David C. Homans

Evidence for Functional Sympathetic Reinnervation of Left Ventricle and Coronary Arteries After Orthotopic Cardiac Transplantation in Humans

BACKGROUND Structural sympathetic reinnervation of the transplanted human heart is believed to occur > 1 year after cardiac transplantation. The functional effects of reinnervating neurons, however, are undefined. METHODS AND RESULTS To test directly for functional sympathetic reinnervation, we measured left ventricular or coronary hemodynamics in 11 patients < or = 4 months after transplantation, in 45 patients > or = 1 year after transplantation, and in 13 untransplanted, normally innervated patients. Sympathetic neurons were stimulated with left coronary injection of tyramine (10 micrograms/kg), which causes norepinephrine release from intact sympathetic nerve terminals. Reinnervation was defined as a measure of cardiac norepinephrine release after intracoronary tyramine injection. Left ventricular pressure was measured before and at 1-minute intervals after tyramine with a micromanometer-tipped catheter (Millar Instruments). Coronary blood flow velocity (CBFV) was measured with a 3F Doppler catheter (Numed), and coronary artery cross-sectional area was calculated using quantitative coronary angiography. In both early patients and patients studied > or = 4 months after transplantation without reinnervation (late denervated), there was no change in left ventricular function in response to tyramine (delta dP/dt = 31 +/- 61 and 49 +/- 54 mm Hg/s, respectively; P = NS). In transplant recipients with reinnervation (late reinnervated), left ventricular dP/dt rose significantly (delta dP/dt = 210 +/- 97 mm Hg/s; P < .05) but less than in healthy patients (delta dP/dt = 577 +/- 66 mm Hg/s; P < .05). In both early and late denervated patients, there was no change in CBFV in response to tyramine (CBFV = 1.02 +/- 0.1 and 1.0 +/- 0.1 x basal, respectively; P = NS). In late reinnervated patients, CBFV fell significantly (CBFV = 0.94 +/- 0.1 x basal; P < .05). In healthy patients, CBFV fell even more (CBFV = 0.88 +/- 0.1 x basal; P < .05). CONCLUSIONS Stimulation of reinnervating sympathetic neurons with tyramine in transplant recipients causes a significant but subnormal increase in dP/dt and a transient decrease in CBFV, suggesting that reinnervating sympathetic neurons can produce physiologically meaningful changes in left ventricular function and coronary artery tone.

Oxygen consumption and coronary reactivity in postischemic myocardium.

Coronary vascular responses in regions of reversible postischemic myocardial contractile dysfunction (stunned myocardium) were examined in chronically instrumented, awake dogs. Left anterior descending coronary artery blood flow and oxygen extraction, aortic and left ventricular pressures, and regional myocardial segment shortening were determined. Regional myocardial blood flow was measured with microspheres. Coronary reactive hyperemia and vasodilator reserve, and regional myocardial oxygen consumption were determined. Three sequential 10-minute left anterior descending coronary artery occlusions separated by 30-minute reperfusion periods resulted in progressive postischemic dysfunction so that 1 hour after the final coronary artery occlusion, myocardial segment shortening was reduced to 37% of baseline. Despite this decrease in contractile function, left anterior descending artery flow (19.6±2.6 vs. 18.4±3.0 ml/min), myocardial blood flow and the transmural distribution of flow measured with microspheres, and regional myocardial oxygen consumption were unchanged. Although the coronary vasodilator reserve hi response to adenosine was unaltered (63±9 vs. 70±15 ml/min), the reactive hyperemia response to a 10-second coronary occlusion was decreased in intensity (debt repayment ratio=474±78% vs. 322±74%; p<0.05) and duration (57±9.1 vs. 35±4.5 seconds; p<0.05), while the peak flow response was unchanged (57±6.8 vs. 60±7.1 ml/min). Thus, in the intact awake animal postischemic myocardial contractile dysfunction was not associated with decreased myocardial oxygen consumption and did not impair the normal relation between coronary blood flow and myocardial oxygen utilization. Although coronary vessels showed a normal ability to vasodilate in response to adenosine, coronary reactive hyperemia was reduced.

Role of adenosine in coronary vasodilation during exercise.

