Determination of mesoridazine by liquid chromatography-tandem mass spectrometry and its application to pharmacokinetic study in rats.

The object of the present study was to develop and validate an assay method of mesoridazine in rat plasma using liquid chromatography-tandem mass spectrometry (LC-MS/MS). Plasma samples from rats were prepared by simple protein precipitation and injected onto the LC-MS/MS system for quantification. Mesoridazine and chlorpromazine as an internal standard (IS) were separated by a reversed phase C18 column. A mobile phase was composed of 10mM ammonium formate in water and acetonitrile (ACN) (v/v) by a linear gradient system, increasing the percentage of ACN from 2% at 0.4min to 98% at 2.5min with 4min total run time. The ion transitions monitored in positive-ion mode [M+H](+) of multiple-reaction monitoring (MRM) were m/z 387>126 for mesoridazine and m/z 319>86 for IS. The detector response was specific and linear for mesoridazine at concentrations within the range 0.001-4µg/ml and the correlation coefficient (R(2)) was greater than 0.999 and the signal-to-noise ratios for the samples were ≥10. The intra- and inter-day precision and accuracy of the method were determined to be within the acceptance criteria for assay validation guidelines. The matrix effects were approximately 101 and 99.5% from rat plasma for mesoridazine and chlorpromazine, respectively. Mesoridazine was stable under various processing and/or handling conditions. Mesoridazine concentrations were readily measured in rat plasma samples after intravenous and oral administration. This assay method can be practically useful to the pharmacokinetic and/or toxicokinetic studies of mesoridazine.

Relevance of CYP2D6 -1584C>G polymorphism for thioridazine:mesoridazine plasma concentration ratio in psychiatric patients.

AIMS: The CYP2D6 -1584C>G (rs1080985) polymorphism has been identified as another major factor for CYP2D6 function that is possibly associated with ultrarapid metabolism. The mutant -1584G promoter genotype seems to be consistently related to a higher protein expression than -1584C. However, the impact this SNP in the CYP2D6 promoter region has on plasma levels of patients taking CYP2D6 substrates, such as thioridazine, has not been studied. Previously, we showed the validity of the mesoridazine:thioridazine ratio to assess CYP2D6 activity in clinical settings. Therefore, the aim of this study was to analyze the relationship between the presence of the CYP2D6 -1584C>G polymorphism and the plasma concentrations of thioridazine and its metabolites in a previously studied population of patients in order to evaluate the implications for CYP2D6 hydroxylation capacity. MATERIALS & METHODS: The CYP2D6 -1584C>G polymorphism was determined by using a PCR-RFLP method in 61 Caucasian psychiatric patients receiving thioridazine monotherapy. RESULTS: Among patients with two active CYP2D6 genes, there were significant differences in the thioridazine:mesoridazine plasma concentrations ratio (p < 0.05) among the three CYP2D6 -1584C>G genotype groups. Moreover, in this group of patients the thioridazine:mesoridazine ratio was lower (p < 0.05) in carriers of CYP2D6 -1584G allele than in patients homozygous for CYP2D6 -1584C allele. However, no differences in thioridazine or its metabolite concentrations between homozygous CYP2D6 -1584C allele carriers and carriers of the -1584G allele were found. CONCLUSION: According to the present results the concentration ratio of thioridazine to mesoridazine was related to the CYP2D6 -1584C>G polymorphism. It is likely that individuals who carry CYP2D6 -1584G versus homozygotes for the -1584C allele may present an increased CYP2D6 activity.

Factors affecting drug concentrations and QT interval during thioridazine therapy.

