UMLS:C0011849 - FACTA Search

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Query: UMLS:C0011849 (diabetes)
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Dichloroacetate (DCA) represents a potentially novel class of oral antidiabetic agents that reduce blood glucose and lipids without stimulating insulin secretion. DCA reduces blood glucose by inhibiting hepatic glucose synthesis and stimulating glucose clearance and use by peripheral tissues. A major site of action of the drug is pyruvate dehydrogenase (PDH), the rate-limiting enzyme of aerobic glucose oxidation. Stimulation of PDH by DCA increases peripheral oxidation of alanine and lactate, thereby interrupting the Cori and alanine cycles and reducing the availability of three-carbon precursors for gluconeogenesis. In experimental models of ketosis, DCA reduces ketonemia and ketonuria while significantly lowering blood glucose. DCA inhibits hepatic triglyceride and cholesterol biosynthesis. Short-term studies in patients with non-insulin-dependent diabetes have demonstrated a capacity of the drug to markedly reduce circulating a very-low-density lipoprotein cholesterol and triglyceride concentrations. In genetic models of insulin-dependent diabetes, oral administration of DCA significantly reduces insulin requirements and blood levels of glucose and triglycerides. Several derivatives of DCA have been synthesized and found to have biological activity in animals. Further work is required to determine whether DCA and its analogues may be safe and effective agents for chronic treatment of the carbohydrate and lipid abnormalities of human diabetes.
Diabetes Care 1992 Jun
PMID:Dichloroacetate. 160 Aug 37

To investigate the effects of carnitine on insulin sensitivity in non-insulin-dependent diabetes, insulin-mediated glucose disposal was measured in nine diabetic patients (age 54 +/- 3 years, BMI 27 +/- 1 kg/mq) during a primed (3 mmol) constant (1.7 mumol/min) intravenous infusion of carnitine. In control experiments, the same patients received saline instead of carnitine. Plasma glucose concentration was maintained constant at the level of 100 mg/dl during both studies while plasma insulin was raised to a plateau of 60 microU/ml. Despite similar insulin levels, whole-body glucose utilization was higher with carnitine (4.05 +/- 0.37 mg/kg/min) than saline infusion (3.52 +/- 0.36). Blood lactate concentrations were similar in the basal state and decreased significantly during carnitine infusion (P less than 0.05-0.005), whereas it remained substantially unchanged during saline infusion. Plasma FFA decreased to a similar level (0.1 mmol/l) in both studies. We conclude that an acute carnitine administration is able to improve insulin sensitivity in NIDDM patients. The lactate data suggest that this effect may at least in part be mediated by carnitine activation of pyruvate dehydrogenase.
Diabetes Res Clin Pract 1991 Dec
PMID:Carnitine improves peripheral glucose disposal in non-insulin-dependent diabetic patients. 177 12

It has been hypothesized that the androgens testosterone and dehydroepiandrosterone (DHEA) may have opposing actions on insulin sensitivity. To test this hypothesis, we selected patients with polycystic ovary syndrome (PCO) and hypertestosteronemia and a group of individuals with adrenal hyperplasia (AH) and elevated DHEA and studied their 1) insulin and glucose responses to a 75-g oral glucose tolerance test, 2) insulin resistance by hypoglycemic responses to a standard dose of intravenous (IV) insulin, and 3) insulin binding and pyruvate dehydrogenase (PDH) responsiveness to insulin in phytohemagglutinin (PHA)-activated T lymphocytes. PCO patients exhibited elevated basal and glucose-challenged insulin levels and had blunted hypoglycemic responses to IV insulin. Conversely, AH patients had hypoglycemic responses to IV insulin significantly greater than and basal and glucose-challenged insulin levels lower than the PCO patients and weight-matched control subjects. In vitro, T-lymphocyte insulin binding of the PCO patients was 40-60% below control values; in AH patients, insulin binding and PDH insulin sensitivity were above those of the control subjects. Testosterone levels in all study subjects were negatively correlated to T-lymphocyte insulin binding and positively correlated to basal insulin, insulin area under the curve (AUC), and insulin-glucose indices. DHEA levels were positively correlated to insulin binding and inversely related to basal insulin, insulin AUC, and insulin-glucose indices. In all instances, the parameters of insulin sensitivity were more strongly correlated to individuals' ratios of DHEA to testosterone than to either of these androgens alone.(ABSTRACT TRUNCATED AT 250 WORDS)
Diabetes 1991 Jun
PMID:Opposing actions of dehydroepiandrosterone and testosterone on insulin sensitivity. In vivo and in vitro studies of hyperandrogenic females. 182 39

