AGNP Consensus Guidelines for Therapeutic Drug Monitoring in Psychiatry: Update 2011.

Therapeutic drug monitoring (TDM), i. e., the quantification of serum or plasma concentrations of medications for dose optimization, has proven a valuable tool for the patient-matched psychopharmacotherapy. Uncertain drug adherence, suboptimal tolerability, non-response at therapeutic doses, or pharmacokinetic drug-drug interactions are typical situations when measurement of medication concentrations is helpful. Patient populations that may predominantly benefit from TDM in psychiatry are children, pregnant women, elderly patients, individuals with intelligence disabilities, forensic patients, patients with known or suspected genetically determined pharmacokinetic abnormalities or individuals with pharmacokinetically relevant comorbidities. However, the potential benefits of TDM for optimization of pharmacotherapy can only be obtained if the method is adequately integrated into the clinical treatment process. To promote an appropriate use of TDM, the TDM expert group of the Arbeitsgemeinschaft für Neuropsychopharmakologie und Pharmakopsychiatrie (AGNP) issued guidelines for TDM in psychiatry in 2004. Since then, knowledge has advanced significantly, and new psychopharmacologic agents have been introduced that are also candidates for TDM. Therefore the TDM consensus guidelines were updated and extended to 128 neuropsychiatric drugs. 4 levels of recommendation for using TDM were defined ranging from "strongly recommended" to "potentially useful". Evidence-based "therapeutic reference ranges" and "dose related reference ranges" were elaborated after an extensive literature search and a structured internal review process. A "laboratory alert level" was introduced, i. e., a plasma level at or above which the laboratory should immediately inform the treating physician. Supportive information such as cytochrome P450 substrate- and inhibitor properties of medications, normal ranges of ratios of concentrations of drug metabolite to parent drug and recommendations for the interpretative services are given. Recommendations when to combine TDM with pharmacogenetic tests are also provided. Following the guidelines will help to improve the outcomes of psychopharmacotherapy of many patients especially in case of pharmacokinetic problems. Thereby, one should never forget that TDM is an interdisciplinary task that sometimes requires the respectful discussion of apparently discrepant data so that, ultimately, the patient can profit from such a joint effort.

AGNP consensus guidelines for therapeutic drug monitoring in psychiatry: update 2011.

Therapeutic drug monitoring (TDM), i. e., the quantification of serum or plasma concentrations of medications for dose optimization, has proven a valuable tool for the patient-matched psychopharmacotherapy. Uncertain drug adherence, suboptimal tolerability, non-response at therapeutic doses, or pharmacokinetic drug-drug interactions are typical situations when measurement of medication concentrations is helpful. Patient populations that may predominantly benefit from TDM in psychiatry are children, pregnant women, elderly patients, individuals with intelligence disabilities, forensic patients, patients with known or suspected genetically determined pharmacokinetic abnormalities or individuals with pharmacokinetically relevant comorbidities. However, the potential benefits of TDM for optimization of pharmacotherapy can only be obtained if the method is adequately integrated into the clinical treatment process. To promote an appropriate use of TDM, the TDM expert group of the Arbeitsgemeinschaft für Neuropsychopharmakologie und Pharmakopsychiatrie (AGNP) issued guidelines for TDM in psychiatry in 2004. Since then, knowledge has advanced significantly, and new psychopharmacologic agents have been introduced that are also candidates for TDM. Therefore the TDM consensus guidelines were updated and extended to 128 neuropsychiatric drugs. 4 levels of recommendation for using TDM were defined ranging from "strongly recommended" to "potentially useful". Evidence-based "therapeutic reference ranges" and "dose related reference ranges" were elaborated after an extensive literature search and a structured internal review process. A "laboratory alert level" was introduced, i. e., a plasma level at or above which the laboratory should immediately inform the treating physician. Supportive information such as cytochrome P450 substrate and inhibitor properties of medications, normal ranges of ratios of concentrations of drug metabolite to parent drug and recommendations for the interpretative services are given. Recommendations when to combine TDM with pharmacogenetic tests are also provided. Following the guidelines will help to improve the outcomes of psychopharmacotherapy of many patients especially in case of pharmacokinetic problems. Thereby, one should never forget that TDM is an interdisciplinary task that sometimes requires the respectful discussion of apparently discrepant data so that, ultimately, the patient can profit from such a joint eff ort.

