Steady-state plasma concentrations of cis- and trans-10-OH amitriptyline metabolites

Pharmacokinetic Variability of Drugs Used for Prophylactic Treatment of Migraine

In this review, we evaluate the variability in the pharmacokinetics of 11 drugs with established prophylactic effects in migraine to facilitate 'personalized medicine' with these drugs. PubMed was searched for 'single-dose' and 'steady-state' pharmacokinetic studies of these 11 drugs. The maximum plasma concentration was reported in 248 single-dose and 115 steady-state pharmacokinetic studies, and the area under the plasma concentration-time curve was reported in 299 single-dose studies and 112 steady-state pharmacokinetic studies. For each study, the coefficient of variation was calculated for maximum plasma concentration and area under the plasma concentration-time curve, and we divided the drug variability into two categories; high variability, coefficient of variation >40%, or low or moderate variability, coefficient of variation <40%. Based on the area under the plasma concentration-time curve in steady-state studies, the following drugs have high pharmacokinetic variability: propranolol in 92% (33/36), metoprolol in 85% (33/39), and amitriptyline in 60% (3/5) of studies. The following drugs have low or moderate variability: atenolol in 100% (2/2), valproate in 100% (15/15), topiramate in 88% (7/8), and naproxen and candesartan in 100% (2/2) of studies. For drugs with low or moderate pharmacokinetic variability, treatment can start without initial titration of doses, whereas titration is used to possibly enhance tolerability of topiramate and amitriptyline. The very high pharmacokinetic variability of metoprolol and propranolol can result in very high plasma concentrations in a small minority of patients, and those drugs should therefore be titrated up from a low initial dose, depending mainly on the occurrence of adverse events.

Pharmacogenetics of Agents Acting on the Central Nervous System

This article will review the various agents affecting the central nervous system (CNS) such as the analgesics, antidepressants, anticonvulsants, antipsychotics, and benzodiazepines. Most of the research in pharmacogenetics with the CNS agents have been conducted in the antidepressants. The cytochrome 450 IID6 isozyme system has been shown to influence the disposition of the antidepressants and antipsychotics. Amitriptyline metabolism to nortriptyline and nortriptyline conversion to its 10-OH metabolite were shown to be influenced by the IID6 isozyme. Interestingly, imipramine metabolism to desipramine is only partially related to the IID6 isozyme. Biotransformation of imipramine to its 2-OH metabolite was shown to be affected by the IID6 isozyme, but its metabolism to the 10-OH remains to be investigated. Of the antipsychotic drugs, haloperidol and thioridazine are two agents most studied. Haloperidol is converted to a reduced metabolite via a ketone reductase enzyme. The reduced metabolite is oxidized back to Haloperidol. This oxidation pathway was reported to be affected by the IID6 isozyme. Thioridazine metabolism to mesoridazine and conversion of codeine to morphine appear to be also influenced by CP-450 IID6. Other 450 isozymes are reported to be involved with other CNS agents.

CYP2D6 and CYP2C19 genotypes and amitriptyline metabolite ratios in a series of medicolegal autopsies

In a series of 202 postmortem toxicology cases, the CYP2D6 and CYP2C19 genes were genotyped, and the concentrations of amitriptyline (AT) and six metabolites were analyzed. The polymorphic CYP2D6 and CYP2C19 genes encode enzymes participating in the metabolism of several potentially toxic drugs, and mutations in these genes may lead to adverse drug reactions, possibly even intoxications. AT was chosen as the substrate of interest because it is mainly metabolized by these enzymes, is considered relatively toxic, and ranks among the major causes of fatal drug poisoning in Finland. Our objective was to evaluate genetically determined interindividual variation in conjunction with metabolite ratios of drugs found in toxicological analysis in a series of medicolegal autopsies. Positive correlations were found between the proportion of trans-hydroxylated metabolites and the number of functional copies of CYP2D6 and between the proportion of demethylated metabolites and the number of functional copies of CYP2C19. None of the accidental or undetermined AT poisonings coincided with the CYP2D6 or CYP2C19 genotype which predicts a poor metabolizer phenotype. However, an unusually high femoral blood concentration of AT, 60mg/l, was found in one suicide case with no functional CYP2D6 genes. Our study shows a concordance of AT metabolite patterns with CYP2D6 and CYP2C19 genotypes in the presence of confounding factors typical for postmortem material. This result demonstrates the feasibility of postmortem pharmacogenetic analysis and supports the dominant role of genes in drug metabolism.

