Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0027121 (myositis)
 4,538 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

266 patients with primary hypercholesterolaemia were followed for 48 weeks at 27 different centres to evaluate the safety, tolerability and effect on plasma lipids of lovastatin ranging from 20 to 80 mg/day. Mean change from baseline after 12 weeks of treatment with lovastatin was -34% (CI:33-35) for total cholesterol, -42% (CI:40-43) for LDL-cholesterol, +14% (CI:12-17) for HDL-cholesterol and -14% (CI:10-18) for triglycerides. Combination therapy with cholestyramine (8-24 g/day) was optional, and was started in 89 patients from week 13. At week 48 only 25% of all patients had obtained the second objective of the study: a total cholesterol value below 5.2 mmol/l. At the same time 60% of all patients had a total cholesterol below 6.2 mmol/l. Four patients dropped out of the study owing to adverse clinical experience. Only three of these events were probably related to lovastatin. Six patients were withdrawn because of adverse laboratory experiences. One patient showed clinical signs of myositis and increase of CK. In severe primary hypercholesterolaemia combination therapy with lovastatin and a resin such as cholestyramine is required to obtain total cholesterol values below 5.2 mmol/l.
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PMID:[Lovastatin in primary hypercholesterolemia. A Norwegian multicenter study]. 147 Nov 27

Seventy-four patients with plasma low-density lipoprotein cholesterol levels > or = 160 mg/dl after an American Heart Association phase 1 diet were randomized to double-blind treatment with fluvastatin, 20 mg/day, or placebo for 6 weeks. Immediate-release niacin was then added to both treatment regimens and titrated to a maximum of 3 g/day for a further 9 weeks. After 6 weeks of fluvastatin monotherapy, low-density lipoprotein cholesterol levels decreased by 21% (p < 0.001 vs placebo), and after the addition of niacin, response was potentiated to 40% compared with 25% for the niacin control group at study end point (p < 0.001). Fluvastatin, alone and in combination with niacin, also significantly improved high-density lipoprotein cholesterol (increases of about 30%) and triglyceride profiles (decreases of approximately 28%) from baseline. Lipoprotein(a) decreased by 37% in those receiving fluvastatin-niacin but was unaltered in those receiving fluvastatin alone. No serious adverse events were ascribed to fluvastatin, and no cases of myositis were observed. Small, transient, asymptomatic increases in aspartate aminotransferase were noted with fluvastatin-niacin treatment but were not considered clinically relevant. Although the fluvastatin-niacin combination in this study was without evidence of significant transaminitis, myopathy, or rhabdomyolysis, it would seem prudent to continue to monitor its safety with longer term use. In conclusion, fluvastatin, both as monotherapy and in combination with niacin, proved to be an effective, safe, and well-tolerated therapeutic alternative for hypercholesterolemia.
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PMID:Fluvastatin with and without niacin for hypercholesterolemia. 802 79

A double-blind, randomized study was undertaken to evaluate the efficacy and safety of fluvastatin as monotherapy and as combination therapy with niacin in the treatment of hypercholesterolemia refractory to diet. Seventy-four patients with plasma low-density lipoprotein cholesterol (LDL-C) levels > or = 160 mg/dL were treated with fluvastatin, 20 mg/d, or placebo for 6 weeks. Thereafter, immediate-release niacin, at a dosage titrated to a maximum of 3 g/d, was added to both regimens for another 9 weeks. All adverse events were monitored, with particular attention to the evaluation of liver and muscle enzymes. Initial analysis of the data shows that fluvastatin and its combination with niacin was well tolerated and was not associated with any serious adverse events. Small, transient, asymptomatic rises in aspartate aminotransferase (AST) occurred in 28.9% of fluvastatin-niacin treated patients compared to 8.3% in the niacin-placebo control arm (p < 0.05). These were considered clinically insignificant in that no transaminase elevations > 3 times the upper limit of normal occurred. No evidence of myopathy, creatine kinase levels exceeding 10 times the upper limit of normal, myositis, or rhabdomyolysis were demonstrated in this short-term trial. The majority of adverse events resulting in patient withdrawals were ascribed to niacin therapy and included cutaneous vasodilatation, flushing, itching, and rash. These preliminary results suggest that fluvastatin, both alone and combined with niacin, is an effective, safe, and well-tolerated treatment for hypercholesterolemia.
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PMID:Combination therapy with fluvastatin and niacin in hypercholesterolemia: a preliminary report on safety. 819 20

