Topical delivery of doxepin using liposome containing cream: An emerging approach in enhancing skin retention.

Conventional formulation of topical doxepin has similar antihistaminic effects as oral doxepin; however, its efficacy is limited due to poor localized effects on the skin. This study was designed to compare the ex vivo permeation and retention of two topical doxepin formulations; liposomal cream and plain cream. Doxepin-containing liposomes were prepared with the thin-film hydration method and assessed for size, size distribution, morphology, entrapment efficiency (EE%) and stability Using rat skin specimens in a Franz diffusion cell. Doxepin concentration in skin and receptor fluid was quantified by a validated HPLC method. The optimized liposomal formulation represented a uniform shape with narrow size distribution and an average diameter of 208.7±5.6nm. EE% of doxepin was 79±1.3 and the liposomes were stable at least for six weeks at 4°C. Ex vivo studies showed that while a significantly higher amount of doxepin has passed through the skin and entered the receptor compartment from conventional dosage form (47.06±2.5µg/cm2vs 11.20±0.6µg/cm2 for liposomal formulation), liposomal doxepin favoured accumulation in dermis and epidermis. These results suggest that the liposomal doxepin cream is an effective and easy-to-use formulation and may improve the cutaneous retention of doxepin, thus decreasing its systemic side effects.

Histamine Neuroimaging in Stress-Related Disorders.

Although histamine plays a major role in animal models of stress-related disorders, human neuroimaging data are sparse. Histamine H1 receptors in the human brain were first imaged by Professor Kazuhiko Yanai in 1992 by using 11C-doxepin, a potent ligand of H1 receptors, and positron emission tomography (PET). Subsequent work revealed that H1 receptors are reduced in the prefrontal and anterior cingulate cortices in patients with major depressive disorders. A sex difference in H1 receptor binding in the brain has also been found, with women exhibiting more abundant H1 receptor binding than men. Moreover, female patients with anorexia nervosa show higher H1 receptor binding in the amygdala and lentiform nucleus. These studies also found an inverse correlation of depression scores with H1 receptor binding. Histamine is considered to play a major role in the pathophysiology of irritable bowel syndrome (IBS), a representative disorder of brain-gut interactions. Along these lines, hypnotic suggestion dramatically changes the waveforms of viscerosensory cerebral evoked potentials in response to electrical rectal stimulation and these changes are modified by the administration of H1 antagonist. The direction of the H1 antagonist-induced changes in the viscerosensory cerebral evoked potentials differs between IBS patients and healthy controls. Thus, histamine likely plays an important role in stress-related disorders. Further histamine brain imaging studies of humans are warranted.

Effect of Ions and Sequence Variants on the Antagonist Binding Properties of the Histamine H1 Receptor.

The histamine H1 receptor (H1R) is a G protein-coupled receptor (GPCR) and represents a main target in the treatment of allergic reactions as well as inflammatory reactions and depressions. Although the overall effect of antagonists on H1 function has been extensively investigated, rather little is known about the potential modulatory effect of ions or sequence variants on antagonist binding. We investigated the dynamics of a phosphate ion present in the crystal structure and of a sodium ion, for which we determined the position in the allosteric pocket by metadynamics simulations. Both types of ions exhibit significant dynamics within their binding site; however, some key contacts remain stable over the simulation time, which might be exploited to develop more potent drugs targeting these sites. The dynamics of the ions is almost unaffected by the presence or absence of doxepin, as also reflected in their small effect (less than 1 kcal·mol-1) on doxepin binding affinity. We also examined the effect of four H1R sequence variants observed in the human population on doxepin binding. These variants cause a reduction in doxepin affinity of up to 2.5 kcal·mol-1, indicating that personalized medical treatments that take into account individual mutation patterns could increase precision in the dosage of GPCR-targeting drugs.

Binding of histamine to the H1 receptor-a molecular dynamics study.

