Single-dose pharmacokinetics of levetiracetam in healthy Chinese male subjects

WHAT IS ALREADY KNOWN ABOUT THIS SUBJECT: * Levetiracetam has been evaluated for epilepsy since 1992. * Pharmacokinetic studies of levetiracetam have been conducted in healthy volunteers, in adults, children and elderly patients with epilepsy, and in patients with renal and hepatic impairment. * Although this antiepileptic has been well studied in Western countries, this paper describes the first such trial of the drug in a Chinese population. WHAT THIS STUDY ADDS: * Information is given on the pharmacokinetics, dose proportionality, safety and tolerability profile of levetiracetam in healthy male Chinese volunteers, and the results are compared with published data obtained in White subjects. * The pharmacokinetics and the pattern of adverse events of levetiracetam in Chinese subjects are similar to the data reported in White subjects. AIMS: The main aims of this study were to evaluate the pharmacokinetics of levetiracetam in healthy male Chinese volunteers and to assess the dose proportionality between the 500-mg and 1500-mg single doses. METHODS: This was a randomized, single-centre, single-dose, two-way crossover study. Twenty-six healthy male Chinese subjects were enrolled. All subjects received a single dose of 500 mg or 1500 mg levetiracetam tablet(s) on the dosing day, and the wash-out period was 7 days. Blood was obtained for a 36-h pharmacokinetic evaluation. RESULTS: Following single-dose administration of 500 mg and 1500 mg of levetiracetam, the median t(max) was 0.5 and 0.5 h; t(1/2) was 7.3 +/- 0.8 and 7.3 +/- 0.7 h; C(max) was 13.6 +/- 3.2 and 47.1 +/- 12.1 microg ml(-1); AUC(0-infinity) was 109.3 +/- 14.1 and 340.4 +/- 50.6 microg h(-1) ml(-1); and AUC(0-t) was 105.7 +/- 13.3 and 329.0 +/- 47.9 microg h(-1) ml(-1), respectively. CONCLUSIONS: Both C(max) and AUCs were dose-proportional over the range of 500-1500 mg. The pharmacokinetic data obtained in these Chinese subjects were similar to the historical data from a matched group of White subjects.     

Population pharmacokinetics modeling of levetiracetam in Chinese children with epilepsy

Aim:

To establish a population pharmacokinetics (PPK) model of levetiracetam in Chinese children with epilepsy.

Methods:

A total of 418 samples from 361 epileptic children in Peking University First Hospital were analyzed. These patients were divided into two groups: the PPK model group (n=311) and the PPK validation group (n=50). Levetiracetam concentrations were determined by HPLC. The PPK model of levetiracetam was established using NONMEM, according to a one-compartment model with first-order absorption and elimination. To validate the model, the mean prediction error (MPE), mean squared prediction error (MSPE), root mean-squared prediction error (RMSPE), weight residues (WRES), and the 95% confidence intervals (95% CI) were calculated.

Results:

A regression equation of the basic model of levetiracetam was obtained, with clearance (CL/F)=0.988 L/h, volume of distribution (V/F)=12.3 L, and K_a=1.95 h⁻¹. The final model was as follows: K_a=1.56 h⁻¹, V/F=12.1 (L), CL/F=1.04×(WEIG/25)^0.583 (L/h). For the basic model, the MPE, MSPE, RMSPE, WRES, and the 95%CI were 9.834 (−0.587–197.720), 50.919 (0.012–1286.429), 1.680 (0.021–34.184), and 0.0621 (−1.100–1.980). For the final model, the MPE, MSPE, RMSPE, WRES, and the 95% CI were 0.199 (−0.369–0.563), 0.002082 (0.00001–0.01054), 0.0293 (0.001−0.110), and 0.153 (−0.030–1.950).

Conclusion:

A one-compartment model with first-order absorption adequately described the levetiracetam concentrations. Body weight was identified as a significant covariate for levetiracetam clearance in this study. This model will be valuable to facilitate individualized dosage regimens.     