One of the major side-effects of the use of HMG CoA reductase inhibitors for the treatment of hypercholesterolemia is the development of myositis and, in some patients undergoing concomitant immunosuppressive treatment, the development of rhabdomyolysis. Experiments outlined in these studies demonstrate that inhibitors of HMG-CoA reductase activity which differ primary in the substitution of a methyl group for a hydroxyl group have differential effects on both cholesterol levels and cell viability in a striated muscle cell model, the mouse C2-C12 myoblast. Thus, concentrations as high as 200 microM of pravastatin had little effect on total cholesterol level while 25 microM of lovastatin decreased cellular cholesterol by over 90%. Simvastatin and lovastatin decreased viability of C2-C12 myoblasts by nearly 50% at concentrations as low as 1 and 5 microM, respectively, and decreased viability by almost 90% at 10 and 15 microM respectively. However, 300 microM of pravastatin decreased cell viability by less than 50%. The order of potency for the effects on cell viability wassimvastatin>lovastatin>>>pravastatin. The possible relationship between effects on cell viability and the development of myositis is discussed.
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PMID:Differential sensitivity of C2-C12 striated muscle cells to lovastatin and pravastatin. 857 54

Both the European Atherosclerosis Society and the US National Cholesterol Education Program have issued revised guidelines for the prevention of coronary heart disease (CHD), based on a multitude of recent epidemiological and angiographic studies. Both authorities agree that a target plasma low-density lipoprotein cholesterol (LDL-C) level is the single most important parameter, this target level being different for primary and secondary prevention. The introduction of statins for the treatment of hypercholesterolaemia provides an important tool to enable target LDL-C levels to be reached in most cases of primary prevention. For secondary prevention, however, the target LDL-C levels--2.6 mmol/l (100 mg/dl)--may be achieved in only a fraction of cases. Others may require the concomitant administration of other cholesterol-lowering drugs, such as bile-acid sequestrants (resins) and/or derivatives of fibric acid (fibrates). The use of statin-fibrate combinations has been discouraged since the report by the US Food and Drug Administration of 12 sporadic cases of myositis or rhabdomyolysis. During the past 7 years, however, 21 clinical trials have examined the efficacy and safety of statin-fibrate combinations in a total of 486 patients with a variety of dyslipidaemias. Overall, the combinations were proven to be effective and safe, and the incidence of abnormalities in liver function tests and levels of creatine kinase (CK) was low. A double-blind study has been carried out at the Hadassah University Hospital to examine the efficacy and safety of fluvastatin when combined with either cholestyramine (group 1) or bezafibrate (group 2) for the treatment of 38 patients with heterozygous familial hypercholesterolaemia (FH). Patients in group 2 showed a reduction in plasma LDL-C levels of 35% and in LDL-C to high-density lipoprotein cholesterol (HDL-C) ratio of 45% compared with 32% and 38% respectively in group 1. Both cholestyramine and bezafibrate produced an additional benefit of a 13% reduction in LDL-C levels in comparison with fluvastatin as monotherapy. An open-label ongoing study on a larger cohort of FH patients reveals that a decrease in plasma LDL-C levels of up to 38.5% may be achieved with a combination of fluvastatin 80 mg/day and bezafibrate 400 mg/day. In both studies, biochemical safety analyses revealed no notable abnormalities in liver function tests or levels of CK. It was concluded that fluvastatin-bezafibrate is a very effective synergistic therapy for heterozygous FH and is superior to a fluvastatin-cholestyramine combination.
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PMID:The patient at risk: who should we be treating? 1949 69