Binding of histamine to the G-protein coupled histamine H1 receptor plays an important role in the context of allergic reactions; however, no crystal structure of the resulting complex is available yet. To deduce the histamine binding site, we performed unbiased molecular dynamics (MD) simulations on a microsecond time scale, which allowed to monitor one binding event, in which particularly the residues of the extracellular loop 2 were involved in the initial recognition process. The final histamine binding pose in the orthosteric pocket is characterized by interactions with Asp1073.32, Tyr1083.33, Thr1945.43, Asn1985.46, Trp4286.48, Tyr4316.51, Phe4326.52, and Phe4356.55, which is in agreement with existing mutational data. The conformational stability of the obtained complex structure was subsequently confirmed in 2 µs equilibrium MD simulations, and a metadynamics simulation proved that the detected binding site represents an energy minimum. A complementary investigation of a D107A mutant, which has experimentally been shown to abolish ligand binding, revealed that this exchange results in a significantly weaker interaction and enhanced ligand dynamics. This finding underlines the importance of the electrostatic interaction between the histamine ammonium group and the side chain of Asp1073.32 for histamine binding.

Development of a buccal doxepin platform for pain in oral mucositis derived from head and neck cancer treatment.

This study describes the development of semisolid formulations containing doxepin (DOX) for pain relief in oral mucositis, frequently related to chemotherapy and/or radiotherapy treatments in patients with head and neck cancer. Chemical permeation enhancers were evaluated and selected according to the results obtained from rheological studies, drug release, and drug permeation and retention through buccal mucosa. Finally, the selected formulation was compared in vivo, with a reference DOX mouthwash, whose clinical efficacy had been previously reported. The obtained findings showed that an orabase® platform loading transcutol® (10%) and menthol (5%) for the buccal vehiculization of DOX exhibited a decreased elastic and viscous behavior improving its application. The main drug release mechanism could be considered as diffusion according to Higuchi model. Obtained DOX permeation rates were considered optimal for an analgesic effect and far below to an antidepressant activity. Similar in vivo plasma concentrations were found for the semisolid formulation and the reference mouthwash. However, DOX amounts retained in the mucosa of animals for the semisolid formulation were higher than the reference, which let us hypostatize even stronger potential local therapeutic effect with additional advantages such as, mucoadhesive properties, absence of alcohol, some degree of freshness, as well as, drug palatability improvement.

Spectroscopic, electrochemical and molecular docking studies of dothiepin and doxepin with bovine serum albumin and DNA base.

The interaction of dothiepin (DOT) and doxepin (DOX) with bovine serum albumin (BSA) and a DNA base (adenine) was studied using UV-visible, fluorescence, attenuated total reflection-infra-red (ATR-IR), cyclic voltammetry and molecular docking methods. Strong fluorescence quenching was observed upon interaction of DOT and DOX with BSA/adenine and the mechanism suggested static quenching. Hydrophobic and hydrogen bonding interactions were the predominant intermolecular forces needed to stabilize the copolymer. Upon addition of the drugs: (i) the tautomeric equilibrium structure of the adenine was changed; and (ii) the oxidation and the reduction peaks of the adenine/BSA interaction shifted towards high and low potentials, respectively. In ATR-IR, the band shift of amides I and II indicated a change in secondary structure of BSA upon binding to DOT and DOX drugs. The reduction in voltammetric current in the presence of BSA/adenine was attributed to slow diffusion of BSA/adenine binding with DOX/DOT. The docking method indicated that the drug moiety interacted with the BSA molecule. Copyright © 2016 John Wiley & Sons, Ltd.

Histamine H1 receptor occupancy by the new-generation antipsychotics olanzapine and quetiapine: a positron emission tomography study in healthy volunteers.

RATIONALE: Histamine H1 antagonists have hypnotic, appetite-promoting, and sedative side effects. Most second-generation antipsychotics have potent antagonistic effects on histamine H1 receptor (H1R). Positron emission tomography (PET) can measure the H1R occupancy (H1RO) in vivo, although there are no reports regarding antipsychotics. OBJECTIVES: We studied the H1RO of olanzapine and quetiapine in vivo with respect to their plasma concentrations and subjective drowsiness by performing human PET imaging studies with [(11)C]doxepin, a potent PET ligand of H1R. METHODS: Six healthy Japanese male volunteers were enrolled. Cross-randomized PET imaging was performed after a single oral administration of olanzapine (2.5 mg), quetiapine (25 mg), or placebo. PET data were analyzed by region of interest and voxel-by-voxel analysis. We concurrently measured plasma drug concentrations by liquid chromatography/tandem mass spectrometry and evaluated subjective sleepiness. RESULTS: The binding potential ratios of olanzapine and quetiapine in the cerebral cortex were significantly lower than that of the placebo. The H1RO values of olanzapine and quetiapine in the cortex were approximately 61-80 and 56-81%, respectively. The binding potential ratios of the drugs were significantly lower than that of the placebo in the dorsolateral prefrontal and lateral temporal cortices, and anterior and posterior cingulate gyri. The H1RO values in the cortex were significantly correlated with subjective sleepiness but not plasma drug concentrations. CONCLUSIONS: Olanzapine and quetiapine have high H1RO values in the human brain under their clinical minimum doses. This study provides a foundation of the properties by which new-generation antipsychotics block the central histaminergic system in humans.