To determine the dose-response characteristics of impaired glucose oxidation in non-insulin-dependent diabetes mellitus (NIDDM), indirect calorimetry was performed on eight matched control and NIDDM subjects during the basal state and during three glucose clamps at insulin infusion rates of 150, 300, and 1,500 pmol.m-2.min-1. Hyperglycemia was used to achieve matched rates of glucose uptake at each insulin infusion. Glucose uptake in the basal state was greater in NIDDM [3.75 +/- 0.23 vs. 2.50 +/- 0.10 mg.kg fat-free mass (FFM)-1.min-1, P less than 0.005] but was similar at approximately 8, 12, and 26 mg.kg FFM-1.min-1 at each insulin infusion. Basal protein oxidation, fat oxidation, and plasma free fatty acids were similar and equally sensitive to suppression by insulin in both groups. Glucose oxidation was reduced 20-26%, and circulating lactate increased 50-90% at physiological but not at pharmacological insulin concentrations in NIDDM. The dose-response relationship between serum insulin and glucose oxidation was right shifted in NIDDM with half-maximal activation at 368 +/- 91 vs. 179 +/- 27 pM in controls (P less than 0.05). In conclusion, glucose oxidation is reduced at physiological insulin concentrations in NIDDM and cannot be explained by concomitant obesity, increased fat oxidation, or reduced glucose uptake but results from impaired sensitivity to stimulation by insulin, possibly at pyruvate dehydrogenase.
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PMID:Dose-response characteristics of impaired glucose oxidation in non-insulin-dependent diabetes mellitus. 185 69

Increased nonesterified fatty acid (NEFA) levels may be important in causing insulin resistance in skeletal muscles in patients with non-insulin-dependent diabetes mellitus (NIDDM). The acute effect of the antilipolytic nicotinic acid analogue Acipimox (2 X 250 mg) on basal and insulin-stimulated (3 h, 40 mU/m2 per min) glucose metabolism was therefore studied in 12 patients with NIDDM. Whole-body glucose metabolism was assessed using [3-3H]glucose and indirect calorimetry. Biopsies were taken from the vastus lateralis muscle during basal and insulin-stimulated steady-state periods. Acipimox reduced NEFA in the basal state and during insulin stimulation. Lipid oxidation was inhibited by Acipimox in all patients in the basal state (20 +/- 2 vs. 33 +/- 3 mg/m2 per min, P less than 0.01) and during insulin infusion (8 +/- 2 vs. 17 +/- 2 mg/m2 per min, P less than 0.01). Acipimox increased the insulin-stimulated glucose disposal rate (369 +/- 49 vs. 262 +/- 31 mg/m2 per min, P less than 0.01), whereas the glucose disposal rate was unaffected by Acipimox in the basal state. Acipimox increased glucose oxidation in the basal state (76 +/- 4 vs. 50 +/- 4 mg/m2 per min, P less than 0.01). During insulin infusion Acipimox increased both glucose oxidation (121 +/- 7 vs. 95 +/- 4 mg/m2 per min, P less than 0.01) and nonoxidative glucose disposal (248 +/- 47 vs. 167 +/- 29 mg/m2 per min, P less than 0.01). Acipimox enhanced basal and insulin-stimulated muscle fractional glycogen synthase activities (32 +/- 2 vs. 25 +/- 3%, P less than 0.05, and 50 +/- 5 vs. 41 +/- 4%, P less than 0.05). Activities of muscle pyruvate dehydrogenase and phosphofructokinase were unaffected by Acipimox. In conclusion, Acipimox acutely improved insulin action in patients with NIDDM by increasing both glucose oxidation and nonoxidative glucose disposal. This supports the hypothesis that elevated NEFA concentrations may be important for the insulin resistance in NIDDM. The mechanism responsible for the increased insulin-stimulated nonoxidative glucose disposal may be a stimulatory effect of Acipimox on glycogen synthase activity in skeletal muscles.
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PMID:Effect of the antilipolytic nicotinic acid analogue acipimox on whole-body and skeletal muscle glucose metabolism in patients with non-insulin-dependent diabetes mellitus. 191 78

