UMLS:C0242339 - FACTA Search

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Query: UMLS:C0242339 (dyslipidemia)
13,927 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Hypertension and diabetes appear to increase coronary heart disease risk in part by causing an abnormality in lipid metabolism. Most affected are patients with familial dyslipidemic hypertension (FDH) and noninsulin-dependent diabetes mellitus (NIDDM). The lipid disorders most often encountered in these patients are increased levels of triglycerides, very low-density lipoprotein (VLDL) cholesterol, and small, dense low-density lipoprotein (LDL) cholesterol, and low levels of high-density lipoprotein (HDL) cholesterol. These abnormalities appear to result from increased hepatic secretion of VLDL particles due to increased concentrations of free fatty acids and glucose, reduced VLDL clearance due to reduced activity of lipoprotein lipase, and reduced LDL clearance due to glycosylation of ligand proteins. Treatment of the dyslipidemia associated with FDH should follow the guidelines from the National Cholesterol Education Program. Treatment in men and women with NIDDM should be considered when LDL cholesterol levels are 130 mg/dl or above, triglyceride levels are 200 mg/dl or above, or non-HDL cholesterol levels are 160 mg/dl or greater. Aggressive lifestyle changes should be initiated first, including weight loss in obese patients, control of glucose levels in those with NIDDM, avoidance of antihypertensive drugs that may worsen lipid levels in patients with FDH, and eating a diet restricting saturated fat and cholesterol. Addition of lipid-altering drugs should be considered if such changes do not achieve effective lipid control. The agent should be tailored to the patient's lipid profile, in general by using bile acid resins, niacin, or reductase inhibitors to lower LDL cholesterol and gemfibrozil or niacin to lower triglycerides. Niacin should be avoided in patients with NIDDM.
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PMID:Understanding and treating dyslipidemia associated with noninsulin-dependent diabetes mellitus and hypertension. 836 60

Dyslipidaemia may be treated with a number of safe and effective pharmacological agents that target specific lipid disorders through a variety of mechanisms. The bile-acid sequestrants--cholestyramine and colestipol--primarily decrease LDL cholesterol by binding bile acids, thereby decreasing intrahepatic cholesterol, and by increasing the activity of LDL receptors. Nicotinic acid lowers LDL cholesterol and triglyceride by decreasing VLDL synthesis and by decreasing free fatty acid mobilization from peripheral adipocytes. The HMG-CoA reductase inhibitors--fluvastatin, lovastatin, pravastatin and simvastatin--lower LDL cholesterol by partially inhibiting HMG-CoA reductase (the rate-limiting enzyme of cholesterol biosynthesis) and by increasing the activity of LDL receptors. The fibric-acid derivatives--bezafibrate, ciprofibrate, clofibrate, fenofibrate and gemfibrozil--primarily decrease triglyceride by increasing lipoprotein lipase activity and by decreasing the release of free fatty acids from peripheral adipose tissue. Probucol decreases LDL cholesterol by increasing non-receptor-mediated LDL clearance; as an anti-oxidant, probucol also decreases LDL oxidation; oxidized LDL which is thought to lead to atherogenesis. Although these agents have been proven safe in clinical trials, like any drug, they carry the risk for adverse effects. The bile-acid sequestrants may cause constipation, reflux oesophagitis, and dyspepsia, and may bind coadministered medications such as digitalis glycosides, beta blockers, warfarin, and exogenous thyroid hormone. Nicotinic acid use is commonly associated with flushing and pruritus and may also cause non-specific gastrointestinal complaints, hepatotoxicity (hepatic necrosis, hepatitis, or elevated liver enzymes), gout, myolysis, decreased glucose tolerance and increased fasting glucose levels, and ophthalmological complications including decreased visual acuity, toxic amblyopia, and cystic maculopathy. The HMG-CoA reductase inhibitors may produce liver enzyme elevations, creatine kinase elevations and rhabdomyolysis. The combination of a reductase inhibitor and a fibrate increases the risk for rhabdomyolysis. Possible adverse effects of the fibric-acid derivatives include abdominal discomfort, nausea, flatulence, increased lithogenicity of bile, liver enzyme elevations and creatine kinase elevations. Probucol may increase the QTc interval and may cause non-specific gastrointestinal complaints.
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PMID:Currently available hypolipidaemic drugs and future therapeutic developments. 859 27

