Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0011860 (type 2 diabetes)
 57,723 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Nateglinide is a novel D-phenylalanine derivative that inhibits ATP-sensitive K+ channels in pancreatic beta-cells in the presence of glucose and thereby stimulates the prandial release of insulin. Nateglinide reduces fasting and mealtime blood glucose levels in animals, healthy volunteers, and patients with type 2 (non-insulin-dependent) diabetes mellitus, and produces prompt prandial insulin responses with return to baseline insulin levels between meals. In randomised, double-blind 24-week studies in patients with type 2 diabetes, oral nateglinide 120 mg 3 times daily before meals improved glycaemic control significantly relative to placebo. Nateglinide 120 mg plus metformin 500 mg, both 3 times daily, conferred greater glycaemic improvement than either drug given alone, and nateglinide 60 or 120 mg 3 times daily plus metformin 1 g twice daily was superior to metformin plus placebo. Nateglinide 120 mg 3 times daily significantly reduced hyperglycaemia relative to placebo in a 16-week double-blind study in patients with type 2 diabetes mellitus. Combination therapy with troglitazone 600 mg daily produced significantly better glycaemic control than either drug given as monotherapy. Mild hypoglycaemia was the most frequently reported adverse event (1.3% of patients) after treatment with nateglinide 120 mg 3 times daily in a 16-week clinical study. No clinically significant abnormalities in laboratory results, ECGs, vital signs or physical examination findings have been noted in patients taking the drug.
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PMID:Nateglinide. 1103 Apr 70

Glucose stimulates insulin secretion by generating triggering and amplifying signals in beta-cells. The triggering pathway is well characterized. It involves the following sequence of events: entry of glucose by facilitated diffusion, metabolism of glucose by oxidative glycolysis, rise in the ATP-to-ADP ratio, closure of ATP-sensitive K+ (KATP) channels, membrane depolarization, opening of voltage-operated Ca2+ channels, Ca2+ influx, rise in cytoplasmic free Ca2+ concentration ([Ca2+]i), and activation of the exocytotic machinery. The amplifying pathway can be studied when beta-cell [Ca2+]i is elevated and clamped by a depolarization with either a high concentration of sulfonylurea or a high concentration of K+ in the presence of diazoxide (K(ATP) channels are then respectively blocked or held open). Under these conditions, glucose still increases insulin secretion in a concentration-dependent manner. This increase in secretion is highly sensitive to glucose (produced by as little as 1-6 mmol/l glucose), requires glucose metabolism, is independent of activation of protein kinases A and C, and does not seem to implicate long-chain acyl-CoAs. Changes in adenine nucleotides may be involved. The amplification consists of an increase in efficacy of Ca2+ on exocytosis of insulin granules. There exists a clear hierarchy between both pathways. The triggering pathway predominates over the amplifying pathway, which remains functionally silent as long as [Ca2+]i has not been raised by the first pathway; i.e., as long as glucose has not reached its threshold concentration. The alteration of this hierarchy by long-acting sulfonylureas or genetic inactivation of K(ATP) channels may lead to inappropriate insulin secretion at low glucose. The amplifying pathway serves to optimize the secretory response not only to glucose but also to nonglucose stimuli. It is impaired in beta-cells of animal models of type 2 diabetes, and indirect evidence suggests that it is altered in beta-cells of type 2 diabetic patients. Besides the available drugs that act on K(ATP) channels and increase the triggering signal, novel drugs that correct a deficient amplifying pathway would be useful to restore adequate insulin secretion in type 2 diabetic patients.
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PMID:Triggering and amplifying pathways of regulation of insulin secretion by glucose. 1107 40

Diabetes mellitus type 2 is a syndrome with different etiopathology and clinical picture. Results of clinical studies show that hyperglycaemia increases during the time of diabetes even if it is intensively treated. At the present time some new hypoglycaemic drugs have been introduced for type 2 diabetes mellitus therapy. These drugs can increase insulin secretion by the inhibition of the ATP-sensitive K+ channels (glimepyride, repaglinide) or by incretin action (glucagon-like peptide-1). Other drugs can decrease insulin resistance acting on nuclear receptors (troglitazone). Normalization of stomach motoric activity can also lead to decreasing of blood glucose concentration (pramlintid). Also other mechanisms of action are taken into consideration, like changing of cytokine activity or catabolism regulation of beta-cells of the Langerhans' islets.
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PMID:[New hypoglycemic drugs in treatment of diabetes type 2]. 1110 71