Prospective study of zonisamide therapy for refractory idiopathic epilepsy in dogs.

OBJECTIVES: Investigation of the efficacy of zonisamide as an add-on therapy in dogs with refractory epilepsy. METHODS: Thirteen dogs fulfilled the inclusion criteria of poor seizure control despite adequate serum levels of phenobarbital, potassium bromide or both. One further dog was treated with zonisamide as monotherapy because of severe blood dyscrasia due to phenobarbital treatment. Various seizure parameters were evaluated retrospectively for a four month period without zonisamide and prospectively for the same time period under zonisamide add-on therapy. The study time period was extended by up to 17 months to evaluate long-term outcome. RESULTS: Data of 11 dogs could be evaluated: nine of them were responders. The median reduction of seizure frequency of all dogs on zonisamide add-on therapy was 70 per cent (range 14 to 100 per cent). Only transient central nervous system side effects were reported. No further increase of liver enzymes occurred. In three of the responder dogs, seizure control subsided after individual time periods (between 69 days and seven months). CLINICAL SIGNIFICANCE: In dogs with refractory epilepsy, zonisamide may have a beneficial effect on seizure control. In three responder dogs, seizure activity relapsed possibly because of an induction of tolerance. Limiting factors are the high costs.

Lamotrigine clinical pharmacokinetics.

Lamotrigine is a new antiepileptic agent chemically unrelated to any established drugs in use. The drug can be estimated in biological fluids by high performance liquid chromatography and immunoassays. It is rapidly absorbed, reaching peak concentrations within about 3 hours postdose. The bioavailability of the oral formulation is about 98%. The area under the plasma concentration-time curve indicates dose-linear pharmacokinetics. The degree of plasma protein binding is 56%. Saliva concentrations are 46% of the plasma concentration. The concentration of lamotrigine in the brain is similar to the total concentration in the plasma. Lamotrigine exhibits first-order linear kinetics during long term administration. 43 to 87% of a dose is recovered in the urine, predominantly as glucuronide metabolites. Mean half-lives of lamotrigine in healthy volunteers (single and multiple doses) as well as in epileptic patients receiving lamotrigine monotherapy range from 22.8 to 37.4 hours. Enzyme-inducing antiepileptic drugs such as phenytoin, phenobarbital (phenobarbitone) or carbamazepine reduce the half-life of lamotrigine (to mean values of 13.5 to 15 hours), whereas valproic acid increases the half-life of the drug (to mean values of 48.3 to 59 hours). Lamotrigine itself does not influence the plasma concentrations of concomitant antiepileptic drugs, except for causing an increase in concentrations of carbamazepine-10,11-epoxide, the main metabolite of carbamazepine. Other observations indicate that the interaction of carbamazepine and lamotrigine may be primarily pharmacodynamic rather than pharmacokinetic. Usual dosages of lamotrigine range from 50 to 400 mg/day depending on an enzyme-inducing or -inhibiting comedication. Therapeutic plasma concentrations of the drug are not known, but a putative therapeutic range of 1 to 4 mg/L has been proposed. Some patients have tolerated concentrations > 10 mg/L with benefit and without clinical toxicity. The value of measuring the concentrations of lamotrigine in helping to optimise the dosage or reduce the likelihood of adverse effects has not been established. Safety data from several large studies indicate that the incidence of adverse effects of the drug is low and that unwanted effects are reversible.