The Metabolic Fate of Amitriptyline, Nortriptyline and Amitriptylinoxide in Man

Amitriptyline (AT), the most widely used tricyclic antidepressant, undergoes oxidative metabolism in the side chain with production of the secondary amine nortriptyline (NT), a primary amine, and the N-oxide amitriptylinoxide (AT-NO); in addition, direct conjugation leads to a quaternary ammonium-linked glucuronide. Hydroxylation of AT or NT at the ethylene bridge of the central seven-membered ring results in four isomeric alcohols and occurs with high stereo- and enantioselectivity, the (-)-(E)-10-hydroxy compounds usually being the major products. The disposition of the alcohols is also partially enantioselective, for instance with regard to glucuronidation and reversible oxidation to ketones. Introduction of a second hydroxy group results in isomeric glycols. Oxidative attack at an aromatic ring is a minor pathway leading to dihydrodiols and phenols. Numerous metabolites originate by combinations of reactions in the ring system and the side chain. AT-NO is by about one-third excreted in unchanged form or as 10-hydroxy derivative; the major part is reduced to AT and metabolized further. The review covers current knowledge on the enzymes participating in the individual pathways. Their quantitative importance is inferred from kinetic studies in volunteers and patients and from experiments in vitro. Clinical consequences of biochemical findings mainly derive from the impact of the polymorphic CYP2D6 mediating (-)-(E)-10-hydroxylation and from its potential inhibition by other psychoactive drugs.

Enantioselective analytical methods in pharmacokinetics with specific reference to genetic polymorphic metabolism

The new trend towards developing enantiospecific drugs has increased the interest in enantiospecific pharmacokinetics of chiral drugs, mainly in the case where only one of the two enantiomers is responsible for the pharmacological activity. Enantiospecific bioassays are also useful in investigating the pharmacokinetic behaviour of the two enantiomers when a given drug is marketed as racemate. The stability of the stereogenic centre in vitro and in vivo, as far as unidirectional and bidirectional inversions are concerned, is another reason for requiring stereospecific assay and bioassay. These assays are often complicated in order to achieve quantification, mainly for in vivo measurements, which are often in the low pg/ml range. This paper considers the enantiospecific bioassays, the methods and approaches used, the need for chemical derivatization, and the difficulties involved. It includes a specific discussion for the genetic polymorphic metabolism involving stereogenic centres.

Metabolism of tricyclic antidepressants

1. Despite the considerable advances in the treatments available for mood disorders over the past generation, tricyclic antidepressants (TCAs) remain an important option for the pharmacotherapy of depression. 2. The pharmacokinetics of TCAs are characterized by substantial presystemic first-pass metabolism, a large volume of distribution, extensive protein binding, and an elimination half-life averaging about 1 day (up to 3 days for protriptyline). 3. Clearance of tricyclics is dependent primarily on hepatic cytochrome P450 (CYP) oxidative enzymes. Although the activities of some P450 isoenzymes are largely under genetic control, they may be influenced by external factors, such as the concomitant use of other medications or substances. Patient variables, such as ethnicity and age, also affect TCA metabolism. The impact of gender and related reproductive issues is coming under increased scrutiny. 4. Metabolism of TCAs, especially their hydroxylation, results in the formation of active metabolites, which contribute to both the therapeutic and the adverse effects of these compounds. 5. Renal clearance of the polar metabolites of TCAs is reduced by normal aging, accounting for much of the increased risk of toxicity in older patients. 6. Knowledge of factors affecting the metabolism of TCAs can further the development and understanding of newer antidepressant medications.

