UMLS:C0020473 - FACTA Search

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

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

In all patients with coronary heart disease a fasting lipid profile (total cholesterol, LDL cholesterol, HDL cholesterol, triglycerides) should be obtained. Hyperlipidemias can then be classified as hypercholesterolemia (LDL cholesterol elevated), mixed hyperlipidemia (LDL cholesterol elevated, triglycerides elevated) and hypertriglyceridemia (triglycerides elevated). Primary goal of lipid intervention is a LDL cholesterol < 100 mg/dl, secondary goals are HDL cholesterol > 35 mg/dl and triglycerides < 200 mg/dl. These goals can be reached by dietary intervention alone (reduction in fat and modification of fat intake) or in combination with lipid lowering drugs. Monotherapy with HMG-CoA reductase inhibitors or combined therapy with bile acid sequestrants will allow a reduction in LDL cholesterol by more than 50%; in predominant hypertriglyceridemia fibrates or nicotinic acid will lower triglycerides and elevate HDL cholesterol.
...
PMID:[Goals and practical implementation of lipid therapy in coronary heart disease]. 930 97

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.
...
PMID:Management of dyslipidemia in adults with diabetes. 953 88

The aim of the study was to compare efficacy and safety of one-year therapy with slow-release nicotinic acid (KN-SR) and with ordinary form of the acid (KN). The examination was performed in the group of 136 patients with hyperlipidemia-type II. KN-SR had satisfactory effectiveness and was much better tolerated than KN. During one-year treatment with KN-SR there were observed the decrease of total cholesterol (TC) by 18%, LDL-C by 22%, triglycerides by 36%, Lp(a) by 56%, and the increase of HDL-C by 12%. The percentage of skin unwanted signs differed significantly between KN-group (90.2%) and KN-SR group (24%). Hepatotoxic effects were not observed and antipyrine kinetics did not change during one-year treatment with slow-release nicotinic acid.
...
PMID:[Prolonged treatment with slow release nicotinic acid in patients with type II hyperlipidemia]. 959 56

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.
...
PMID:Management of dyslipidemia in adults. 960 9

The paper is aimed at evaluation of the efficacy and safety of one-year therapy with slow-release nicotinic acid (NA-SR). The study involved a group of 30 patients with hyperlipidemia of type II. The concentration of nicotinic acid in serum was determined using capillary electrophoresis. After the placebo period (2 months), NA-SR was applied at the dose of 1.5 g/d (2 months), and subsequently 2-3 g/d (10 months), on average 2.13 g/d. During the treatment with 2.0 g/d dose, the steady-state concentration of NA in serum was within a range of 2.7-4.9 microg/ml and with 3.0 g/d of 6.17-7.75 microg/ml. These doses of the drug were tolerated well and advantageously modified the serum lipids.
...
PMID:Efficacy and safety of one-year treatment with slow-release nicotinic acid. Monitoring of drug concentration in serum. 966 40

According to the NCEP resins and nicotinic acid were selected as drugs of choice to treat hypercholesterolemia. Gemfibrozil and nicotinic acid were recommended for patients with HDL cholesterol below 35 mg/dl. Current concepts of efficacy and side effects lead to the following recommendations. a) type IIa severe hypercholesterolemia (LDL > 220 mg/dl): HGMC inhibitors or combined therapy with resins and nicotinic acid, fenofibrate, or bezafibrate. b) Moderate hypercholesterolemia (LDL < 220 mg/dl): bezafibrate and/or acipimox if HDL is < 35 mg/dl; fenofibrate, bezafibrate and/or acipimox if HDL > 35 mg/dl. As second line drugs, the HGMC inhibitors. c) Type IIb hyperlipidemia: first line, acipimox; second line, fibrates associated to acipimox. d) Type III hyperlipidemia: first line, fibrates; second line, an association of HGMC inhibitors and fibrates or acipimox. e) Type IV moderate hyperlipidemia (TG < 500 mg/dl): first line, acipimox, second line, fibrates alone or in association with acipimox. As general remarks, lovastatin has been effective and well tolerated in 98% of cases. Pravastatin seems to have very little side effects. Acipimox, a nicotinic acid derivative is especially effective in elevating HDL2b levels and decreasing LDL III. Given its adequate tolerance, acipimox has replaced nicotinic acid.
...
PMID:[Pharmacologic treatment of dyslipidemias: Analysis of initiation recommendations and drug selection]. 972 1

