Faculty Bibliography

OBJECTIVE:The purpose of this study was to examine the degree to which mechanical alterations in left ventricular papillary muscles of renal hypertensive-diabetic rat hearts correlate with functional measurements made on the same hearts in situ. METHODS:Female Wistar rats weighing 170-200 g were made hypertensive by placing a 0.24 mm clip on the left renal artery, and made diabetic 1 week later by a single intravenous injection of streptozotocin (60 mg/kg). Approximately 3-5 months later hemodynamic measurements including left ventricular pressure and dP/dtmax, arterial pressure and aortic flow were made on control and hypertensive-diabetic hearts in situ and correlated with mechanical measurements in left ventricular papillary muscles isolated from the same hearts. Body and tissue weights and biochemical and histological measurements were made at the time of sacrifice. RESULTS:Hypertensive-diabetic rats which survived to the time of study had decreased body weights, increased left ventricular weights and increased right ventricular weight to body weight and lung weight to body weight ratios. Those rats which died before the scheduled in-situ measurements had significantly more severe hypertension, greater left ventricular hypertrophy, increased right ventricular and lung weights, and more interstitial fibrosis than either surviving hypertensive-diabetics or controls. Rates of isometric tension development (normalized) and relaxation as well as shortening and relaxation velocities were significantly depressed in papillary muscles from hypertensive-diabetic rat hearts despite unchanged developed tension and peak shortening. Time to peak tension and time to peak shortening were markedly prolonged. Mean aortic flow was maintained in the hypertensive-diabetic group despite significant depression of left ventricular dP/dtmax (normalized), peak aortic flow, peak aortic flow acceleration and heart rate. There was also significant depression of left ventricular-dP/dtmax. Ejection duration was markedly prolonged and correlated with both time to peak shortening in vitro and with stroke volume in vivo. CONCLUSIONS:Surviving hypertensive-diabetic rats were not in overt congestive heart failure; nevertheless, their hearts showed abnormal contractile performance which was qualitatively and quantitatively similar to that of left ventricular papillary muscles obtained from them. Depression of peak aortic flow, peak aortic flow acceleration and heart rate in the hypertensive-diabetic group was offset by increased ejection duration, resulting in normal mean aortic flow. The close correlation of ejection duration with time to peak shortening of the isolated papillary muscles suggests that it is a manifestation of an intrinsic change in the myocardium. To the extent that this prolongation is already maximized, further decreases in contractile speed would be expected eventually to cause depressed pump function and congestive heart failure. The possibility that this sequence of events occurred in the dying animals needs to be examined by evaluating in-vitro and in-vivo myocardial function at various stages of this disease model.

Diabetes mellitus is a complex group of diseases that has hyperglycemia as a common metabolic abnormality. Although it is well-known that diabetic patients are susceptible to the effects of large vessel atherosclerosis with specific cardiac and cerebral complications, the association of diabetes mellitus with cardiac dysfunction caused by cardiomyopathy in the absence of significant coronary artery disease has been recognized for many years. However, the pathogenesis of diabetic cardiomyopathy remains unknown and has been somewhat controversial. Specifically, whether diabetes mellitus with its metabolic effects is sufficient to account for cardiomyopathy remains to be proven. This paper reviews the evidence for and against a metabolic etiology. In addition, we review the clinical and experimental evidence that supports the view that diabetes mellitus acts together with hypertension to produce structural damage in the heart that manifests as ventricular dysfunction and ultimately congestive heart failure. The concomitant effects of the metabolic derangements of diabetes and the vascular abnormalities associated with hypertension may lead to microvascular-induced tissue injury. Findings supporting this hypothesis are presented, along with observations suggesting that treatment with vasodilating calcium channel blockers or angiotensin converting enzyme inhibitors may be beneficial in regard to tissue pathology and mortality in experimental models. Recent clinical studies also support a role for the microcirculation in diabetics. Finally, it is suggested that if the microcirculation is pathogenetically involved in diabetic cardiomyopathy, then agents that improve microcirculatory flow along with tight control of hypertension may be as beneficial in the treatment or prevention of diabetic cardiomyopathy as strict metabolic control of hyperglycemia.

