycerin is effective in relieving myocardial ischemia; however, intracoronary nitroglycerin often fails to relieve angina and has been reported to have deleterious effects on subendocardial blood flow. To understand the mechanisms involved, we evaluated the direct effect of nitroglycerin on coronary circulation of the ischemic hearts. METHODS AND RESULTS. We measured the phasic pattern of intramyocardial coronary arterial flow with an 80-channel, 20-MHz pulsed Doppler ultrasound flowmeter under moderate to severe coronary artery stenosis (distal perfusion pressure approximately 45 mm Hg group 1, n = 6) and transmyocardial blood flow distribution using radioactive microspheres while maintaining coronary pressure at a low constant level (40 mm Hg, group 2, n = 6). In anesthetized open-chest dogs, the left main coronary artery was perfused directly from the right carotid or femoral artery. In this bypass circuit, pressure was controlled with an occluder or a reservoir was connected to the circuit. In group 1, the systolic and diastolic pressures distal to the stenosis decreased significantly after intracoronary administration of nitroglycerin at maximal coronary flow from 66.5 +/- 18.5 to 56.5 +/- 13.8 mm Hg (p less than 0.01) and from 36.6 +/- 14.4 to 27.5 +/- 8.9 mm Hg (p less than 0.01), respectively. The phasic pattern of the septal artery flow was predominantly diastolic and was characterized by systolic reverse flow even in the absence of stenosis. Coronary stenosis increased systolic reverse flow. Nitroglycerin increased diastolic forward flow (p less than 0.05) but augmented systolic reverse flow markedly (p less than 0.001). In group 2, nitroglycerin increased subepicardial flow (p less than 0.05) but failed to increase subendocardial flow. With the administration of nitroglycerin, the subendocardial-to-subepicardial flow ratio decreased significantly from 0.73 +/- 0.19 to 0.32 +/- 0.14 (p less than 0.01). CONCLUSIONS. The increased systolic reverse flow after intracoronary administration of nitroglycerin may be closely related to failure of subendocardial blood flow to increase with increase subepicardial flow.     

Hemodynamic abnormalities during coronary angiography: comparison of Hypaque-76, Hexabrix, and Omnipaque-350

The hemodynamic effects induced by coronary angiography in dogs with low osmolar ionic dimer Hexabrix (HB) and nonionic Omnipaque-350 (OM) were compared to the standard ionic contrast medium, Hypaque-76 (H76), both in the normal heart and in one with simulated severe cardiac disease. Left coronary angiography was performed in 12 "normal" closed-chest dogs with 10-cc injections of H76, HB, and OM in a randomized, blinded fashion. The maximal change in the left ventricular (LV) systolic pressure (SP), mean aortic pressure (MAP), left ventricular end diastolic pressure (LVEDP), and LV dp/dt were recorded. The LVSP and MAP fell 30 +/- 3 mm Hg and 26 +/- 4 mm Hg with H76, 22 +/- 2 mm Hg and 19 +/- 2 mm Hg with HB, and 7 +/- 1.5 mm Hg and 5 +/- 1 mm Hg with OM (P less than .001). The LVEDP increased 4.8 +/- 0.5 mm Hg with H76, 3 +/- 0.5 mm Hg with HB, but only 0.2 mm Hg with OM (P less than .001). The LV dp/dt decreased 392 +/- 63 mm Hg/sec with H76 and 235 +/- 21 mm Hg/sec with HB, but increased 411 +/- 50 mm Hg with OM (P less than .001). In eight additional open-chest dogs, left coronary angiography was performed 1 hr after occlusion of the proximal LAD coronary artery and in the presence of a critical circumflex coronary artery (CX) stenosis.(ABSTRACT TRUNCATED AT 250 WORDS)     

Relation of intramyocardial and intracavitary pressure to regional myocardial asynergy in the canine left ventricle

The purpose of this study was to investigate the relation between abnormalities of left ventricular (LV) wall thickening during systole in ischemic regions and the interaction of LV pressure and regional intramyocardial pressure. Wall thickness was measured in 10 open-chest dogs with ultrasonic dimension gauges. LV pressure, aortic pressure, and intramyocardial pressure in the subendocardium were measured with catheter-tip micromanometers. Regional ischemia was produced by occlusion of the left anterior descending coronary artery. During the control period, peak subendocardial pressure exceeded LV pressure by 44 +/- 6 mm Hg. With hypokinesia, defined as a 50% to 89% reduction of systolic wall thickening, peak subendocardial pressure exceeded peak LV pressure but to a lesser extent (15 +/- 1 mm Hg). During akinesia, defined as a 90% to 100% reduction of systolic wall thickening, there was less than 1 mm Hg difference between peak subendocardial pressure and peak LV pressure. During dyskinesia, defined as systolic thinning of the ischemic wall, peak LV pressure exceeded peak subendocardial pressure by 29 +/- 6 mm Hg. These observations indicate that regional changes of LV wall thickness characterized by hypokinesia, akinesia, and dyskinesia are associated with pressure gradients between the LV cavity and the LV wall that are compatible with the abnormalities of wall motion.     