The objective of this study was to investigate factors affecting steady-state plasma concentrations of thioridazine. A cross-sectional study of patients receiving chronic thioridazine was employed. Common allelic variants of CYP2D6 and CYP2C19, as well as thioridazine and metabolite concentrations and QTc intervals, were determined. In 97 patients, dose-corrected plasma concentrations (C/Ds) of thioridazine and metabolites were correlated with age but not sex or CYP2C19 genotype. Patients with no functional CYP2D6 alleles (n=9) had significantly higher C/D for thioridazine (P=0.017) and the ring sulfoxide metabolite and a significantly higher thioridazine/mesoridazine ratio compared with those with >/=1 functional CYP2D6 allele (n=82). Smokers had significantly lower C/D for thioridazine, mesoridazine, and sulforidazine and significantly lower thioridazine/ring sulfoxide ratios than non-smokers. QTc interval was not significantly affected by CYP2D6 or CYP2C19 genotypes. Plasma concentrations of thioridazine are influenced by age, smoking, and CYP2D6 genotype, but CYP2D6 genotype does not appear to influence on-treatment QTc interval.

Comparison of the effects of thioridazine and mesoridazine on the QT interval in healthy adults after single oral doses.

We compared the effects of single doses of thioridazine and mesoridazine on the heart rate-corrected QT (QTc) interval in healthy adult volunteers. QTc intervals and plasma concentrations of thioridazine, mesoridazine, and metabolites were measured after single oral doses of thioridazine hydrochloride 50 mg, mesoridazine besylate 50 mg, or placebo in a double-blind, crossover study. Mean maximum increases in the QTc interval following thioridazine (37.3+/-4.1 ms, P=0.023) and mesoridazine (46.6+/-7.4 ms, P=0.021) were similar and significantly greater than following placebo (12.9+/-8.1 ms). The area under the effect-time curve over 8 h following drug administration was similar between the two drugs (129.3+/-22.1 vs 148.3+/-43.0 ms h). In conclusion, thioridazine and mesoridazine are associated with similar effects on the QTc interval.

Use of the mesoridazine/thioridazine ratio as a marker for CYP2D6 enzyme activity.

Thioridazine is metabolized in humans by CYP2D6 to mesoridazine, which is an active metabolite. Two or more CYP2D6 substrates are seldom given simultaneously to elderly patients because potentially dangerous metabolic interactions may occur. It may be valuable to know the CYP2D6 metabolic capacity of such patients to avoid drug interactions, which depend on the metabolic phenotype. The goal of this study was to evaluate the use of the mesoridazine/thioridazine ratio for the estimation of CYP2D6 enzyme capacity. A sensitive and reliable method has been developed for the determination of thioridazine and its metabolites, mesoridazine and sulforidazine. Commonly used central nervous system (CNS) comedications do not interfere with the method. A group of 27 chronic patients with mental illness receiving monotherapy with thioridazine were studied. There were 23 men and 4 women between 37 and 80 years old (mean +/- SD: 61.2 +/- 10.2). The thioridazine/mesoridazine ratio correlated with the debrisoquine metabolic ratio (r = 0.74, p < 0.001). Therefore, the authors suggest that the measurement of thioridazine and its metabolite might be a useful tool to assess CYP2D6 activity during treatment.

Pharmacokinetic interaction of fluvoxamine and thioridazine in schizophrenic patients.

This study investigated to what extent fluvoxamine affects the pharmacokinetics of thioridazine (THD) in schizophrenic patients under steady-state conditions. Concentrations of THD, mesoridazine, and sulforidazine were measured in plasma samples obtained from 10 male inpatients, aged 36 to 78 years, at three different time points: A, during habitual monotherapy with THD at 88 +/-54 mg/day; B, after addition of a low dosage of fluvoxamine (25 mg twice a day) for 1 week; and C, 2 weeks after fluvoxamine discontinuation. After the addition of fluvoxamine, THD concentrations relative to time point A significantly increased approximately threefold from 0.40 to 1.21 micromol/L (225%) (p < 0.002), mesoridazine concentrations increased from 0.65 to 2.0 micromol/L (219%) (p < 0.004), and sulforidazine levels increased from 0.21 to 0.56 micromol/L (258%) (p < 0.004). The THD-mesoridazine and THD-sulforidazine ratios remained unchanged during the study. Mean plasma THD, mesoridazine, and sulforidazine levels decreased at time point C, but despite fluvoxamine discontinuation for 2 weeks, three patients continued to exhibit elevated concentrations of THD and its metabolites. In conclusion, fluvoxamine markedly interferes with the metabolism of THD, probably at the CYP2C19 and/or CYP1A2 enzyme level. Therefore, clinicians should be aware of the potential for a clinical drug interaction between both compounds, and careful monitoring of THD levels is valuable to prevent the accumulation of the drug and resulting toxicity.