Diabetic cardiomyopathy as a distinct entity was first recognized by Rubler et al. in diabetics with congestive heart failure (CHF), who had no evidence of coronary atherosclerosis. The Framingham study showed a 2.4-fold increased incidence of CHF in diabetic men and a 5.1-fold increase in diabetic women over 18 years. Pathological studies show left ventricular hypertrophy and fibrosis with varying degrees of small vessel disease, the functional significance of which is uncertain. Hypertension was recognized as an important cofactor in the development of fatal congestive heart failure in diabetics. On cardiac catheterization, in patients symptomatic of heart failure, either congestive or restrictive patterns have been observed. In contrast, asymptomatic diabetics had decreased left ventricular compliance but normal systolic function on hemodynamic study. Noninvasive studies show alterations in systolic and especially diastolic function, particularly in diabetics with microvascular complications and/or coexistent hypertension. Using load-independent measures of contractility, however, systolic function was generally found to be normal in asymptomatic normotensive diabetics. Experimental studies have focused on the mildly diabetic dog and the severely diabetic rat. Decreased left ventricular compliance and increased interstitial connective tissue were observed in chronically diabetic dogs. In contrast, ventricular myocardium from diabetic rats exhibits a reversible decrease in the speed of contraction, prolongation of contraction, and a delay in relaxation. These mechanical changes are associated with a decreased myosin ATPase, a shift in myosin isoenzyme distribution, alterations in a variety of Ca2+ fluxes, and changes in responses to alpha- and beta-adrenergic and cholinergic stimulation. These biochemical changes may be secondary to alterations in carbohydrate, lipid, and adenine nucleotide metabolism in the diabetic heart.(ABSTRACT TRUNCATED AT 250 WORDS)

Hypertensive diabetic rats develop a cardiomyopathy characterized by systolic and diastolic ventricular dysfunction, myocardial hypertrophy and fibrosis, pulmonary congestion and a very high mortality rate. Alterations in contractile proteins and sarcoplasmic reticular calcium (Ca2+) transport in diabetic myocardium and their partial reversal with verapamil suggest that calcium channel blockade may prevent death from congestive heart failure in hypertensive diabetic rats. A large group of rats with renovascular hypertension and streptozotocin diabetes were divided into four groups: untreated animals (Group 1) and animals treated with 100 (Group 2), 300 (Group 3) or 600 (Group 4) mg/kg per day of sustained release diltiazem mixed in their food. Treatment was begun shortly after the onset of hypertension and diabetes. Mortality rates after 4 months were 59% (19 of 32), 53% (17 of 32), 27% (7 of 26) and 35% (12 of 34) in Groups 1, 2, 3 and 4, respectively; the mortality rate in age-matched control rats was 5% (1 of 19). The reductions in mortality rates in Groups 3 and 4 were statistically significant. Diltiazem did not change systolic blood pressure, serum glucose concentration, heart rate or left ventricular mass. There was a trend to decreased left ventricular interstitial fibrosis and perivascular fibrosis in diltiazem-treated animals. Ventricular collagen concentration was similar in untreated hypertensive diabetic and control rats; levels were higher in hypertensive diabetic rats that died than in those that survived. There was a trend to decreased collagen concentration as diltiazem dose increased. Myosin isoenzyme distribution was not changed in Groups 3 and 4 (in comparison with Group 1). In all hypertensive diabetic groups, rats that died had a higher blood pressure, heart rate, relative left ventricular mass, lung weight and lung water than did survivors. The mortality rate was two to three times higher among rats with an initial blood pressure greater than or equal to 180 mm Hg. The beneficial effects of diltiazem on survival were most significant among rats with severe hypertension.

The myocardial adaptation to chronic beta-adrenergic blockade was explored in diabetic and control female Wistar rats. Propranolol was administered by intraperitoneal injection, 30 mg/kg every 12 h. Treatment began 2 months after streptozotocin injection and at a comparable time in controls. Diabetes reduced the heart rate by 90 beats/min; propranolol decreased the heart rate by 30 beats/min further in diabetic rats. Propranolol reduced the heart rate by 100 beats/min in controls. Study of isolated ventricular papillary muscle showed qualitatively similar effects of propranolol in control and diabetic animals. Diabetes resulted in prolonged contraction duration and decreased shortening velocity; both developed tension and peak shortening were unchanged. In contrast, propranolol resulted in prolonged contraction duration but no change in shortening velocity; both developed tension and peak shortening were increased. The shortening of isometric relaxation in response to norepinephrine was exaggerated with propranolol therapy in control but not diabetic rats. These findings indicate that the myocardial adaptation to chronic beta-blockade results in increased developed tension and increased extent of muscle shortening in vitro, and differs qualitatively from the adaptation to diabetes.