Pharmacokinetic interactions of the new antiepileptic drugs.

Therapy with traditional antiepileptic drugs is associated with a wide range of pharmacokinetic drug-drug interactions. In particular, enzyme induction, enzyme inhibition and displacement from protein binding may result in important changes in serum concentrations of antiepileptics. Relevant interactions have also been described for some new antiepileptics. Felbamate increases serum concentrations of phenytoin, phenobarbital and valproic acid (sodium valproate). On the other hand, it reduces concentrations of carbamazepine and increases concentrations of its metabolite carbamazepine-10,11-epoxide. Concentrations of felbamate itself are reduced by phenytoin and carbamazepine. Concentrations of lamotrigine are considerably increased by valproic acid and decreased by phenytoin, carbamazepine and phenobarbital (phenobarbitone). Vigabatrin reduces serum concentrations of phenytoin by approximately 20%. On the other hand, some new antiepileptics have the important advantage of not interfering with the metabolism of other antiepileptics; this is the case for gabapentin, lamotrigine and oxcarbazepine. Furthermore, the pharmacokinetics of gabapentin, oxcarbazepine and vigabatrin are independent of concomitant drugs. These aspects are especially important as, until now, new antiepileptics have been most often utilised as add-on therapy.

Steady-state pharmacokinetics of phenytoin from routinely collected patient data.

Previously reported routine phenytoin clinical pharmacokinetic data from Japan, England, and Germany were analysed to estimate population pharmacokinetic parameters. There were 780 steady-state phenytoin concentrations and associated dosage rates (mg/day) from 322 patients. The patient group spanned paediatric and adult ages, mean age being 18.4 +/- 17.3 (SD) years; 53% were males. The data were analysed using NONMEM, a computer programme designed for population pharmacokinetic analysis. Estimates of the influence of age, gender, data source, height and weight on the maximum elimination rate (Vm) and Michaelis-Menten constant (Km) were obtained. The Vm and Km of a 70 kg adult male European were estimated to be 415 mg/day and 5.7 mg/L, respectively. Vm is not influenced by gender, age or data source. The parameters of a power function of height and weight were estimated to adjust Vm for body size. The best function adjusts Vm in proportion to weight to the 0.6 power; height contains no useful information. Km is not influenced by gender. The Km for patients less than 15 years old is 43% less than that of older patients. The Km of Japanese patients appears to be 23% less than that for European patients. Even after adjustments for age, etc., apparent Vm and Km vary unpredictably among individuals with a coefficient of variation between 10 to 20% and approximately 50% respectively.

Lack of effect of histological lesions on the phenytoin and phenobarbital concentrations in the brain cortex of epileptic patients.

Postmortem concentrations of phenytoin (PHT) and phenobarbital (PB) were determined in 24 specimens of the frontal, temporal, occipital or neocerebellar cortex with different pathological changes and in the serum (total and free) from 11 epileptic patients. The cortical lesions were characterized by various degrees of neuronal loss or necrosis associated with other changes such as proliferated gliocytes, fibre gliosis, Rosenthal fibres or numerous corpora amylacea. According to other investigators neurons are the main binding sites of PHT and PB in rodent brains. The PHT and PB concentrations in 20 cortical lesions from nine patients were not significantly reduced as compared to the data of 46 deceased epileptic control patients. A significantly decreased PB value could only be demonstrated in the temporal specimen of an old scarred infarction with complete demyelination. On the other hand a slight but significant increase of PB was observed in three neocortical samples from a child exhibiting severe brain oedema and thrombosis of the sinuses. The results favour the unspecific binding of PHT and PB to cerebral tissue constituents and do not support the hypothesis of major binding to specific receptors.

Lack of influence of histopathological changes on carbamazepine and carbamazepine-10, 11-epoxide concentrations in the brain cortex of epileptic patients.

