Alterations of myocardial blood flow associated with experimental canine left ventricular hypertrophy secondary to valvular aortic stenosis.

Experimental renovascular hypertension or supravalvular aortic constriction results in left ventricular hypertrophy and impaired minimum coronary vascular resistance. However, these experimental models expose the coronary arteries to increased intra-arterial pressure, so that hypertensive vascular changes might be responsible for the impaired minimum coronary resistance. This study was performed to test the hypothesis that left ventricular hypertrophy in the absence of increased coronary pressure results in abnormalities of myocardial perfusion. Aortic valve stenosis was produced by plication of the noncoronary aortic cusp of 11 dogs at 6-8 weeks of age. Studies were carried out when the animals reached adulthood; mean left ventricular:body weight ratio was 7.1 +/- 0.4 as compared to 4.4 +/- 0.3 g/kg in 11 normal dogs (P less than 0.01). Under quiet resting conditions, myocardial blood flow measured with microspheres was significantly greater than normal in dogs with aortic stenosis. However, during maximum coronary vasodilation with adenosine, mean left ventricular blood flow in dogs with hypertrophy (3.29 +/- 0.39) was substantially less than in normal dogs (6.19 +/- 0.54 ml/min per g; P less than 0.01), whereas minimum coronary resistance was increased from 14.1 +/- 1.7 in normal dogs to 23.7 +/- 5.4 mmHg. min X g/ml (P less than 0.01). To examine the response of myocardial perfusion to cardiac stress, blood flow was measured during pacing at 200 and 250 beats/min. Compared with normal dogs, animals with hypertrophy had a subnormal increase in myocardial blood flow during tachycardia; this perfusion deficit was most marked in the subendocardium. These data demonstrate that left ventricular hypertrophy alone, without increased coronary artery pressure, is associated with impaired minimum coronary vascular resistance and with abnormalities of myocardial blood flow during pacing stress.

Myocardial perfusion in compensated and failing hypertrophied left ventricle.

This study examined blood flow in the hypertrophied left ventricle with and without failure. Left ventricular hypertrophy was produced in 20 dogs by banding the ascending aorta at 6-7 wk of age; studies were performed after animals reached adulthood. Sixteen dogs had compensated hypertrophy, while four dogs had cardiac failure manifested by left ventricular dilatation and end-diastolic pressures greater than 18 mmHg. The degree of hypertrophy, assessed by left ventricular-to-body weight ratio, was similar in animals with compensated hypertrophy (7.29 +/- 0.26 g/kg) and failure (8.45 +/- 0.15); both were greater than control (4.50 +/- 0.15, P less than 0.01). Left ventricular systolic pressure was similar in compensated hypertrophy (184 +/- 9 mmHg) and failure (226 +/- 29), as compared with control (130 +/- 4; P less than 0.01). Left ventricular blood flow measured with microspheres was 0.89 +/- 0.07 ml X min-1 X g-1 in control animals, was increased to 1.34 +/- 0.05 with compensated hypertrophy (P less than 0.001), and was further increased with failure to 1.86 +/- 0.40 (P less than 0.05). The left ventricular wall thickness-to-cavity diameter ratio was increased to 0.63 +/- 0.04 with compensated hypertrophy but was only 0.40 +/- 0.05 in dogs with failure (P less than 0.01), suggesting that wall stress was greater in hearts with failure. These data suggest that increased blood flow rates in dogs with failure resulted from increased myocardial O2 requirements due to increased systolic wall stress. Need for increased blood flow during resting conditions in dogs with failure would impair the ability for further coronary vasodilation during periods of cardiac stress.

Effects of global ischemia on the diastolic properties of the left ventricle in the conscious dog.

The alterations in regional diastolic mechanics that occur during regional myocardial ischemia (creep and increased myocardial stiffness) may be the result of interactions between the ischemic and surrounding nonischemic myocardium rather than the direct result of ischemia. Thus similar changes may not occur when the entire left ventricle is ischemic. Thus similar changes may not occur when the entire left ventricle is ischemic. To investigate this proposition, left ventricular diastolic mechanics were studied in seven chronically instrumented conscious dogs during global left ventricular ischemia. The anterior-posterior, septal-free wall, and base-apex axes of the left ventricle were measured with ultrasonic dimension transducers. Left and right ventricular pressures were measured with micromanometers. Myocardial blood flows were measured with left atrial injections of 15 microns radioactive microspheres. Global left ventricular ischemia was induced by hydraulic constriction of the left main coronary artery, which resulted in a 54% decrease in mean left ventricular subendocardial blood flow. Left ventricular volume, midwall circumference, and midwall circumferential stress were calculated from ellipsoidal shell theory. To construct pressure-strain and stress-strain relationships from diastolic data collected during vena caval occlusions, all measured and calculated dimensions were normalized to Lagrangian strains (fractional extension from unstressed dimension). During ischemia, creep (elongation of unstressed dimension) occurred in each of the three left ventricular axes. The mean unstressed dimension of the anterior-posterior axis increased from 5.39 +/- 0.53 to 5.85 +/- 0.50 cm ( p less than or equal to .05); the septal-free wall unstressed dimension increased from 5.11 +/- 0.53 to 5.72 +/- 0.80 cm (p less than or equal to .05); and the base-apex unstressed dimension increased from 7.04 +/- 0.61 to 7.25 +/- 0.65 cm (p less than or equal to .05). The relationship between diastolic midwall circumferential stress and strain shifted upward and to the left with ischemia, indicating that an increase in intrinsic myocardial stiffness had occurred. As a result of these mechanical alterations, there was a decrease in left ventricular chamber compliance that was manifested by a leftward shift of the diastolic pressure-volume strain relationship. Neither systolic bulging nor dysynchronous systolic shortening occurred in any of the three left ventricular spatial axes during ischemia.(ABSTRACT TRUNCATED AT 400 WORDS)