Transmural variation in autoregulation of right ventricular blood flow

We examined transmurally the right coronary autoregulatory flow response to varied perfusion pressures in 11 anesthetized, open-chest dogs. Right coronary artery flow was measured electromagnetically, and its transmural distribution was defined with 15-micron radioactive microspheres. Heart rate, mean aortic blood pressure, right ventricular systolic pressure, end-diastolic pressure, and dP/dtmax were constant. At 100 mm Hg, subepicardial flow averaged 0.48 +/- 0.04 ml/min/g, and subendocardial flow averaged 0.56 +/- 0.05 ml/min/g. In contrast to the left coronary circulation, right coronary hypotension did not cause preferential subendocardial ischemia. As right coronary perfusion pressure was decreased from 100 to 40 mm Hg in five dogs, subepicardial and subendocardial flows were reduced similarly by 35-36%. As right coronary perfusion pressure was elevated from 100 to 150 mm Hg in six dogs, right ventricular subepicardial blood flow increased by 31%, whereas subendocardial blood flow increased by 70%. Right ventricular subendocardial-to-subepicardial flow ratios averaged 1.15-1.20 for perfusion pressures of 40 to 120 mm Hg, and they increased to 1.36 +/- 0.05 at 150 mm Hg. Right coronary artery autoregulatory closed-loop gain averaged 0.47 +/- 0.06 between 70 and 100 mm Hg and was greater than zero from 40 to 120 mm Hg. Between 120 and 150 mm Hg, gain fell to -0.15 +/- 0.10. Regional gain varied from 0.59 +/- 0.10 to 0.44 +/- 0.08 in subepicardium as pressure was decreased from 100 to 40 mm Hg. Subendocardial gains were similar to subepicardial gains over this pressure range.(ABSTRACT TRUNCATED AT 250 WORDS)     

Microvascular pressures and resistances in the left ventricular subepicardium and subendocardium

These experiments tested the hypothesis that differences in the distribution of subepicardial and subendocardial microvascular resistances may alter the transmural distributions of microvascular pressures. Isolated blood- and physiological saline-perfused porcine hearts were surgically incised to enable exposure of the subendocardial and subepicardial microcirculations. Microvascular pressures were measured during cardiac arrest and maximal vasodilation at various perfusion pressures to formulate relations between perfusion pressure and microvascular pressure in the different subendocardial (both free wall and papillary muscle) and subepicardial segments. Measurements of arteriolar and venular pressures in both myocardial regions were performed in comparably sized vessels (80-120 microns in diameter). At a coronary perfusion pressure of 100 mm Hg, subendocardial arteriolar and venular pressures were 60 +/- 4 and 33 +/- 3 mm Hg, respectively. In contrast, at the same coronary perfusion pressure, arteriolar and venular pressures in the subepicardial microcirculation averaged 80 +/- 6 and 22 +/- 3 mm Hg, respectively (p less than 0.05 versus subendocardium). At all levels of coronary perfusion pressure, arteriolar pressures were significantly lower in the subendocardium than in the subepicardium (p less than 0.05). Venular pressures were also higher in the subendocardial microcirculation than in the subepicardial microcirculation at all but the lowest perfusion pressure (p less than 0.05). The relative distribution of resistances in arteries, microvessels, and veins was also different between the subepicardium and subendocardium. Specifically, in the subendocardium, arterial and venous resistances were higher, percentage-wise, but microvascular resistance was proportionately lower than that in the subepicardium (p less than 0.05). From these data, it is concluded that the distribution of microvascular resistances and pressures is different during maximal vasodilation in the subepicardial and subendocardial microcirculations of the left ventricle. It is also speculated that differences in autoregulatory capacity and vulnerability to ischemia may be partially related to unequal distribution of microvascular resistances across the wall of the left ventricle.     

The effect of molsidomine on intramyocardial pressure and regional myocardial blood flow in the canine ischemic myocardium

Molsidomine was administered intraduodenally to anesthetized dogs which were instrumented for measurements of aortic and left ventricular (LV) pressures, coronary perfusion pressure, intramyocardial pressure in the subendocardium, and subendocardial and subepicardial myocardial blood flow in the ischemic and non-ischemic regions. The dogs were divided into two groups: group M (n = 9) was administered molsidomine (0.2 mg/kg), group S (n = 10), saline only. Maximum LV systolic pressure decline was 20% in group M and 3% in group S (p less than 0.05). Maximum LV end-diastolic pressure decline was 63% and 35% in groups M and S, respectively (p less than 0.05). There was no difference between mean aortic pressure and coronary perfusion pressure between the two groups. The subepicardial blood flow in the ischemic region was decreased (-23% in group M vs 5% in group S; p less than 0.05), but subendocardial blood flow in the ischemic region increased only slightly in group M. The ratio of subendocardial to subepicardial blood flow increased at 15 and 30 min after administration of molsidomine in the ischemic area (67% in group M vs -10% in group S; p less than 0.05), but did not show any change in the non-ischemic region. Intramyocardial pressure at systole did not show any change but it decreased at end-diastole, (-32% in group M vs -7% in group S; p less than 0.05). Thus molsidomine redistributed the myocardial blood flow from the subepicardium to the subendocardium and from the non-ischemic to the ischemic region. This redistribution was associated with a reduction in both LV end-diastolic pressure and intramyocardial pressure at end-diastole.     