Pharmacokinetics of thioridazine and its metabolites in blood plasma and the brain of rats after acute and chronic treatment.

This study was aimed at investigation of the pharmacokinetics of thioridazine and its metabolites after a single and repeated administrations. Male Wistar rats received thioridazine as a single dose (10 mg/kg i.p.) or they were treated chronically with the neuroleptic (10 mg/kg i.p., twice a day for two weeks). Plasma and brain concentrations of thioridazine and its metabolites (N-desmethylthioridazine, mesoridazine, sulforidazine, and the ring sulfoxide) were determined using the HPLC method. The obtained data showed that sulfoxidation in position 2 of the thiomethyl substituent and in the thiazine ring are main metabolic pathways of thioridazine, and showed that, in contrast to humans, in the rat N-desmethylthioridazine is formed in appreciable amount. The biotransformation of thioridazine was rather fast yielding plasma peak concentrations of metabolites lower than that of the parent compound. The maximum concentrations of thioridazine and its metabolites in the brain appeared later than in plasma. The peak concentrations and AUC values of thioridazine and its metabolites were higher in the brain than in plasma and this corresponded well with their longer half-lives in the brain as compared to plasma. The drug was not taken up by the brain as efficiently as other phenothiazines. Chronic treatment with thioridazine produced significant increases (with the exception of thioridazine ring sulfoxide) in the plasma concentrations of the parent compound and its metabolites which was accompanied with the prolongation of their plasma half-lives. The observed plasma levels of thioridazine were within 'therapeutic range' while the concentrations of its metabolites were relatively lower as compared to those observed in psychiatric patients. The increased plasma concentrations of thioridazine and its metabolites observed in plasma after chronic treatment were not followed by parallel changes in the brain.

Plasma levels of the enantiomers of thioridazine, thioridazine 2-sulfoxide, thioridazine 2-sulfone, and thioridazine 5-sulfoxide in poor and extensive metabolizers of dextromethorphan and mephenytoin.

Concentrations of total (R) + (S) and of the enantiomers (R) and (S) of thioridazine and metabolites were measured in 21 patients who were receiving 100 mg thioridazine for 14 days and who were comedicated with moclobemide (450 mg/day). Two patients were poor metabolizers of dextromethorphan and one was a poor metabolizer of mephenytoin. Cytochrome P450IID6 (CYP2D6) is involved in the formation of thioridazine 2-sulfoxide (2-SO) from thioridazine and also probably partially in the formation of thioridazine 5-sulfoxide (5-SO), but not in the formation of thioridazine 2-sulfone (2-SO2) from thioridazine 2-SO. Significant correlations between the mephenytoin enantiomeric ratio and concentrations of thioridazine and metabolites suggest that cytochrome P450IIC19 could contribute to the biotransformation of thioridazine into yet-unknown metabolites, other than thioridazine 2-SO, thioridazine 2-SO2, or thioridazine 5-SO. An enantioselectivity and a large interindividual variability in the metabolism of thioridazine have been shown: measured (R)/(S) ratios of thioridazine, thioridazine 2-SO fast eluting (FE), thioridazine 2-SO slow eluting (SE), thioridazine 2-SO (FE+SE), thioridazine 2-SO2, thioridazine 5-SO(FE), and thioridazine 5-SO(SE) were (mean +/- SD) 3.48 +/- 0 .93 (range, 2.30 to 5.80), 0.45 +/- 0.22 (range, 0.21 to 1.20), 2.27 +/- 8.1 (range, 6.1 to 40.1), 4.64 +/- 0.68 (range, 2.85 to 5.70), 3.26 +/- 0.58 (range, 2.30 to 4.30), 0.049 +/- 0.019 (range, (0.021 to 0.087), and 67.2 +/- 66.2 (range, 16.8 to 248), respectively. CYP2D6 is apparently involved in the formation of (S)-thioridazine 2-SO(FE), (R)-thioridazine 2-SO(SE), and also probably (S)-thioridazine 5-SO(FE) and (R)-thioridazine 5-SO(SE).

