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Query: UMLS:C0020505 (
hyperphagia
)
6,116
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Diabetes is characterized by
hyperphagia
, polydipsia, polyuria, elevations in blood and urinary glucose, and alterations in the adrenergic nervous system. Insulin treatment is effective in reversing most of the adverse conditions of diabetes in the streptozotocin-treated rat. Acarbose (BAY G 5421), an intestinal
alpha-glucosidase
inhibitor, decreases postprandial glycemia by delaying carbohydrate absorption and also affords some beneficial effects in the diabetic animal. The purpose of this study was to evaluate the effects of chronic insulin (< or = 2 U/day) with and without acarbose treatment (20 mg/100 g of diet) on the metabolic and adrenergic parameters altered in streptozotocin (50 mg/kg, intravenously)-induced diabetes in female rats. Insulin dosage was changed weekly after the first 2 weeks of treatment in both insulin-treated groups in an attempt to maintain a level of blood glucose that was comparable to that achieved with acarbose treatment alone. Insulin dosage was reduced to a greater extent in the dual-treated group than in the group treated with insulin alone. Diabetic rats were hyperphagic, polydipsic, and polyuric within 1 week of streptozotocin treatment. Each treatment alone was effective in reducing these alterations. However, these reductions were more apparent in the combined therapy group. Only in this combined therapy group was glycated hemoglobin returned to normal. All treatments also prevented the significant weight loss observed in untreated diabetic animals. Adrenergic responses were assessed by monitoring the rise in tail skin temperature associated with administration of isoproterenol. Diabetic rats were less responsive than controls, and each of the treatments restored this response.(ABSTRACT TRUNCATED AT 250 WORDS)
...
PMID:Effects of insulin and acarbose alone and in combination in the female streptozotocin-induced diabetic rat. 830 97
Glucagon-like peptide 1 (GLP-1) is a physiological incretin hormone in normal humans explaining in part the augmented insulin response after oral versus intravenous glucose administration. In addition, GLP-1 also lowers glucagon concentrations, slows gastric emptying, stimulates (pro)insulin biosynthesis, reduces food intake upon intracerebroventricular administration in animals, and may, in addition, enhance insulin sensitivity. Therefore, GLP-1, in many aspects, opposes the Type 2-diabetic phenotype characterized by disturbed glucose-induced insulin secretory capacity, hyperglucagonaemia, moderate insulin deficiency, accelerated gastric emptying,
overeating
(obesity) and insulin resistance. The other incretin hormone, gastric inhibitory polypeptide (GIP), has lost almost all its activity in Type 2-diabetic patients. In contrast, GLP-1 glucose-dependently stimulates insulin secretion in diet- and sulfonylurea-treated Type 2-diabetic patients and also in patients under insulin therapy long after sulfonylurea secondary failure. Exogenous administration of GLP-1 ([7-37] or [7-36 amide]) in doses elevating plasma concentrations to approximately 3-4 fold physiological postprandial levels fully normalizes fasting hyperglycaemia in Type 2-diabetic patients. The half life of GLP-1 is too short to maintain therapeutic plasma levels for sufficient periods by subcutaneous injections. Current research activities aim at finding GLP-1 analogues with more suitable pharmacokinetic properties than the original peptide. Another approach could be the augmentation of endogenous release of GLP-1, which is abundant in L cells of the lower small intestine and the colon. Interference with sucrose digestion using
alpha-glucosidase
inhibition moves nutrients into distal parts of the gastrointestinal tract and, thereby, prolongs and augments GLP-1 release. Enprostil, a prostaglandin E2 analogue, fully suppresses GIP responses, while only marginally affecting insulin secretion and glucose tolerance after oral glucose, suggesting compensatory hypersecretion of additional insulinotropic peptides, possibly including GLP-1. Given the large amount of GLP-1 present in L cells, it appears worthwhile to look for more agents that could 'mobilize' this endogenous pool of the 'antidiabetogenic' gut hormone GLP-1.
...
PMID:Glucagon-like peptide 1 (GLP-1) as a new therapeutic approach for type 2-diabetes. 928 4
We previously demonstrated that chronic dietary treatment with acarbose, an
alpha-glucosidase
inhibitor, improves glucose homeostasis in the streptozotocin (STZ)-induced diabetic rat. In this study we evaluated the effects of 4 weeks of acarbose treatment on glucose homeostasis in STZ-diabetic rats for both meal-fed (three times daily) and ad libitum feeding conditions. Sprague Dawley male rats (n = 58) were started on a daily meal-feeding paradigm consisting of three 2-h feeding periods: 0700 to 0900 hours, 1300 to 1500 hours, and 1900 to 2100 hours. Following 2 weeks of adaptation, half of the animals were switched to ad libitum feeding. The feeding paradigm itself (meal fed versus ad lib.) affected neither body weight nor daily food intake. Twenty animals from each feeding group then received STZ (60 mg/kg i.v.), whereas control animals received vehicle injections only. Two days later, the diet of 10 STZ-treated animals from each paradigm was supplemented with acarbose (40 mg of BAY G 5421/100-g diet), and the groups were treated for 4 weeks. Untreated diabetic rats had lower body weight than vehicle-injected control rats at all time points after STZ treatment. Acarbose treatment delayed this effect on body weight. STZ treatment induced
hyperphagia
regardless of feeding paradigm, which was significantly attenuated by acarbose only for the first week of treatment. Untreated diabetic rats had fasting blood glucose values 4 times those of vehicle-injected controls in both the meal-fed and ad libitum-fed conditions. Acarbose significantly lowered fasting blood glucose in the treated STZ groups. Blood glucose was also assessed 0, 90, and 180 min following the start of a meal. The postprandial rise in blood glucose was significantly reduced in acarbose-treated meal-fed diabetic rats, to values not significantly different from those of vehicle-injected control rats. During the fourth week of treatment glycated hemoglobin levels were significantly higher in untreated diabetic groups compared to vehicle-injected control groups. Acarbose treatment significantly reduced this rise, regardless of the feeding paradigm. Collectively, the results demonstrate that acarbose reduces diabetes-induced increases of blood glucose and glycated hemoglobin and that the glycemic effects of acarbose are most apparent during the absorptive period. Feeding paradigm (ad lib. versus meal fed) has little or no influence on acarbose's metabolic effects, indicating that large meals are not required to realize the beneficial effects of the drug. The meal-fed STZ-diabetic rat may be a good model with which to test meal-based diabetes treatments.
...
PMID:Positive effects of acarbose in the diabetic rat are not altered by feeding schedule. 961 10