Load dependence of left ventricular diastolic pressure-volume relations during short-term coronary artery occlusion.

We evaluated the effect of altered loading conditions on left ventricular (LV) diastolic pressure-volume relations during acute coronary artery occlusion that was produced by inflation of an intracoronary balloon. Open-chest anesthetized dogs (n = 18) were instrumented so that LV pressure (micromanometer) and LV volume (conductance) could be measured without disturbing the pericardium. The effects of brief periods of occlusion (1-2 minutes) were assessed under steady-state conditions before and after dextran infusion with the pericardium present and absent and during vena caval occlusion. Under steady-state conditions before dextran infusion with the pericardium removed, at an LV end-diastolic pressure (EDP) of 8.4 +/- 1.4 mm Hg, occlusion resulted in a rightward shift in the diastolic portion of the LV pressure-volume loop (delta LVEDP, 2.7 +/- 2.3 mm Hg; delta LVEDV, 6.3 +/- 4.7 ml, both p less than 0.05 versus control). After dextran infusion (LVEDP, 20.9 +/- 6.0 mm Hg), occlusion resulted in a rightward and upward shift in the diastolic portion of the LV pressure-volume loop (delta LVEDP, 5.8 +/- 4.4 mm Hg; delta LVEDV, 4.2 +/- 3.0 ml, both p less than 0.05 versus control). At low cardiac volumes before dextran infusion, the intact pericardium did not affect the response to occlusion. By contrast, after dextran infusion in the presence of an intact pericardium, LVEDP significantly increased (delta, 6.4 +/- 3.6 mm Hg, p less than 0.05) but LVDEV did not (delta, 0.7 +/- 1.5 ml, p = NS). There was a parallel upward shift in the diastolic portion of the LV pressure-volume loop that was eliminated by removal of the pericardium. Thus, the change in LV diastolic pressure and volume during occlusion varied and depended on the baseline cardiac volume and presence of the pericardium. Before dextran infusion with the pericardium present and absent, coronary artery occlusion did not alter the LV diastolic chamber stiffness parameter, which was calculated from the diastolic interval of an averaged steady-state beat (0.040 +/- 0.019 versus 0.036 +/- 0.015 mm Hg/ml, p = NS). After dextran infusion with the pericardium present and absent, coronary artery occlusion increased the LV diastolic chamber stiffness parameter (0.057 +/- 0.034 and 0.074 +/- 0.034 mm Hg/ml, both p less than 0.05 versus controls, respectively). Vena caval occlusion eliminated the shifts in the diastolic portion of the LV pressure-volume loop with the pericardium present and absent.(ABSTRACT TRUNCATED AT 400 WORDS)     

Pulmonary artery pressure and left ventricular late diastolic pressure in rest and during dynamic load. Comparative studies on pressure transmission in the pulmonary circulation during simultaneous determination]

Left ventricular enddiastolic pressure (LVEDP), mean pulmonary artery pressure (PAPM) and enddiastolic pulmonary artery pressure (PADP) were simultaneously recorded in 19 subjects with normal left ventricular (LV) function, and in 109 patients with LV-dysfunction, 83 of whom were also studied during exercise. Patients with valvular heart disease or atrial fibrillation were excluded from this study. LVEDP and mean pulmonary capillary wedge (PCW) pressure were simultaneously recorded in 81 patients at rest, andin 16 patients also during exercise; the LV diastolic pressure prior to atrial contraction (LVPpreA) could accurately be identified in 45 patients at rest and in 23 patients with exercise. In contrast to the widely accepted opinion of others, the PADP (mean 8.2 +/- 2.2 mm Hg at rest and 12.3 +/- 3.4 mm Hg with exercise) showed a close approximation of LVEDP (10.0 +/- mm Hg at rest and 16.2 +/- 3.5 mm Hg with exercise) only in normal subjects at rest (p less than 0.05 and p less than 0.01 respectively). In patients with LV dysfunction there was no significant difference between PADP (11.7 +/- 4.5 mm Hg and 23.0 +/- 8.9 mm Hg), PCW (11.6 +/- 5.1 mm Hg and 24.1 +/- 11.9 mm Hg) and LVPpreA (12.5 +/- 5.5 and 21.5 +/- 7.7 mm Hg) at rest and during exercise. LVEDP could be estimated with sufficient accuracy only from the PAPM (18.9 +/- 6.5 and 35.7 +/- 10.8 mm Hg). The increase in LVEDP (14.7 +/- 7.7 mm Hg) with exercise was not significantly different from the increase in PAPM (16.8 +/- 7.1 mm Hg). There were highly significant correlations (p less than 0.001) between LVEDP and PADP (r = 0.85) as well as PAPM (r = 0.86) at rest and during exercise with the regressionline being closest to the line of identity for LVEDP and PAPM. The pressure gradient between LVEDP and PADP (LVEDP - PADP = 6.3 mm Hg with exercise) equaled the pressure increase in LV by atrial contraction (LVEDP - LVPpreA = 6.3 and 13.3 mm Hg). The pressure difference between PADP or PAPM and LVEDP remained constant despite marked variation of other hemodynamic parameters, e.g. stroke volume index (SVI), heart rate (HR) and cardiac index(CI). These data suggest that an elevated LVEDP is caused mainly by an augmented atrial contraction in patients with LV dysfunction at rest and with exercise. This mechanism precludes an enddiastolic pressure equilibrium between pulmonary artery and left ventricel. PAPM allows the best estimation of LVEDP independent from other hemodynamic variables.     