Hyperlipidemia (HP) was induced in quails by feeding high lipid food. Effect of tea polyphenol (TP) on development of HP was observed by feeding various dosage of TP simultaneously and was compared with that of nicotinic acid (NA). The results showed: (1) TP could prevent the increase of serum total cholesterol (TC), triglycerides (TG) and low-density lipoprotein cholesterol (LDL-C). Effect of the group treated with large dose of TP was more significant than that treated with NA (P < 0.05). But no statistically significant difference was observed on the changes of TG and LDL-C between TP and NA treated group. (2) No significant change of HDL-C level was observed in both TP groups and NA group, but both of them could inhibit the elevation of atherogenic index (TC/HDL-C), their effects were similar. It suggested that TP might be a regulator of blood lipid.
...
PMID:[Experimental study on tea polyphenols in prevention of hyperlipidemia]. 977 5

Abnormal interaction between low density lipoprotein receptors (LDLR) and their ligands, apolipoprotein E and B, causes decreased catabolism of lipoproteins which carry these apolipoproteins (VLDL, IDL and/or LDL) and thereby increased plasma concentrations of these. In familial hypercholesterolemia (FH), abnormal interaction is due to mutations in the LDLR gene, and in type III hyperlipidemia due to mutations in the apo E gene. A few mutations in the apolipoprotein B (apo B) gene have been described, of which the apo B-3,500Arg-Gln seems by far the most frequent, that causes defective binding to normal LDLR. The metabolic disorder associated with these mutations has been named familial defective apolipoprotein B-100 (FDB). The frequency of the apo B-3,500Arg-Gln mutation is particularly high in Central Europe (Switzerland) with lower frequencies south of the Alpes, in Russia and in Scandinavia. We found an incidence of 1/1250 of the mutation in Denmark (III), employing a DNA based assay optimized to allow detection of the mutation in very small amounts of DNA (I). Since other mutations in the receptor binding domain of the apo B-100 have been described, we developed another DNA based assay, employing DGGE technique, to screen for other mutations in the region of amino acid 3,456 to 3,553 (II). However, no other mutations but the apo B-3,500Arg-Gln have so far been detected in Danish hypercholesterolemic patients. In a study of 5 Danish families with FDB (46 heterozygous FDB patients and 57 unaffected relatives) we found that FDB patients had significantly increased mean cholesterol and LDL cholesterol concentrations, but with a wide range of variation and with approximately 30% having cholesterol concentrations below the 95th percentile for the general population (IV). This was confirmed in a compilation of data on 205 FDB patients from the Netherlands, Germany and Denmark (V). In this study we also compared the biochemical and clinical features of FDB with those of 101 Danish FH patients in whome FDB had been ruled out. Our data support, that the LDL cholesterol elevation is less pronounced in FDB than in FH and that the age-specific prevalence of atherosclerotic cardiovascular disease (CVD) is lower in FDB than in FH. In the compiled study of 205 FDB heterozygotes (V), we found that age, gender and genetic variation in the LDLR gene explained a considerable part of the between-individual variation in total and LDL cholesterol. We conducted a prospective study of the lipid lowering effect of pravastatin and gemfibrozil in 30 Danish FDB patients (VI). Together with other, retrospective, studies, we conclude that the cholesterol lowering effect of HMG-coA-reductase inhibitors, anion binding resins and nicotinic acid is fully comparable to that observed when treating FH patients and type IIa hypercholesterolemic patients, without clinical signs of FH.
...
PMID:Familial defective apolipoprotein B-100. 977 89