Food intake and the presystemic metabolism of single doses of amitriptyline and nortriptyline

The influence of food on presystemic metabolism of single doses of amitriptyline (AMI) and nortriptyline (NT) was examined. In randomised order 25 mg tablets of each drug was given to 9 healthy, female volunteers both in the fasting state and together with a standardised breakfast. Concentrations of the drugs and of their dealkylated, hydroxylated and conjugated metabolites were measured by gas chromatography--mass spectrometry (AMI experiment) or high-pressure liquid chromatography (NT experiment). Standard pharmacokinetic parameters were calculated. Food intake did not consistently or significantly influence the bioavailability of either AMI or NT, nor the demethylation of AMI, nor the hydroxylation or the primary or secondary conjugation of NT. There were large interindividual changes in AUC of AMI after food (+94% to -44%). A significant negative correlation between AUC of AMI but not of NT during fasting conditions and per cent change in AUC after food was found (r = -0.72, P = 0.029). The implication of this (negative) correlation for an individual patient might be to keep the intake of the drug in standardised relation to food to avoid undue heavy changes in drug concentration, which might just occur with a change in time relation between intake of drug and food. From a mechanistic view the results argue against a direct and selective influence of food on the presystemic oxidation and conjugation of weakly basic drugs but does not exclude that food may reduce the presystemic metabolism of some such drugs indirectly, by enhancing their rate of hepatic delivery. Presentation of data from food interaction studies should not be restricted to general descriptions. It seems equally important to present the variability of individual data to allow inspection of the extent and direction of effects. This should be of interest for patient, prescriber as well as the regulatory agency.

Investigation of xenobiotic metabolism by CYP2D6 and CYP2C19: importance of enantioselective analytical methods

Investigations into the genetic polymorphism of drug metabolism have involved specific models to screen poor and extensive metabolisers of xenobiotics. Debrisoquine, sparteine, S-mephenytoin and dextromethorphan are particularly well known. They have been extensively described in the literature and are used to phenotype human subjects before performing investigations with new drugs which are believed to be under the control of a genetic polymorphism. Dextromethorphan, debrisoquine and sparteine are good substrates for CYP2D6, whereas the S-enantiomer of mephenytoin is a good substrate for CYP2C19, both being two isozymes of cytochrome P-450. In many drugs, the hepatic microsomal oxidative metabolism involving stereogenic centres congregates either with CYP2D6 or with CYP2C19 or, in certain cases, with both of them. The availability of both CYP2D6 from poor and extensive metabolisers and an enantioselective assay would allow genetic polymorphism in drug biotransformation to be investigated in vitro ex vivo at an early stage of drug development before the IND (investigational new drug). Single-dose investigations in vivo can also be performed when only minimal pre-clinical toxicological data are available and produce more reliable results than in vitro studies. This paper focuses on the problem of genetic polymorphism in drug development and specifically discusses some relevant knowledge gained in the last two decades on enantioselective bioassays. Specific examples are given.

Stereoselective reversible ketone formation from 10-hydroxylated nortriptyline metabolites in human liver

1. E- and Z-10-hydroxynortriptyline are major metabolites of amitriptyline and nortriptyline in man. Upon incubation with human liver microsomes or cytosol, these metabolites were oxidized to the corresponding ketones, E- and Z-10-oxonortriptyline. (+)-E- and (+)-Z-10-hydroxynortriptyline were distinctly preferred over the (-)-isomers as substrates. NADP+ supported the oxidation in cytosol, whereas in microsomes NAD+ was the best cofactor. 2. Incubation of E- and Z-10-oxonortriptyline with NADPH and cytosol resulted in the nearly exclusive formation of (+)-E- and (+)-Z-10-hydroxynortriptyline. Kinetic analysis revealed high-affinity reduction (K(m) 1-2 microM) of the two ketones and an additional low-affinity component with the E-isomer. 10-Oxonortriptyline reduction was also catalysed by rabbit, but not by rat or guinea pig liver cytosol. 3. With [4-3H]NADPH as cosubstrate, tritium was incorporated into E- and Z-10-hydroxynortriptyline preferentially from the pro-4R position. Redox cycling of (+)-E- and (+)-Z-10-hydroxynortriptyline in cytosol in the presence of NAD- and NADPH was indicated by 3H incorporation from [pro-4R-3H]NADPH. 4. Recombinant human carbonyl reductase catalysed low-affinity reduction of E-10-oxonortriptyline with preferential transfer of the pro-4S-3H of labelled NADPH. 5. Ketone reduction in cytosol was strongly inhibited by 9,10-phenanthrenequinone and dehydrolithocholic acid and moderately by other 3-oxo steroids and some anti-inflammatory drugs. 6. The high-affinity reduction of E- and Z-10-oxonortriptyline and the oxidation of the alcohols in cytosol are probably mediated by a member of the aldo-keto reductase family of enzymes.