Niacin has been used for many years to treat hyperlipidemia. It has been shown to reduce coronary death and non-fatal myocardial infarction and, in a separate analysis of long-term (15-year) follow-up, all cause mortality. It reduces total cholesterol, low density lipoprotein cholesterol (LDL-C) and triglycerides and increases high density lipoprotein cholesterol (HDL-C). Sustained-release niacin may be associated with more dramatic changes in LDL-C and triglyceride, whereas the short acting preparation causes greater increases in HDL-C. The increase of HDL-C occurs at a lower dose (1500 mg/day) than the reduction of LDL-C (> 1500 mg/day). Niacin also favorably influences other lipid parameters including lipoprotein(a) [Lp(a)], alimentary lipemia, familial defective apolipoprotein B-100 and small dense LDL. Combination of niacin with a bile acid sequestrant or a reductase inhibitor represents a powerful lipid-altering regimen. Whereas the reductase inhibitors and bile acid binding resins primarily affect LDL-C, the combined therapy has a synergistic effect to reduce LDL-C and, in addition, the niacin reduces triglycerides and increases HDL-C. The major drawback in the use of niacin is associated side effects (flushing and palpitations) and toxicity (worsening of diabetes control, exacerbation of peptic ulcer disease, gout, hepatitis). Niacin has a long history of use as a lipid lowering agent and has several attractive features. Unfortunately, the side effect profile of this agent warrants its use only in patients with marked dyslipidemia in whom side effects and potential toxicity are closely monitored.
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PMID:New developments in the use of niacin for treatment of hyperlipidemia: new considerations in the use of an old drug. 885 85

Niacin (nicotinic acid) in large doses (> 2 g) has been increasingly the choice of lipid-lowering agent by clinicians. However, the potential risks of the use of high doses of the vitamin have not been critically considered in the same way as has the use of other lipid-lowering drugs. The present study provides evidence that pharmacological levels of niacin interfere with the metabolism of methionine, leading to hyperhomocysteinemia and hypocysteinemia. Male Sprague-Dawley rats were fed a semisynthetic diet supplemented with either 400 or 4000 mg niacin/kg (compared with 47 mg/kg diet in the control diet). In Experiment 1, feeding these diets for 3 wk resulted in a dose-related increase in the plasma and urine methionine concentrations while cysteine levels were decreased. This altered methionine metabolism was accompanied by a lower plasma vitamin B-6 concentration in niacin-supplemented rats compared with controls. In Experiment 2, the methionine and cysteine levels in plasma and urine were normalized when vitamin B-6 (10 mg/kg diet) was added to the diet containing 4000 mg niacin/kg and fed for 6 wk. This experiment also showed that plasma and urine homocysteine concentrations were increased by niacin and normalized by vitamin B-6. The hypolipidemic action of niacin was unaffected by the presence of vitamin B-6. These results indicate that niacin at large dosages interferes with methionine metabolism by affecting vitamin B-6 status. The treatment of dyslipidemia with simultaneous administration of niacin and vitamin B-6 could be a better therapy than the use of niacin alone.
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PMID:Vitamin B-6 normalizes the altered sulfur amino acid status of rats fed diets containing pharmacological levels of niacin without reducing niacin's hypolipidemic effects. 904 May 54

