Rhabdomyolysis a result of azithromycin and statins: an unrecognized interaction

AIMS

In a systematic screening of the World Health Organization Adverse Drug Reaction database, VigiBase, in July 2008, a measure of association used to detect interactions (Omega) highlighted azithromycin with the individual statins atorvastatin, lovastatin and simvastatin and rhabdomyolysis. The aim was to examine all reports including rhabdomyolysis-azithromycin and statins in VigiBase to assess if the data were suggestive of an interaction.

METHODS

The individual case reports in VigiBase and the original files were reviewed. In order to investigate the reporting over time for rhabdomyolysis with azithromycin and statins to VigiBase, Omega values were generated retrospectively.

RESULTS

The reporting over time showed that rhabdomyolysis under concomitant use of azithromycin and statins was reported more often than expected from 2000 and onwards in Vigibase. After exclusion of possible duplicates and follow-up reports, 53 cases from five countries remained. Rhabdomyolysis occurred shortly after initiation of azithromycin in 23% of cases. In 11 patients an interaction had been suggested by the reporter. With the exception of one patient, the statin doses reported were within the recommended daily doses.

CONCLUSIONS

Case reports in VigiBase are suggestive that interactions between azithromycin and statins resulting in rhabdomyolysis may occur. This analysis showed the potential of the newly developed disproportionality measure, Omega, which can help to identify drug interactions in VigiBase in the future. The results also showed that reviewing spontaneous reports can add information to drug interactions not established previously.     

Statin-induced myotoxicity: pharmacokinetic differences among statins and the risk of rhabdomyolysis, with particular reference to pitavastatin

3-hydroxy-3-methylglutaryl coenzyme A reductase inhibitors (statins) are the most widely prescribed therapeutic class of drugs worldwide, with established clinical benefits both in terms of improving serum lipid profiles and reducing cardiovascular events and mortality. Although statins have a favorable risk-to-benefit ratio, they have the potential to cause adverse events which can result in muscular inflammation (myositis), muscle breakdown (rhabdomyolysis) and, ultimately, kidney failure. While the incidence of rhabdomyolysis is approximately 3.4 cases per 100,000 person-years with standard-dose statin therapy, the risk of developing the condition increases substantially at higher therapeutic doses. This effect may be exacerbated by prescribing statins in combination with certain other medications because drug ? drug interactions increase statin exposure by interacting with enzymes that would normally be involved in their metabolism and clearance. Co-administration of drugs that inhibit the cytochrome P450 (CYP) enzymes responsible for metabolizing statins, or that interact with the organic anion-transporting polypeptides (OATPs) responsible for statin uptake into hepatocytes, substantially increases the risk of developing myotoxicity. Such effects vary among statins according to their metabolic profile. For example, pitavastatin, a novel statin approved for the treatment of hypercholesterolemia and combined (mixed) dyslipidemia, is not catabolized by CYP3A4, unlike other lipophilic statins, and may be less dependent on the OATP1B1 transporter for its uptake into hepatocytes before clearance. Such differences in drug ? drug interaction profiles among available statins offer the possibility of reducing the risk of myotoxicity among high-risk patients.     

Colesevelam HCl: a non-systemic lipid-altering drug

Colesevelam HCl (WelChol, Sankyo Pharmaceuticals Inc.) is a bile acid sequestrant polymer, which has been shown to significantly lower low density lipoprotein cholesterol and favourably affect high-density lipoprotein cholesterol blood levels in monotherapy and in combination with statins (HMG-CoA reductase inhibitors). Although it is similar to other bile acid sequestrants in that it binds bile acids and is non-systemic, colesevelam HCl differs in that it has a unique polymer structure that allows for greater tolerability with less potential drug interactions than with resins. Currently, statins are the most commonly prescribed lipid-altering drugs. However, it is not uncommon that patients demonstrate true or perceived intolerances to statin therapy, that are often dose-related and may include elevations in liver or muscle enzyme blood levels, or myalgias or muscle weakness without muscle enzyme elevation. In rare circumstances, myopathy and even rhabdomyolysis can occur with statins. In addition, many statins also have important potential drug interactions. Finally, statin monotherapy is often not sufficient in achieving lipid treatment goals in many severely dyslipidaemic patients and the availability of colesevelam HCl provides a lipid-altering treatment addition to other lipid-altering drugs. From a clinical perspective, such combination therapy is often required to achieve treatment goals [1] in patients with more complicated or severe dyslipidaemia. Colesevelam HCl may also be an alternative in monotherapy for many patients with mild-to-moderate hypercholesterolaemia, as well as in some patients at potential risk from systemic exposure to alternative lipid-altering drugs (such as young children and fertile women).     