左乙拉西坦在癫痫患儿中的群体药动学研究

目的建立癫痫患儿口服左乙拉西坦的群体药动学(PPK)模型,并用此模型探讨左乙拉西坦在儿童患者群体内的药动学特征。方法收集344例癫痫患儿口服左乙拉西坦后的血药浓度数据和临床资料。将患儿随机分为两组,模型组(n=259)采用NLME程序进行PPK分析,建立一房室药动学模型(个体间变异采用指数模型,残差变异采用加法模型表示),考察各协变量对参数Ka、Vd和CL的影响。用拟合优度、自举法对最终模型的性能进行内部验证。采用最终模型预测验证组(n=85)患儿的血药浓度,计算平均预测误差(MPE)、平均绝对预测误差(MAE)、平均预测误差平方(MSE)和均方根预测误差(RMSE)对最终模型进行外部验证。结果 PPK最终模型为:Ka(h-1)=1.01×eηKa,Vd(L·kg-1)=[0.42+0.000 35×(AGE-56)]×eηVd,CL(L·kg-1·h-1)=[0.05-0.009 5×(ln WT-2.83)]×eηCl;年龄(AGE)正相关影响Vd,体重的自然对数值(ln WT)负相关影响CL。拟合优度、自举验证的评价结果表明最终模型稳定、预测结果可靠。外部验证最终模型结果为:MPE=0.01 mg·L-1,MAE=0.91 mg·L-1,MSE=1.16(mg·L-1)2,RMSE=1.08 mg·L-1。血药浓度实测值和最终模型的个体预测值的决定系数R2=0.990 6。外部验证说明最终模型预测准确度高。结论本研究成功建立了癫痫患儿口服左乙拉西坦后的PPK模型,模型结构表明左乙拉西坦体重校正的清除率随患儿年龄和体重的增加有下降趋势。     

Clinical development of levetiracetam for amyotrophic lateral sclerosis

This month's Spotlight on... focuses on the current clinical development of the antiepileptic drug levetiracetam for amyotrophic lateral sclerosis. We highlight the experimental rationale behind its progress into patient cohorts with regards to targeting three currently untreatable aspects of human amyotrophic lateral sclerosis: cramps, spasticity and disease progression.     

Clinical pharmacology of levetiracetam for the treatment of epilepsy

Levetiracetam is an antiepileptic drug that is mainly indicated for the adjunctive treatment of partial-onset seizures in adults and children and of myoclonic and primary generalized tonic–clonic seizures in patients with idiopathic generalized epilepsy. In Europe, levetiracetam is also indicated as monotherapy for partial-onset seizures in patients with newly diagnosed epilepsy. Synaptic vesicle protein 2A is the primary molecular target for its anticonvulsive effect but additional mechanisms may also contribute. Recent clinical and pharmacokinetic developments for levetiracetam are reviewed in specific populations, including the effects of age, pregnancy, birth and lactation, pediatric development, and ethnic origin. The population pharmacokinetics of levetiracetam and drug–drug interactions have been explored across large adult and pediatric populations. The exposure–response relationship has also been characterized in adults and children through nonlinear mixed-effects modeling. Finally, new formulations including intravenous infusion and extended-release once-daily tablets have been compared with immediate-release tablets and oral solution, and can be used interchangeably.     

Clinical pharmacology of levetiracetam for the treatment of epilepsy

Levetiracetam is an antiepileptic drug that is mainly indicated for the adjunctive treatment of partial-onset seizures in adults and children and of myoclonic and primary generalized tonic-clonic seizures in patients with idiopathic generalized epilepsy. In Europe, levetiracetam is also indicated as monotherapy for partial-onset seizures in patients with newly diagnosed epilepsy. Synaptic vesicle protein 2A is the primary molecular target for its anticonvulsive effect but additional mechanisms may also contribute. Recent clinical and pharmacokinetic developments for levetiracetam are reviewed in specific populations, including the effects of age, pregnancy, birth and lactation, pediatric development, and ethnic origin. The population pharmacokinetics of levetiracetam and drug-drug interactions have been explored across large adult and pediatric populations. The exposure-response relationship has also been characterized in adults and children through nonlinear mixed-effects modeling. Finally, new formulations including intravenous infusion and extended-release once-daily tablets have been compared with immediate-release tablets and oral solution, and can be used interchangeably.     