The present studies were undertaken to determine whether fasting hyperglycemia can compensate for decreased insulin-stimulated glucose disposal, oxidation, and storage in noninsulin-dependent diabetes mellitus (NIDDM) as well as to determine whether hyperglycemia normalizes insulin-stimulated skeletal muscle glycogen synthase and pyruvate dehydrogenase (PDH) activities. To accomplish this, we used the glucose clamp technique with isotopic determination of glucose disposal and indirect calorimetry for measuring the pathways of glucose metabolism, and vastus lateralis muscle biopsies to determine the effects of insulin on glycogen synthase and PDH activities. Nine patients with NIDDM and eight matched non-diabetic subjects were infused with insulin (40 mU/m2.min) while plasma glucose was maintained at the prevailing fasting concentration. During insulin infusion, rates of glucose disposal, storage, and oxidation were the same in the two groups. Insulin infusion significantly activated glycogen synthase fractional velocity to the same extent in NIDDM (0.210 +/- 0.056 vs. 0.332 +/- 0.079) and controls (0.192 +/- 0.036 vs. 0.294 +/- 0.050). Insulin infusion increased PDH fractional velocity in controls (from 0.281 +/- 0.022 to 0.404 +/- 0.038), but not in NIDDM (from 0.356 +/- 0.043 to 0.436 +/- 0.060), although the activity of PDH during insulin infusion did not differ between the groups. We conclude that prevailing fasting hyperglycemia normalizes the nonoxidative and oxidative pathways of insulin-stimulated glucose in metabolism in NIDDM and may act as a homeostatic mechanism to normalize muscle glucose metabolism.
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PMID:Fasting hyperglycemia normalizes oxidative and nonoxidative pathways of insulin-stimulated glucose metabolism in noninsulin-dependent diabetes mellitus. 212 78

The diminished ability of insulin to promote glucose disposal and storage in muscle has been ascribed to impaired activation of glycogen synthase (GS). It is possible that decreased glucose storage could occur as a consequence of decreased glucose uptake, and that GS is impaired secondarily. Muscle glucose uptake in 15 diabetic subjects was matched to 15 nondiabetic subjects by maintaining fasting hyperglycemia during infusion of insulin. Leg muscle glucose uptake, glucose oxidation (local indirect calorimetry), release of glycolytic products, and muscle glucose storage, as well as muscle GS and pyruvate dehydrogenase (PDH) were determined before and during insulin infusion. Basal leg glucose oxidation and PDH were increased in the diabetics. Insulin-stimulated leg glucose uptake in the diabetics (8.05 +/- 1.41 mumol/[min.100 ml leg tissue]) did not differ from controls (5.64 +/- 0.37). Insulin-stimulated leg glucose oxidation, nonoxidized glycolysis, and glucose storage (2.48 +/- 0.27, 0.68 +/- 0.15, and 5.04 +/- 1.34 mumol/[min.100 ml], respectively) were not different from controls (2.18 +/- 0.12, 0.62 +/- 0.16, and 2.83 +/- 0.31). PDH and GS in noninsulin-dependent diabetes mellitus (NIDDM) were also normal during insulin infusion. When diabetics were restudied after being rendered euglycemic by overnight insulin infusion, GS and PDH were reduced compared with hyperglycemia. Thus, fasting hyperglycemia is sufficient to normalize insulin-stimulated muscle glucose uptake in NIDDM, and glucose is distributed normally to glycogenesis and glucose oxidation, possibly by normalization of GS and PDH.
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PMID:Hyperglycemia normalizes insulin-stimulated skeletal muscle glucose oxidation and storage in noninsulin-dependent diabetes mellitus. 212 90