The data for an independent association between triglyceride concentrations and risk for coronary artery disease (CAD) are equivocal, unlike the data for low-density lipoprotein (LDL) cholesterol and high-density lipoprotein (HDL) cholesterol, which show strong, consistent, and opposing correlations with CAD risk. There is some evidence for triglyceride as an independent risk factor in certain subgroups, for example, women 50-69 years of age (Framingham Heart Study) and in patients with noninsulin-dependent diabetes. However, the evidence is stronger for triglyceride as a synergistic CAD risk factor. For example, patients with the "lipid triad" of high LDL cholesterol, low HDL cholesterol, and high triglyceride accounted for most of the event reduction with lipid-lowering therapy in the Helsinki Heart Study. An important confounder of the correlation between triglyceride and CAD risk is the heterogeneity of triglyceride-rich lipoproteins: the larger triglyceride-rich particles are thought not to be associated with CAD risk, whereas the smaller (and denser) particles are believed to be atherogenic. At present, measurement of fasting triglyceride levels and triglyceride assessment in conjunction with LDL cholesterol and HDL cholesterol concentrations are the most practical methods of evaluating hypertriglyceridemia in CAD risk, although postprandial lipemia may prove a better indicator of atherogenicity. Management of hypertriglyceridemia should initially focus on nonpharmacologic therapy (i.e., diet, exercise, weight control, and alcohol reduction). In diabetic patients, meticulous glycemic control is also important. However, if this approach proves inadequate, there are several pharmacologic options. Fibrates may be effective in decreasing triglyceride and increasing HDL cholesterol. Nicotinic acid (niacin) has been shown to decrease triglyceride, increase HDL cholesterol, lower LDL cholesterol, and decrease lipoprotein(a); it also decreases fibrinogen. The statins appear to be effective in decreasing triglyceride and LDL cholesterol in hypertriglyceridemia; however, they do not normalize metabolism of apolipoprotein B, and HDL cholesterol may remain low. Therefore, combination with a fibrate or niacin may be appropriate. Attention to hypertriglyceridemia with respect to increased CAD risk represents an important step in assessing global risk for CAD development.
...
PMID:Triglyceride as a risk factor for coronary artery disease. 981

The effect of different routes and modes of administration of niacin (nicotinic acid) on its hypolipidaemic activity has been evaluated. Our working hypothesis was that the major sites of niacin action are located presystemically (i.e. in the gut wall or the liver, or both) which would make niacin a gastrointestinal drug. For such drugs continuous administration to the gastrointestinal tract is expected to augment their efficacy compared with bolus oral administration or parenteral administration. The hypothesis was examined in two rat models of experimentally induced hyperlipidaemia-Model A, based on a cholesterol-enriched diet, and Model B, in which acute hyperlipidaemia is induced by intraperitoneal administration of triton (225 mg kg(-1)). Continuous administration of niacin into the duodenum at 1.66 mg h(-1) (total dose 40 mg kg(-1) day(-1)) for up to 7 days (Model A) or at 2.22 mg h(-1) over 18 h (Model B) had significantly greater lipid-reducing effects both on total cholesterol and on triglyceride levels (15-25%) and elevation of high-density lipoprotein (HDL) cholesterol levels than did bolus oral administration of the same dose. Continuous duodenal infusion of niacin also had an even greater lipid-reducing effect than continuous intravenous infusion of the drug at the same rate and dose. The results indicate that the site(s) of action are located presystemically and that continuous duodenal administration of a low dose of niacin (40 mg kg(-1)) has a greater lipid-lowering effect than a higher dose (200 mg kg(-1)) administered by peroral bolus administration. These conclusions were validated by administration of a specially designed niacin sustained-release matrix tablet formulation that was non-invasively administered to hyperlipidaemic rats. The hypolipidaemic activity of the sustained-release tablet was of similar magnitude to that resulting from continuous duodenal administration, thus providing a pharmacodynamic rationale for this mode of administration.
...
PMID:The effect of the mode of administration on the hypolipidaemic activity of niacin: continuous gastrointestinal administration of low-dose niacin improves lipid-lowering efficacy in experimentally-induced hyperlipidaemic rats. 987 8

<< Previous 1 2 3 4 5 6 7 8 9 10 Next >>