Insulin secretion is finely tuned to tissue requirements by tight links to prevailing blood glucose levels. The normal regulation of insulin secretion is linked to glucose metabolism in the pancreatic beta-cell, a major but not exclusive signal for secretion being closure of K+ ATP-dependent channels in the cell membrane through an increase in the cytosolic ATP/ADP. Insulin secretion in type 2 diabetes is abnormal in several respects, due to genetic causes, but also due to the metabolic environment of the pancreatic beta-cells. This environment may be particularly important for the deterioration of insulin secretion, which occurs with increasing duration of diabetes. Factors of the environment with potential importance include over-stimulation, a negative effect of hyperglycaemia per se ("glucotoxicity"), and adverse effects of elevated fatty acids ("lipotoxicity"). A better understanding of the mechanisms behind these factors and of their clinical importance will pave the way for treatment which could preserve beta-cell function in type 2 diabetic patients.
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PMID:[Why is insulin release from beta cells insufficient in type 2 diabetes?]. 1110 28

It is discussed that Alzheimer disease does not form a nosologic entity. 5 to 10% of all Alzheimer cases are due to inherited abnormalities on chromosomes 1, or 14, or 21, whereas the majority of 90-95% is sporadic in origin. Age-related changes in the composition of membranes and in glucose/energy metabolism along with a sympathetic tone in the brain are assumed to be cellular/molecular risk factors for this disease. In its pathogenesis, the desensitization of the neuronal insulin receptor similar to non-insulin dependent diabetes mellitus may be of pivotal significance. This abnormality along with a reduction in insulin concentration is assumed to induce a cascade-like process of disturbances including decreases in cellular glucose, acetylcholine, cholesterol, and ATP, associated with changes in the metabolism of amino acids and fatty acids. There is evidence that the reductions in the availability of both glucose/energy and insulin contribute to the formation of amyloidogenic derivatives and hyperphosphorylated tau protein. This may indicate that the amyloid cascade hypothesis in not valid for sporadic Alzheimer disease but that the formation of both, amyloidogenic derivatives and hyperphosphorylated tau protein is downstream the origin of this neurodegenerative disease.
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PMID:Brain glucose and energy metabolism abnormalities in sporadic Alzheimer disease. Causes and consequences: an update. 1111 14

Type 2 diabetes mellitus is a complex heterogenous metabolic disorder in which peripheral insulin resistance and impaired insulin release are the main pathogenetic factors. The rapid response of the pancreatic beta-cells to glucose is already markedly disturbed in the early stages of type 2 diabetes mellitus. The consequence is often postprandial hyperglycaemia, which seems to be extremely important in the development of secondary complications, especially macrovascular disease. Therefore one of the main aims of treatment is to minimise blood glucose oscillations and attain near-normal glycosylated haemoglobin levels. Meglitinide analogues belong to a new family of insulin secretagogues which stimulate insulin release by inhibiting ATP-sensitive potassium channels of the beta-cell membrane via binding to a receptor distinct from that of sulphonylureas (SUR1/KIR 6.2). The pharmacokinetic and pharmacodynamic properties of repaglinide, the first drug of these new antihyperglycaemic agents on the market, and of nateglinide, which will be available soon, differ markedly from the currently used sulphonylureas [mainly glibenclamide (glyburide) and glimepiride]. Repaglinide and nateglinide are absorbed rapidly, stimulate insulin release within a few minutes, are rapidly metabolised in the liver and are mainly excreted in the bile. Therefore, following preprandial administration of these drugs, insulin is more readily available during and just after the meal. This leads to a significant reduction in postprandial hyperglycaemia without the danger of hypoglycaemia between meals. The short action of these compounds and biliary elimination makes repaglinide and nateglinide especially suitable for patients with type 2 diabetes mellitus who would like to have a more flexible lifestyle, need more flexibility because of unplanned eating behaviour (e.g. geriatric patients) or in whom one of the other first-line antidiabetic drugs, i.e. metformin, is strictly contraindicated (e.g. nephropathy with creatinine clearance < or = 50 ml/min). Meglitinide analogues act synergistically with metformin and thiazolidinediones (pioglitazone and rosiglitazone) and can be also combined with long-acting insulin (NPH insulin at bedtime). Therefore, these drugs enrich the palette of antidiabetic drugs and make the treatment more flexible and better tolerated, which both add to better metabolic control and support the empowerment and compliance of the patient. However, this will only be the case if the patient and the diabetes care team are trained for this new therapeutic schedule and the healthcare system is able to pay for these rather expensive drugs.
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PMID:Meglitinide analogues in the treatment of type 2 diabetes mellitus. 1119 Apr 20