Clinical pharmacokinetics of cabergoline

Cabergoline is a synthetic ergoline dopamine agonist with a high affinity for D(2) receptors indicated for use in both early and advanced Parkinson's disease and in hyperprolactinaemic disorders.Following oral administration, peak plasma concentrations of cabergoline are reached within 2-3 hours. Over the 0.5-7mg dose range, cabergoline shows linear pharmacokinetics in healthy adult volunteers and parkinsonian patients. Cabergoline is moderately bound (around 40%) to human plasma proteins in a concentration-independent manner; concomitant administration of highly protein-bound drugs is unlikely to affect its disposition. The absolute bioavailability of cabergoline is unknown.Cabergoline is extensively metabolised by the liver, predominantly via hydrolysis of the acylurea bond of the urea moiety. Cytochrome P450-mediated metabolism appears to be minimal. The major metabolites identified thus far do not contribute to the therapeutic effect of cabergoline. A significant fraction of the administered dose undergoes a first-pass effect. Less than 4% is excreted unchanged in the urine. The elimination half-life of cabergoline estimated from urinary data of healthy subjects ranges between 63 and 109 hours. Mild to moderate renal and hepatic impairment, administration of food and the use of concomitant antiparkinsonian medications, such as levodopa and selegiline, have no effect on the pharmacokinetics of cabergoline.The pharmacokinetic properties of cabergoline allow once daily administration in patients with Parkinson's disease and twice weekly administration in patients with hyperprolactinaemia, making this drug advantageous over other dopaminergic agents in term of both therapeutic compliance and better symptom control.     

Clinical pharmacokinetics of fenofibrate

Summary

Although the levels of low-density lipoprotein (LDL) cholesterol remain the main therapeutic goal when treating dyslipidaemias, there is a need to consider high-density lipoprotein (HDL) concentrations. This conclusion is based on the findings of epidemiological surveys and appropriately designed trials using statins or fibrates. The importance of HDL, as a ‘protective’ lipoprotein fraction, has been recognised by major treatment guidelines.

This review considers the differences in HDL-raising capacity of two of the most commonly prescribed statins – atorvastatin and simvastatin. When compared with simvastatin, atorvastatin is associated with progressively decreasing rises in the levels of HDL as the dose increases (negative dose response), an effect not reported with other statins. In contrast, simvastatin shows a positive dose response (increasing concentrations of HDL with increasing dose). This effect is paralleled by changes in apolipoprotein A-I levels. Apolipoprotein A-I is the main apolipoprotein associated with HDL.

This dissimilarity in HDL response is an example of several differences that have

been reported when comparing various statins. If ‘all statins are not created equal’, we should focus prescribing on those statins

that have end point evidence originating from appropriately designed trials.     

Clinical pharmacokinetics of fingolimod

Fingolimod (FTY720), a sphingosine 1-phosphate receptor modulator, is the first in a new class of therapeutic compounds and is the first oral therapy approved for the treatment of relapsing forms of multiple sclerosis (MS). Fingolimod is a structural analogue of endogenous sphingosine and undergoes phosphorylation to produce fingolimod phosphate, the active moiety. Fingolimod targets MS via effects on the immune system, and evidence from animal models indicates that it may also have actions in the central nervous system. In phase III studies in patients with relapsing-remitting MS, fingolimod has demonstrated efficacy superior to that of an approved first-line therapy, intramuscular interferon-β-1a, as well as placebo, with benefits extending across clinical and magnetic resonance imaging measures. The pharmacokinetic profiles of fingolimod and fingolimod phosphate have been extensively investigated in studies in healthy volunteers, renal transplant recipients (the indication for which fingolimod was initially under clinical development, but the development was subsequently discontinued) and MS patients. Results from these studies have demonstrated that fingolimod is efficiently absorbed, with an oral bioavailability of >90%, and its absorption is unaffected by dietary intake, therefore it can be taken without regard to meals. Fingolimod and fingolimod phosphate have a half-life of 6-9 days, and steady-state pharmacokinetics are reached after 1-2 months of daily dosing. The long half-life of fingolimod, together with its slow absorption, means that fingolimod has a flat concentration profile over time with once-daily dosing. Fingolimod and fingolimod phosphate show dose-proportional exposure in single- and multiple-dose studies over a range of 0.125-5?mg; hence, there is a predictable relationship between dose and systemic exposure. Furthermore, fingolimod and fingolimod phosphate exhibit low to moderate intersubject pharmacokinetic variability. Fingolimod is extensively metabolized, with biotransformation occurring via three main pathways: (i) reversible phosphorylation to fingolimod phosphate; (ii) hydroxylation and oxidation to yield a series of inactive carboxylic acid metabolites; and (iii) formation of non-polar ceramides. Fingolimod is largely cleared through metabolism by cytochrome P450 (CYP) 4F2. Since few drugs are metabolized by CYP4F2, fingolimod would be expected to have a relatively low potential for drug-drug interactions. This is supported by data from in vitro studies indicating that fingolimod and fingolimod phosphate have little or no capacity to inhibit and no capacity to induce other major drug-metabolizing CYP enzymes at therapeutically relevant steady-state blood concentrations. Population pharmacokinetic evaluations indicate that CYP3A inhibitors and CYP3A inducers have no effect or only a weak effect on the pharmacokinetics of fingolimod and fingolimod phosphate. However, blood concentrations of fingolimod and fingolimod phosphate are increased moderately when fingolimod is coadministered with ketoconazole, an inhibitor of CYP4F2. The pharmacokinetics of fingolimod are unaffected by renal impairment or mild-to-moderate hepatic impairment. However, exposure to fingolimod is increased in patients with severe hepatic impairment. No clinically relevant effects of age, sex or ethnicity on the pharmacokinetics of fingolimod have been observed. Fingolimod is thus a promising new therapy for eligible patients with MS, with a predictable pharmacokinetic profile that allows effective once-daily oral dosing.     

