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Query: UMLS:C0028754 (obesity)
 124,988 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The JCR:LA-cp rat is one of a number of strains incorporating the autosomal recessive cp gene that induces obesity. This strain is unique in the development of not only a profound insulin resistance, but an accompanying cardiovascular disease that correlates strongly with hyperinsulinemia. The hyperinsulinemia develops rapidly after 4 weeks of age, with an age at half-maximum of 5.5 weeks. This reflects postprandial plasma insulin levels that peak at 1000 mU/l in a standardized meal tolerance test. Defective acetylcholine-mediated vascular relaxation develops with a 1-week lag over the developing hyperinsulinemia. The frequency of staining for the vascular adhesion molecules, VCAM-1 and ICAM, does not show either age or genotype variation, although plasma levels do show an age variation. Treatment of the rats with the alpha-glucosidase inhibitor, miglitol (Bay m1099), obviates the exaggerated postprandial glucose and, especially, the insulin responses of the cp/cp rat. This causes an improvement in insulin sensitivity, prevention of the impaired vascular relaxation, and reduction in plasma levels of advanced glycated end-products. Arterial wall morphology, as visualized by both scanning and transmission electron microscopy, shows abnormal endothelium, adherent macrophages, and activated migrating smooth muscle cells in the intima. Oil-Red-O staining reveals lipid deposits in the intimal spaces, as confirmed by the presence of foam cells. The lesions resemble fatty streaks or modest atherosclerosis in man, rather than the extensive cholesterol-laden lesions seen in familial hypercholesterolemia or cholesterol-fed rabbit models. The lean rats of the strain show similar, but less marked, intimal abnormalities. The vasculopathy in this animal model appears to be precipitated by the developing hyperinsulinemia, but also requires an underlying abnormality of vascular smooth muscle and possibly also of the endothelium.
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PMID:Vasculopathy and insulin resistance in the JCR:LA-cp rat. 967 79

The C57BL/6 (B6) mouse is more sensitive to the effects of a high-fat diet than the A/J strain. The B6 mouse develops severe obesity, hyperglycemia, and hyperinsulinemia when fed this dietary regimen. This study was conducted to determine the effects of dietary fat and sucrose concentrations on body composition and intestinal sucrase (EC 3.2.1.48) and maltase (EC 3.2.1.20) activity in these two mouse strains. High-fat diets, regardless of sucrose content, resulted in significant weight gain, higher body fat, and lower body protein and water content in both strains of mice. The shift toward higher body fat and lower protein and water content was far greater in the B6 strain. Low-fat, high-sucrose diets resulted in lower body weight in both strains, as well as significantly greater body protein content in B6 mice. Analysis of intestinal sucrase showed that the enzyme was less active in B6 mice when the diet was high in sucrose. Both sucrase and maltase had lower activity in the presence of high dietary fat in both mouse strains. The percent reduction of intestinal enzyme activity due to dietary fat was similar in both strains. The B6 mouse exhibits disproportionate weight gain and altered body composition on a high-fat diet. This coupled with the reduced body weight and increased body protein on a low-fat, high-sucrose diet suggests that factors-relative to fat metabolism rather than sucrose metabolism are responsible for obesity.
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PMID:Differential effects of fat and sucrose on body composition in A/J and C57BL/6 mice. 982 12

Obesity is common in NIDDM; in a cohort of 314 diabetics in Singapore, 44.3% are overweight. Management of obesity in diabetics differs from that in non-diabetics in that it is more urgent; weight maintenance is more difficult and hypoglycaemic medication may cause weight changes. Like in the non-diabetic, management of obesity in diabetic requires a pragmatic and realistic approach. A team approach is required: the help of the nurse educator, the dietitian, behaviour modification therapist, exercise therapist etc are required. A detailed history, careful physical examination and relevant investigations are required to assess the severity of the diabetic state and to exclude an occasional underlying cause of the obesity in the obese NIDDM. Weight loss is urgent in the obese NIDDM, especially those with android obesity. There must be a reduction in caloric intake. Weight loss leads to improvement in the glucose tolerance, insulin sensitivity, reduction in lipid levels and fall in blood pressure in the hypertensive. Exercise is of limited value except in the younger obese NIDDM. Metformin is the hypoglycaemic drug of choice as it leads to consistent weight reduction. The sulphonylureas may cause weight gain. Insulin should be avoided where possible as it causes further weight gain. Other hypoglycaemic agents include Glucobay (alpha-glucosidase inhibitor) and Troglitazone (insulin sensitizer) which do not alter the weight. Orlistat (lipase inhibitor) is promising as it causes reduction of weight, blood-glucose and lipid levels. Anti-obesity drugs (noradrenergic and serotonergic agents) have modest effects on weight reduction in the obese NIDDM; a widely use preparation, Dexfenfluramine (Adifax) has been withdrawn because of side effects. Surgery such as gastric plication is the last resort in treating the morbidly obese NIDDM. The discovery of leptin in 1994 has led to intense research into energy homeostasis in obesity; hopefully this will lead to better treatment of obesity in diabetics and non-diabetics.
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PMID:Management of obesity in NIDDM (non-insulin-dependent diabetes mellitus). 984 3