Troglitazone, a thiazolidinedione derivative, is an oral antidiabetic agent that enhances insulin sensitivity in insulin-resistant states. K(ATP) channels, on the other hand, have important roles protecting cardiovascular system in ischemic and/or hypoxic states. They are also important in the control of vascular tone, and therefore of blood pressure. We tested whether troglitazone can directly affect vascular K(ATP) channel opener-induced relaxations in vitro. 1, 10 or 100 microM troglitazone incubations for 30 min did not alter cromakalim (a K(ATP) channel opener)--induced relaxations in endothelium-denuded aortas from rat, saphenous veins from type 2 diabetic and nondiabetic patients. In addition, we compared the sensitivity to cromakalim in diabetic saphenous veins with that of nondiabetic veins. The concentration-response curve for cromakalim was shifted to the right in diabetic vein. pD2 values for cromakalim were 6.85+/-0.08 vs. 6.61+/-0.04 (p<0.05) in nondiabetic (n:10) and diabetic (n:7) veins respectively. % maximum response of cromakalim was also significantly decreased by 24+/-3% in diabetic veins. However, responsiveness of veins to phenylephrine or sodium nitroprusside were similar in both groups. The results obtained may be clinically useful 1. suggesting that in ischaemic and/or hypoxic insults troglitazone may not worsen vascular dilatation, through K(ATP) channel, in diabetic patients who are more prone to these conditions than healthy people, 2. providing an evidence that diabetes causes an impaired dilatation of human saphenous vein through K(ATP) channels. This may partly be related with diabetes-induced vascular complications, such as vasospasm and even hypertension. Accordingly, since saphenous veins are used as conduit vessels in coronary by-pass graft surgery, the results also suggest that the defective dilatation through K(ATP) channels may play a role on the performance of saphenous vein grafts in type 2 diabetes.
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PMID:Troglitazone has no effect on K(ATP) channel opener induced-relaxations in rat aorta and in human saphenous veins from patients with type 2 diabetes. 1119 53

Psammomys obesus is a model of type 2 diabetes that displays resistance to insulin and deranged beta-cell response to glucose. We examined the major signaling pathways for insulin release in P. obesus islets. Islets from hyperglycemic animals utilized twice as much glucose as islets from normoglycemic diabetes-prone or diabetes-resistant controls but exhibited similar rates of glucose oxidation. Fractional oxidation of glucose was constant in control islets over a range of concentrations, whereas islets from hyperglycemic P. obesus showed a decline at high glucose. The mitochondrial substrates alpha-ketoisocaproate and monomethyl succinate had no effect on insulin secretion in P. obesus islets. Basal insulin release in islets from diabetes-resistant P. obesus was unaffected by glucagon-like peptide 1 (GLP-1) or forskolin, whereas that of islets of the diabetic line was augmented by the drugs. GLP-1 and forskolin potentiated the insulin response to maximal (11.1 mmol/l) glucose in islets from all groups. The phorbol ester phorbol myristic acid (PMA) potentiated basal insulin release in islets from prediabetic animals, but not those from hyperglycemic or diabetes-resistant P. obesus. At the maximal stimulatory glucose concentration, PMA potentiated insulin response in islets from normoglycemic prediabetic and diabetes-resistant P. obesus but had no effect on islets from hyperglycemic P. obesus. Maintenance of islets from hyperglycemic P. obesus for 18 h in low (3.3 mmol/l) glucose in the presence of diazoxide (375 pmol/l) dramatically improved the insulin response to glucose and restored the responsiveness to PMA. Immunohistochemical analysis indicated that hyperglycemia was associated with reduced expression of alpha-protein kinase C (PKC) and diminished translocation of lambda-PKC. In summary, we found that 1) P. obesus islets have low oxidative capacity, probably resulting in limited ability to generate ATP to initiate and drive the insulin secretion; 2) insulin response potentiated by cyclic AMP-dependent protein kinase is intact in P. obesus islets, and increased sensitivity to GLP-1 or forskolin in the diabetic line may be secondary to increased sensitivity to glucose; and 3) islets of hyperglycemic P. obesus display reduced expression of alpha-PKC and diminished translocation of lambda-PKC associated with impaired response to PMA. We conclude that low beta-cell oxidative capacity coupled with impaired PKC-dependent signaling may contribute to the animals' poor adaptation to a high-energy diet.
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PMID:Defective stimulus-secretion coupling in islets of Psammomys obesus, an animal model for type 2 diabetes. 1127 41