Docking and MD study of histamine H4R based on the crystal structure of H1R.

Histamine H4 receptor (H4R), a member of histamine receptor family, which belongs to class A of G-protein coupled receptors (GPCRs), has been reported to play a critical role in histamine-induced chemotaxis in mast cells and eosinophils. Recently, the crystal structure of human histamine H1 receptor (H1R) was reported, which facilitates structure-based drug discovery of histamine receptor significantly. In the current work, the homology models of H4R and H3R are first constructed based on the crystal structure of H1R. Clobenpropit is then docked into the binding pocket of H4R and two different binding modes can be identified. In order to select a reasonable binding mode, several other ligands including agonists and antagonists are docked into H4R, and the results reveal that all ligands share one preferable binding mode: the protonated NH tightly interacts with Asp(3.32) and the imidazole NH interacts with Glu(5.46). By comparing H3R and H4R, we find that Glu(5.20) and Thr(6.55) in H4R involve in the selectivity of H4R. Then, we perform molecular dynamics (MD) simulations for H4R in complex with its compounds. MD results indicate that the preferable docking mode is more stable. Finally, we dock agonist histamine into H1R and H4R, and then perform 20ns MD simulations for the complexes. H1R or H4R bound with histamine show strong conformational changes from TM5, TM6 and TM7, outward movement of intracellular part of TM6, and conformational change of Tyr(7.53), which is consistent with the recent crystal structures of active GPCRs. Our results reveal the mechanism of selectivity and activation for H4R, which is important for developing selective antagonists and agonists for H4R.

Structure of the human histamine H1 receptor complex with doxepin.

The biogenic amine histamine is an important pharmacological mediator involved in pathophysiological processes such as allergies and inflammations. Histamine H(1) receptor (H(1)R) antagonists are very effective drugs alleviating the symptoms of allergic reactions. Here we show the crystal structure of the H(1)R complex with doxepin, a first-generation H(1)R antagonist. Doxepin sits deep in the ligand-binding pocket and directly interacts with Trp 428(6.48), a highly conserved key residue in G-protein-coupled-receptor activation. This well-conserved pocket with mostly hydrophobic nature contributes to the low selectivity of the first-generation compounds. The pocket is associated with an anion-binding region occupied by a phosphate ion. Docking of various second-generation H(1)R antagonists reveals that the unique carboxyl group present in this class of compounds interacts with Lys 191(5.39) and/or Lys 179(ECL2), both of which form part of the anion-binding region. This region is not conserved in other aminergic receptors, demonstrating how minor differences in receptors lead to pronounced selectivity differences with small molecules. Our study sheds light on the molecular basis of H(1)R antagonist specificity against H(1)R.

Dose dependency of brain histamine H(1) receptor occupancy following oral administration of cetirizine hydrochloride measured using PET with [11C]doxepin.

AIMS: The strength of sedation due to antihistamines can be evaluated using positron emission tomography (PET). The purpose of the present study is to measure histamine H(1) receptor (H(1)R) occupancy following oral administration of cetirizine (10 and 20 mg) in order to examine dose dependency. METHODS: Fifteen healthy male volunteers (age range, 20-35 years) were divided into 3 subgroups and were studied following single oral administration of cetirizine at 10 mg (n = 5) and 20 mg (n = 5) or hydroxyzine at 30 mg (n = 5) using PET with 11C-doxepin. Each subject was scanned also following the administration of placebo. Binding potential and H(1)RO values were calculated in the prefrontal and anterior cingulate cortices. Subjective sleepiness was also measured, and the correlation to H(1)RO was examined for each antihistamine. RESULTS: The averaged H(1)ROs of cetirizine 10 mg, 20 mg, and hydroxyzine 30 mg in the prefrontal and cingulate cortices was 12.6%, 25.2%, and 67.6%, respectively. The H(1)RO of hydroxyzine 30 mg correlated well with subjective sleepiness (p < 0.001); however, those of cetirizine 10 and 20 mg showed no correlation with subjective sleepiness. CONCLUSION: It was demonstrated that the brain penetration of orally administered cetirizine was dose-dependent. Cetirizine 10 mg, with its low H(1)RO and thus minimal sedation, could be more safely used than cetirizine 20 mg for the treatment of various allergic disorders.