Non-insulin-dependent diabetes mellitus (NIDDM) is associated with approximately two fold increase in coronary heart disease (CHD) in men and fourfold increase in CHD in women. In most studies, the duration of diabetes and severity of glycemia are only weakly related to CHD in NIDDM, suggesting that the prediabetic period may be important for the increased CHD in NIDDM subjects. Both hyperinsulinemia and/or insulin resistance predict the development of NIDDM. A number of studies have shown that increased cardiovascular risk factors (especially high triglyceride, blood pressure, and small dense low-density lipoprotein (LDL) and low high-density liproprotein (HDL) cholesterol) precede the onset of NIDDM. Recent data from the San Antonio Heart Study suggest that the atherogenic pattern of cardiovascular risk factors is more marked in prediabetic women than in prediabetic men, thus partially explaining the higher risk of CHD in prediabetic women than in prediabetic men. The atherogenic changes in cardiovascular risk factors appear to be mainly due to increased hyperinsulinemia and insulin resistance in nondiabetic subjects. Interventions to reduce cardiovascular disease in NIDDM subjects should emphasize the primary prevention of NIDDM and very aggressive treatment of traditional cardiovascular risk factors in prediabetic subjects. Treatment of hypertension and dyslipidemia in high-risk patients for NIDDM should avoid agents that further worsen insulin resistance (nicotinic acid, beta blockers, and thiazides), as subjects with hypertension and dyslipidemia are already at increased risk of NIDDM.
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PMID:The prediabetic problem: development of non-insulin-dependent diabetes mellitus and related abnormalities. 910 90

Patients with diabetes mellitus have an increased risk for coronary artery disease due to hyperglycemia, hypertension, dyslipidemia, and other risk factors. The diabetic dyslipidemia in these patients is characterized by moderately high levels of (1) serum cholesterol and triglycerides; (2) small, dense low-density lipoprotein (LDL) particles; and (3) low high-density lipoprotein (HDL) cho-lesterol concentrations. Recent clinical trials have demonstrated the benefits of cholesterol-lowering therapy in both diabetic and nondiabetic patients, thus supporting aggressive treatment of diabetic dyslipidemia for coronary artery disease prevention. A 3-step approach is recommended for the treatment of diabetic dyslipidemia. First, modification of diet and lifestyle, including decreased intakes of cholesterol, cholesterol-raising fats, and total energy, and increased physical activity should be advised. Second, good glycemic control should be achieved with diet and hypoglycemic drugs, if needed. Third, lipid-lowering drugs should be used, if necessary. Non-HDL cholesterol levels, which include both very-low-density lipoprotein (VLDL) and LDL cholesterol, should be the target of cholesterol-lowering therapy. The use of 3-hydroxy-3-methylglutaryl coenzyme A reductase inhibitors (the "statins") has become the first-line drug therapy for diabetic dyslipidemia. Bile acid sequestrants are effective cholesterol-lowering agents in normotriglyceridemic patients with non-insulin-dependent diabetes mellitus (NIDDM). Patients with severe hypertriglyceridemia may require fibric acids or n-3 polyunsaturated fatty acids. Nicotinic acid worsens hyperglycemia; therefore, it should be avoided in most cases. The efficacy and safety of estrogen-replacement therapy in postmenopausal women with diabetes needs to be determined. The combination of two lipid-lowering agents may be appropriate for some NIDDM patients but should be used judiciously.
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PMID:Treatment of diabetic dyslipidemia. 952 14

Marked lowering of plasma total and low-density lipoprotein cholesterol levels that occur during treatment of dyslipidemia with pharmacologic doses of nicotinic acid result from hepatotoxicity. Therefore, a marked reduction in low-density lipoprotein may suggest generalized liver toxicity and drug treatment should be discontinued.
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PMID:Effects of crystalline nicotinic acid-induced hepatic dysfunction on serum low-density lipoprotein cholesterol and lecithin cholesteryl acyl transferase. 952 2