Clinical pharmacokinetics of orthofen

Translated from Khimiko-Farmatsevticheskii Zhurnal, Vol. 25, No. 12, pp. 71–75, December, 1991.     

Clinical pharmacokinetics of urapidil

Urapidil is a selective alpha 1-adrenoceptor antagonist with central antihypertensive action which is increasingly used in the treatment of hypertension. Urapidil is readily absorbed, is subject to moderate first-pass metabolism and is eliminated primarily as metabolites of much lower antihypertensive activity than the parent drug. The influences of age, renal and hepatic disease on the disposition of urapidil are reviewed. Studies on the relationship between pharmacodynamics and pharmacokinetics show that the optimum use of urapidil in clinical practice depends on an understanding of the pharmacokinetic properties of the drug.     

Clinical pharmacokinetics of voriconazole

This review presents the published clinical pharmacokinetic data for the antifungal agent voriconazole. Aspects regarding absorption, tissue distribution, elimination and kinetic interactions are also discussed.     

Clinical pharmacokinetics of atorvastatin

Hypercholesterolaemia is a risk factor for the development of atherosclerotic disease. Atorvastatin lowers plasma low-density lipoprotein (LDL) cholesterol levels by inhibition of HMG-CoA reductase. The mean dose-response relationship has been shown to be log-linear for atorvastatin, but plasma concentrations of atorvastatin acid and its metabolites do not correlate with LDL-cholesterol reduction at a given dose. The clinical dosage range for atorvastatin is 10-80 mg/day, and it is given in the acid form. Atorvastatin acid is highly soluble and permeable, and the drug is completely absorbed after oral administration. However, atorvastatin acid is subject to extensive first-pass metabolism in the gut wall as well as in the liver, as oral bioavailability is 14%. The volume of distribution of atorvastatin acid is 381L, and plasma protein binding exceeds 98%. Atorvastatin acid is extensively metabolised in both the gut and liver by oxidation, lactonisation and glucuronidation, and the metabolites are eliminated by biliary secretion and direct secretion from blood to the intestine. In vitro, atorvastatin acid is a substrate for P-glycoprotein, organic anion-transporting polypeptide (OATP) C and H+-monocarboxylic acid cotransporter. The total plasma clearance of atorvastatin acid is 625 mL/min and the half-life is about 7 hours. The renal route is of minor importance (<1%) for the elimination of atorvastatin acid. In vivo, cytochrome P450 (CYP) 3A4 is responsible for the formation of two active metabolites from the acid and the lactone forms of atorvastatin. Atorvastatin acid and its metabolites undergo glucuronidation mediated by uridinediphosphoglucuronyltransferases 1A1 and 1A3. Atorvastatin can be given either in the morning or in the evening. Food decreases the absorption rate of atorvastatin acid after oral administration, as indicated by decreased peak concentration and increased time to peak concentration. Women appear to have a slightly lower plasma exposure to atorvastatin for a given dose. Atorvastatin is subject to metabolism by CYP3A4 and cellular membrane transport by OATP C and P-glycoprotein, and drug-drug interactions with potent inhibitors of these systems, such as itraconazole, nelfinavir, ritonavir, cyclosporin, fibrates, erythromycin and grapefruit juice, have been demonstrated. An interaction with gemfibrozil seems to be mediated by inhibition of glucuronidation. A few case studies have reported rhabdomyolysis when the pharmacokinetics of atorvastatin have been affected by interacting drugs. Atorvastatin increases the bioavailability of digoxin, most probably by inhibition of P-glycoprotein, but does not affect the pharmacokinetics of ritonavir, nelfinavir or terfenadine.     