This study examined the hypothesis that increases in myocardial blood flow during exercise are mediated by adenosine-induced coronary vasodilation. Active hyperemia associated with graded treadmill exercise and coronary reactive hyperemia were examined in chronically instrumented awake dogs during control conditions, after intracoronary infusion of adenosine deaminase (5 units/kg/min for 10 minutes), and after adenosine receptor blockade with 8-phenyltheophylline. Both adenosine deaminase and 8-phenyltheophylline caused a rightward shift of the dose-response curve to intracoronary adenosine; 8-phenyltheophylline was significantly more potent than adenosine deaminase. Adenosine deaminase caused a 33 ± 7 to 39 ± 3% decrease in reactive hyperemia blood flow following coronary occlusions of 5–20 seconds duration, respectively, while 8-phenyltheophylline produced a 40 ± 6 to 62 ± 8% decrease in reactive hyperemia. Increasing myocardial oxygen consumption during treadmill exercise was associated with progressive increases of coronary blood flow. Neither adenosine deaminase nor 8-phenyltheophylline attenuated the increase in coronary blood flow or the decrease of coronary vascular resistance during exercise. Neither agent altered the relation between myocardial oxygen consumption and coronary blood flow. Thus, although both adenosine deaminase and 8-phenyltheophylline antagonized coronary vasodilation in response to exogenous adenosine and blunted coronary reactive hyperemia, neither agent impaired coronary vasodilation associated with increased myocardial oxygen requirements produced by exercise. These findings fail to support a substantial role for adenosine in mediating coronary vasodilation during exercise.

Regional function and perfusion at the lateral border of ischemic myocardium.

To determine whether function is depressed in areas of myocardium adjacent to an area of myocardial ischemia, 16 open-chest dogs were studied with both two-dimensional echocardiography and ultrasonic microcrystals. Regional myocardial blood flow was measured with radioactive microspheres during control periods and after coronary arterial ligation. Segments of myocardium adjacent to the area of ischemia were found to have no significant change in transmural blood flow (1.02 +/- 0.38 ml/g/min control vs 0.95 +/- 0.3 ml/g/min after ligation) or subendocardial flow (1.18 +/- 0.41 ml/g/min control vs. 1.19 +/- 0.37 ml/g/min after ligation). Regional function assessed echocardiographically as percent change in segment area was significantly depressed in these normally perfused adjacent areas (69.5 +/- 18.8% control vs 52.5 +/- 19.8% after ligation; p less than .01). There was a significant relationship between proximity to border of infarction and degree of adjacent dysfunction (r = .50, p less than .01 for echocardiography; r = .70, p less than .01 for ultrasonic microcrystals). It is concluded that systolic performance is depressed in nonischemic myocardium directly adjacent to the lateral border of an area of acute myocardial ischemia.

Coronary vasodilator reserve after human orthotopic cardiac transplantation.

Cardiac transplantation is frequently associated with accelerated coronary atherosclerosis and immune-mediated microvascular injury. To determine if orthotopic cardiac transplantation impairs the capacity of the coronary vasculature to vasodilate and conduct hyperemic blood flow, maximal coronary vasodilator reserve was measured in 25 cardiac allograft recipients with no evidence of rejection 6-57 months after transplantation and in 20 normal subjects. Left ventricular wall thickness was assessed echocardiographically, and epicardial coronary anatomy was evaluated by quantitative coronary angiography. Coronary vasodilator reserve (CVDR) was measured in all patients with a coronary Doppler catheter and a maximally vasodilating dose of intracoronary papaverine. CVDR measured in the transplant recipients with normal coronary arteries, left ventricular function, and wall thickness (5.0 +/- 0.3 [mean +/- SEM] peak/resting velocity; range, 3.8-7.3; n = 16) was not different from that of normal subjects (4.8 +/- 0.2; range, 3.7-8.3). CVDR in the five cardiac allograft recipients with diffuse coronary atherosclerosis producing 30 +/- 5% narrowing (range, 25-38%) of epicardial vessel diameter also was normal (5.1 +/- 0.3; range, 4.3-6.2; n = 5). The CVDR was reduced, however, in two of the four cardiac allograft recipients with left ventricular hypertrophy. In the only transplant recipient in whom a regional wall motion abnormality was present, CVDR was abnormal in the vascular distribution of the hypokinetic wall segment (1.8) but was normal in the artery that supplied normally functioning myocardium (4.0). These findings demonstrate that in the absence of allograft rejection, acquired left ventricular hypertrophy, and regional wall motion abnormalities, coronary vasodilator reserve is normal after orthotopic human cardiac transplantation.(ABSTRACT TRUNCATED AT 250 WORDS)

Relationships Between Myocardial Bioenergetic and Left Ventricular Function in Hearts With Volume-Overload Hypertrophy