Light-induced racemization: artifacts in the analysis of the diastereoisomeric pairs of thioridazine 5-sulfoxide in the plasma and urine of patients treated with thioridazine.

The ring sulfoxidation of thioridazine (THD), a widely used neuroleptic agent, yields two diastereoisomeric pairs, fast- and slow-eluting (FE and SE) thioridazine 5-sulfoxide (THD 5-SO). Until now, studies in which concentrations of these metabolites were measured in THD-treated patients have revealed no significant differences in their concentrations. Preliminary experiments in our laboratory had shown that sunlight and, to a lesser extent, dim daylight led to racemization and probably also to photolysis of the diastereoisomeric pairs as measured by high-performance liquid chromatography. Similar results were also obtained with direct UV light (UV lamp). In appropriate light-protected conditions, THD, northioridazine, mesoridazine, sulforidazine, and FE and SE THD 5-SO were measured in 11 patients treated with various doses of THD for at least 1 week. Significantly higher concentrations of the FE stereoisomeric pair were found. The concentration ratios THD 5-SO (FE)/THD 5-SO (SE) ranged from 0.89 to 1.75 in plasma and from 1.15 to 2.05 in urine. Because it is known that the ring sulfoxide contributes to the cardiotoxicity of the drug even more potently than the parent compound does, these results justify further studies to determine whether there is stereoselectivity in the cardiotoxicity of THD 5-SO.

Plasma levels of thioridazine and metabolites are influenced by the debrisoquin hydroxylation phenotype.

The pharmacokinetics of thioridazine and its metabolites were studied in 19 healthy male subjects: 6 slow and 13 rapid hydroxylators of debrisoquin. The subjects received a single 25 mg oral dose of thioridazine, and blood samples were collected during 48 hours. Concentrations of thioridazine and metabolites in serum were measured by HPLC. Slow hydroxylators of debrisoquin obtained higher serum levels of thioridazine with a 2.4-fold higher Cmax and a 4.5-fold larger AUC(0-infinity) associated with a twofold longer half-life compared with that of rapid hydroxylators. The side-chain sulphoxide (mesoridazine) and sulphone (sulphoridazine), which are active metabolites, appeared more slowly in serum and had lower Cmax values, but comparable AUC. The thioridazine ring-sulphoxide attained higher Cmax and 3.3-fold higher AUC in slow hydroxylators than in rapid hydroxylators of debrisoquin. Thus the formation of mesoridazine from thioridazine and the 4-hydroxylation of debrisoquin seem to be catalyzed by the same enzyme, whereas the formation of thioridazine ring-sulphoxide is probably formed mainly by another enzyme.

Single dose kinetics of thioridazine and its two psychoactive metabolites in healthy humans: a dose proportionality study.