The purpose of this article was to review the clinical and experimental features of diabetic cardiomyopathy, with particular relevance to the Black population. One hundred thirty-seven studies were identified, of which 57 were selected as references for this article. Diabetes is associated with the development of cardiomyopathy, independent of coronary atherosclerosis. Pathological studies show myocardial hypertrophy and fibrosis; microvascular pathology is also present, but all of these pathological findings have an uncertain relationship to myocardial failure. Hemodynamic findings of both congestive and restrictive cardiomyopathy have been described. Noninvasive studies revealed abnormal systolic and diastolic function in many diabetic subjects, particularly in the presence of diabetic complications and/or hypertension. Experimental studies have focused on the mildly diabetic dog and the severely diabetic rat. One year of diabetes in dogs resulted in decreased left ventricular compliance and increased interstitial connective tissue. Studies in the diabetic rat showed a marked slowing of contraction and relaxation. Chronic insulin therapy reversed the changes in the rat model. Combining hypertension with diabetes in the rat resulted in increased myocardial and coronary microvascular pathology and greater changes in isolated muscle function, electrophysiology, and contractile protein biochemistry. Many hypertensive diabetic rats died spontaneously, showing signs of congestive heart failure. Diabetic cardiomyopathy is a significant cause of heart failure in diabetic subjects and occurs more frequently in those with microvascular complications and/or hypertension. Clinical studies are needed to clarify the natural history of this disorder, focusing on the benefits of tight control of hyperglycemia and treatment of associated hypertension. Experimental studies will clarify the pathophysiology and contribute to improved therapy. The high prevalence of diabetes and hypertension in Blacks makes these considerations especially relevant to this population.

Left ventricular papillary muscle function, transmembrane action potentials, myosin adenosinetriphosphatase (ATPase) and isoenzyme distribution, and myocardial pathology were studied in hypertensive (H), diabetic (D), hypertensive-diabetic (HD), and control (C) rats. There was approximately 50% relative left ventricular hypertrophy in H and HD rats. Relative lung and liver weights were greater in HD rats. Peak velocity of shortening tended to decrease progressively in H, D, and HD rats. The duration of contraction and relaxation was markedly prolonged in Ds and HDs. The length-developed tension relation was blunted in HDs. The negative inotropic effect of verapamil was similar in all groups. Resting membrane potential and amplitude were decreased in D and HD rats. Action potential duration was increased in H, D, and especially HD rats. The shortening of action potential duration with increased stimulus frequency was greater in H, D, and especially HD rats than in Cs. Left ventricular myosin ATPase and V1 isoenzyme content decreased progressively in H, D, and HD rats. Right ventricular V1 isoenzyme content was not affected in H rats but was markedly decreased in D and HD rats. Left (and right) ventricular pathology was unchanged in rats with diabetes but was increased in rats with hypertension. These data suggest that the combination of myocardial pathology (due to hypertension) and cellular dysfunction (caused mainly by diabetes) may result in cardiomyopathy and congestive heart failure in the HD rat.

The hypertensive-diabetic rat is a new small animal model of cardiomyopathy characterized by ventricular damage. To determine the extent of pathology in this model, quantitation of light microscopic changes in hearts from 15 hypertensive-diabetic rats and 15 age-matched controls was performed. The fraction of myocardium involved by interstitial fibrosis, myocyte necrosis, replacement fibrosis, vascular sclerosis and perivascular fibrosis was computed separately for right and left ventricles. Spontaneously dying as well as deliberately killed hypertensive-diabetic rats were studied. Spontaneously dying animals had higher systolic blood pressures compared with rats killed deliberately. Body weights were lower and lung weights higher in the former group. Left and right ventricular necrosis and fibrosis were increased in spontaneously dying compared with deliberately killed rats. The degree of right ventricular necrosis and fibrosis paralleled that in the left ventricle, but was, unexpectedly, several times greater in magnitude. Thus, quantitative histology in the hypertensive-diabetic rat reveals more cardiac necrosis and fibrosis, in either ventricle, from spontaneously dying animals compared with deliberately killed rats. This damage, coupled with major functional alterations in the viable myocardium, may lead to congestive heart failure or arrhythmia.

To study the effects of chronic diabetes on heart rate and adrenergic responsiveness we compared unanesthetized diabetic rabbits, 10-13 mo after alloxan monohydrate injection, to age-matched controls. There were no significant differences found between groups for body or heart weight. Both resting and intrinsic heart rate (the latter obtained after atropine sulfate and propranolol HCl) were similar. In addition, serum and left ventricular epinephrine and norepinephrine concentrations as well as left ventricular beta-receptor density and affinity were unchanged in diabetic animals. Heart rate responses to isoproterenol were blunted in diabetics at the three highest doses. Base-line mean blood pressure was modestly lower in diabetic rabbits, and parallel declines in pressure for both groups were observed in response to isoproterenol. The diminished heart rate response to isoproterenol in diabetic rabbits may be due to diminished myocardial sensitivity to catecholamines, possibly combined with altered baroreceptor reflexes. These experiments may provide an explanation for the blunted heart rate response to exercise described in human diabetics.