Besides the classical dietary regimen, it is possible to use specific pharmacological approaches, targeted at the intestine, in order to treat some metabolic disorders. Three approaches will be described: anionic resins for treating hypercholesterolaemia, alpha-glucosidase inhibitors for treating diabetes mellitus and reactive hypoglycaemia, and intestinal lipase inhibitors for treating obesity. All these drugs are based on original concepts, but their clinical use is often limited by the occurrence of digestive side-effects. The latter may generally be reduced by progressive and individual titration of the dosage of each drug and/or by following an appropriate diet.
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PMID:[Drug clinics. How I treat various metabolic diseases treated by a drug intervention that targets the intestine]. 988 53

The efficacy and safety of treatment with troglitazone combined with an alpha-glucosidase inhibitor, in obese type 2 diabetic patients who were previously administered alpha-glucosidase inhibitors alone, in improving glycaemic control and reducing insulin resistance were studied. Obese type 2 diabetic patients, poorly controlled with alpha-glucosidase inhibitors, were randomized to receive either oral troglitazone 200 mg twice daily (22 patients: group A) or a placebo (20 patients: group B) in addition to their usual alpha-glucosidase inhibitor. In group A, significant decreases in the mean levels of haemoglobin A1c and basal plasma insulin levels were observed 6 months after the start of combined therapy. Serum triglyceride levels significantly decreased but serum lactic acid dehydrogenase and body weight significantly increased. New systemic oedema was observed in six patients. Combined therapy with troglitazone and alpha-glucosidase inhibitors may be effective for diabetic metabolic abnormalities, although the potential development of adverse effects such as body-weight gain and systemic oedema demands vigilance.
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PMID:Troglitazone combination therapy in obese type 2 diabetic patients poorly controlled with alpha-glucosidase inhibitors. 1044 91

Besides genetic predisposition, obesity is the most important risk factor for the development of diabetes mellitus, and weight reduction has been shown to markedly improve blood glucose control in obese subjects with type 2 diabetes. Therapeutic strategies for the obese diabetic patient include: 1) promoting weight loss through lifestyle modifications (hypocaloric diet and exercise) and anti-obesity drugs (orlistat, sibutramine, etc.); 2) improving blood glucose control, essentially through the reduction of insulin resistance (metformin, eventually thiazolidinediones) or insulin need (alpha-glucosidase inhibitors) and, at a later stage, the correction of defective insulin secretion (sulphonylureas, repaglinide) or low circulating insulin levels (exogenous insulin); and 3) treating common associated risk factors, such as arterial hypertension and dyslipidaemias, to improve cardiovascular prognosis. When morbid obesity is present, both restoring a good glycemic control and correcting associated risk factors can only be obtained through marked and sustained weight loss. This primary objective justifies more aggressive weight reduction programmes, including very low-calorie diets and bariatric surgery, but only within a multidisciplinary approach and in well-selected patients.
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PMID:Treatment of diabetes in patients with severe obesity. 1075 90

Most of type 2. diabetic patients require medication for several concomitant diseases, most important being, hypertension, ischaemic heart disease, heart failure, dyslipidaemias, obesity. Thus the risk of drug interactions is important, particularly in elderly patients. Oral antidiabetic drugs include hypoglycaemic agents (sulphonylureas, meglitenides) and biguanides (metformin), alpha-glucosidase inhibitors, tiazolinidediones. Drug interactions with antihyperglycaemic agents can be divided into pharmacokinetic and pharmacodynamic interactions. Numerous drugs due to interactions enhance hypoglycaemic action of sulphonylureas, thus increase the risk of hypoglycaemia. Several drugs may cause impairment of glycaemic control through various mechanisms in diabetic patients treated with oral antidiabetic drugs. Currently the most controversial problem is safety of combination therapy with sulphonylurea and metformin, as several observations indicated that it can increase mortality from cardio-vascular causes.
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PMID:[Clinically important effects of oral antidiabetic drug interactions]. 1112 85