Post-mortem concentrations of carbamazepine (CBZ) and its anticonvulsive metabolite carbamazepine-10,11-epoxide (CE) were determined in different lesions of the cerebral cortex and in the serum (total and free) from 13 epileptic patients. Twenty cortical specimens were obtained from the superior frontal gyrus, the temporopolar region and the neocerebellum. The cortical samples showed various pathological changes characterized by augmented glial cells, fibre gliosis or ulegyria as well as abundant corpora amylacea or encephalitic signs of viral type besides neuronal depletion. The CBZ and CE concentrations in the 20 cortical lesions were not significantly decreased when compared to the control specimens of 32 epileptic patients without essential histopathological alterations of the specified cortical areas (p < 0.05). A comparable result had been found in our former study on phenytoin (PHT) and phenobarbital (PB). Six patients with cortical lesions of the present series had already been included in this PHT/PB study. Five of these patients revealed unchanged CBZ and CE as well as PHT and PB concentrations. Only in one neocerebellar specimen the CE concentration was just above the upper 95% confidence limit of the control group. But, most probably this finding has no further relevance. The results greatly favour the nonspecific binding of CBZ and CE to cerebral tissue constituents.

Comparison between premortem and postmortem serum concentrations of phenobarbital, phenytoin, carbamazepine and its 10,11-epoxide metabolite in institutionalized patients with epilepsy.

The last premortem serum concentrations of phenobarbital (PB), phenytoin (PHT), carbamazepine (CBZ) and its CBZ-10,11-epoxide metabolite (CE) were compared with the corresponding postmortem serum concentrations in 16 adult patients of an epilepsy centre. Based on complete postmortem examinations, 12 individuals showed a known cause of death (KCD) and four patients succumbed from sudden unexplained death (SUD). The last premortem and the postmortem serum levels of PB (r = 0.991), PHT (r = 0.986), CBZ (r = 0.985) and CE (r = 0.936) were highly correlated. However, the regression analysis indicated that, except for CE, the premortem concentrations were significantly higher than the postmortem concentrations, i.e. 65% for PB, 34% for PHT, and 16% for CBZ. Varying time lapses (4-62 h) between death and serum sampling during autopsy did not significantly influence the ratio of premortem to postmortem serum levels for PB, PHT, CBZ, and CE (p > 0.1). Furthermore we found no significant differences between the premortem and the postmortem serum concentration ratios CE/CBZ. Considering the above variables, the data of SUD and KCD patients were comparable. Postmortem decrease in anticonvulsant serum concentrations, especially for PB and PHT, should be considered in order to avoid misinterpretation in respect to so-called 'subtherapeutic' serum levels and noncompliance in context with SUD or fatal intoxication.

Relationship between ischemic damage and concentrations of phenytoin and phenobarbital in the brain cortex of epileptic patients in vegetative state at death.

Post-mortem concentrations of phenytoin (PHT) and phenobarbital (PB) were determined by high-performance liquid chromatography in the cortical matter of specified brain regions and in the serum (total and free) from 3 epileptic males in vegetative state and compared to the data of 45 deceased epileptic control patients. The duration of the vegetative state was 12 days, 15 days or about 4 months until death and was associated with corresponding stages of generalized ischemic brain damage. The histological examination was completed by immunohistochemical and morphometric methods. According to other investigators nerve cells are the major binding sites for PHT and PB in the cerebral cortex of rodents. But, in the 3 comatose patients the PHT and PB concentrations of the isocortex and neocerebellum were not significantly decreased in comparison with the control patients despite necrosis and loss of neurons as well as other distinct tissue alterations. The results strongly favor the non-specific binding of PHT and PB to cells and subcellular structures of the brain-mainly based on simple physico-chemical principles.

[Therapeutic drug monitoring in epileptology and psychiatry]. / "Therapeutic drug monitoring" in Epileptologie und Psychiatrie.

