The effect of perazine on the CYP2D6 and CYP2C19 phenotypes as measured by the dextromethorphan and mephenytoin tests in psychiatric patients.

There is evidence that the antipsychotic drug perazine is an inhibitor of CYP2D6. This study aimed at evaluating its effect on CYP2D6 and CYP2C19 activities in submitting psychiatric patients to phenotyping with dextromethorphan and mephenytoin, respectively, substrates of these enzymes, before and during a treatment with perazine. A total of 31 patients were phenotyped with dextromethorphan (CYP2D6) and mephenytoin (CYP2C19) before and after a 2-week treatment with 450 ± 51 mg/day (mean ± sd) perazine. At baseline, five patients appeared to be poor metabolizers (PM) of dextromethorphan and two patients of mephenytoin. The metabolic ratio (MR) of dextromethorphan/dextrorphan as determined in collected urine increased significantly (Wilcoxon; P < .0001) from baseline (0.39 ± 1.38 [mean ± sd]) till day 14 (1.46 ± 2.22). In 19 out of 26 extensive metabolizers (EM) of dextromethorphan, the phenotype changed from EM to PM. This suggests an almost complete inhibition of CYP2D6 by perazine and/or its metabolites. On the other hand, perazine (or some of its metabolites) did seemingly not inhibit CYP2C19. In conclusion, this study suggests that in patients treated with perazine and co-medicated with CYP2D6 substrates, there could be an increased risk of adverse effects as a consequence of a pharmacokinetic interaction.

Cytochrome P450-mediated interaction between perazine and risperidone: implications for antipsychotic polypharmacy.

BACKGROUND: Although clinically widespread, scientific evidence for antipsychotic polypharmacy is still limited. Combining different drugs increases the potential for drug-drug interactions, enhancing the risk of adverse drug reactions. We aimed to unravel the potential pharmacokinetic interactions between risperidone (RIS) and perazine. METHODS: Using a therapeutic drug monitoring database containing plasma concentrations of RIS and its active metabolite [9-hydroxyrisperidone (9-OH-RIS)], we considered two groups: a group of patients under antipsychotic monotherapy with RIS (n = 40) and a group of patients that was comedicated with perazine (n = 16). Groups were matched for demographic characteristics and daily dosage of RIS. Plasma concentrations, concentrations corrected for the dose (C/D) of RIS, 9-OH-RIS and the active moiety (RIS + 9-OH-RIS), as well as the metabolic ratios of concentrations of 9-OH-RIS/RIS, were compared using nonparametric tests. RESULTS: All parameters other than plasma concentrations and the C/D ratio of 9-OH-RIS differed between groups. Median values for plasma concentrations of the active moiety and C/D of the active moiety were higher in the perazine group (P < 0.001 and P < 0.001, respectively). Differences were driven by variations in the plasma concentrations and C/D of RIS, which were higher in the perazine group (P < 0.001 and P < 0.001, respectively). Metabolic ratios were lower in the perazine group (P = 0.003). DISCUSSION: The coadministration of perazine in RIS-medicated patients leads to significantly higher plasma concentrations and C/D values of RIS and its active moiety, and a lower metabolic ratio, reflecting the cytochrome P450 (CYP) 2D6 phenotype. We suggest that the mechanism underlying the effect of perazine on RIS metabolism is based on an inhibition of CYP2D6 and CYP3A4 activity.

The phenothiazine-class antipsychotic drugs prochlorperazine and trifluoperazine are potent allosteric modulators of the human P2X7 receptor.