Effects of HMG-CoA reductase inhibitors on skeletal muscle: are all statins the same?

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.     

Combination therapy for the treatment of dyslipidemia

Statins have been proven to reduce cardiovascular risk, and guidelines for cardiovascular prevention recommend statin therapy in a wide range of patients. However, in spite of the dramatic success in large randomized clinical trials, two thirds of patients administered statins are not protected against cardiovascular events. This has prompted a search for additional targets for therapy. The pandemic of metabolic syndrome and type 2 diabetes has led to a dramatic increase in the prevalence of dyslipidemia. This, in turn, has prompted a resurgence of the search for drugs and algorithms that favorably affect high-density lipoprotein (HDL) and very low-density lipoprotein (VLDL) metabolism and function. Fibrates are the best-studied class of agents to be used as an addition to statins since they have also been proven to reduce clinical events as a monotherapy. However, there is a need for large safety trials of statin-fibrate combination therapy. Statin-niacin combination therapy has proven to be safe and effective in altering lipoprotein pattern. Randomized clinical trials and more research on the mechanism of action of niacin are necessary. Inhibitors of cholesterol ester transfer protein and HDL therapy drugs are in early developmental stages, and are the most promising potential additions to the current arsenal.     

Risk-benefit of HMG-CoA reductase inhibitors in the treatment of HIV protease inhibitor-related hyperlipidaemia

HIV protease inhibitors decrease mortality and improve quality of life in patients with HIV infection. However, these drugs have been associated with serum lipid elevations, which may pose an increased risk of cardiovascular disease and pancreatitis. Treatment of protease inhibitor-related hyperlipidaemia (PIH) is complicated by drug interactions, which significantly increase concentrations of most 3-hydroxy-3-methylglutaryl-coenzyme A (HMG-CoA) reductase inhibitors (statins). Although pravastatin and atorvastatin effectively lower cholesterol and triglyceride concentrations in HIV-infected patients, a significant number of patients did not achieve their National Cholesterol Education Program low density lipoprotein concentration goals. Nonetheless, due to the increased risk of rhabdomyolysis with elevated statin concentrations, atorvastatin should be considered a second-line agent. The limited available PIH data supports the fact that pravastatin and atorvastatin are well-tolerated in HIV-infected individuals. More data are needed on the appropriate starting doses, maximum safe doses, role of combination statin-fibrate therapy, documentation of coronary heart disease benefit and incidence of myotoxicity and hepatotoxicity. Pravastatin has an acceptable risk-benefit ratio in PIH, while theoretical toxicity concerns exist with atorvastatin.     

Statins, neuromuscular degenerative disease and an amyotrophic lateral sclerosis-like syndrome: an analysis of individual case safety reports from vigibase.