BACKGROUND Left ventricular (LV) hypertrophy secondary to volume overload can result in alterations in myocardial bioenergetics and LV dysfunction. This study examined whether bioenergetic abnormalities contribute to the pump dysfunction. METHODS AND RESULTS Severe mitral regurgitation (MR) was produced in 10 dogs by disruption of the chordal apparatus. Hemodynamics and ventricular function were examined 11.7 months later under baseline conditions and during treadmill exercise. Myocardial high-energy phosphates were measured by using magnetic resonance spectroscopy at rest, during coronary vasodilation with adenosine, and during oxidative stress induced by rapid pacing and dobutamine. Chronic MR caused a 30% increase in LV mass and a 65% increase in LV volume. In MR animals, the hemodynamic and LV function were normal at rest, but abnormalities developed during beta-blockade and exercise. Myocardial creatine phosphate-to-ATP ratios were significantly lower in each layer across the LV wall in MR hearts than normal hearts. Myocardial blood flow and coronary reserve were normal in MR hearts. Moreover, hyperperfusion did not correct the abnormal bioenergetics. Despite altered bioenergetics at rest, the MR hearts tolerated rapid pacing and dobutamine infusion well. CONCLUSIONS In volume-overloaded LV hypertrophied hearts, alterations in myocardial high-energy phosphate levels do not induce abnormal mechanical performance at rest but may be related to a decreased contractile reserve during exercise.

The role of alpha 1- and alpha 2-adrenergic receptors in mediation of coronary vasoconstriction in hypoperfused ischemic myocardium during exercise.

This study was carried out to test the hypothesis that adrenergic coronary vasoconstriction limits blood flow to hypoperfused regions of myocardium during exercise. The vasoconstrictor influence of alpha-adrenergic receptor subtypes was assessed by use of selective adrenergic blocking agents. Dogs chronically instrumented with a circumflex coronary artery hydraulic occluder and an intra-arterial catheter underwent treadmill exercise in the presence of a coronary stenosis that decreased distal perfusion pressure to 40 mm Hg. Myocardial blood flow was measured with radioactive microspheres (15 microns) before and during selective alpha 1- or alpha 2-adrenergic receptor blockade produced by intracoronary infusion of prazosin (1 microgram/kg/min x 10 min) or idazoxan (1 microgram/kg/min x 10 min), respectively. Coronary perfusion pressure was held equal before and during receptor blockade with the hydraulic occluder. Compared with control exercise, subendocardial blood flow increased during alpha 1-receptor blockade with prazosin from 0.60 +/- 0.14 to 1.12 +/- 0.17 ml/min/g (p less than 0.05), and mean transmural flow increased from 1.07 +/- 0.19 to 1.60 +/- 0.22 ml/min/g (p less than 0.05). In contrast, subendocardial and mean transmural blood flow were not different from control during selective alpha 2-adrenergic receptor blockade with idazoxan (0.48 +/- 0.10 vs. 0.67 +/- 0.14 ml/min/g, p = 0.33, and 0.82 +/- 0.15 vs. 1.02 +/- 0.20 ml/min/g, p = 0.45, respectively). These data indicate that even in the presence of a coronary stenosis that causes substantial myocardial underperfusion during exercise, residual coronary vasoconstrictor tone is present in ischemic myocardium, and this vasoconstriction is mediated predominantly by the alpha 1-adrenergic receptor.

Effect of exercise intensity and duration on regional function during and after exercise-induced ischemia.

BackgroundTransient reversible myocardial dysfunction has been documented after episodes of exercise-induced ischemia. This study was undertaken to determine whether the duration or intensity of exercise affects the severity of postischemic dysfunction in this setting. Methods and ResultsTen dogs were instrumented with ultrasonic microcrystals for measurement of wall thickening, with circumflex coronary artery flow probes, and with hydraulic occluders. Dogs performed low-intensity exercise, which was sufficient to increase coronary perfusion 50% above control, and high-intensity exercise, which was sufflicient to double coronary blood flow. To investigate the effects of exercise intensity on postischemic dysfunction, we had dogs perform high-intensity exercise for 5 minutes in the presence of a stenosis. On the alternate day, dogs performed low-intensity exercise for 10 minutes in the presence of a stenosis. These two protocols provide equivalent coronary flow debts. Mean transmural blood flow during high-intensity exercise without stenosis (2.61 ± t0.54 ml/min/g) was significantly higher than that during low-intensity exercise (1.74 ± 0.61 ml/min/g, p < c0.002). During highintensity exercise with coronary artery stenosis, subendocardial blood flow was significantly lower than that during low-intensity exercise with stenosis (0.64 ± 0.40 versus 1.08+0.28 ml/min/g, p < 0.02). This difference in subendocardial perfusion was associated with greater degrees of regional dysfunction during exercise (circumflex wall thickening was 44± 23% of control for high-intensity exercise versus 60 ± 18% of control for low-intensity exercise, p < 0.01). In addition, from 10 to 30 minutes after exercise, wall thickening in myocardium perfused by the circumflex coronary artery remained significantly lower after high-intensity exercise than that after low-intensity exercise. To assess the effects of exercise duration on the severity of postischemic dysfunction, we had dogs perform low-intensity exercise in the presence of a coronary stenosis for 10 minutes and low-intensity exercise for only 5 minutes on alternate days. Systolic wall thickening was significantly lower after low-intensity exercise for 10 minutes than after low-intensity exercise for 5 minutes. ConclusionsHigh-intensity exercise results in greater degrees of subendocardial hypoperfusion and greater degrees of regional dysfunction both during and after exercise-induced ischemia than does low-intensity exercise. Second, exercise duration also exerts an effect on the severity of postischemic dysfunction, although the magnitude of this effect is less important than the effect of exercise intensity. (Circulation 1991;83:2029—2037)