P2X7, an ATP-gated cation channel, is involved in immune cell activation, hyperalgesia and neuropathic pain. By regulating cytokine release in the brain, P2X7 has been linked to the pathophysiology of mood disorders and schizophrenia. We here assess the impact of 123 drugs that act in the central nervous system on human P2X7. Most prominently, the tricyclic antipsychotics prochlorperazine (PCP) and trifluoperazine (TFP) potently inhibited P2X7-mediated Ca2+ entry, dye permeation and ionic currents. In divalent cation-containing bath solutions or after prolonged incubation, ATP-evoked P2X7 currents were inhibited by 10 µM PCP. This effect was not related to dopamine receptor antagonism. Surprisingly, PCP co-applied with ATP enhanced inward currents in bath solutions with low divalent cation concentrations. Intracellular perfusion with PCP did not substitute for the extracellularly applied drug, indicating that its binding sites are accessible from the extracellular space. Since P2X7 current potentiation by PCP was voltage-dependent, at least one site may be located within the electrical field of the membrane. While the channel opening and closure kinetic was altered by PCP, the apparent affinity of ATP remained unchanged (potentiation) or changed slightly (inhibition). Measurements in human monocyte-derived macrophages confirmed the PCP-induced inhibition of ATP-evoked Ca2+ influx, Yo-Pro-1 permeability, and whole cell currents. Interestingly, neither heterologously expressed rat or mouse P2X7 nor native P2X7 in rat astrocyte cultures or in mouse bone marrow-derived macrophages were inhibited by perazines with a similar potency. We conclude that perazine-type neuroleptics are potent, but species-selective allosteric modulators of human but not murine P2X7 receptors.

Autoinduction of the metabolism of phenothiazine neuroleptics in a primary culture of human hepatocytes.

BACKGROUND: The metabolism of phenothiazine neuroleptics (promazine, perazine) in a primary culture of human hepatocytes after pretreatment of cells with those neuroleptics was studied. METHODS: The hepatocytes were pretreated with 25 µM promazine or perazine for 96 h. Then, the cells were incubated for 2, 4, 6, 8 and 24 h in the presence of neuroleptics. At the indicated time points, concentrations of phenothiazines and their metabolites (5-sulfoxides and N-desmethyl derivatives) were measured in the culture medium using HPLC with UV detection. RESULTS: Pretreatment of the primary culture of human hepatocytes with promazine or perazine resulted in accumulation of their metabolites in the culture medium. Such an effect was not observed in the case of control cultures (not pretreated with neuroleptics). CONCLUSION: The obtained results suggest that the tested phenothiazines may stimulate their own metabolism by inducing CYP1A2, CYP3A4 and CYP2C19 isoforms.

Perazine at therapeutic drug concentrations inhibits human cytochrome P450 isoenzyme 1A2 (CYP1A2) and caffeine metabolism--an in vitro study.

The aim of the present study was to estimate the inhibitory effect of perazine, a phenothiazine neuroleptic with piperazine structure in a side chain, on human CYP1A2 activity measured as a rate of caffeine 3-N- and 1-N-demethylation. Moreover, the influence of perazine on other caffeine metabolic pathways such as 7-N-demethylation (CYP1A2, CYP2C8/9, CYP3A4) and 8-hydroxylation (CYP3A4, CYP1A2, CYP2C8/9) was also determined. The Dixon analysis showed that in both human liver microsomes and Supersomes CYP1A2 perazine potently and to a similar degree inhibited caffeine 3-N-demethylation (K(i) = 3.5 microM) and 1-N-demethylation (K(i) = 5 microM). Perazine moderately diminished the rate of caffeine 7-N-demethylation in Supersomes CYP1A2 (K(i) = 11.5 microM) and liver microsomes (K(i) = 20 microM), and attenuated C-8-hydroxylation (K(i) = 15.5 microM) in Supersomes CYP1A2. On the other hand, perazine weakly inhibited caffeine C-8-hydroxylation in liver microsomes (K(i) = 98 microM). About 80% of basal CYP1A2 activity was reduced by the therapeutic concentrations of perazine (5-10 microM). The obtained results show that perazine at its therapeutic concentrations is a potent inhibitor of human CYP1A2. Hence, taking account of CYP1A2 contribution to the metabolism of endogenous substances (steroids), drugs (xanthine derivatives, phenacetin, propranolol, imipramine, phenothiazine neuroleptics, clozapine) and carcinogenic compounds, the inhibition of CYP1A2 by perazine may be of physiological, pharmacological and toxicological importance.