Effects of nontransmural ischemia on inner and outer wall thickening in the canine left ventricle

The effect of ischemic subendocardial dysfunction on contractile function in the normally perfused subepicardium remains controversial. Accordingly, regional wall thickening (WT) was measured directly in the left ventricle of 10 open-chest dogs using epicardial echocardiography. Two silk sutures, used as echocardiographic targets, were inserted beneath the transducer to a depth of 25.0 +/- 0.7% (subepicardium) and 48.0 +/- 2.7% (midmyocardium) of transmural thickness. A hydraulic cuff, placed around the left anterior descending coronary artery (LAD) was then inflated slowly until transmural WT was reduced to 62 +/- 2% of baseline. Myocardial blood flow (MBF) was not significantly altered in the subepicardial third of the wall; however, flow to the midwall and subendocardial thirds decreased by 39% (p less than 0.001) and 50% (p less than 0.001), respectively. Nontransmural ischemia produced a small but significant decrease in epicardial WT (baseline = 0.77 +/- 0.08 mm, ischemia = 0.69 +/- 0.08 mm; p less than 0.05) and substantially larger decreases in midwall (baseline = 1.66 +/- 0.14 mm, ischemia = 1.03 +/- 0.09 mm; p less than 0.001) and subendocardial WT (baseline = 3.39 +/- 0.34 mm, ischemia = 2.10 +/- 0.26 mm; p less than 0.001). The degree of regional dysfunction was linearly correlated with tissue depth (r = 0.88, p less than 0.001). Thus the degree of dysfunction produced by nontransmural ischemia increased progressively from the subepicardium to the subendocardium, paralleling the pattern of perfusion. We conclude that perfusion, rather than transmural tethering, largely determines subepicardial function in the setting of nontransmural ischemia.     

Mechanisms of subendocardial dysfunction in response to exercise in dogs with severe left ventricular hypertrophy.

The effects of exercise on regional myocardial blood flow and function were examined in the presence and absence of beta-adrenergic receptor blockade in 10 adult conscious dogs with severe left ventricular (LV) hypertrophy induced by aortic banding in puppies, which increased the LV weight/body weight ratio by 87%. Exercise at the most intense level studied increased LV systolic (+87 +/- 8 mm Hg) and end-diastolic (+28 +/- 5 mm Hg) pressures, systolic (+85 +/- 12 g/cm2) and diastolic (+49 +/- 11 g/cm2) wall stresses, and subepicardial wall thickening (+0.18 +/- 0.05 mm) but reduced subendocardial wall thickening (-0.45 +/- 0.12 mm) and full wall thickening (-0.42 +/- 0.13 mm). This was associated with a fall in the subendocardial/subepicardial (endo/epi) blood flow ratio to 0.87 +/- 0.06 from 1.24 +/- 0.08. Subendocardial dysfunction persisted during recovery, at a time when transmural blood flow distribution returned to baseline, suggesting myocardial stunning. At the least intense level of exercise studied, the endo/epi blood flow ratio did not fall (1.27 +/- 0.14), but increases in heart rate (+73 +/- 8 beats per minute) and LV systolic (+35 +/- 8 g/cm2) and diastolic (+27 +/- 3 g/cm2) wall stresses were observed, and subendocardial wall thickening fell significantly (-0.21 +/- 0.08 mm, p less than 0.05). With anticipation of exercise, subendocardial wall thickening was not changed. However, subendocardial dysfunction was even evident after 10 beats, i.e., the first 3 seconds of exercise, at a time when LV pressures and stresses had not increased. After beta-adrenergic receptor blockade with propranolol, the most intense level of exercise was associated with lesser increases in systolic and diastolic LV wall stresses, heart rate, and LV dP/dt, and the endo/epi blood flow ratio was no longer reduced below unity (1.17 +/- 0.09). In addition, there were no decreases in subendocardial or full wall thickening, and myocardial stunning was no longer observed. Thus, the subendocardial hypoperfusion and depression in subendocardial wall thickening observed during exercise in dogs with LV hypertrophy was prevented by pretreatment with beta-adrenergic receptor blockade. Furthermore, the subendocardial dysfunction occurred rapidly, before alterations in LV systolic or diastolic wall stress or an alteration in the endo/epi blood flow ratio.(ABSTRACT TRUNCATED AT 400 WORDS)     