Dose proportionality in some pharmacokinetic parameters for thioridazine and its two active metabolites (mesoridazine and sulforidazine) was investigated in 11 healthy human subjects following oral administration of three single doses (25, 50, and 100 mg) of thioridazine hydrochloride separated in each case by an interval of two weeks. Also, after a further two weeks, another 100-mg dose of thioridazine (divided as 5 mg every 0.5 h) was administered to all the volunteers to investigate the effect of a slow rate of dosage input on the pharmacokinetic parameters of this drug. An HPLC method was used to measure concentrations of thioridazine, mesoridazine, and sulforidazine in plasma samples collected up to 72 h following each dose. Dose proportionality for the three single doses of thioridazine was observed for all three analytes in the area under the plasma concentration versus time curves (AUC infinity 0 or AUCt0) and the maximum plasma concentration (Cmax) in that the relationships between the dose and these parameters were each describable by an equation for a straight line (r2 greater than or equal to 0.8). However, the mean apparent distribution and elimination rate constants for thioridazine and mesoridazine and the mean apparent oral clearance for thioridazine decreased significantly with increasing dose. This suggests nonlinear trends in the elimination kinetics at high doses of thioridazine. When a 100-mg divided oral dose of thioridazine was administered, no statistically significant differences between single and divided doses were observed in the mean AUC infinity 0 or AUCt0 for thioridazine or sulforidazine. A significant decrease in the mean AUC infinity 0 or AUCt0 was observed for mesoridazine after the administration of the divided dose.(ABSTRACT TRUNCATED AT 250 WORDS)

Radioreceptor assay and high-performance liquid chromatography yield similar results for serum thioridazine and its major metabolites.

Thioridazine and its major metabolites were quantified in serum of thioridazine-treated psychiatric patients by radioreceptor assay and high performance liquid chromatography (HPLC) every second day during 3 weeks of drug administration. Serum neuroleptic levels measured by radioreceptor assay and serum concentrations of thioridazine and its active metabolites estimated by HPLC correlated (r = 0.82, n = 60); the intra- and interassay coefficients of variation of both assays were low (less than 7%). Thus, serum thioridazine can be adequately monitored by radioreceptor assay as well as by HPLC.

Development of a radioimmunoassay procedure for mesoridazine and its comparison with a high-performance liquid chromatographic method.

A radioimmunoassay (RIA) procedure for mesoridazine was developed using an antiserum raised in rabbits immunized with N-(2-carboxyethyl) desmethylmesoridazine-porcine thyroglobulin conjugate. The RIA procedure enabled the quantitation of 40 pg of mesoridazine in a 200-microliters human plasma sample with a coefficient of variation of less than 5%. Except for N-desmethylmesoridazine, the antiserum showed no marked cross-reaction with any of the other available potential cross-reactants. Furthermore, statistically indistinguishable results were obtained for the determination of mesoridazine in the presence or absence of a fivefold excess of thioridazine or sulforidazine. This RIA procedure was compared with a high-performance liquid chromatographic (HPLC) method by determining concentrations of mesoridazine in plasma samples from human volunteers over 72 h after administration of single 50-mg oral doses of thioridazine hydrochloride. Good correlation existed between the assay values (n = 55) determined by the RIA and HPLC methods (r2 = 0.940), but the slope of the regression line was significantly different from 1.0 (p less than 0.05, when RIA values were plotted on the gamma axis and HPLC values were plotted on the chi axis; p less than 0.001, when HPLC values were plotted on the gamma axis and RIA values were plotted on the chi axis). The plot of the differences between these two assay values against the average of the assay values showed, however, that the differences were independent of the concentration range studied. Moreover, statistically favorable comparisons were obtained for area under the plasma level/time curve to 48 h (AUC0(48)), Cmax, and Tmax calculated from the data obtained by the two methods.

Plasma propranolol levels and their effect on plasma thioridazine and haloperidol concentrations.

The relationship between chronic oral dosage with a long-acting formulation of propranolol and plasma propranolol levels 22 to 23 hours later is described in 12 adult male patients with organic brain disease. Separately, the effects on plasma levels of thioridazine plus metabolites with concomitant rising dose long-acting propranolol administration were studied in five patients. Significant dose-related increases in levels of thioridazine and metabolites were found when long-acting propranolol was given. No changes in haloperidol levels were found in three patients studied in a similar protocol.

Mesoridazine and thioridazine: clinical effects and blood levels in refractory schizophrenics.