BACKGROUND: The WHO Foundation Collaborating Centre for International Drug Monitoring (Uppsala Monitoring Centre [UMC]) has received many individual case safety reports (ICSRs) associating HMG-CoA reductase inhibitor drug (statin) use with the occurrence of muscle damage, including rhabdomyolysis, and also peripheral neuropathy. A new signal has now appeared of disproportionally high reporting of upper motor neurone lesions. AIM AND SCOPE: The aim of this paper is to present the upper motor neurone lesion cases, with other evidence, as a signal of a relationship between statins and an amyotrophic lateral sclerosis (ALS)-like syndrome. The paper also presents some arguments for considering that a spectrum of severe neuromuscular damage may be associated with statin use, albeit rarely. The paper does not do more than raise the signal for further work and analysis of what must be regarded as a potentially very serious and perhaps avoidable or reversible adverse reaction, though it also suggests action to be taken if an ALS-like syndrome should occur in a patient using statins. METHODS: The 43 reports accounting for the disproportional reports in Vigibase (the database of the WHO Programme for International Drug Monitoring) are summarised and analysed for the diagnosis of an ALS-like syndrome. The issues of data quality and potential reporting bias are considered. RESULTS: 'Upper motor neurone lesion' is a rare adverse event reported in relationship to drugs in Vigibase (a database containing nearly 4 million ICSRs). Of the total of 172 ICSRs on this reported term, 43 were related to statins, of which 40 were considered further: all but one case was reported as ALS. In 34/40 reports a statin was the sole reported suspected drug. The diagnostic criteria were variable, and seven of the statin cases also had features of peripheral neuropathy. Of a total of 5534 ICSRs of peripheral neuropathy related to any drug in Vigibase, 547 were on statins. The disproportional reporting of statins and upper motor neurone lesion persisted after age stratification, and such disproportionality was not seen for statins and Parkinson's disease, Alzheimer's disease, extrapyramidal disorders, or multiple sclerosis-like syndromes. DISCUSSION: Because the cases were sometimes atypical we propose the use of the term 'ALS-like syndrome' and speculate whether this is part of a spectrum of rare neuromuscular damage. The diagnosis of ALS is often problematic, and the insidiousness and chronicity of the disease make causality with a drug difficult to assess. The disproportionally high reporting makes this an important signal nevertheless, since ALS is serious clinically and statins are so widely used. Wide use of the statins also makes a chance finding more probable, but is unlikely to cause disproportional reporting when there are no obvious biases identified. CONCLUSION: We emphasise the rarity of this possible association, and also the need for further study to establish whether a causal relationship exists. We do advocate that trial discontinuation of a statin should be considered in patients with serious neuromuscular disease such as the ALS-like syndrome, given the poor prognosis and a possibility that progression of the disease may be halted or even reversed.     

Risk-benefit of HMG-CoA reductase inhibitors in the treatment of HIV protease inhibitor-related hyperlipidaemia

HIV protease inhibitors decrease mortality and improve quality of life in patients with HIV infection. However, these drugs have been associated with serum lipid elevations, which may pose an increased risk of cardiovascular disease and pancreatitis. Treatment of protease inhibitor-related hyperlipidaemia (PIH) is complicated by drug interactions, which significantly increase concentrations of most 3-hydroxy-3-methylglutaryl-coenzyme A (HMG-CoA) reductase inhibitors (statins). Although pravastatin and atorvastatin effectively lower cholesterol and triglyceride concentrations in HIV-infected patients, a significant number of patients did not achieve their National Cholesterol Education Program low density lipoprotein concentration goals. Nonetheless, due to the increased risk of rhabdomyolysis with elevated statin concentrations, atorvastatin should be considered a second-line agent. The limited available PIH data supports the fact that pravastatin and atorvastatin are well-tolerated in HIV-infected individuals. More data are needed on the appropriate starting doses, maximum safe doses, role of combination statin-fibrate therapy, documentation of coronary heart disease benefit and incidence of myotoxicity and hepatotoxicity. Pravastatin has an acceptable risk-benefit ratio in PIH, while theoretical toxicity concerns exist with atorvastatin.     

Rhabdomyolysis after addition of digitoxin to chronic simvastatin and amiodarone therapy

Rhabdomyolysis is a well known side effect of statin therapy. Several drugs may increase its risk by drug-drug interactions. In particular, patients with heart disease receive more and more different compounds to cope with all the pathomechanisms involved and may therefore be of high risk for side effects. We report a case of rhabdomyolysis in a patient with heart failure on a multi-drug regimen caused by a drug interaction between chronic statin therapy (simvastatin), amiodarone and newly administrated digitoxin. The patient recovered fully after cessation of simvastatin therapy, the other drugs were given continuously. Potential mechanisms of this event are discussed. Most interesting in this case is that rhabdomyolysis occurred only after starting digitoxin after long-term therapy with the statin.     