Measurement of pulmonary artery diastolic pressure from a right ventricular pressure transducer in patients with heart failure

Recent studies have demonstrated that pulmonary artery diastolic (PAD) pressure can be measured from a transducer positioned in the right ventricle (RV) based on the finding that PAD and RV pressures are equal at the time of pulmonary valve opening, which is associated with the time of maximum positive rate of pressure development (dP/dtmax) in the ventricle. The objective of this study was to assess the correlation between estimated PAD (ePAD) pressure, obtained through a RV transducer, and actual PAD (aPAD) pressure in patients with heart failure who have abnormal hemodynamics, reduced systolic function, and variable degrees of mitral regurgitation (MR) and tricuspid regurgitation (TR). Simultaneous measurements of pulmonary artery and RV pressures were obtained with a high-fidelity Millar catheter (Millar Instruments, Houston, TX) in 10 patients with New York Heart Association class III-IV heart failure who were being evaluated for cardiac transplantation. The overall correlation between ePAD and aPAD pressures was .92 (R2 = .878). This was not significantly different during the Valsalva maneuver (r = .96, R2 = .943), submaximal bicycle exercise (r = .87, R2 = .756), or infusions of dobutamine and nitroglycerin (r = .82, R2 = .730). The overall average difference between the average ePAD (24.6 +/- 7.0 mmHg) and aPAD (23.6 +/- 7.0 mmHg) pressures was 1.0 +/- 3.4 mmHg. The average difference between the two pressures in patients with mild to severe MR or TR was not different compared to those patients with no or trace MR or TR. The estimation of PAD pressure from an RV transducer is valid in patients with heart failure who have abnormal hemodynamics, reduced systolic function, and variable degrees of MR and TR. This correlation was observed at rest and during several provocative maneuvers. These data will be important for the development of a chronic, implantable hemodynamic monitor for patients with heart failure.

Two-dimensional echocardiographic identification of complicated aortic root endocarditis: implications for surgery

Two-dimensional echocardiography successfully displayed the location and extent of aortic root complications, annular abscess or mycotic aneurysm in nine patients with aortic valve endocarditis. Five of the nine patients had prosthetic valve endocarditis and four had native valve endocarditis. The infective process extended into the paravalvular structures, including the interventricular septum (seven patients), right ventricular outflow tract (three patients), interatrial septum (one patient) and anterior mitral valve leaflet (four patients). The amount of aorto-left ventricular discontinuity caused by these complications was quantitated in degrees of annular circumference on the parasternal short axis image and in distance on the parasternal long axis image. The echocardiographic findings were confirmed at surgery and were helpful in the preoperative anticipation of the type of surgical procedure required: aortic valve replacement or composite aortic valve and root replacement. Five patients had prosthetic valve endocarditis with calculated aorto-left ventricular discontinuity of 173 +/- 55 degrees on parasternal short axis images and 1.36 +/- 0.72 cm on parasternal long axis images. Initial surgical repair included three composite aortic root-valve prosthesis implants, one reconstructive procedure with valve replacement and one simple aortic valve replacement. During a follow-up period of 18 months (range 1 to 35), a second reparative procedure was required for only one patient to repair an aortic conduit to coronary artery venous bypass graft. Four patients had native valve endocarditis with calculated aorto-left ventricular discontinuity of 100 +/- 17 degrees on parasternal short axis images and 0.88 +/- 63 cm on parasternal long axis images. Initial surgical repair included two reconstructive procedures with valve replacement and two simple aortic valve replacements. During a follow-up period of 30 months (range 16 to 42), three of these four patients required a second reparative procedure: one each for repair of a paraprosthetic leak, a ventricular septal defect and persistent aorto-left ventricular discontinuity. Two-dimensional echocardiography accurately detected aortic annular abscess and mycotic aneurysm complicating aortic valve endocarditis and the resultant degree of aorto-left ventricular discontinuity. Circumferential aorto-left ventricular discontinuity with these complications is greater for prosthetic than native valve endocarditis and predicts a more extensive surgical repair.(ABSTRACT TRUNCATED AT 400 WORDS)