Effect of chronic treatment with perazine on lipopolysaccharide-induced interleukin-1 beta levels in the rat brain.

In the present study, we sought to determine whether chronic treatment with perazine alters lipopolysaccharide (LPS)-induced interleukin-1 beta (IL-1 beta) levels in the following rat brain regions: the hypothalamus, frontal cortex, striatum and hippocampus. Male Wistar rats were administered perazine dimaleate (15 or 30 mg/kg/day) in drinking water for 21 days. On day 22, LPS was injected i.p. (125 microg/kg) 2 h before decapitation. Concentrations of perazine and its metabolites in plasma and brain was assessed by HPLC. The levels of IL-1 beta were determined using ELISA. Treatment with perazine (30 mg/kg/day) reduced LPS-stimulated IL-1 beta levels in the hypothalamus, and a tendency to its decrease in the striatum and frontal cortex was observed. This in vivo study suggests for the first time that long-term oral administration of perazine modulates reactivity of cells producing IL-1 beta.

Direct effects of neuroleptics on the activity of CYP2A in the liver of rats.

The aim of the present study was to investigate the influence of classic and atypical neuroleptics on the activity of rat CYP2A measured as a rate of testosterone 7alpha-hydroxylation. The reaction was studied in control liver microsomes in the presence of neuroleptics, as well as in microsomes of rats treated intraperitoneally (i.p.) for one day or two weeks (twice a day) with pharmacological doses (mg/kg) of the drugs (promazine, levomepromazine, thioridazine, perazine 10, chlorpromazine, haloperidol 0.3, risperidone 0.1, sertindole 0.05), in the absence of the neuroleptics in vitro. Most of the neuroleptics added in vitro to control liver microsomes decreased the activity of the rat CYP2A. Chlorpromazine (Ki = 11 microM) was the most potent inhibitor of the rat CYP2A among the studied drugs, whose effect was more pronounced than that of the other tested phenothiazines (Ki = 41-83 microM), haloperidol (Ki = 190 microM) or sertindole (Ki = 78 microM). Risperidone was not active in this respect. The investigated neuroleptics when given to rats in vivo for one day or two weeks--did not produce any indirect inhibitory effect on CYP2A via other mechanisms. The obtained results show direct inhibitory effects of phenothiazine neuroleptics on the activity of CYP2A in rat liver, which may be of physiological importance for the metabolism of testosterone, considering simultaneous inhibition of CYP2C11 and CYP3A by those drugs.

The metabolism of the piperazine-type phenothiazine neuroleptic perazine by the human cytochrome P-450 isoenzymes.

Identification of cytochrome P-450 isoenzymes (CYPs) involved in perazine 5-sulphoxidation and N-demethylation was carried out using human liver microsomes and cDNA-expressed human CYPs (Supersomes). In human liver microsomes, the formation of perazine metabolites correlated significantly with the level of CYP1A2 and ethoxyrezorufin O-deethylase activity, as well as with the level of CYP3A4 and cyclosporin A oxidase activity. Moreover, the formation of N-desmethylperazine also correlated well with S-mephenytoin 4'-hydroxylase activity (CYP2C19). alpha-Naphthoflavone (a CYP1A2 inhibitor) and ketoconazole (a CYP3A4 inhibitor) significantly decreased the rate of perazine 5-sulphoxidation, while ticlopidine (a CYP2C19 inhibitor) strongly reduced the rate of perazine N-demethylation in human liver microsomes. The cDNA-expressed human CYPs generated different amounts of perazine metabolites, but the preference of CYP isoforms to catalyze perazine metabolism was as follows (pmol of product/pmol of CYP isoform/min): 1A1>2D6>2C19>1A2>2B6>2E1>2A6 approximately 3A4>2C9 for 5-sulphoxidation and 2C19>2D6>1A1>1A2>2B6>3A4>2C9>2A6 for N-demethylation. In the light of the obtained results and regarding the contribution of each isoform to the total amount of CYP in human liver, it is concluded that CYP1A2 and CYP3A4 are the main isoenzymes catalyzing 5-sulphoxidation (32% and 30%, respectively), while CYP2C19 is the main isoform catalyzing perazine N-demethylation (68%). CYP2C9, CYP2E1 CYP2C19 and CYP2D6 are engaged to a lesser degree in 5-sulphoxidation, while CYP1A2, CYP3A4 and CYP2D6 in perazine N-demethylation (6-10%, depending on the isoform).

