Dietary copper restriction in rats results in cardiomyopathy. In rats fed copper-restricted diets from weaning for 5 to 8 weeks, a concentric hypertrophy is apparent, whereas postweaning copper restriction does produce cardiomyopathy without apparent hypertrophy. Both sets of circumstances appear to affect the integrity of the basal laminae of cardiac myocytes and capillaries. In rats fed copper-restricted diets from weaning, decreases in cytochrome c oxidase are related not only to copper's role as a coenzyme, but also to a marked decrease in the nuclear encoded subunits of the enzyme complex. Decreased levels of the delta-subunit of ATP synthase have been observed. However, such aberrations in mitochondrial enzymes, as well as morphologic alterations, apparently do not affect cardiac levels of ATP. This review suggests mechanisms of cardiac adaptation and initiation factors leading to cardiac hypertrophy. We present a hypothetical working model explaining the events leading to cardiac failure in the copper-deficient rat heart based on the present body of knowledge, and compare the pathology with other models of cardiomyopathies.
Cardiac ultrastructural and functional characteristics were determined in copper-depleted and copper-repleted rats. Male weanling rats were randomized into five groups that were fed either copper-adequate or copper-deficient diets. After 5 wk, one group fed each diet was studied to obtain baseline values. At this time, one copper-adequate postweanling group continued to receive the adequate diet as control, one deficient postweanling group was fed the adequate diet to evaluate the effect of copper repletion and one postweanling adequate group was fed the deficient diet to evaluate copper depletion in relatively older rats. These dietary treatments were continued for six additional weeks. Copper-depleted rats of both ages exhibited significant cardiac ultrastructural pathology and electrocardiogram abnormalities and the postweanling copper-depleted rats exhibited these abnormalities in the absence of hypertrophy and anemia. Increased mitochondrial volume density, disarranged cristae, and nonaligned myofibrils with disturbances at Z-bands were displayed. Additionally, all copper-depleted rats demonstrated fragmented basal laminae at capillary-myocyte interface. Increased QRS amplitude and notching and greater QT intervals were displayed. Copper-repleted rats exhibited some, but not total, reversal of these abnormalities. These results suggest that capillary-myocyte interface changes may play an important role in the developing pathology of copper depletion.
This study determined if reported decreases in the delta subunit of ATP synthase and nuclear-encoded cytochrome c oxidase subunits in hearts of copper-deficient rats were secondary to the heart disease pathology or due to lack of the trace element. Male weanling Long-Evans rats were randomly divided into six groups: rats fed a copper-adequate or copper-deficient diet (with free access) with or without 5% dimethyl sulfoxide (DMSO) in the drinking water and rats pair-fed the copper-adequate or copper-deficient diet without DMSO treatment. After 4 wk, rats in the groups fed the copper-deficient diet had lower liver superoxide dismutase and heart cytochrome c oxidase activities compared with groups fed the copper-adequate diet. Administration of DMSO, an antioxidant, and energy restriction (pair-feeding) partially blocked cardiac hypertrophy in rats fed the copper-deficient diet. Greater mitochondrial volume density and mitochondrial:myofibrillar ratio and disrupted myofibrils and basal laminae were observed in the hearts from rats fed the copper-deficient diet and not treated with DMSO compared with hearts from groups fed the copper-adequate diet. The DMSO-treated rats fed the copper-deficient diet had hearts with intact structure but enlarged mitochondria compared with other groups fed the copper-deficient diet. The delta subunit of ATP synthase and the nuclear-encoded cytochrome c oxidase subunits IV and V were depressed in rats fed a copper-deficient diet regardless of antioxidant treatment and pair-feeding. These data suggest that the effects of copper deficiency upon ATP synthase and cytochrome c oxidase proteins are not due to the cardiac pathology.
Early detection of nutritional risk in free-living elderly is critical in healthcare, yet comprehensive measurements are time consuming and can be frustrating to both health professionals and elderly. In addition, body composition measurements provide information regarding fat and fat-free mass that have been linked to morbidity and mortality in elderly. In this study, nutritional risk was assessed in 69 elderly, aged 50-90 years, attending congregate meal-site programs, using Mini Nutritional Assessment, and body composition was assessed by bioelectric impedance. Analysis revealed that 31.9% of the elderly were at risk for malnutrition and 2.9% were malnourished. Males had significantly greater body weight, height and fat-free mass, and females had significantly greater body fat as percentage of body weight, but there was no gender difference in nutritional risk. Of elderly, 36.2% had body mass index > 85th percentile and 8.7% < 15th percentile using national population reference standards. Age-related decline in fat-free mass was an early indicator of changes in body composition.
Researchers explored predictors of meaning in life such as physical and mental health and volunteerism in a representative sample of older adults. Measures included the Geriatric Depression Scale and the Life Regard Index. Implications for counseling older adults are discussed.
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