Clinical pharmacokinetics of oxcarbazepine

Oxcarbazepine is an antiepileptic drug with a chemical structure similar to carbamazepine, but with different metabolism. Oxcarbazepine is rapidly reduced to 10,11-dihydro-10-hydroxy-carbazepine (monohydroxy derivative, MHD), the clinically relevant metabolite of oxcarbazepine. MHD has (S)-(+)- and the (R)-(-)-enantiomer, but the pharmacokinetics of the racemate are usually reported. The bioavailability of the oral formulation of oxcarbazepine is high (>95%). It is rapidly absorbed after oral administration, reaching peak concentrations within about 1-3 hours after a single dose, whereas the peak of MHD occurs within 4-12 hours. At steady state, the peak of MHD occurs about 2-4 hours after drug intake. The plasma protein binding of MHD is about 40%. Cerebrospinal fluid concentrations of MHD are in the same range as unbound plasma concentrations of MHD. Oxcarbazepine can be transferred significantly through the placenta in humans. Oxcarbazepine and MHD exhibit linear pharmaco-kinetics and no autoinduction occurs. Elimination half-lives in healthy volunteers are 1-5 hours for oxcarbazepine and 7-20 hours for MHD. Longer and shorter elimination half-lives have been reported in elderly volunteers and children, respectively. Mild to moderate hepatic impairment does not appear to affect MHD pharmacokinetics. Renal impairment affects the pharmacokinetics of oxcarbazepine and MHD. The interaction potential of oxcarbazepine is relatively low. However, enzyme-inducing antiepileptic drugs such as phenytoin, phenobarbital or carbamazepine can reduce slightly the concentrations of MHD. Verapamil may moderately decrease MHD concentrations, but this effect is probably without clinical relevance. The influence of oxcarbazepine on other antiepileptic drugs is not clinically relevant in most cases. However, oxcarbazepine appears to increase concentrations of phenytoin and to decrease trough concentrations of lamotrigine and topiramate. Oxcarbazepine lowers concentrations of ethinylestra-diol and levonorgestrel, and women treated with oxcarbazepine should consider additional contraceptive measures. Due to the absent or lower enzyme-inducing effect of oxcarbazepine, switching from carbamazepine to oxcarbazepine can result in increased serum concentrations of comedication, sometimes associated with adverse effects. The effect of oxcarbazepine appears to be related to dose and to serum concentrations of MHD. In general, daily fluctuations of MHD concentration are relatively slight, smaller than would be expected from the elimination half-life of MHD. However, relatively high fluctuations can be observed in individual patients. Therapeutic monitoring may help to decide whether adverse effects are dependent on MHD concentrations. A mean therapeutic range of 15-35 mg/L for MHD seems to be appropriate. However, more systematic studies exploring the concentration-effect relationship are required.     

Clinical pharmacokinetics of ropinirole

Ropinirole is a selective non-ergoline dopamine D2 receptor agonist indicated for use in treating Parkinson's disease. When taken as oral tablets, ropinirole is rapidly and almost completely absorbed, and it is extensively distributed from the vascular compartment. The bioavailability is approximately 50%. Ropinirole shows low plasma protein binding. The drug is inactivated by metabolism in the liver, and none of the major circulating metabolites have pharmacological activity. The principal metabolic enzyme is the cytochrome P450 (CYP) isoenzyme CYP1A2. Ropinirole shows approximately linear pharmacokinetics when given as single or repeated doses, and is eliminated with a half-life of approximately 6 hours. Population pharmacokinetics have demonstrated that gender, mild or moderate renal impairment, Parkinson's disease stage and concomitant illnesses or the use of several common concomitant medications have no effect on the pharmacokinetics of ropinirole. Clearance is slower for patients older than 65 years compared with those who are younger, and in women taking hormone replacement therapy compared with those who are not. The CYP1A2 inhibitor ciprofloxacin produced increases in the plasma concentrations of ropinirole when these 2 drugs were coadministered, but no interaction was seen with theophylline which, like ropinirole, is also a substrate for CYP1A2. There is no obvious plasma concentration-effect relationship for ropinirole.     