Effect of nitroglycerin-induced reduction of left ventricular filling pressure on diastolic filling in acute dilated heart failure

Recent information has suggested that early diastolic filling may be influenced by the left ventricular filling pressure, especially in the failing left ventricle. Acute severe left ventricular dysfunction was induced in 14 dogs by severe left ventricular global ischemia produced by left main coronary artery microsphere embolization until the left ventricular end-diastolic pressure was greater than or equal to 20 mm Hg. To assess the importance of left ventricular filling pressure on left ventricular diastolic filling, nitroglycerin was infused and titrated to reduce left ventricular end-diastolic pressure to less than 15 mm Hg in seven dogs, whereas the remaining seven dogs were observed for 1 h after acute severe left ventricular dysfunction. In both groups of dogs, severe left ventricular dysfunction resulted in left ventricular dilation and elevation of end-diastolic pressure, reduction in area ejection fraction (echocardiographically determined) and an early redistribution of diastolic filling (increased filling fractions at one-third and one-half diastole) despite prolongation of the time constant of left ventricular pressure decline. Pressure-area plots shifted upward and rightward with severe left ventricular dysfunction and were unchanged at 1 h as were all other variables. Nitroglycerin infusion reduced left ventricular size and filling pressure, redistributed diastolic filling to later in diastole as characterized by reduced filling fraction at one-third diastole (left ventricular dysfunction 48.8 +/- 9.7%, nitroglycerin 17.9 +/- 7.9%, p less than 0.001) and shifted downward left ventricular pressure-area plots. Nitroglycerin also improved the time constant of relaxation (left ventricular dysfunction 83 +/- 15 ms, nitroglycerin 52 +/- 15 ms, p less than 0.001) and lengthened the diastolic filling period.(ABSTRACT TRUNCATED AT 250 WORDS)     

Mechanism of augmented rate of left ventricular filling during exercise.

At rest, most of left ventricular (LV) filling occurs early in diastole. This LV filling occurs in response to the pressure gradient produced as LV pressure falls below left atrial (LA) pressure. Because mitral valve flow occurs in response to an LA to LV pressure gradient, augmented diastolic mitral valve flow during exercise may be due to an increased mitral valve pressure gradient resulting from a rise in LA pressure and/or a fall in LV early diastolic pressure. Accordingly, we studied 13 conscious dogs, instrumented to measure micromanometer LV and LA pressures, and determined LV volume from three ultrasonic dimensions during exercise. The animals ran on a treadmill for 8-15 minutes at 5-8 miles/hr. With reflexes intact, during exercise, the heart rate increased from 116 +/- 20 to 189 +/- 24 beats per minute (mean +/- SD, p less than 0.01), the maximum rate of change of LV volume (dV/dtmax) increased from 185 +/- 44 to 282 +/- 76 ml/sec (p less than 0.01), the ejection fraction and cardiac output increased, and the duration of diastole decreased from 296 +/- 83 to 162 +/- 71 msec (p less than 0.01). Mitral valve opening pressure, mean LA pressure (10.9 +/- 4.4 versus 10.2 +/- 3.9 mm Hg, p = NS), and LV end-diastolic pressure (12.8 +/- 4.8 versus 13.1 +/- 3.3 mm Hg, p = NS) were all relatively unchanged. The time constant of the fall of isovolumic LV pressure decreased from 28 +/- 3.3 to 21 +/- 4.4 msec (p less than 0.05). The early diastolic portion of the LV pressure-volume loop was shifted downward during exercise, with the minimum LV pressure decreasing from 3.3 +/- 2.8 to -2.8 +/- 3.4 mm Hg (p less than 0.05) and the maximum mitral valve pressure gradient increasing from 5.5 +/- 1.7 to 11.8 +/- 3.5 mm Hg (p less than 0.01). A similar downward shift of the early diastolic portion of the LV pressure-volume loop was produced by infusion of dobutamine (6 micrograms/kg/min i.v.) at rest, as well as by exercise when the heart rate was held constant by right ventricular pacing at 190-210 beats per minute. The downward shift during exercise was prevented by beta-blockade (metoprolol, 0.5 mg/kg i.v.). We conclude that during exercise, sympathetic stimulation and tachycardia produce a downward shift of the early diastolic portion of the LV pressure-volume loop.(ABSTRACT TRUNCATED AT 400 WORDS)     

Mechanisms of heart failure with well preserved ejection fraction in dogs following limited coronary microembolization