Cerebral histamine H1 receptor binding potential measured with PET under a test dose of olopatadine, an antihistamine, is reduced after repeated administration of olopatadine.

UNLABELLED: Some antihistamine drugs that are used for rhinitis and pollinosis have a sedative effect as they enter the brain and block the H(1) receptor, potentially causing serious accidents. Receptor occupancy has been measured with PET under single-dose administration in humans to classify antihistamines as more sedating or as less sedating (or nonsedating). In this study, the effect of repeated administration of olopatadine, an antihistamine, on the cerebral H(1) receptor was measured with PET. METHODS: A total of 17 young men with rhinitis underwent dynamic brain PET with (11)C-doxepin at baseline, under an initial single dose of 5 mg of olopatadine (acute scan), and under another 5-mg dose after repeated administration of olopatadine at 10 mg/d for 4 wk (chronic scan). The H(1) receptor binding potential was estimated using Logan graphical analysis with cerebellum as reference region input. RESULTS: The acute scan showed a slight decrease in H(1) receptor binding potential across the cerebral cortex (by 15% in the frontal cortex), but the chronic scan showed a marked decrease (by 45% from the acute scan in the frontal cortex). Behavioral data before and after the PET scans did not reveal any sedative effect. CONCLUSION: The results may be interpreted as either intracerebral accumulation of olopatadine or H(1) receptor downregulation due to repeated administration. The study shows feasibility and potential value for PET in evaluating the pharmacologic effect of a drug not only after a single dose but also after repeated administration.

Analytical method for simultaneously measuring ex vivo drug receptor occupancy and dissociation rate: application to (R)-dimethindene occupancy of central histamine H1 receptors.

We introduce a novel experimental method to determine both the extent of ex vivo receptor occupancy of administered compound and its dissociation rate constant (k4). [Here, we reference k4 as the rate of offset of unlabeled ligand in convention with Motulsky and Mahan (1)]. We derived a kinetic rate equation based on the dissociation rate constant for an unlabeled compound competing for the same site as a labeled compound and describe a model to simulate fractional occupancy. To validate our model, we performed in vitro kinetics and ex vivo occupancy experiments in rat cortex with varying concentrations of (R)-dimethindene, a sedating antihistamine. Brain tissue was removed at various times post oral administration, and histamine H1 receptor ligand [3H]-doxepin binding to homogenates from drug-treated or vehicle-treated rats was measured at multiple time points at room temperature. Fractional occupancy and k4 for (R)-dimethindene binding to H1 receptors were calculated by using our proposed model. Rats dosed with 30 and 60 mg/kg (R)-dimethindene showed 42% and 67% occupancy of central H1 receptors, respectively. These results were comparable to occupancy data determined by equilibrium radioligand binding. In addition, drug k4 rate determined by using our ex vivo method was equivalent to k4 determined by in vitro competition kinetics (dissociation half-life t(1/2) approximately 30 min). The outlined method can be used to assess, by simulation and experiment, occupancy for compounds based on dissociation rate constants and contributes to current efforts in drug optimization to profile antagonist efficacy in terms of its kinetic drug-target binding parameters. Data described by the method may be analyzed with commercially available software. Suggested fitting procedures are given in the appendix.

Histamine H1 receptors in schizophrenic patients measured by positron emission tomography.

Increasing evidence has shown that the histaminergic neuron system is implicated in the pathophysiology of schizophrenia. The aim of this study was to compare the distribution of histamine H1 receptors between schizophrenics and normal human subjects in vivo using positron emission tomography (PET). H1 receptor binding was measured in 10 normal subjects and 10 medicated schizophrenic patients by PET and [11C] doxepin, a radioligand for the H1 receptor. The binding potential (BP=Bmax/K(D)) of [11C] doxepin for available brain H1 receptors was calculated by a graphical analysis on voxel-by-voxel basis and compared between schizophrenics and normal subjects using the regions of interest (ROIs) and the statistical parametrical mapping (SPM99). BP values for H1 receptors in the frontal and prefrontal cortices and the cingulate gyrus were significantly lower among the schizophrenic patients than among the control subjects. On the contrary, there were no areas of the brain where H1 receptors were significantly higher among the schizophrenic patients than the control subjects. The results of our study suggest that the central histaminergic neuron system could be involved in the pathophysiology of schizophrenia, although further studies are needed to confirm this hypothesis.