Ezetimibe: a selective cholesterol absorption inhibitor

Ezetimibe is the first agent of a novel class of selective cholesterol absorption inhibitors recently approved by the Food and Drug Administration for treatment in the United States. Ezetimibe inhibits the absorption of biliary and dietary cholesterol from the small intestine without affecting the absorption of fat-soluble vitamins, triglycerides, or bile acids. Ezetimibe localizes at the brush border of the small intestine and decreases cholesterol uptake into the enterocytes. Preclinical studies demonstrated lipid-lowering properties of ezetimibe as monotherapy and showed a synergistic effect in combination with 3-hydroxy-3-methylglutaryl coenzyme A reductase inhibitors (statins). The efficacy and safety of ezetimibe 10 mg/day have been established in phase III clinical trials. In these trials, ezetimibe was investigated as monotherapy, as an add-on to ongoing statin therapy, and as combination therapy with statins in patients with primary hypercholesterolemia. In addition, ezetimibe has been evaluated in patients with homozygous and heterozygous familial hypercholesterolemia and in those with sitosterolemia. When given as monotherapy or in combination with statins or fenofibrate, ezetimibe reduces low-density lipoprotein cholesterol (LDL) by 15-20% while increasing high-density lipoprotein cholesterol by 2.5-5%. Unlike other intestinally acting lipid-lowering agents, ezetimibe does not adversely affect triglyceride levels and, due to its minimal systemic absorption, drug interactions are few. Ezetimibe's side-effect profile resembles that of placebo when given as monotherapy or in combination with statins. In clinical practice, ezetimibe has a role as monotherapy for patients who require modest LDL reductions or cannot tolerate other lipid-lowering agents. In combination therapy with a statin, ezetimibe is used in patients who cannot tolerate high statin doses or in those who need additional LDL reductions despite maximum statin doses.     

Safety review of combination drugs for hyperlipidemia

INTRODUCTION: Despite statin monotherapy, many high-risk patients are not at recommended low-density lipoprotein cholesterol goals. Moreover, these patients are also likely to exhibit an atherogenic dyslipidemia characterized by decreased high-density lipoprotein cholesterol and elevated triglycerides. As a consequence, combination lipid-altering drug therapies are frequently required to improve the lipid profile. The long-term safety and tolerability of these combination therapies are key determinants for good compliance and cardiovascular benefits. AREAS COVERED: This review summarizes the safety data published on combination drugs for the treatment of hyperlipidemia by examining the various combinations with a statin and also the other combination therapies used when statin treatment is not tolerated. The reader will gain insight into the incidence and severity of the major adverse events expected with combination therapies and the recommendations on the use of these combined treatments. A specific focus is made on muscle-related side effects. EXPERT OPINION: The existing data suggest that ezetimibe, bile acid sequestrants and ω-3 fatty acids appear unlikely to increase the risk of adverse events, particularly myopathy, when used in combination with a statin, even with a high-dose statin. Although the combination of niacin or fenofibrate with moderate-dose statins appears to be safe, prescribing a combination of these drugs with high-dose statins needs caution and requires giving careful information to the patient.     

Statins and myotoxicity: a therapeutic limitation

Hydroxymethylglutaryl-coenzyme A (HMG-CoA) reductase inhibitors represent the most successful class of drugs for the treatment of hypercholesterolaemia and dyslipidaemia implicated in the pathogenesis of coronary heart disease and atherosclerosis. However, the popular profile of statins in terms of efficacy has been maligned by its adverse events. The myotoxicity, ranging from mild myopathy to serious rhabdomyolysis, associated with HMG-CoA reductase inhibitors, during treatment of hypercholesterolaemia is of paramount importance. Rhabdomyolysis is a rare but idiosyncratic muscle wasting disorder of different etiologies. Statin-associated rhabdomyolysis causes skeletal muscle injury by self-perpetuating events leading to fatal irreversible renal damage through a series of biochemical reactions. Preferential distribution and action of statins in liver could be the key to minimise myotoxicity concerns. Hepato-specific distribution of statins is governed by various factors such as physicochemical properties, pharmacokinetic properties and selective transporter-mediated uptake in liver rather in extrahepatic cells. The interactions of statins with concomitant drugs of different classes merit attention for their safety profile. Although pharmacokinetic as well as pharmacodynamic interactions have been implicated in pathophysiology of statin-induced muscle wasting, the underlying mechanism is not clearly understood. Besides, pharmacokinetic and phramcodynamic factors, statin-associated myotoxcity may also implicate pharmacogenomic factors. The pharmacogenomics characterised by CYP polymorphism and other genetic factors is responsible for inter-individual variations to efficacy and tolerability of statins. The pathophysiological mechanisms may include statin-induced differences in cholesterol:phospholipid ratio, isoprenoid levels, small GTP binding proteins and apoptosis. However, the present understanding of pathophysiological mechanisms, does not offer a reliable approach to address the same at preclinical level. Although statin-associated myotoxicity affects compliance, quality of life of patient and discontinuation rate, yet the low incidence of myotoxicty including rhabdomyolysis and less severity of commonly occurring myopathy and myalgia do not raise doubts about the clinical efficacy and tolerability of statins. Medical management of myotoxicity seems to be pivotal for the proper compliance of patients with statin treatment. The appropriate and judicious use of drugs would substantially reduce the likelihood of developing clinically important myopathy.     