The contribution of cytochrome P-450 isoenzymes to the metabolism of phenothiazine neuroleptics.

The aim of the present study was to determine optimum conditions for studying promazine and perazine metabolism in rat liver microsomes, and to investigate the influence of specific cytochrome P-450 inhibitors on 5-sulfoxidation and N-demethylation of these neuroleptics. Based on the developed method, the metabolism of neuroleptics in liver microsomes was studied at linear dependence of product formation on time, and protein and substrate concentrations (incubation time: 10 min; concentration of microsomal proteins: promazine-0.7 mg ml(-1), perazine-0.5 mg ml(-1); substrate concentrations: promazine-25, 40 and 75 nmol ml(-1), perazine-20, 35, 50 nmol ml(-1)). A Dixon analysis of the metabolism of neuroleptics showed that quinine (a CYP2D1 inhibitor), metyrapone (a CYP2B1/B2 inhibitor) and alpha-naphthoflavone (a CYP1A1/2 inhibitor) affected, whereas erythromycin (a CYP3A inhibitor) and sulfaphenazole (a CYP2C inhibitor) did not change the neuroleptic biotransformation. N-Demethylation of promazine was competitively inhibited by quinine (K(i)=20 microM) and metyrapone (K(i)=83 microM), while that of perazine-by quinine (K(i)=46.5 microM), metyrapone (K(i)=46 microM) and alpha-naphthoflavone (K(i)=78.8 microM). 5-Sulfoxidation of promazine was inhibited only by quinine (K(i)=28.6 microM), whereas that of perazine-by quinine (K(i)=10 microM) and metyrapone (K(i)=96 microM). The results obtained are compared with our previous findings of analogous experiments concerning thioridazine, and with the data on other phenothiazines and species. In summary, it is proposed that N-demethylation of the mentioned phenothiazine neuroleptics in the rat is catalyzed by the isoenzymes CYP2D1, CYP2B2 and CYP1A2 (CYP1A2 does not refer to promazine). 5-Sulfoxidation of these drugs may be mediated by different isoenzymes, e.g. CYP2D1 (promazine and perazine), CYP2B2 (perazine) and CYP1A2 (thioridazine). Isoenzymes belonging to subfamilies CYP2C and CYP3A do not seem to be involved in the metabolism of the investigated neuroleptics in the rat. The results obtained point to the drug structure and species differences in the contribution of cytochrome P-450 isoenzymes to the metabolism of phenothiazines.

Perazine as a potent inhibitor of human CYP1A2 but not CYP3A4.