Interleukin-1 beta (IL-1 beta) has been implicated in the pathogenesis of insulin-dependent diabetes mellitus. In the present study we have investigated the effects of IL-1 beta on glucose metabolism in clonal HIT-T15 beta cells. In the short-term (1 h), 25 U/ml IL-1 beta significantly increased the rates of insulin release and glucose utilisation, but not glucose oxidation. In contrast, after 48 h, IL-1 beta inhibited insulin release and glucose utilisation and oxidation. By assaying enzymes (hexokinase, glucokinase, pyruvate dehydrogenase, glucose 6-phosphatase) and nucleotides (ATP, ADP) associated with the regulation of glycolysis and glucose oxidation, we conclude that the inhibitory effects of IL-1 beta may be due to impaired glucokinase activity.
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PMID:Interleukin-1 beta inhibits glucokinase activity in clonal HIT-T15 beta-cells. 219 15

Lactic acidosis is a relatively frequent acid-base disorder in a hospital setting. It is defined by the association of an arterial pH inferior to 7.35 and an arterial lactate level superior to 5 mmol/l. Classically, 2 types of acidosis are distinguished on the basis of their mechanisms of onset: the type A, with evident clinical signs of tissue hypoperfusion and the type B, more are, without apparent hypoxia. This last category is observed in various circumstances such as diabetes, acute liver failure, poisoning and, more rarely, inborn errors of carbohydrate metabolism. Treatment aims primarily at the correction of the cause. The efficacy of sodium bicarbonate is presently debated, considering the risk to worsen hyperlactatemia and to induce hyperosmolarity or rebound alkalosis. The administration of dichloroacetate, an activator of pyruvate dehydrogenase, permits to correct partially the lactic acidosis but is not harmless especially in case of prolonged administration. Other therapeutic modalities are evoked. Arterial lactate level is a reliable prognostic index of shock, because blood values do not depend only of the oxygen debt but also of the efficacy of hepatic and renal lactate uptake. Sequential measurements are recommended.
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PMID:[Lactic acidosis and hyperlactatemia]. 223 2

The chronic use of dichloroacetate (DCA) for diabetes mellitus or hyperlipoproteinemias has been compromised by neurologic and other forms of toxicity. DCA is metabolized to glyoxylate, which is converted to oxalate and, in the presence of adequate thiamine levels, to other metabolites. DCA stimulates the thiamine-dependent enzymes pyruvate dehydrogenase and alpha-ketoacid dehydrogenase. We postulated that the neurotoxicity from chronic DCA administration could result from depletion of body thiamine stores and abnormal metabolism of oxalate, a known neurotoxin. For 7 weeks, rats were fed ad lib. Purina chow and water or chow plus sodium DCA (50 mg/kg or 1.1 g/kg) in water. A portion of the DCA-treated animals also received intraperitoneal injections of 600 micrograms thiamine three times weekly or 600 micrograms thiamine daily by mouth. Thiamine status was assessed by determining red cell transketolase activity and, in a blinded manner, by recording the development of clinical signs known to be associated with thiamine deficiency. At the 50 mg/kg dose, chronic administration of DCA showed no clinical toxicity or effect on transketolase activity. At the 1.1 g/kg dose, however, DCA markedly increased the frequency and severity of toxicity and decreased transketolase activity 25%, compared to controls. Coadministration of thiamine substantially reduced evidence of thiamine deficiency and normalized transketolase activity. Inhibition of transketolase by DCA in vivo was not due to a direct action on the enzyme, however, since DCA, glyoxylate, or oxalate had no appreciable effects on transketolase activity in vitro. After 7 weeks, plasma DCA concentrations were similar in rats receiving DCA alone or DCA plus thiamine, while urinary oxalate was 86% above control in DCA-treated rats but only 28% above control in DCA plus thiamine-treated animals. No light microscopic changes were seen in peripheral nerve, lens, testis, or kidney morphology in either DCA-treated group, nor was there disruption of normal sperm production in the DCA-treated group. We conclude that stimulation by DCA of thiamine-requiring enzymes may lead to depletion of total body thiamine stores and to both a fall in transketolase activity and an increase in oxalate accumulation in vivo. DCA neurotoxicity may thus be due, at least in part, to thiamine deficiency and may be preventable with thiamine treatment.
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PMID:Chronic toxicity of dichloroacetate: possible relation to thiamine deficiency in rats. 231 57

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