Statins and myotoxicity: a therapeutic limitation

Hydroxymethylglutaryl-coenzyme A (HMG-CoA) reductase inhibitors represent the most successful class of drugs for the treatment of hypercholesterolaemia and dyslipidaemia implicated in the pathogenesis of coronary heart disease and atherosclerosis. However, the popular profile of statins in terms of efficacy has been maligned by its adverse events. The myotoxicity, ranging from mild myopathy to serious rhabdomyolysis, associated with HMG-CoA reductase inhibitors, during treatment of hypercholesterolaemia is of paramount importance. Rhabdomyolysis is a rare but idiosyncratic muscle wasting disorder of different etiologies. Statin-associated rhabdomyolysis causes skeletal muscle injury by self-perpetuating events leading to fatal irreversible renal damage through a series of biochemical reactions. Preferential distribution and action of statins in liver could be the key to minimise myotoxicity concerns. Hepato-specific distribution of statins is governed by various factors such as physicochemical properties, pharmacokinetic properties and selective transporter-mediated uptake in liver rather in extrahepatic cells. The interactions of statins with concomitant drugs of different classes merit attention for their safety profile. Although pharmacokinetic as well as pharmacodynamic interactions have been implicated in pathophysiology of statin-induced muscle wasting, the underlying mechanism is not clearly understood. Besides, pharmacokinetic and phramcodynamic factors, statin-associated myotoxcity may also implicate pharmacogenomic factors. The pharmacogenomics characterised by CYP polymorphism and other genetic factors is responsible for inter-individual variations to efficacy and tolerability of statins. The pathophysiological mechanisms may include statin-induced differences in cholesterol:phospholipid ratio, isoprenoid levels, small GTP binding proteins and apoptosis. However, the present understanding of pathophysiological mechanisms, does not offer a reliable approach to address the same at preclinical level. Although statin-associated myotoxicity affects compliance, quality of life of patient and discontinuation rate, yet the low incidence of myotoxicty including rhabdomyolysis and less severity of commonly occurring myopathy and myalgia do not raise doubts about the clinical efficacy and tolerability of statins. Medical management of myotoxicity seems to be pivotal for the proper compliance of patients with statin treatment. The appropriate and judicious use of drugs would substantially reduce the likelihood of developing clinically important myopathy.     

2008–2013年他汀类药物致横纹肌溶解症文献分析

目的调查他汀类药物引起横纹肌溶解症的临床特征、发生原因及治疗措施.方法：以“他汀”、“横纹肌溶解”为检索词,检索PubMed、CNKI、VIP 数据库,对患者的一般情况、用药情况、横纹肌溶解症的临床表现、用药关联性、治疗与转归等进行分析.结果：共纳入54 篇文献,合计59 例患者.他汀类药物所致横纹肌溶解症多发生于70 岁以上患者.乏力、肌痛是他汀类药物致肌病的主要临床症状.辛伐他汀引起横纹肌溶解发病率最高,共35例（59.32%）.用药至发病最短时间为12 h,最长超过10 年,多数累计用药时间大于1 年.经过对症治疗后,45 例痊愈,11 例好转,3 例死亡.结论：密切观察应用他汀类药物患者的临床表现及生化指标检测结果,他汀类药物对高龄、合并用其他调脂药的患者可能会增加肌病发生的风险,易出现肾功能损害,一旦出现横纹肌溶解,应立即停药,给予血液净化、碱化尿液、保护肝肾功能等治疗.     