OBJECTIVE: It has been suggested that in some settings, heart failure (HF) may occur with normal ejection fraction (EF) as a consequence of undetected systolic dysfunction. However, others have argued that this can only occur in the presence of diastolic dysfunction. We therefore sought to determine the contribution of diastolic dysfunction in an animal model of HF with normal EF. METHODS AND RESULTS: Limited myocardial injury was induced in 21 dogs chronically instrumented to measure hemodynamics and LV properties by daily coronary microembolization ( approximately 115 microm beads) until LV end diastolic pressure (LVEDP) was > or =16 mm Hg. Nine dogs developed HF within 16+/-6 days (LVEDP 12+/-2 vs. 21+/-2 mm Hg, p<0.001) with no significant change in dP/dt(max) (2999+/-97 vs. 2846+/-189 mm Hg/s), mean arterial pressure (103+/-4 vs. 100+/-4 mm Hg), EF (57+/-5% vs. 53+/-4%) or E(es) (end-systolic elastance, 3.1+/-0.9 vs. 2.9+/-0.8 mm Hg/ml) but with an approximately 10 ml increase in V(o) (14+/-12 vs. 25+/-16 ml; p<0.01). The EDPVR and time constant of relaxation (tau, 25+/-3 vs. 28+/-3 ms) did not change significantly. These animals were hemodynamically stable out to 3 1/2 months. Neurohormonal activation occurred (elevations of NE, AngII, BNP) and there was intravascular volume expansion by approximately 16% (p<0.05). CONCLUSIONS: A small amount of myocardial injury can lead to neurohormonal activation with intravascular volume expansion and elevation of LVEDP in the absence of reductions in dP/dt(max) or EF and without diastolic dysfunction. Thus, HF with preserved EF does not a priori equate with diastolic heart failure.     

Left ventricular blood flow during aortic pressure reduction in hypertensive dogs.

We measured left ventricular blood flow with radioactive microspheres during aortic pressure reduction in 10 open-chest, anesthetized dogs with left ventricular hypertrophy due to chronic hypertension and in 10 matched normotensive dogs. Heart rate and left atrial pressure were held constant, and autonomic reflexes were abolished with ganglionic blockade. Aortic diastolic pressure was lowered from baseline to 90, 75, and 60 mm Hg with an arteriovenous fistula. During aortic pressure reduction, a stepwise decline in the endocardial-to-epicardial flow ratio in hypertrophied hearts from 1.23 +/- 0.04 at baseline to 0.96 +/- 0.09 at a diastolic pressure of 75 mm Hg parallelled that in normal hearts and was not associated with any deterioration in left ventricular performance. However, a further fall in the endocardial-to-epicardial flow ratio to 0.76 +/- 0.10 at a diastolic pressure of 60 mm Hg in hypertrophied hearts exceeded that in normal hearts (0.92 +/- 0.05, p less than 0.05) and was accompanied by evidence of left ventricular isovolumic and end-systolic dysfunction. We conclude that in hearts with pressure-overload left ventricular hypertrophy, aortic pressure reduction causes a transmural blood flow redistribution from subendocardial to subepicardial muscle layers. At moderately low aortic pressures, this redistribution is more pronounced than in normal hearts and is associated with functional evidence of myocardial ischemia.     

Transmural redistribution of coronary resistance during embolization: a clue to intramyocardial small artery architecture

The aim of this study is to assess vascular architecture and the single vessel resistance distribution of the subepicardial (epi) and subendocardial (endo) layers of the left ventricular wall. For this purpose, coronary embolization was performed by injecting three boluses of 25 microns plastic microspheres into the maximally vasodilated left circumflex artery of six dogs; transmural blood flow was assessed by 15-microns radioactive microspheres. A branching tree model of the intramyocardial small artery system--whose general characteristics were described in a previous study (Pelosi et al., 1987, Microvasc. Res. 34, 318-335)--was developed and its parameters were tested against the increase in epi and endo coronary resistance observed during embolization. Embolization produced a significantly greater increase in epi resistance after each bolus injection (from 10.3 +/- 1.1 to 195.6 +/- 32.5 mm Hg/ml/min/g after the last bolus, P less than 0.001) as compared to endo resistance (from 10.3 +/- 2.0 to 56.5 +/- 8.2 mm Hg/ml/min/g after the last bolus, P less than 0.001); as a consequence, the epi/endo resistance ratio increased from 1.09 +/- 0.11 to 1.50 +/- 0.13, 2.48 +/- 0.51, and 3.66 +/- 0.42 (P less than 0.05 for all embolizing injections). The experimental relation (occlusion function) between the number of embolizing beads injected and the epi and endo resistance values was used to define the parameters of the epi and endo branching tree model. Assuming that the embolizing microspheres lodge in vessels of similar resistance (that is similar diameter and length) in the two layers, the experimental results indicate that the intramyocardial small artery system can be depicted as a symmetric dichotomous branching tree with twofold more terminal vessels in the endo than in the epi.     

