Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: UMLS:C0020473 (hyperlipidemia)
15,891 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Two main classes of oral hypoglycaemic drugs, the sulphonylureas and the biguanides, are currently used in the therapy of type II, non-insulin-dependent diabetes mellitus (NIDDM). The basic pharmacokinetic properties of these agents are discussed with a view to efficient and safe treatment. Both first- and second-generation sulphonylureas are rapidly absorbed from the gastrointestinal tract. In the plasma compartment, these drugs are strongly bound to serum proteins. All sulphonylureas are metabolised in the liver, and the metabolites and the parent drugs are eliminated mainly in the urine, but also (second-generation derivatives) in the faces. Rapid- and short-acting sulphonylureas may improve early insulin release and promote better postprandial glucose control. Long-acting derivatives may ensure better control of overnight glycaemia. The elderly are at risk of developing severe sulphonylurea-induced hypoglycaemia, and in this population the agent chosen should have a short or intermediate duration of action and no active metabolites. Caution is needed when prescribing any sulphonylurea in patients receiving drugs known to affect sulphonylurea action, and in those with impaired liver and/or kidney function. The bioavailability of the biguanides ranges from 40 to 60%. Binding to plasma proteins is absent or very low. Metformin and buformin are not metabolised and are excreted in the urine; phenformin undergoes hepatic hydroxylation and is excreted in both urine and faeces. Metformin is the only agent of this class currently recommended for clinical use. The main indications of metformin treatment are NIDDM associated with obesity and/or hyperlipidaemia, and in combination with sulphonylurea both as primary treatment and when secondary failure occurs with sulphonylurea alone. Lactic acidosis may develop in patients receiving therapy with biguanides, especially in the presence of a preexisting contraindication to their use.
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PMID:Pharmacokinetic optimisation of oral hypoglycaemic therapy. 176 Sep 2

A 31-year-old male patient with type Ia glycogen storage disease was admitted to our department complaining of general fatigue and right hypochondriac pain. He exhibited massive hepatomegaly with systemic hypoglycemia, lactic acidosis, hyperuricemia, hyperpyruvatemia and hyperlipemia. The failure of blood glucose levels to increase after a glucagon loading test, and a reduced lactate level on glucose tolerance test were also observed. Various imaging techniques suggested hepatic adenoma with hemorrhage in the tumor, which was confirmed histologically. There was a complete absence of glucose 6-phosphatase activity, as determined by an enzyme assay on resected liver specimens, which proved the case to be type Ia glycogen storage disease. We also reviewed all previously reported cases of hepatic tumor and glycogen storage diseases. We conclude that, since hepatic adenoma is not rare in this disease, and is complicated by hemorrhage, rupture and malignancy, careful follow-ups are necessary.
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PMID:A case of type Ia glycogen storage disease complicated by hepatic adenoma. 217 Feb 59

Dichloroacetate (DCA) reduces blood glucose, lactate and lipids in diabetes or during fasting. Chronic use of DCA, however, is limited by toxicity, probably due in part to its rapid conversion to oxalate in vivo. In theory, therefore, DCA's efficacy may be retained and its toxicity minimized by controlling its rate of metabolism. We attempted to alter DCA pharmacokinetics and bioavailability by synthesizing various derivatives comprising DCA esters with polyols and DCA ionic complexes. Twenty-four hour fasted, nondiabetic rats received single, orogastric doses of saline (control) sodium DCA (100mg/kg) or the following derivatives (D1-4): the esters D1-D3: potassium tetra (dichloroacetyl) glucuronate (D1), inositol-monophosphate-tetradichloroacetate (D2), inositol-hexadichloroacetate (D3) and inositol-hexa [N-methylnicotinate] hexadichloroacetate salt (D4). Each derivative was administered at a dose that would ultimately provide 100 mg/kg DCA as the anion. All derivatives were orally effective in significantly decreasing blood glucose and lactate. D4 exerted the most potent and long-lasting glucose- and lactate-lowering effects, yet increased plasma DCA concentrations less than an equivalent dose of the sodium salt. When administered to reverse light-cycled rats, D4 markedly inhibited the incorporation of tritiated water into cholesterol and triglycerides. We conclude that derivatives of DCA retain the biological activity of the parent compound, but may exhibit different pharmacokinetics. They may eventually prove useful in the treatment of diabetes mellitus, hyperlipidemia and lactic acidosis in man.
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PMID:Dichloroacetate derivatives. Metabolic effects and pharmacodynamics in normal rats. 366 16