Sulphonylurea derivatives (SUD) are a mainstay of treatment of type 2 diabetes but questions have been raised about the potential adverse effects of these drugs as far as cardiovascular functions are concerned. An early prospective study which examined the effects of glycaemic control with various agents on coronary heart disease was stopped in the 70-ies due to excess cardiovascular mortality in the group receiving SUD of first generation: tolbutamide. The discovery of ATP-sensitive potassium channels in the heart, their role in ischaemic heart disease and mechanisms of endogenous cardiac cell protection--preconditioning have brought back concerns of SUD safety. Recently, a new SUD--glimepiride--claimed as the first representant of III generation of these agents--has been introduced into clinical practice. Glimepiride appears to be devoid of vascular ATP-sensitive potassium channels binding properties. Postulated and confirmed in animal experimental studies cardioprotective features of glimepiride were evaluated in a randomised, placebo-controlled study with glimepiride and glibenclamide comparing effects of these drugs on ischaemic preconditioning during angioplasty of high grade coronary artery stenoses in patients with stable angina. Myocardial ischaemia was quantified by intracoronary electrocardiography and time to occurrence of angina during vessel occlusion was measured. The results of the study confirmed glimepiride effects of maintaining myocardial preconditioning. The article summarises current knowledge of SUD influence on cardiovascular system and discusses some differences in pharmacodynamics of glimepiride which appear to provide this agent with clinical advantages over conventional SUD at least in cardiovascular aspects.
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PMID:[Sulphonylurea derivatives and the cardiovascular system]. 1129 25

This article reviews the pharmacological and clinical aspects of glimepiride, the latest second-generation sulfonylurea for treatment of Type 2 diabetes mellitus (DM). Glimepiride therapy ameliorates the relative insulin secretory deficit found in most patients with Type 2 DM. It is a direct insulin secretagogue; indirectly, it also increases insulin secretion in response to fuels such as glucose. Its action to augment insulin secretion requires binding to a high affinity sulfonylurea receptor, which results in closure of ATP-sensitive potassium channels in the beta-cells of the pancreas. The question has been raised whether insulin secretagogues by acting on vascular or myocardial potassium channels may prevent ischaemic preconditioning, a physiological adaptation that could affect the outcome of coronary heart disease, but there is evidence against this concern being applicable to glimepiride. Glimepiride's antihyperglycaemic efficacy is equal to other secretagogues. It has pharmacokinetic properties that make it less prone to cause hypoglycaemia in renal dysfunction than some other insulin secretagogues, particularly glyburide (also known as glibenclamide in Europe). Its convenient once daily dosing may enhance compliance for diabetic patients who often also require medications for other co-morbid conditions, such as hypertension, hyperlipidaemia and cardiac disease. Glimepiride is approved for monotherapy, for combination with metformin and with insulin. Clinically, its reduced risk of hypoglycaemia makes it preferable to some other insulin secretagogues when attempting to achieve recommended glycaemic control (haemoglobin A(1c) (HgbA(1c)) 7%). Using suppertime neutral protamine Hagedorn (NPH) and regular insulin with morning glimepiride in overweight diabetic patients achieves glycaemic goals more quickly than insulin alone and with lower insulin doses.
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PMID:Clinical review of glimepiride. 1133 17


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