The beneficial effects of statins are assumed to result from their ability to reduce cholesterol biosynthesis. However, because mevalonic acid is the precursor not only of cholesterol, but also of many nonsteroidal isoprenoid compounds, inhibition of 3-hydroxy-3-methylglutaryl coenzyme A reductase may result in pleiotropic effects. It has been shown that several statins decrease smooth muscle cell migration and proliferation and that sera from fluvastatin-treated patients interfere with its proliferation. Cholesterol accumulation in macrophages can be inhibited by different statins, while both fluvastatin and simvastatin inhibit secretion of metalloproteinases by human monocyte-derived macrophages. The antiatherosclerotic effects of statins may be achieved by modifying hypercholesterolemia and the arterial wall environment as well. Although statins rarely have severe adverse effects, interactions with other drugs deserve attention. Simvastatin, lovastatin, cerivastatin, and atorvastatin are biotransformed in the liver primarily by cytochrome P450-3A4, and are susceptible to drug interactions when co-administered with potential inhibitors of this enzyme. Indeed, pharmacokinetic interactions (e.g., increased bioavailability), myositis, and rhabdomyolysis have been reported following concurrent use of simvastatin or lovastatin and cyclosporine A, mibefradil, or nefazodone. In contrast, fluvastatin (mainly metabolized by cytochrome P450-2C9) and pravastatin (eliminated by other metabolic routes) are less subject to this interaction. Nevertheless, a 5- to 23-fold increase in pravastatin bioavailability has been reported in the presence of cyclosporine A. In summary, statins may have direct effects on the arterial wall, which may contribute to their antiatherosclerotic actions. Furthermore, some statins may have lower adverse drug interaction potential than others, which is an important determinant of safety during long-term therapy.
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PMID:New insights into the pharmacodynamic and pharmacokinetic properties of statins. 1066 38

Although there is little information from primary or secondary prevention trials on cholesterol-lowering medication in diabetic patients, the reduction of elevated cholesterol is widely recommended for this group. The American Diabetes Association (ADA) recommends drug therapy in diabetic patients if low density lipoprotein (LDL)-cholesterol remains at > 130 mg/dl, or > 100 mg/dl in patients with macroangiopathy, after dietary intervention. When cholesterollowering medication is indicated, the choice of the drug must take into account the other lipid abnormalities that are often present and the need to maintain optimal glycaemic control. In the present study we compared the efficacy and safety of the novel HMG-CoA reductase inhibitor atorvastatin at the dose of 10 mg/day with simvastatin , lovastatin and pravastatin at doses of 10, 20 and 20 mg/day, respectively, and placebo, in type 2 diabetic patients with moderate elevation of LDL-cholesterol with or without elevation of triglycerides. All the quoted agents are enzyme inhibitors effective in lowering LDL-cholesterol in humans. The efficacy endpoints were the mean per cent changes in plasma LDL-cholesterol (primary), total cholesterol, triglycerides, and high-density lipoprotein (HDL)-cholesterol concentrations from baseline to the end of treatment (24 weeks). Atorvastatin at a dose of 10 mg/day produced: (1) a significant reduction in LDL-cholesterol (-37%) in comparison with equivalent doses of simvastatin (-26%), pravastatin (-23%), lovastatin (-21%), and placebo (-1%); (2) HDL-cholesterol increases (7.4%) comparable to or greater than those obtained with simvastatin (7.1%), pravastatin (3.2%), lovastatin (7.21%), and placebo (-0.5%); (3) a significantly greater reduction in total cholesterol (- 29%) than that obtained with simvastatin (-21%), pravastain (-16%), lovastatin (-18%), and placebo (1%); and (4) a significantly greater reduction in triglycerides than that obtained with all the other drugs and placebo. In all treatment groups no significant variation in fibrinogen concentration was observed. All reductase inhibitors studied had similar levels of tolerance. There were no incidents of persistent elevations of serum aminotransferases or myositis.
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PMID:Comparative efficacy study of atorvastatin vs simvastatin, pravastatin, lovastatin and placebo in type 2 diabetic patients with hypercholesterolaemia. 1122 65