Clinical pharmacokinetics of ketanserin

Ketanserin is a serotonin S2-receptor antagonist introduced for the treatment of arterial hypertension and vasospastic disorders. Plasma concentrations of ketanserin (and some metabolites) can be measured with high performance liquid chromatography using ultraviolet or fluorescence detection, or by radioimmunoassay. The methods are sensitive, accurate and specific. Following oral administration ketanserin is almost completely (more than 98%) and rapidly absorbed and peak concentrations in plasma are reached within 0.5 to 2 hours. It is subject to considerable extraction and metabolism in the liver (first-pass effect) and the absolute bioavailability is around 50%. The compound is extensively distributed to tissues and the volume of distribution is in the order of 3 to 6 L/kg. In plasma ketanserin binds avidly to plasma proteins, mainly albumin, and the free fraction is around 5%. Ketanserin is extensively metabolised and less than 2% is excreted as the parent compound. The major metabolic pathway is by ketone reduction leading to formation of ketanserin-ol which is mainly excreted in the urine. Ketanserin-ol, which by itself does not contribute to the overall pharmacological effect, is partly reoxidised into ketanserin, and it is likely that the terminal half-life of the parent compound is related to the slow ketanserin regeneration from the metabolite. Following intravenous administration plasma ketanserin concentrations decay triexponentially with sequential half-lives of 0.13, 2 and 14.3 h. The terminal half-life is similar after oral administration. Following long term oral dosing (20 or 40 mg twice daily) the pharmacokinetics remain linear and steady-state concentrations, which can be predicted from single-dose kinetics, are reached within 4 days. During long term treatment with the common dosage of 40 mg twice daily, steady-state concentrations fluctuate between 40 micrograms/L (trough) and 100 to 140 micrograms/L (peak). The pharmacokinetic properties of ketanserin are predictable in a wide group of patients and there is no influence from the duration of treatment, age and sex of the patient or concomitant treatment with beta-blockers or diuretics. There is no direct relationship between plasma concentrations of ketanserin and the antihypertensive effect in a group of patients. Side effects, including prolongation of the Q-T interval, are dose-dependent and, at least in the individual patient, related to peak plasma concentrations. In separate studies the pharmacokinetics of ketanserin were investigated in special patient groups, namely the elderly and patients with hepatic and renal insufficiency.(ABSTRACT TRUNCATED AT 400 WORDS)     

Clinical pharmacokinetics of teicoplanin

Teicoplanin is a recently introduced glycopeptide antibiotic for the treatment of a variety of aerobic and anaerobic Gram-positive infections. It is a mixture of 5 closely related components, of similar polarity and biological activity, and 1 or more polar hydrolysis products. Teicoplanin is rapidly and extensively absorbed from muscle and the peritoneal cavity but very poorly absorbed from the gastrointestinal tract. Following intravenous administration, the disposition kinetics are best described by a tri-exponential equation, and the majority of drug is excreted unchanged, by glomerular filtration. In patients with normal renal function, the half-lives of the first, second and terminal phases are 35 minutes, 10 hours and 87 hours, respectively. The initial volume of distribution is 0.089 L/kg, the volume of distribution at steady-state is 0.86 L/kg, clearance is 0.0114 L/h/kg and renal clearance is 0.0083 L/h/kg. Teicoplanin is highly bound in plasma to albumin (fraction unbound = 0.1) and in tissues. The pharmacokinetics are linear over a wide dose range (2 to 26 mg/kg). The minor differences in the pharmacokinetics of the components of teicoplanin can be accounted for by differences in lipophilicity. The events following multiple dosing are predicted from single dose data; renal clearance decreases in patients with renal insufficiency in a predictable manner. Negligible drug is lost during haemodialysis. As expected, clearance per kilogram is higher in children than in adults, and lower in the elderly, associated with a decrease in glomerular filtration rate with advancing years. Tissue distribution data are limited. Concentrations, relative to those in plasma, are high in lung and bone tissue and low in fat. Animal data show high concentrations in most tissues, and particularly high in liver and kidneys. Teicoplanin penetrates slowly and poorly into cerebrospinal fluid, but relatively rapidly and effectively in synovial and pleural fluids and in soft tissue. The manufacturer's recommended intravenous or intramuscular dosage regimens rapidly achieve and maintain adequate plasma concentrations of teicoplanin; the dosing interval is usually 1 day. The maintenance dosing rate, but not the loading dose (if needed), must be reduced in patients with poor renal function and in the elderly. For those patients on continuous ambulatory peritoneal dialysis, the peritoneal cavity offers a convenient alternative route of drug administration.