Seven schizophrenic (according to DSM-III criteria) inpatients completed a two-phase study; each phase had a 1-week drug-free period followed by 6 weeks of a drug trial. The first phase uniformly involved treatment with chlorpromazine, and in the second phase patients received either mesoridazine (N = 3) or thioridazine (N = 4). Clinical ratings (Brief Psychiatric Rating Scale and Clinical Global Impressions) and neuroleptic blood levels were obtained weekly throughout the study. Whereas patients failed to respond to chlorpromazine 1800 mg/day, response to mesoridazine 400 mg/day and to thioridazine 800 mg/day was established on all Brief Psychiatric Rating Scale factors except for anxiety-depression. A higher neuroleptic blood level was achieved with mesoridazine or thioridazine at less than half the reference chlorpromazine dosage. Correlations between neuroleptic blood level and clinical response were positive for mesoridazine, negative for chlorpromazine, and nonsignificant for thioridazine. These findings are consistent with earlier research. We conclude that drug-resistant schizophrenics seem to improve clinically with mesoridazine or thioridazine, unlike with chlorpromazine, and that for mesoridazine this difference may be a function of selective dopamine receptor blockade.

The pharmacokinetics of some psychoactive drugs and relationships to clinical response.

Over the past decade a variety of studies have been carried out in the Department of Psychiatry and Human Behavior at the University of California, Irvine, investigating the pharmacokinetics of some psychoactive pharmacological agents and the relationships of these pharmacokinetics to certain clinical responses. This report summarizes and provides an overview of these studies.

Plasma and red cell levels of thioridazine and clinical response in schizophrenia.

The relationship of plasma and red blood cell (RBC) levels of thioridazine to clinical response in schizophrenia was evaluated in a fixed-dose study. Steady-state plasma and RBC levels of thioridazine, mesoridazine, and sum of thioridazine and mesoridazine, determined by gas-liquid chromatography, were not significantly correlated with clinical response as measured by improvement on the Brief Psychiatric Rating Scale. RBC thioridazine levels were not substantially more strongly correlated with clinical response than plasma levels.

Partitioning of thioridazine and mesoridazine in human blood fractions.

The partitioning of 3H-thioridazine and 3H-mesoridazine in fresh human whole blood was studied. The packed red blood cells were solubilized using the New England Nuclear protocol for whole blood solubilization. The plasma fraction was further fractionated into protein bound and free drug by molecular ultrafiltration. All solutions were counted in Biofluor LSC cocktail and corrected for quenching. Greater than 99% of the labeled drug was bound to the red blood cells and plasma protein. For thioridazine, 59% is bound to RBC, 41% is bound to plasma protein and 0.7% is free; for mesoridazine, 63% is bound to RBC, 37% is bound to plasma protein and 0.9% is free. Though substantial overlap is found in the bound percentage for mesoridazine and thioridazine, more mesoridazine binds to RBC than thioridazine (p less than 0.01). There is no statistically significant relationship between the amount of drug bound to the RBC or to plasma protein and the percent free drug. Though the total drug concentration is the same (1 microgram/ml) the percent free drug is quite variable across subjects by as much as a factor of three. Since free drug is the pharmacologically active portion and therefore determinant of clinical response, the reported variation in free drug concentration at the same total blood concentration invalidates the measurements of total serum or plasma drug concentration as predictive of clinical response.

Red blood cell and plasma levels of thioridazine and mesoridazine in schizophrenic patients.

Thioridazine and mesoridazine levels and levels of thioridazine plus metabolites were determined in plasma and red blood cells (RBC) by gas-liquid chromatography (GLC) and spectrofluorometry (SP), respectively, in schizophrenic patients treated with fixed doses of thioridazine. There was wide interpatient variability in RBC:plasma ratios for thioridazine and mesoridazine, a higher ratio of thioridazine to mesoridazine in RBC than plasma, and a higher ratio of GLC total (thioridazine plus mesoridazine), to SP-determined total drug constituents in RBC than in plasma. RBC showed a monotonic increase in drug levels with dose, whereas levels of drug in the plasma began to level off above the 250 mg/day dose. Drug levels 24 h after the acute dose did not predict steady-state blood levels in plasma or RBC.