Subjects with diabetes have a greatly increased risk of CHD, which is only partially related to their elevated glucose. Other factors such as insulin resistance and dyslipidemia are likely to be important. The type of dyslipidemia that is most characteristic of type 2 diabetic subjects is elevated triglycerides and decreased HDL cholesterol levels, although all lipoproteins have compositional abnormalities. Surprisingly few good prospective studies of lipoprotein levels in relation to CHD have been done in diabetic subjects. Available studies suggest that low HDL cholesterol may be the most important risk factor for CHD in observational studies. In studies in which total cholesterol and triglyceride were done, cholesterol and triglycerides were risk factors for CHD, although triglycerides were often a stronger predictor. However, the strength of triglyceride as a risk factor for CHD may depend partially on its association with other variables (e.g., hypertension, plasminogen activator inhibitor 1 [PAI-1], etc.). In clinical trials in diabetic subjects, LDL reduction with statins has led to significant reductions in CHD incidence. In addition, overall mortality was reduced with statin therapy, although the results were not statistically significant. Gemfibrozil has led to reductions in CHD incidence in diabetic subjects, although the results were not statistically significant perhaps because of low sample size. Regarding lipoproteins and CHD risk in diabetic patients, the very positive results of statin trials point to LDL cholesterol being more important than previous realized. Apparently, having a borderline high LDL cholesterol (between 130 and 160 mg/dl) in a diabetic patient is equivalent to a much higher LDL cholesterol in terms of CHD risk for a nondiabetic subject. Therefore, the primary target of therapy in diabetic patients is lowering LDL cholesterol (or possibly, non-HDL cholesterol). Statins are the preferred pharmacological agent in this situation. Once LDL cholesterol levels have been lowered, attention can be given to treatment of residual hypertriglyceridemia and low HDL. The goal here is weight reduction and increased exercise. However, for selected patients, combining a fibric acid (or low-dose nicotinic acid) with a statin also can be considered. Reduction of LDL levels should take priority over reduction of triglycerides in combined hyperlipidemia because of the proven safety of the statin class of drugs as well as greater reduction in CHD incidence.
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PMID:Management of dyslipidemia in adults with diabetes. 953 88

The importance of treating dyslipidemias based on cardiovascular risk factors is highlighted by the National Cholesterol Education Program guidelines. The first step in evaluation is to exclude secondary causes of hyperlipidemia. Assessment of the patient's risk for coronary heart disease helps determine which treatment should be initiated and how often lipid analysis should be performed. For primary prevention of coronary heart disease, the treatment goal is to achieve a low-density lipoprotein (LDL) cholesterol level of less than 160 mg per dL (4.15 mmol per L) in patients with only one risk factor. The target LDL level in patients with two or more risk factors is 130 mg per dL (3.35 mmol per L) or less. For patients with documented coronary heart disease, the LDL cholesterol level should be reduced to less than 100 mg per dL (2.60 mmol per L). A step II diet, in which the total fat content is less than 30 percent of total calories and saturated fat is 8 to 10 percent of total calories, may help reduce LDL cholesterol levels to the target range in some patients. A high-fiber diet is also therapeutic. The most commonly used options for pharmacologic treatment of dyslipidemia include bile acid-binding resins, HMG-CoA reductase inhibitors, nicotinic acid and fibric acid derivatives. Other possibilities in selected cases are estrogen replacement therapy, plasmapheresis and even surgery in severe, refractory cases.
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PMID:Management of dyslipidemia in adults. 960 9

Hypolipidemic drugs that are efficacious in man are not always active in classical animal models of dyslipidemia. Inhibitors of HMG-CoA reductase (statins) do not lower plasma cholesterol in rats, but yet this species was alone in providing activity for fibrate-type drugs. Nicotinic acid possesses many desirable features with regard to clinical use, but most of these actions are lacking in rats and monkeys. The metabolism of low density lipoproteins in hamsters is widely thought to be similar to that in humans, yet neither statins or fibrates lower plasma lipids in these species. With the advent of mouse models expressing specific human genes (or disruption of genes) it is now possible to re-examine the effect of established drugs and to characterize new hypolipidemic compounds with respect to site and mechanism of action. Drug responses observed in humans are now being seen in such mouse models (e.g. HDL elevation with fenofibrate in mice with the human apo A-I gene). Moreover, mice are now being screened for compounds that lower plasma (human) Lp(a), or lower plasma cholesterol in the absence of LDL receptors. It is proposed that these new genetic mouse models may afford a more focused examination of drug action and provide, for new compounds, better prediction of the human response.
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PMID:Lack of predictability of classical animal models for hypolipidemic activity: a good time for mice? 973 11

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