Effects of fructose feeding in moderate amounts on lipid metabolism of obese versus lean, and diabetic versus nondiabetic Zucker rats, were studied. Forty pairs of male lean and obese animals were assigned to two dietary groups, fructose and glucose. For each diet, one-half of lean and obese animals were injected with streptozotocin intraperitoneally (i.p.) to induce diabetes, and the other half were injected with buffer i.p. as a nondiabetic control group. After 9 wk of feeding, animals were fasted overnight, decapitated and exsanguinated. Organs were removed and weighed. Blood glucose, insulin, lactic acid, triglycerides, cholesterol, total liver lipids and urinary glucose were determined. Hyperphagia was observed in obese, non-diabetic and lean-diabetic animals. Streptozotocin injection drastically reduced insulin levels, and produced an impairment of growth, hyperglycemia, glucosuria, polydipsia and polyuria. Fructose feeding increased organ weights in kidney, liver and retroperitoneal adipose tissue, regardless of diabetic state. However, lactic acid levels were lower in fructose-fed groups than glucose-fed groups. In obese rats serum triglyceride levels were also lower in fructose-fed groups than in glucose-fed groups. Serum cholesterol was not affected by fructose feeding. The results indicated that fructose feeding did not produce hyperlipemia and lactic acidosis in the blood circulation in Zucker rats. However, fructose feeding did not improve glucose intolerance in diabetic animals, rather fructose feeding produced hyperinsulinemia in nondiabetic, obese animals.
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PMID:Effects of fructose feeding on lipid parameters in obese and lean, diabetic and nondiabetic Zucker rats. 390 Mar 13

1. GSD-I is described in a child with partial deficiency of hepatic glucose-6-phosphatase. 2. Growth retardation and hepatosplenomegaly were major clinical features. 3. Hyperlipidaemia, lactic acidaemia, hyperuricaemia and reduced uric acid clearance were major biochemical findings. 4. Although the glucose response to glucagon and galactose was impaired, there was a striking absence of hypoglycaemia which may be attributable to residual catalytic activity of the enzyme. 5. Preliminary studies of the crude liver enzyme showed it to have a normal pH inactivation profile and apparent Km with a reduced Vmax. 6. No evidence of increased PP-ribose-P availability in fresh liver tissue was detected. 7. Continuous glucose feeding resulted in accelerated growth without complete correction of lactic acidosis or hyperuricaemia. 8. GSD-I with partial deficiency of hepatic glucose-6-phosphatase should be considered in patients with gout or hyperuricaemia associated with hypertriglyceridaemia and lactic acidaemia even in the absence of hypoglycaemia.
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PMID:Clinical and enzymological studies in a child with type I glycogen storage disease associated with partial deficiency of hepatic glucose-6-phosphatase. 615 47

Type IB Glycogen storage disease (GSD) is a new variant of type I Glycogen storage disease. It is characterized by same clinical findings: hepatomegaly, fasting hypoglycemia, hyperlipidemia, hyperuricemia, lactic acidosis, renal enlargement, short stature; but it distinguish for normal glucose-6-phosphatase hepatic activity in vitro. The involvement is in G-6-P transport system. Recently has been described in some patients with GSD IB, neutropenia and defective neutrophil mobility. In this report the authors described two family cases of GDS IB that one characterized by severe neutropenia.
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PMID:[Neutropenia in glycogenesis I B]. 659 20