Safety review of combination drugs for hyperlipidemia

Introduction: Despite statin monotherapy, many high-risk patients are not at recommended low-density lipoprotein cholesterol goals. Moreover, these patients are also likely to exhibit an atherogenic dyslipidemia characterized by decreased high-density lipoprotein cholesterol and elevated triglycerides. As a consequence, combination lipid-altering drug therapies are frequently required to improve the lipid profile. The long-term safety and tolerability of these combination therapies are key determinants for good compliance and cardiovascular benefits.

Areas covered: This review summarizes the safety data published on combination drugs for the treatment of hyperlipidemia by examining the various combinations with a statin and also the other combination therapies used when statin treatment is not tolerated. The reader will gain insight into the incidence and severity of the major adverse events expected with combination therapies and the recommendations on the use of these combined treatments. A specific focus is made on muscle-related side effects.

Expert opinion: The existing data suggest that ezetimibe, bile acid sequestrants and ω-3 fatty acids appear unlikely to increase the risk of adverse events, particularly myopathy, when used in combination with a statin, even with a high-dose statin. Although the combination of niacin or fenofibrate with moderate-dose statins appears to be safe, prescribing a combination of these drugs with high-dose statins needs caution and requires giving careful information to the patient.     

Statin-fibrate combination: therapy for hyperlipidemia: a review

Statins and fibrates are well-established treatments for hyperlipidaemias and the prevention of vascular events. However, fibrate + statin therapy has been restricted following early reports of rhabdomyolysis that mainly involved gemfibrozil, originally with bovastatin, and recently, with cerivastatin. Despite this limitation, several reports describing combination therapy have been published. This review considers these studies and the relevant indications and contraindications. Statin + fibrate therapy should be considered if monotherapy or adding other drugs (e.g. cholesterol absorption inhibitors, omega-3 fatty acids ornicotinic acid) did not achieve lipid targets or is impractical. Combination therapy should be hospital-based and reserved for high-risk patients with a mixed hyperlipidaemia characterised by low density lipoprotein cholesterol (LDL) >2.6 mmol/l(100 mg/dl, high density lipoprotein cholesterol (HDL) <1.0 mmol/l (40 mg/dl) and/or triglycerides> 5.6 mmol/l (500 mg/dl. These three 'goals' are individually mentioned in guidelines. Patients should have normal renal, liver and thyroid function tests and should not be receiving therapy with cyclosporine, protease inhibitors or drugs metabolised through cytochrome P450 (especially 3A4). Combination therapy is probably best conducted using drugs with short plasma half-lives; fibrates should be prescribed in the morning and statins at night to minimise peak dose interactions. Both drug classes should be progressively titated from low doses. Regular (3-monthly) monitoring of liver function and creatine kinase is required. In conclusion, fibrate + statin therapy remains an option in high-risk patents. However, long-term studies involving safety monitoring and vascular endpoints are required to demonstrate the efficacy of this regimen.     

医院门诊患者克拉霉素与他汀类药物潜在代谢性相互作用处方分析

目的 分析门诊患者克拉霉素与他汀类药物代谢性相互作用处方，促进合理用药。方法 通过医院合理用药软件系统抽取2017年1月1日—2018年12月31日使用克拉霉素联合他汀类药物的所有门诊处方，以Micromedex药物相互作用数据库为基础，鉴别出潜在的代谢性药物相互作用（pDDIs）并进行严重性分级，结合CNKI、VIP、万方及PubMed数据库收载的克拉霉素与他汀类药物相互作用致不良反应个案报道文献进行分析。结果 共收集到克拉霉素联合使用他汀类药物处方41张，发生pDDIs处方30张，其中阿托伐他汀24张，辛伐他汀6张，严重性分级均为“Major （B）”。检索出克拉霉素与他汀类药物相互作用致不良反应个案报道12例，其中发生横纹肌溶解11例。结论 该院克拉霉素与他汀类药物存在pDDIs，且辛伐他汀超剂量使用，需要加强监测和干预，减少用药风险。