Experts from epileptology and psychiatry reviewed the current significance of therapeutic drug monitoring (TDM) of antiepileptic drugs and psychiatric drugs in a workshop at Bethel Epilepsy Centre in December 2005. TDM has been essential in epileptology for about 30 years, and it is also increasingly important in psychiatry, in which consensus recommendations were published recently. With regard to cost-cutting in the health system, there are discussions about the financial effect of TDM and outsourcing it to bigger laboratories. In psychiatry it has however been shown that sensibly used TDM may lead to reduced costs. Many issues in TDM require the knowledge and experience of specialised laboratories. The use of TDM data for scientific purposes was discussed at the workshop as well.

Pharmacological interactions of mesuximide with phenobarbital and phenytoin in hospitalized epileptic patients.

In order to study the pharmacological interactions of the anticonvulsant drugs mesuximide (MSM), phenobarbital (PB), and phenytoin (PHT), serum concentrations of N-desmethyl-mesuximide (N-DESM-MSM, the main metabolite of MSM), PB, and PHT were determined in 94 hospitalized patients suffering from petit mal epilepsy. When MSM was administered to patients on stable PB or primidone therapy, the mean concentrations of PB increased by statistically significant amounts of 38 and 40%, respectively. Similarly, the additional administration of MSM caused the mean concentration of PHT to rise by 78%. The data also indicate that patients with PB and/or PHT comedication have higher N-DESM-MSM serum concentrations than patients without comedication. The pharmacological reasons for these interactions are discussed. These studies demonstrate that the disturbing side effects of MSM are often due to the co-medication. A carefully planned therapeutical dose procedure with regular serum level determinations is proposed to avoid or at least reduce the adverse effects of MSM.

Fluctuations of unbound and total phenytoin concentrations during the day in epileptic patients on valproic acid comedication.

The influence of daily fluctuations in the concentration of valproic acid (VPA) on the unbound and total concentration of phenytoin (PT) was examined in a prospective study. The serum concentrations of 28 patients with epilepsy (group PT + VPA) who were treated with PT and concurrently with VPA and 15 patients (group PT) who were treated with PT but without VPA comedication were determined at 8.00, 11.00, 14.00, 17.00, and in part at 20.00 h. The results show that there are significantly greater fluctuations in the total PT concentration among patients on VPA than those not on VPA. The fluctuations in the total PT concentration during the day correlated with the fluctuations in the VPA concentration. On the other hand, the fluctuations in the concentrations of unbound PT of patients on VPA were comparable with those not on VPA. In the absence of VPA, the diurnal fluctuations of the total PT concentration correlated highly significantly with the fluctuations of the unbound PT concentration. This is not the case in patients on VPA. Our data are a further indication of the smaller significance of the total PT concentration as compared with the unbound PT concentration in the combined treatment of PT and VPA.

Fluctuations of carbamazepine concentrations during the day for two slow-release preparations.

Fluctuations in the carbamazepine (CBZ) concentration during the day were studied using the profiles of 88 patients on slow release CBZ preparations. Blood was taken at 800, 1100, 1400, 1700, 2000, 2200 and 800 hr of the following day. The CBZ dosage was divided into two equal doses and administered at 800 and 2000 h. The influence of different factors on the fluctuations in the CBZ concentration during the day was studied. The fluctuation correlated negatively (r = -0.51, p less than 0.001) with the level-dose ratio LDR (CBZ morning concentration-CBZ dose per body weight ratio). The co-medication and preparation had no additional significant influence on fluctuations in the CBZ concentration during the day. The maximal CBZ serum concentration during the day can be described for most patients as a function of the CBZ morning concentration and the level-dose ratio using a suitable regression equation (r = 0.93, standard error of estimate = 1.2 mg/L).

Serum concentrations of valproic acid: influence of dose and comedication.

