31P nuclear magnetic resonance studies of phosphoglyceride metabolism in developing and degenerating brain: preliminary observations.

31P nuclear magnetic resonance (NMR) studies were conducted on perchloric acid extracts of the brain of one control, two Huntington's disease (HD), one probable Alzheimer's disease (AD), and one AD patient. These studies demonstrated significant elevations (over control) in the levels of phosphomonoesters in all brain areas of the patients with HD and AD even in areas devoid of neuropathological findings. Elevations of phosphodiesters were also observed, but they tended to reflect the degree of neuropathological change. We postulate that the 31P NMR findings represent molecular alterations with corresponding metabolic correlates which either antedate or occur in the absence of changes in cellular morphology or structure. As such the 31P NMR findings may reflect a subcellular "molecular neuropathology."

Physiological and metabolic characterization of a cardiomyopathy induced by chronic copper deficiency.

Male weanling rats were made copper deficient with a purified diet containing all known essential dietary nutrients except copper. Copper deficiency was verified by indirect (anemia, growth retardation, hypercholesterolemia, gross pathology, and abnormal electrocardiograms) and direct (tissue copper analysis) criteria. His bundle electrographic and electrocardiographic changes detected in the copper-deficient group consisted most notably of depressed His-Purkinje system conductivity and S-T segment depression. Phosphorus-31 nuclear magnetic resonance spectroscopic analysis of cardiac, renal, and hepatic tissue perchloric acid extracts revealed significant metabolic changes associated with the dietary copper deficiency, including a generalized marked decrease in ATP and phosphocreatine levels and a corresponding increase in inorganic orthophosphate and ADP levels in the various tissues. Tissue-specific changes consisting of elevated ribose 5-phosphate (heart), phosphocholine (heart), and inosine monophosphate (kidney) and decreased glycerol 3-phosphorylethanolamine (liver) and glycerol 3-phosphorylcholine (liver) levels were detected in copper-deficient rats. Microscopic examination of heart tissue from copper-deficient rats revealed extensive disruption of mitochondrial fine structure, including fragmentation of cristae and inner and outer mitochondrial membranes, which resulted in pronounced vacuolization throughout the tissue. Although the physiological and metabolic disturbances manifested in hearts from copper-deficient animals generally mimic myocardial responses to chronic ischemia, the observed changes are interpreted in a broader context to represent the appearance of a copper-dependent cardiomyopathy.

Cardiovascular dysfunction and hypersensitivity to sodium pentobarbital induced by chronic barium chloride ingestion.

Barium-supplemented Long-Evans hooded rats were characterized by a persistent hypertension that was evident after 1 month of barium (100 micrograms/ml mineral fortified water) treatment. Analysis of in vivo myocardial excitability, contractility, and metabolic characteristics at 16 months revealed other significant barium-induced disturbances within the cardiovascular system. The most distinctive aspect of the barium effect was a demonstrated hypersensitivity of the cardiovascular system to sodium pentobarbital. Under barbiturate anesthesia, virtually all of the myocardial contractile indices were depressed significantly in barium-exposed rats relative to the corresponding control-fed rats. The lack of a similar response to ketamine and xylazine anesthesia revealed that the cardiovascular actions of sodium pentobarbital in barium-treated rats were linked specifically to this anesthetic, and were not representative of a generalized anesthetic response. Other myocardial pathophysiologic and metabolic changes induced by barium were manifest, irrespective of the anesthetic employed. The contractile element shortening velocity of the cardiac muscle fibers was significantly slower in both groups of barium-treated rats relative to the control groups, irrespective of the anesthetic regimen. Similarly, significant disturbances in myocardial energy metabolism were detected in the barium-exposed rats which were consistent with the reduced contractile element shortening velocity. In addition, the excitability of the cardiac conduction system was depressed preferentially in the atrioventricular nodal region of hearts from barium-exposed rats. Overall, the altered cardiac contractility and excitability characteristics, the myocardial metabolic disturbances, and the hypersensitivity of the cardiovascular system to sodium pentobarbital suggest the existence of a heretofore undescribed cardiomyopathic disorder induced by chronic barium exposure. These experimental findings represent the first indication that life-long barium ingestion may have significant adverse effects on the mammalian cardiovascular system.

31P NMR studies of the intact perfused rat heart: a novel analytical approach for determining functional-metabolic correlates, temporal relationships, and intracellular actions of cardiotoxic chemicals nondestructively in an intact organ model.

Intact hearts isolated from adult male, Sprague-Dawley rats were perfused under standardized conditions in an apparatus designed for use in a high-resolution nuclear magnetic resonance (NMR) spectrometer system. Myocardial phosphate metabolite concentrations (ATP, PCr, Pi, and phosphomonoesters) and intracellular pH were determined sequentially at timed intervals coincident with the functional assessments of the intact heart by phosphorus-31 (31P) NMR spectroscopic methods. Myocardial functional and metabolic parameters were unaffected by sustained control perfusion (2 hr). The negative inotropic actions of cadmium were associated with significant changes in the chemical environment of inorganic phosphate (Pi) within the cells. This initial cellular response to cadmium, which correlated with the onset and magnitude of the contractile disturbances, appeared to represent the formation of an acidic, intracellular Pi pool (pH, 6.0). This pH compartment reached a steady state during the period in which maximal changes in contractile function were manifested, and before cellular ATP and PCr concentrations were altered. These findings are consistent with the interpretation that the functional deficits caused by cadmium originated primarily from changes in the chemical environment experienced by intracellular metabolites, rather than changes in the amounts of cellular high energy substrates. In contrast, the time-dependent negative inotropic effects of arsenate were proportional to the loss of cellular ATP stores. Intracellular pH was not affected in these hearts. A distinctive metabolic finding associated with the cardiotoxicity of arsenate was the time-dependent accumulation of previously undetected phosphate metabolites in the arsenate-treated hearts. Efforts to chemically identify these metabolites proved inconclusive; however, existing evidence suggests the possibility that these phosphorus-containing compounds may be arsenophosphate derivatives of naturally occurring cellular metabolites. The present findings provide experimental evidence demonstrating that toxicologic assessments in an intact organ model are feasible using whole organ 31P NMR spectroscopic methods and that meaningful, new insights regarding the biochemical mechanisms responsible for the cardiotoxic actions of xenobiotic agents can be obtained by this analytical approach.

Impaired in vivo myocardial reactivity to norepinephrine in diabetic rats.

The effects of long-term diabetes with and without insulin treatment on in vivo myocardial contractile activity were studied under basal conditions and as a function of intravenously infused norepinephrine. Diabetes was induced by iv injection of streptozotocin (50 mg/kg). Insulin-treated diabetic rats received 5 units per day of isophane insulin suspension. The duration of the study was 8 weeks. In vivo myocardial contractility measurements were performed in ketamine-xylazine-anesthetized rats using a miniature catheter-tip pressure transducer advanced through the right carotid artery into the left ventricle. Peak positive dP/dt and intraventricular developed pressure were comparable among the groups when measured under basal conditions; however, the magnitude of the response to variable doses of norepinephrine (6 X 10(-12) to 6 X 10(-8) mole/kg body wt) were significantly diminished in diabetic rats, but the sensitivity was unchanged. Negative dP/dt was decreased under basal conditions and in response to norepinephrine in diabetic rats. Insulin treatment to diabetic rats prevented these changes, but heart rate was elevated. These results demonstrate that the in vivo cardiovascular reactivity of diabetic rats to norepinephrine is significantly attenuated.