Interindividual variations of desmethylation and hydroxylation of amitriptyline in a Japanese psychiatric population

We measured the concentrations in plasma of amitriptyline and its metabolites, nortriptyline and geometric isomers of 10-hydroxynortriptyline and 10-hydroxyamitriptyline, in 73 Japanese psychiatric patients receiving amitriptyline hydrochloride (Tryptanol; Banyu Pharmaceutical Co. Ltd., Tokyo, Japan) by high-performance liquid chromatography. Although there were large interindividual variations of total drug concentrations and concentrations of parent or intermediate metabolic compounds in plasma, significant positive correlations were observed between these drug concentrations and daily doses of amitriptyline hydrochloride (milligrams per kilogram of body weight). The metabolic ratios for both hydroxylation and desmethylation varied substantially with approximately 8- to 19-fold interindividual variations. Frequency distribution histograms and probit analyses of these parameters identified neither definite poor hydroxylators nor poor desmethylators of amitriptyline.

Clinical significance of plasma levels of clomipramine, its hydroxylated and desmethylated metabolites: prediction of clinical outcome in mood disorders using discriminant analysis of therapeutic drug monitoring data

We measured the plasma concentrations of clomipramine and its metabolites, N-desmethylclompiramine, 8-hydroxy-N-desmethylclomipramine, 8-hydroxyclomipramine in 65 depressed patients with subtypes of DSM-III-R mood disorders receiving clomipramine hydrochloride. There were large interindividual variations in the concentrations of the parent and each of the metabolic compounds, though the overall correlations between drug concentrations and daily doses of clomipramine were highly significant. Metabolic ratios for both desmethylation and hydroxylation varied by 15-35-fold interindividually. Discriminant analysis of the data from drug concentrations and scores of Global Assessment of Functioning revealed that it is useful to monitor the concentrations of both desmethylated and hydroxylated metabolites in order to predict the clinical effects of clomipramine.

Simultaneous determination of trimipramine and desmethyl- and hydroxytrimipramine in plasma and red blood cells by capillary gas chromatography with nitrogen-selective detection

A simple procedure is described that permits the simultaneous determination of trimipramine and its two major metabolites, desmethyl- and hydroxytrimipramine, in human plasma or red blood cells (RBCs) at therapeutic concentrations. The extracted biological fluids are injected into a capillary gas chromatograph with an OV-1 fused-silica column coupled to a nitrogen-phosphorus-selective detector. The limit of determination for trimipramine is 3 ng/ml and for that desmethyl- and hydroxytrimipramine is 4 ng/ml. The method permits the RBC/plasma ratios to be determined and to be correlated with the clinical response.

An automated method for the determination of nortriptyline and its isomeric 10-hydroxylated metabolites in plasma by high pressure liquid chromatography

A high pressure liquid chromatography assay for determination of the tricyclic antidepressant nortriptyline (NT) and its two major metabolites, Z- and E-10-Hydroxy-NT, in plasma is described. Sample preparation included addition of internal standard and a single step extraction procedure. Run time was approximately 14 min. with a LC-18. 5 mu 250 x 4.6 mm column, a mobile phase consisting of aqueous ammonium: methanol: acetonitrile (0.8:6.2:93, v/v), and flow of 1.3 ml/min. NT, Z- and E-10-OH-NT, amitriptyline, Z- and E-10-OH-AT and the internal standard desipramine, were adequately separated within this time span. In our laboratory, the assay has been employed mainly for pharmacokinetic and toxicologic studies in experimental animals at relatively high concentrations.