The effects of perazine on the activities of CYP1A2 and CYP3A4 in a primary culture of human hepatocytes of one patient were studied in vitro. The CYPs activities were assessed by measuring the rate of acetanilide 4-hydroxylation (CYP1A2) and cyclosporine A oxidation (CYP3A4) after treatment with TCDD (a CYP1A subfamily inducer) or rifampicin (mainly a CYP3A4 inducer). The amounts of the metabolites formed in hepatocytes were assayed in the extracellular medium using the HPLC method. TCDD and rifampicin induced the formation of 4-hydroxyacetanilide and cyclosporine A metabolites (monohydroxycyclosporine A, dihydroxycyclosporine A, N-desmethylcyclosporine A), respectively. The formation of 4-hydroxyacetanilide was strongly inhibited by three different concentrations of perazine (10, 25 and 50 microM) reaching 8, 3 and 2% of the control value, respectively. In the case of CYP3A4 activity, no such an effect of perazine was observed. Perazine showed only a week inhibition of the activity of cyclosporine A oxidase (to 96-86% of the control value). The obtained results suggest a strong inhibitory effect of perazine on human CYP1A2 activity with predicted Ki value similar to those of the known for CYP1A2 inhibitors, such as furafylline and fluvoxamine.

Neuroleptics normalize increased release of interleukin- 1 beta and tumor necrosis factor-alpha from monocytes in schizophrenia.

Some recent reports show that schizophrenia is accompanied by changes in lymphocyte activity. This study investigated the activity of monocytes by determining their release of interleukin- 1 beta (IL- 1 beta) and tumor necrosis factor-alpha (TNF-alpha). Monocytes were immunomagnetically isolated from the peripheral blood of schizophrenic patients before and after neuroleptic medication and stimulated by lipopolisaccharide (LPS) in vitro. The monocytes of schizophrenic patients released significantly higher amounts of IL- 1 beta and TNF-alpha than those of healthy controls. Treatment with the typical neuroleptics haloperidol and perazine decreased the release of IL- 1 beta and TNF-alpha to the control levels. The study has shown that the activity of monocytes is increased in schizophrenia and that neuroleptic treatment normalizes this activity.

Relevance of liver enzyme elevations with four different neuroleptics: a retrospective review of 7,263 treatment courses.

Data on liver enzyme elevations were collected in a retrospective study of 7,263 treatment courses with haloperidol, clozapine, perphenazine, and perazine. Charts of 233 patients hospitalized between 1980 and 1992 at Tübingen University Psychiatric Clinic were selected because clinically relevant increases of liver enzymes had been detected during monotherapy with one of the four examined neuroleptics. At least one hepatic enzyme (mostly alanine aminotransferase [ALAT]) exceeded the established reference range of 3-fold elevations of ALAT, aspartate aminotransferase, gamma-glutamyl transpeptidase, and glutamate dehydrogenase and 2-fold elevations of alkaline phosphatase (AP) during monotherapy with clozapine in 15%, perazine in 7.6%, perphenazine in 4%, and haloperidol in 2.4% of the cases. If all liver enzyme abnormalities with any elevation greater than the conventional upper limits are considered, incidences were as follows: clozapine, 78%; perphenazine, 62%; perazine, 59%; and haloperidol, 50%. Testing for overall differences within the four neuroleptics resulted in significantly different incidences of liver enzyme elevations (chi2 test,p < 0.0001). Threefold increases of AP (>540 U/L) were seen in three patients receiving haloperidol (0.3%) only. Twofold increases of AP (>360 U/L) were distributed as follows: clozapine, 1%; haloperidol, 0.8%; perazine, 0.3%; and perphenazine, 0.1%. Only in the group with 1-fold elevations of AP (>180 U/L) were the differences within the drug regimens significant (clozapine, 40.3%; haloperidol, 33.2%; perphenazine, 23.4%; and perazine, 23.1%; chi2 test, p < 0.0001). In the period under study, no instance of icterus occurred.

Distribution interactions between perazine and antidepressant drugs. In vivo studies.