In this review we present the agents that are in use in the treatment of type 2 diabetes. Sulfonylureas of the 1st and 2nd generation increase insulin secretion but can induce hyperinsulinemia and sometimes prolonged hypoglycemia. Glimepiride is a new 3rd generation sulfonylurea with some advantages over the other members of this group, such as a lower risk of hypoglycemia, no interaction with cardiovascular KATP-channels and a possibility that it may increase insulin sensitivity. There are also newer insulin secretagogues (such as neteglinide and repaglinide) with a rapid onset of action on the beta-cell, therefore inducing a more physiological profile of insulin secretion during meals. The category of insulin sensitizers includes metformin and thiazolidinediones. Metformin effectively reduces hyperglycemia, hyperlipidemia and macroangiopathy in patients with type 2 diabetes. This agent increases the sensitivity of the liver and peripheral tissues to insulin and, therefore, it could be considered as a drug of choice for the prevention of type 2 diabetes. Thiazolidinediones (rosiglitazone and pioglitazone) increase the sensitivity of the tissues to insulin. This mechanism of action makes them powerful therapeutic tools for the treatment of type 2 diabetes (and possibly other insulin resistant states) either alone or in combination with other oral agents. The category of agents that interfere with the absorption of glucose and lipids includes alpha-glucosidase inhibitors (acarbose and miglitol) and lipase inhibitors (or-listat). alpha-Glucocidase inhibitors improve the time relationship between plasma insulin and glucose increases after a meal. Therefore, these agents may be used in the treatment of patients with type 2 diabetes, either alone at a very early stage of this disease (when insulin secretion is still adequate), or in combination with insulin secretagogues. alpha-Glucosidase inhibition may also prove useful as a supplement to insulin therapy in patients with type 1 diabetes mellitus. The inhibitor of gastrointestinal lipase orlistat may prove a useful adjunct to hypocaloric diets in patients with type 2 diabetes and obesity.
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PMID:Oral hypoglycemic agents: insulin secretagogues, alpha-glucosidase inhibitors and insulin sensitizers. 1146 May 77

As compared to subcutaneous adipocytes, visceral adipocytes have high basal lipolysis, are highly sensitive to catecholamines, and are poorly sensitive to insulin; these traits are amplified when visceral adipocytes hypertrophy. As a result, enlarged visceral fat stores tend to flood the portal circulation with free fatty acids at metabolically inappropriate times when fatty acids are unlikely to be oxidized, thus exposing tissues to excessive free fatty acid levels and giving rise to the insulin resistance syndrome. A logical approach to preventing or correcting visceral obesity is to down-regulate the lipoprotein lipase (LPL) activity of visceral adipocytes relative to that expressed in subcutaneous adipocytes and skeletal muscle. IGF-I activity appears to be a primary determinant of visceral LPL activity in humans; systemic IGF-I activity is decreased when diurnal insulin secretion is low, when hepatocytes detect a relative paucity of certain essential amino acids, and when estrogens are administered orally. The ability of alpha-glucosidase inhibitor therapy to selectively reduce visceral adiposity suggests that down-regulation of diurnal insulin secretion and/or IGF-I activity may indeed have a greater impact on LPL activity in visceral fat than in subcutaneous fat. Thus, low-glycemic-index, vegan, high-protein, or hypocaloric diets can be expected to decrease visceral LPL activity, as can postmenopausal estrogen therapy. Furthermore, estrogen enhances the LPL activity of non-pathogenic gluteofemoral fat cells, whereas testosterone decreases visceral LPL activity in men; this may explain why sex hormone replacement in middle-aged people of both sexes has a favorable impact on visceral fat and insulin sensitivity. Beta-adrenergic activity suppresses transcription of LPL in adipocytes; this phenomenon may contribute to the favorable impact of exercise training on visceral obesity; conceivably, preadministration of safe drugs that boost catecholamine activity (caffeine, yohimbine) could potentiate this beneficial effect of exercise. Glucocorticoids selectively increase the LPL activity of visceral adipocytes; while there is currently no convincing evidence that psychological stress is a major determinant of visceral adiposity, or that stress management techniques can help to correct visceral obesity, reports that anxiolytic therapy can improve glycemic control in type 2 diabetes should encourage further research along these lines.
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PMID:Modulation of adipocyte lipoprotein lipase expression as a strategy for preventing or treating visceral obesity. 1146 Nov 72

New polyhydroxylated alkaloids, (2R,3R,4R)-2-hydroxymethyl-3,4-dihydroxypyrrolidine-N-propionamide from the root bark of Morus alba L., and 4-O-alpha-D-galactopyranosyl-calystegine B(2) and 3 beta,6 beta-dihydroxynortropane from the fruits, were isolated by column chromatography using a variety of ion-exchange resins. Fifteen other polyhydroxylated alkaloids were also isolated. 1-Deoxynojirimycin, a potent alpha-glucosidase inhibitor, was concentrated 2.7-fold by silkworms feeding on mulberry leaves. Some alkaloids contained in mulberry leaves were potent inhibitors of mammalian digestive glycosidases but not inhibitors of silkworm midgut glycosidases, suggesting that the silkworm has enzymes specially adapted to enable it to feed on mulberry leaves. The possibility of preventing the onset of diabetes and obesity using natural dietary supplements containing 1-deoxynojirimycin and other alpha-glucosidase inhibitors in high concentration is of great potential interest.
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PMID:Polyhydroxylated alkaloids isolated from mulberry trees (Morusalba L.) and silkworms (Bombyx mori L.). 1155 12


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