Development of a rapid extraction and high-performance liquid chromatographic separation for amitriptyline and six biological metabolites

The development of a rapid high-performance liquid chromatographic method for the determination of amitriptyline, amitriptyline-N-oxide, 10-hydroxyamitriptyline, 10-hydroxynortriptyline (E and Z isomers), nortriptyline and desmethylnortriptyline in plasma and liver tissue is described. A liquid--liquid extraction with hexane--butanol and back-extraction into phosphoric acid provides efficient extraction of amitriptyline-N-oxide along with amitriptyline and the other metabolites. A Supelcosil C8 reversed-phase column with 5-micron packing and a methanol--sodium phosphate buffer--amine modifier mobile phase was used. The combination of mobile phase pH and amine modifier concentration for the best separation within a reasonable analysis time for all seven solutes plus an internal standard was determined using a factorial design coupled with a multi-factor window diagram technique. Ultraviolet detection at 214 nm provided limits of detection of approximately 1 ng/ml.

Influence of neuroleptics on the metabolism of tricyclic antidepressants--in vitro experiments with rat liver microsomes

The influence of two neuroleptics--the phenothiazine perazine and the butyrophenone haloperidol--on the metabolism of the tricyclic antidepressants amitriptyline (AMI), imipramine (IMI), and chlorimipramine (CMI) was studied in vitro in isolated liver microsomes of female Sprague-Dawley rats. The rats were pretreated over 10 days with either NaCl solutions or with 1, 3, and 10 mg/kg haloperidol or 5 and 15 mg/kg perazine, respectively. The microsomal fraction was incubated with various concentrations of antidepressants. The drugs and their metabolites were analyzed by high-performance liquid chromatography (HPLC). Neither pretreatment with haloperidol nor perazine had any significant influence on the demethylation and N-oxidation activity of the microsomes. Benzylic 10-hydroxylation of AMI or IMI or 10- and 11-hydroxylation of CMI was inhibited significantly by pretreatment with perazine, as was 2-hydroxylation of IMI and CMI, whereas 8-hydroxylation of CMI was not influenced. The inhibition was dose dependent. With haloperidol, only the high dose of 10 mg/kg caused a significant inhibition of benzylic 10-hydroxylation, whereas phenolic hydroxylation was not influenced. The inhibition was much lower than for perazine. Comparing the results with pharmacokinetic studies in humans revealed a good agreement in metabolic pathways. The study could therefore be important in the choice of neuroleptic drugs in combination therapy.

Uptake of serotonin into rat platelets and synaptosomes: comparative structure-activity relationships, energetics and evaluation of the effects of acute and chronic nortriptyline administration

In order to establish whether the uptake systems in platelets and synaptosomes are equivalent, the structure-activity relationships for drug-induced inhibition of serotonin uptake were examined in vitro. The rank order for potency of inhibitors was the same in platelets as in synaptosomes, namely imipramine greater than nortriptyline greater than desmethylimipramine much much greater than norepinephrine greater than histamine; in addition, serotonin uptake was clearly distinguishable from the norepinephrine synaptic uptake mechanism, which displayed a different rank order. The synaptosomal uptake of serotonin was, however, much more dependent upon maintenance of Na+-K+-ATPase activity for its energy source than was the platelet uptake mechanism. Acute administration of nortriptyline produced substantial inhibition of platelet serotonin uptake and a smaller degree of inhibition of synaptosomal uptake; inhibition was detectable even after extensive washing of the platelet and synaptosome preparations, and was associated with persistent binding of the drug to the organelles. Chronic infusion of nortriptyline (20 mg/kg for 21 days, followed by a 24 hr washout period to dissipate persistent binding) did not alter the uptake capacity of synaptosomal or platelet preparations, but did cause a shift in the drug specificity of inhibitors. The latter effect was in opposite directions in platelets vs. synaptosomes. These data indicate that the platelet uptake mechanism does bear some resemblance to that seen in serotonergic neurons, but that the energy source for transport differs and the two mechanisms respond differently to prolonged drug administration in vivo. The use of uptake as a marker during the course of antidepressant administration is likely to be confounded by persistent direct drug effects on these organelles.