Perazine belongs to the most frequently chosen neuroleptics for a combination with antidepressants in the therapy of complex or "treatment-resistant" psychiatric illnesses. The aim of the present study was to investigate the effect of the distribution interaction between perazine and antidepressants in vivo. Experiments were carried out on male Wistar rats. Animals received perazine and an antidepressant drug (imipramine or fluoxetine), separately or jointly, at a dose of 10 mg/kg ip. Concentrations of perazine, imipramine, fluoxetine and their metabolites in the blood plasma and tissues were measured at 1 h after administration of the drugs (HPLC). Effects of distribution interactions were estimated on the basis of the calculated tissue/plasma and lysosome-poor/lysosome-rich tissue concentration ratios, considering the heart and muscles as lysosome-poor and the lungs, liver and kidneys as lysosome-rich ones. Both imipramine and fluoxetine diminished the tissue/plasma concentration ratios of perazine for the lungs and kidneys (not for the liver), but elevated those ratios for the brain, muscles and heart. On the other hand, perazine lowered the lungs/plasma concentration ratio of both antidepressants and the liver/plasma concentration ratio of imipramine. Simultaneously, perazine elevated the brain/plasma and heart/plasma concentration ratios of both antidepressants. Consequently, the perazine concentration ratios of lysosome-poor/lysosome-rich tissue significantly increased in the presence of the investigated antidepressants, with an exception of the muscles/liver concentration ratio. At the same time, perazine raised the heart/lysosome-rich tissue concentration ratios of imipramine and fluoxetine, not changing significantly the muscles/lysosome-rich concentration ratios of the antidepressants. In conclusion, the presented results provide evidence that the observed in vitro distributive interactions between perazine and the antidepressants occur also in vivo, leading to a shift of the drugs from organs rich in lysosomes to those poor in these organella, in particular to the heart. Perazine and the antidepressants mutually increased the drug concentration ratios of heart/plasma and heart/lysosome-rich tissue, i.e. the heart/lung, heart/liver and heart/kidneys ratios. Similar results were obtained with lysosome-poor muscles in the case ofperazine. Moreover, the obtained results indicate that, apart from the lysosome density in the investigated tissues, the potential metabolic interactions in the liver and the order of drug circulation in a body have an important impact on the calculated drug concentration ratios.

In-vitro immunomodulatory effects of haloperidol and perazine in schizophrenia.

There are some reports describing concurrent changes in lymphocytic and monocytic activities in schizophrenia. In this study we investigated T cell activity in schizophrenic patients by measuring the release of interleukin-2 (IL-2) and soluble interleukin-2 receptor (sIL-2R) by T cells and the percentages of CD4+ and CD8+ cells in blood. The release of IL-2 and sIL-2R by T cells was evaluated in dilute whole blood after in-vitro stimulation with phytohemagglutinin. IL-2 levels and the percentage of CD4-cells tended to decrease and sIL-2R levels decreased significantly in schizophrenic patients. Haloperidol and perazine significantly decreased IL-2 levels and increased sIL-2R levels and the percentage CD4-cells. IL-2 and sIL-2R levels were lower in patients with a predominance of positive symptoms. The neuroleptic-induced increase in sIL-2R levels was higher in patients with a predominance of positive symptoms compared with those in whom both positive and negative symptoms were severe. The study has shown that T-cell activity is reduced in schizophrenia and that neuroleptics may have immunomodulatory properties.

Pharmacological studies on perazine and its primary metabolites.

The study served to answer the question whether metabolites possibly contribute to the clinical actions of the neuroleptic drug perazine. The primary metabolites demethylperazine and perazine sulfoxide were investigated with regard to influences on behavior in mice, to an antiemetic action in dogs, and to a modification of the pressor effect of noradrenaline in rats. In contrast to perazine, none of the metabolites exhibited effects that can be interpreted to indicate neuroleptic or antidepressive properties of the compounds.

Pharmaco-EEG analysis by means of FFT and FAD.

The EEG effects of a single oral dose of diazepam, amitriptyline and pernazine were studied in 26 healthy volunteers. The EEG analysis was performed by means of FFT and a new parametric method FAD. The results indicate that the FAD method reveals drug changes significantly more often than does the FFT analysis and that the medication effects are more clearly defined by the FAD. The method can be useful in the assessment of the subtle effects of the psychotropic drugs.

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.