Transmitral pressure-flow velocity relation. Importance of regional pressure gradients in the left ventricle during diastole

Effects of regional diastolic pressure differences within the left ventricle on the measured transmitral pressure-flow relation were determined by simultaneous micromanometric left atrial (LAP) and left ventricular pressure (LVP) measurements, and Doppler echocardiograms in 11 anesthetized, closed-chest dogs. Intraventricular pressure recordings at sites that were 2, 4, and 6 cm from the apex were obtained. Profound differences between these sites were noted in the transmitral pressure relation during early (preatrial) diastolic filling. In measurements from apex to base, minimum LVP increased (1.6 +/- 0.7 to 3.1 +/- 0.8 mm Hg, mean +/- SD); the time interval between the first crossover of transmitral pressures and minimum LVP increased (31 +/- 3 to 50 +/- 17 msec); the slope of the rapid-filling LVP wave decreased (74 +/- 13 to 26 +/- 5 mm Hg/sec); the maximum forward (i.e., LAP greater than LVP) transmitral pressure gradient decreased (3.6 +/- 1.3 to 2.1 +/- 0.7 mm Hg); the time interval between the first and second points of transmitral pressure crossover increased (71 +/- 9 to 96 +/- 13 msec); and the area of reversed (i.e., LVP greater than LAP) gradient between the second and third points of transmitral pressure crossover decreased (101 +/- 41 to 40 +/- 33 mm Hg.msec). During atrial contraction, significant regional ventricular apex-to-base gradients were also noted. The slope of the LV A wave decreased (26 +/- 10 to 16 +/- 4 mm Hg/sec); LV end-diastolic pressure decreased (8.1 +/- 2.0 to 7.4 +/- 2.0 mm Hg), and the upstroke of the LV A wave near the base was recorded earlier than near the apex. All differences were significant at the 0.05 level. Simultaneous transmitral Doppler velocity profiles and transmitral pressures were measured at the 4-cm intraventricular site. The average interval between the first and second points of pressure crossover and between the onset of early rapid filling and maximum E-wave velocity were statistically similar (81 +/- 13 vs. 85 +/- 12 msec; NS); and the average area of the forward transmitral pressure gradient associated with acceleration of early flow was significantly greater than the area of reversed gradient associated with deceleration of early flow (133 +/- 36 vs. 80 +/- 46 msec.mm Hg; p less than 0.025).(ABSTRACT TRUNCATED AT 400 WORDS)     

Hemodynamic effects of contrast media during coronary angiography: a comparison of three nonionic agents to Hypaque-76

Coronary angiography with standard ionic contrast media is associated with marked alterations in cardiac hemodynamics because of the depressant effects of the contrast media on cardiac contractility. Nonionic contrast media have been reported to produce less hemodynamic alteration than standard ionic contrast media. However, there is no information on how one nonionic media compares to another. Thus we compared the hemodynamic effects of three nonionic contrast media, Iopamidol (IOP), Iohexol (IOH), and Ioversol (IOV) to each other as well as to the standard ionic contrast media Hypaque-76 (H76). In 20 closed-chest anesthetized dogs, we recorded the maximal change in left ventricular systolic pressure (LVSP), mean aortic pressure, left ventricular diastolic pressure (LVDP), and left ventricular dp/dt during 10-cc left main coronary artery injections of H76, IOP, IOH, and IOV. The mean aortic pressure and LVSP decreased 36 +/- 17 mm Hg and 46 +/- 21 mm Hg with H76 but only 5 +/- 5 mm Hg and 6 +/- 5 mm Hg with IOP, 5 +/- 4 mm Hg and 6 +/- 6 mm Hg with IOH, and 5 +/- 4 mm Hg and 7 +/- 6 mm Hg with IOV (P less than 0.001). The LVDP increased 6 +/- 5.0 mm Hg with H76 but only 0.2 +/- 0.5 mm Hg with IOP, 0.2 +/- 0.3 mm Hg with IOH, and 0.5 +/- 1.0 mm Hg with IOV (P less than 0.001). The LV dp/dt decreased 545 +/- 261 mm Hg/sec with H76 but increased 886 +/- 477 mm Hg/sec with IOP, 910 +/- 96 mm Hg/sec with IOH, and 473 +/- 335 mm Hg/sec with IOV (P less than 0.001). Whereas each nonionic agent produced significantly less hemodynamic abnormalities than H76, there was no significant difference between any of the nonionic agents on any hemodynamic parameter. Thus, as compared to H76, these nonionic contrast media produced only trivial alterations in hemodynamics and LV dp/dt. These agents may be preferable in patients with LV dysfunction.     