A 68-year-old woman, with type 2 diabetes mellitus, hypercholesterolemia, and prior long-term simvastatin therapy, self-resumed troglitazone after running out of metformin. She developed an acute severe hepatitis with microvesicular steatosis and mysositis. There was subsequent resolution of the myositis but progression of the hepatitis to symptomatic cirrhosis over a period of 12 weeks. Both troglitazone and simvastatin are metabolized by cytochrome P-450 3A4. Troglitazone typically induces metabolism of drugs metabolized by this cytochrome so that simple simvastatin toxicity seems less likely to have been involved. The association with myositis, the severity of the hepatitis with progression to cirrhosis, and the presence of microvesicular steatosis suggests altered mitochondrial metabolism, which has been described with each agent, as the underlying pathogenic mechanism. Although troglitazone (Rezulin) has been withdrawn from the market, other similar agents are available for therapy of type 2 diabetes mellitus. Increased awareness of a potential interaction between these two classes of drugs is warranted.
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PMID:Myositis, microvesicular hepatitis, and progression to cirrhosis from troglitazone added to simvastatin. 1128 Nov 88

The 3-hydroxy-3-methyl coenzyme A (HMG-CoA) reductase inhibitors or statins, specifically inhibit the enzyme HMG-CoA in the liver, thereby inhibiting the rate limiting step in cholesterol biosynthesis and so reducing plasma cholesterol levels. Numerous studies have consistently demonstrated that cholesterol lowering with statin therapy reduces morbidity and mortality from coronary heart disease, whilst recent evidence has demonstrated that benefits of statin therapy may also extend into stroke prevention. Since hypercholesterolaemia is a chronic condition, the long-term safety and tolerability of these agents is an important issue. Numerous large-scale clinical trials have consistently demonstrated a positive safety and tolerability profile for statins. Hepatic, renal and muscular systems are rarely affected during statin therapy, with adverse reactions involving skeletal muscle being the most common, ranging from mild myopathy to myositis and occasionally to rhabdomyolysis and death. Postmarketing data supports the positive safety and tolerability profile of statins, with an overall adverse event frequency of less than 0.5% and a myotoxicity event rate of less than 0.1%. The recent withdrawal of cerivastatin from the world market due to deaths from rhabdomyolysis has, however, focused attention on the risk of adverse events and in particular myotoxicity associated with statins. Indeed, initial clinical trial data supports postmarketing data, demonstrating a higher incidence of myotoxicity associated with cerivastatin, particularly when used in combination with fibrates. The potential mechanisms underlying statin-induced myotoxicity are complex with no clear consensus of opinion. Candidate mechanisms include intracellular depletion of essential metabolites and destabilisation of cell membranes, resulting in increased cytotoxicity. Cytochrome P450 3A4 is the main isoenzyme involved in statin metabolism. Reduced activity of this enzyme due to either reduced expression or inhibition by other drugs prescribed concomitantly such as cyclosporin or itraconazole may increase drug bioavailability and the risk of myotoxicity. Such factors may partly account for the interindividual variability in susceptibility to statin-induced myotoxicity, although other as of yet unclarified, genetic factors may also be involved. The risk of rhabdomyolysis is increased with combination fibrate-statin therapy, with initial evidence suggesting that gemfibrozil-statin combination may particularly increase the risk of myotoxicity, with pharmacodynamic as well as pharmacokinetic mechanisms being involved.
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PMID:Effects of HMG-CoA reductase inhibitors on skeletal muscle: are all statins the same? 1213 59

Fluvastatin was the first wholly synthetic statin to the market and is effective in reducing total and low density lipoprotein cholesterol, which translates into reductions in coronary heart disease events. The Lescol Intervention Prevention Study has established the effectiveness of the early use of statins in reducing recurrent events in high-risk patients with coronary heart disease post percutaneous coronary interventions. Fluvastatin is well-tolerated with few side effects. The occurrence of significant abnormalities in liver enzymes is infrequent, and the risk of myositis and rhabdomyolysis seems to be less than with other statins. There have been no reports of fatal rhabdomyolysis to date. The potential for drug interactions with fluvastatin is low. It seems safe in combination with cyclosporin and there have been few reports of rhabdomyolysis when using fluvastatin in combination with other lipid-lowering agents. It is nevertheless important to be vigilant for this potentially important side effect and, as with other statins, inform patients of the potential risk and suggestive symptoms. Fluvastatin provides a useful option in treating hypercholesterolaemia in patients at high risk of coronary heart disease.
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PMID:Fluvastatin. 1243 96


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