The influence of valproate (VPA) dose, VPA preparation used, comedication (phenobarbital, phenytoin, carbamazepine) and factors such as age, weight, height, and sex on the concentration of VPA in serum was investigated. Nonlinear regression analysis showed that about 63% of the variance in the VPA morning concentrations of 259 inpatients could be explained by the following variables: dose, body weight, sex, and comedication. Age, height, and kind of preparation had no important influence on the VPA concentration. The relationship between dose and concentration of VPA is nonlinear, as the concentration does not increase proportionally with the dose but increases to a lesser extent. The serum concentration of VPA is clearly lower when the drug is given in combination with phenytoin (49.5%), carbamazepine (66.2%), or phenobarbital (76.3%) than when given alone (100%).

Urinary hydroxyphenytoin/creatinine ratios as an index of compliance in adult epileptic patients on phenytoin therapy.

The ratio of the concentration of the phenytoin metabolite hydroxyphenyl phenylhydantoin (HPPH) to the creatinine concentration in morning urine samples was used as an index of compliance in adult epileptic patients on phenytoin therapy. For this purpose, the phenytoin dose was estimated from the urinary HPPH/creatinine ratio with the help of a regression equation that took into consideration body weight, height, age, and sex. A high correlation (r = 0.927 for men and r = 0.954 for women) between the prescribed and estimated dose was found for a reference group (127 hospitalized patients on supervised drug regimen). Compliance was judged from the discrepancy between the prescribed and the estimated dose for 45 patients immediately after their admittance to an epilepsy clinic, as well as for 98 outpatients, who had been treated by neurologists. Noncompliance was suspected in 6.7% of patients admitted to the clinic, as well as in 28.6% of the outpatients.

Serum concentrations of carbamazepine and its epoxide and diol metabolites in epileptic patients: the influence of dose and comedication.

The influence of carbamazepine (CBZ) dose, CBZ preparation used, comedication (phenobarbital, phenytoin, primidone, valproate), and factors such as age, weight, and sex on the concentration of CBZ and its metabolites carbamazepine-10,11-epoxide (CBZ-epoxide) and 10,11-dihydro-10,11-dihydroxy-carbamazepine (CBZ-diol) in serum was investigated. A non-linear regression analysis using the data of 609 patients shows that other anti-epileptic drugs can influence the metabolism of CBZ in various ways. The mean serum concentration of CBZ is lower when the drug is given in combination with phenytoin (59.4%), primidone (58.2%), phenobarbital (65.7%), and valproate (83.0%) than when CBZ is given alone (100%), whereas the mean concentration of CBZ-epoxide is increased by valproate (144.8%), by primidone (118.5%), and by a combination of the latter (167.4%). The CBZ-diol concentrations are also increased during concomitant treatment with the other antiepileptic drugs. Our results indicate a nonlinear relationship between the CBZ dose and the CBZ concentration, but a linear relationship between the CBZ dose and the CBZ-diol concentration.

Gas chromatographic methods for the determination of antiepileptic drugs: a systematic review.

Despite the availability of a variety of methods for determining the concentrations of antiepileptic drugs in body fluids--including thin-layer chromatography, high pressure liquid chromatography, radioimmunoassay, etc.--gas chromatography remains perhaps the routinely used tool for therapeutic drug monitoring in this area. As a result of the need to improve precision and reproducibility, as well as to reduce costs, among other factors, there has been a continuous technical improvement in the technique. And in the last 10 years, more than 100 papers have described gas chromatography for the determination of antiepileptic drugs. Needless to say, only a small percentage of these publications described methods of a significantly new character. In order to facilitate the task, of comparing methods for the purpose of choosing a technique suitable to a specific need, we have reviewed the analytic parameters described in the 114 publications of the last decade. These parameters include the following: (1) drugs determined, (2) internal standard, (3) amount of sample, (4) extraction procedure, (5) preparation of derivatives, (6) sample injection, (7) detection, (8) column support and temperature, and (9) stationary phase. We present these data in a comprehensive tabular form together with a number of comments concerning specific techniques.