Therapeutic monitoring of psychotherapeutic drugs: role of the clinical laboratory

Therapeutic monitoring of drugs is a well established clinical tool. However, the state of the art is somewhat less advanced for drugs used in psychiatry than it is for other classes of drugs, for several reasons. Most psychotherapeutic drugs have large volumes of distribution and achieve relatively low plasma concentrations following therapeutic doses. Many have one or more active metabolites. While psychotherapeutic drugs act through biochemical mechanisms, they are used to treat clinical syndromes which may be heterogeneous in their biochemical pathogenesis. As a consequence, the analytical methodologies are often complex and not always reliable; well-controlled clinical studies are difficult to perform; the therapeutic ranges have been difficult to establish. Despite these limitations, prudent and selective monitoring of serum drug concentrations, particularly of the tricyclic antidepressants, can be helpful in clinical management.

Analysis of tricyclic antidepressant drugs in plasma and serum by chromatographic techniques

A review of methods for the determination of tricyclic antidepressants in plasma or serum, based on the application of chromatographic techniques, is presented. A general discussion of the techniques in terms of their precision, accuracy, sensitivity and selectivity, with respect to parent drug and metabolites, is used to facilitate a comparison of methods. No one technique can be claimed as the method of choice for these drugs, although gas-liquid chromatography with nitrogen selective detection has some strong claims, viz. generally good sensitivity and reproducibility of assays and ready availability of equipment in most laboratories. The ultimate choice of a method for determining tricyclics will be determined more by the clinical application (routine monitoring versus pharmacokinetics) than by other factors.

Determination of trimipramine and metabolites in plasma by liquid chromatography with electrochemical detection

A procedure for the determination of trimipramine, the demethyl, 2-hydroxy, and 2-hydroxy demethyl metabolites in plasma by liquid chromatography with electrochemical detection is described. A 1-mL plasma sample is made alkaline with a carbonate buffer (pH 9.8) and extracted with 20% ethyl acetate in n-heptane. After back-extraction into an acid phosphate buffer, an aliquot is injected onto a reverse-phase trimethylsilyl-packed column and eluted with a phosphate buffer-acetonitrile mobile phase (65:35) containing n-butylamine. The peaks were detected at +1.1 V versus the silver-silver chloride reference electrode. The method provides absolute recoveries of 60-91% and a day-to-day precision of less than 9% for all compounds. The minimum quantifiable level for all compounds was 3 ng/mL. Steady-state plasma concentration data for 29 depressed patients receiving either 75 mg or 150 mg/d is reported.

An evaluation of the EMIT st assay for the detection of tricyclic antidepressant drugs in plasma or serum

The EMIT st assay for tricyclic antidepressant drugs (TADs) was evaluated for use as a screening technique in the detection of these drugs in serum or plasma. The qualitative assay was found to be rapid, easy to perform, requires no sample or reagent preparations, and reliably detected the TADs in patient samples at concentrations greater than or equal to 200 ng/mL. The technique also detected seventeen of nineteen patient samples with TAD concentrations ranging from 150-199 ng/mL and ten of forty-three samples with concentrations less than 150 ng/mL. The EMIT st assay was found to be a reliable technique for detecting high concentrations of TADs and is well-suited for use in emergency drug screening situations.

Selection of analytic methods for therapeutic drug monitoring

Selection of an analytic method for therapeutic drug monitoring usually involves an initial choice between chromatography and immunoassay. Once this decision has been made, numerous options remain within these two broad categories. There is no single correct or preferred assay technique. The best decision, based on technical, clinical, and economic considerations, will vary in different clinical and laboratory environments. The laboratory that has sufficient resources to maintain more than one type of technology will have a greater degree of flexibility in solving special problems.

Quantification of amitriptyline, nortriptyline, and 10-hydroxy metabolite isomers in plasma by capillary gas chromatography with nitrogen-sensitive detection

A selective, sensitive method for the determination of amitriptyline and its metabolites is described. This method involves liquid-liquid extraction and capillary gas chromatography with nitrogen-sensitive detection. The detection limits of amitriptyline, nortriptyline, 10-hydroxy(E)amitriptyline, 10-hydroxy(E)nortriptyline, and 10-hydroxy(Z)nortriptyline were slightly less than 0.5 ng/ml in 1.0-ml plasma samples. The coefficients of variation for within-run and between-run analyses of samples containing 100 ng/ml were less than 12% and 9%, respectively. The method offers rapid analysis of individual isomers, increased sensitivity over high-performance liquid chromatographic methodology and the conveniences of the gas chromatographic technique.