Functional characteristics of intramyocardial capacitance vessels during diastole in the dog

In order to evaluate the functional characteristics of the intramyocardial capacitance vessels during prolonged diastole, we analyzed the response of coronary vein flow after stepwise changes of coronary artery pressure in anesthetized open-chest dogs by using our newly developed laser Doppler velocimeter with an optical fiber. The peripheral portion of the great cardiac vein was isolated and the optical fiber tip was inserted into the vessel. The left anterior descending coronary artery was cannulated and connected to a reservoir to regulate coronary perfusion pressure. Intracoronary adenosine administration was carried out to avoid any change in coronary vasomotor tone. After 15 seconds of occlusion of the perfusion route, the heart was arrested by pacing-off. Two seconds later, coronary perfusion pressure was increased stepwise to a preset target pressure. This procedure was repeated by changing target pressure at 4 (or 5) different pressure levels (31-105 mm Hg). The great cardiac vein flow became zero due to the cardiac arrest and remained at zero for a moment (dead time) after the initiation of reperfusion. Then the flow reappeared and increased with first order time delay. The presence of dead time indicates the existence of unstressed volume, and the first order time delay represents the product of resistance and capacitance. The unstressed volume with a minimal vasomotor tone for perfusion pressure of 60-90 mm Hg was 5.2 +/- 2.2 ml per 100 g left ventricle, which is comparable to coronary blood flow for several beats. The capacitance at perfusion pressure of 60-90 mm Hg was 0.08 +/- 0.04 ml/mm Hg per 100 g left ventricle, while that at low perfusion pressure (30-50 mm Hg) was 0.14 +/- 0.09 ml/mm Hg per 100 g left ventricle. These results indicate that the intramyocardial capacitance vessels have two functional components, and that the phasic nature of coronary vein flow is solely the result of the myocardial squeezing of the blood in the capacitance vessels.     

Phasic mitral blood flow and regional left ventricular dimensions: possible mechanism of active assist to ventricular filling

Postsystolic myocardial segment shortening (PSS) has been observed in dogs and humans by means of ultrasonic crystals but has never been studied specifically. In this study, both subendocardial and subepicardial regional function in the basal circumflex and midventricular anterior myocardium (LAD) was studied during late systole and early diastole with ultrasonic crystals. Fifteen open-chest dogs were instrumented with electrocardiographic leads; Millar catheters for measurement of left ventricular pressure, left ventricular dP/dt, and aortic blood pressure; flow probes for determination of aortic and mitral blood flow; and subendocardial and subepicardial crystal pairs to measure subendocardial segment length shortening velocity (dL/dt). Crystal pairs were placed in the subendocardial left oblique mode and the extreme subendocardial right oblique mode (-50 and +50 degrees from equator) in the lateral basal (circumflex, n = 9) and anterior midventricular myocardium (LAD, n = 6). Subendocardial segments showed PSS averaging 34 +/- 7% of the total shortening distance in the circumflex bed and 21 +/- 2% in the LAD bed (p = NS). The rate of subendocardial segment shortening during PSS increased 273 +/- 42.6% (p less than .05) relative to the rate of segment shortening during ejection in the circumflex bed and 126 +/- 40% (p less than .05) in the LAD bed (p = NS). The most rapid diastolic increase in subendocardial length (peak +dL/dt) occurred immediately after subendocardial PSS. Subendocardial diastolic peak +dL/dt occurred after the onset of mitral inflow during the acceleration limb of the rapid ventricular filling phase. Overlying subepicardial segments began lengthening 82 +/- 12 msec before onset of subendocardial segment lengthening in the circumflex bed and 63 +/- 9 msec before subendocardial lengthening in the LAD bed (p less than .05), indicating that the subepicardial segment had begun to lengthen while subendocardial segment shortening continued after end-systole. Onset of early segmental subepicardial lengthening varied with respect to the point of end-systole. Early segmental subepicardial lengthening with subendocardial PSS may be a mechanism by which the rapid filling phase of the left ventricle is actively potentiated by storing potential energy released as early diastolic elastic recoil.     

Comparative effects of nitroglycerin and nifedipine on myocardial blood flow and contraction during flow-limiting coronary stenosis in the dog

Both nifedipine and nitroglycerin are used to treat angina pectoris. The comparative effects of these agents on myocardial blood flow and contraction in the setting of flow-limiting coronary stenosis are poorly understood. Thus 24 open chest dogs underwent carotid to left anterior descending coronary arterial perfusion with coronary flow probe and perfusion pressure monitoring. Segment length was measured with ultrasonic crystals in the subendocardial ischemic and nonischemic zones. Myocardial blood flow was measured with radioactive microspheres. Partial coronary occlusion was performed to attain a diastolic perfusion pressure of 40 mm Hg. Twelve dogs received intravenous nifedipine, 3 μg/kg per min, and 12 received intravenous nitroglycerin to reduce aortic pressure by 20 mm Hg. Partial occlusion resulted in a slight but significant decrease in segment shortening in the ischemic zone. Neither nitroglycerin nor nifedipine affected shortening in the ischemic zone. After occlusion, blood flow decreased in the subendocardial ischemic zone but was unchanged in the subepicardium. Nifedipine increased subendocardial blood flow in the nonischemic zone and decreased it in the ischemic zone but caused no change in subepicardial flow in the ischemic zone. In contrast, nitroglycerin decreased subendocardial and subepicardial blood flow in both the ischemic and nonischemic zones. In the setting of coronary stenosis, different classes of vasodilators may have varying effects on myocardial blood flow, suggesting different sites and mechanisms of action. In addition, segment function may not always reflect changes in myocardial blood flow.