Individuals with type Ia glycogen storage disease (glucose-6-phosphatase deficiency) frequently develop hepatic adenomas. Potential complications involving these adenomas include malignant transformation and hemorrhage. Five of 9 patients with this disease had evidence of hepatic filling defects on radionucleotide liver scan when first evaluated at our hospital. Dietary therapy aimed at preventing hypoglycemia was begun in 7 of the 9 patients. Prevention of hypoglycemia resulted in the correction of all of the metabolic abnormalities (lactic acidosis, hyperlipidemia, hyperuricemia, and growth retardation). Treatment also corrected the marked elevation in plasma glucagon concentrations. A disappearance of the hepatic lesions occurred in 2 of the treated patients, and a marked reduction in size of the adenoma occurred in the third patient. The hepatic filling defects remained present in the two untreated patients. None of the affected patients receiving dietary therapy have developed hepatic adenomas. One of these patients is now 22 yr old and has received dietary therapy for 7 yr. Early dietary therapy seems to be effective in preventing development of adenomas as well as inducing their resolution.
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PMID:Regression of hepatic adenomas in type Ia glycogen storage disease with dietary therapy. 694 8

Type 2 diabetes mellitus results from impaired insulin secretion and reduced peripheral insulin sensitivity. Treatment options include diet, oral antihyperglycemic agents, and insulin. Metformin, an oral biguanide, ameliorates hyperglycemia by improving peripheral sensitivity to insulin, and reducing gastrointestinal glucose absorption and hepatic glucose production. Unlike sulfonylureas, it does not stimulate insulin secretion, aggravate hyperinsulinemia, or cause hypoglycemia or weight gain (weight stabilizes or decreases). It also has beneficial effects on serum lipid profiles. In lean or overweight type 2 diabetic patients uncontrolled by diet, metformin monotherapy significantly improves glycemic control, compared with placebo, and to similar extents as sulfonylurea monotherapy. In secondary sulfonylurea failure, combination metformin-sulfonylurea treatment significantly improves glycemic control beyond that achieved with either agent along. Metformin-sulfonylurea also appears to be as effective as insulin or insulin plus sulfonylurea, suggesting that such combination therapy may obviate or substantially delay insulin therapy. Limited data suggest that metformin-insulin therapy may improve glycemic control, possibly reducing insulin requirements, in type 2 diabetic patients uncontrolled by insulin alone following secondary sulfonylurea failure. Gastrointestinal side effects are common, but usually tolerated. Lactic acidosis risk is minimal, provided that contraindications, particularly renal impairment, and prescribing guidelines are respected. Aside from elevated plasma metformin levels with cimetidine and synergistic hypoglycemia with sulfonylureas, few interactions occur. Thus, metformin is safe and effective both as monotherapy or in combination with other antihyperglycemic agents in type 2 diabetic patients requiring additional glycemic control and may be advantageous when weight control is desirable and/or hyperlipidemia exists.
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PMID:An overview of metformin in the treatment of type 2 diabetes mellitus. 920 6

In clinical practice, combination antiretroviral therapy is frequently complicated by adverse reactions and drug-related toxicities. The incidence, presentation, differential diagnosis, and management of the most frequent and severe of these complications are discussed. The recently described spectrum of metabolic complications, including hyperlipidemia, fat redistribution, and lactic acidosis, are covered in detail. The management of nephrotoxicity, pancreatitis, bone marrow suppression, peripheral neuropathy, and hypersensitivity reactions related to antiretroviral therapy is also discussed.
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PMID:The management of the clinical complications of antiretroviral therapy. 1114 42

Mutations in the glucose-6-phosphatase (G6Pase) gene are responsible for glycogen storage disease type Ia (GSDIa). This disease is characterized by growth retardation, hepatomegaly, hypoglycemia, hyperlipidemia, and lactic acidosis. In this study, we report mutations in the G6Pase gene in 8 of 25 Brazilian patients with clinical symptoms of GSDIa. Five previously described mutations (R83C, Q347X, V338F, D38V, and G68R) were detected. The two most common mutations identified were R83C and Q347X, accounting for 8 of 14 (57.14%) mutant alleles. A 1,176 single-nucleotide polymorphism and two intronic mutations (IVS3-58T>A and IVS4+10G>A) were also analyzed. We used the minigene strategy in order to verify the effect of these intronic mutations on the splicing mechanism. This study emphasizes that molecular genetic analysis is a reliable and convenient alternative to the assay of enzyme activity in a fresh liver biopsy specimen for diagnosing GSDIa.
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PMID:Glycogen storage disease type Ia: molecular study in Brazilian patients. 1131 May 82


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