Decreased histamine H1 receptor binding in the brain of depressed patients.

The central histaminergic neuron system modulates the wakefulness, sleep-awake cycle, appetite control, learning and memory, and emotion. Previous studies have reported changes in neuronal histamine release and its metabolism under stress conditions in the mammalian brain. In this study, we examined, using positron emission tomography (PET) and [(11)C]-doxepin, whether the histaminergic neuron system is involved in human depression. Cerebral histamine H1 receptor (H(1)R) binding was measured in 10 patients with major depression and in 10 normal age-matched subjects using PET and [(11)C]-doxepin. Data were calculated by a graphical analysis on voxel-by-voxel and ROI (region of interests) basis. Binding potential (BP) values for [(11)C]-doxepin binding in the frontal and prefrontal cortices, and cingulate gyrus were significantly lower in the depressed patients than those in the normal control subjects. There was no area of the brain where [(11)C]-doxepin binding was significantly higher in the depressed patients than in the controls. ROI-based analysis also revealed that BP values for [(11)C]-doxepin binding in the frontal cortex and cingulate gyrus decreased in proportion to self-rating depressive scales scores. The results of this study demonstrate that depressed patients have decreased brain H(1)R binding and that this decrease correlates with the severity of depression symptoms. It is therefore suggested that the histaminergic neuron system plays an important role in the pathophysiology of depression and that its modulation may prove to be useful in the treatment of depression.

The N-demethylation of the doxepin isomers is mainly catalyzed by the polymorphic CYP2C19.

PURPOSE: This study was conducted to identify the cytochrome P450s (CYPs) responsible for the metabolism of the cis- and trans-isomers of the tricyclic antidepressant doxepin to its pharmacologically active N-desmethylmetabolite by in vitro techniques. METHODS: The doxepin N-demethylation was studied by means of pooled human liver microsomes and chemical inhibitors, recombinant human (rh)-CYPs, and geno- and phenotyped human liver microsomes. RESULTS: The N-demethylation of both isomers was inhibited most prominently by tranylcypromine (CYP2C19) to more than 50%. Furafylline (CYP1A2) and sulfaphenazole (CYP2C9) inhibited the N-demethylation to a lesser extent while quinidine (CYP2D6) or troleandomycine (CYP3A4) had no effect. Rh-CYP2C19, -CYP1A2, and -CYP2C9 were able to N-demethylate cis- and trans-doxepin. Only traces of trans-desmethyldoxepin were detectable when CYP3A4 was used. The maximum velocity in the cis- and transdoxepin N-demethylation was significantly (P < 0.05) lower in microsomes with low CYP2C19 activity (345 +/- 44 and 508 +/- 75 pmol/min/ mg protein, respectively) compared to those with high CYP2C19 activity (779 +/- 132 and 1,189 +/- 134 pmollmin/mg). CONCLUSION: The present study demonstrates a significant contribution of the polymorphic CYP2C19 to the N-demethylation of doxepin. CYP2C9 and CYP1A2 play a minor role and CYP3A4 does not contribute substantially.

The isomeric metabolites of doxepin in equine serum and urine.

Due to its tranquilizing properties, the tricyclic antidepressant doxepin may be misused as a doping agent in competition horses. Therefore, efficient analytical procedures are required to detect this drug in samples submitted for doping control. To screen for parent doxepin in equine blood and urine, a less specific method has been accepted employing gas chromatography (GC) combined with electron impact (EI) mass spectrometry (MS). The aim of this study was identification of doxepin metabolites providing more specific MS data to verify positives resulting from screening. Thus, after a horse was given doxepin-HCl (1 mg/kg, i.v.), blood and urine were analyzed for free or conjugated metabolites using GC combined with EI- and positive chemical ionization (PCI) MS. In both of the sample materials, cis- and trans-isomers of desmethyldoxepin were detected for up to 48 h after treatment using trifluoracetylation and GC/EI-MS. Following enzymic hydrolysis of urine and propionylation of extracts, each four isomers of hydroxy desmethyldoxepin and hydroxydoxepin were recovered for up to 24 and 48 h, respectively. These compounds were characterized by their EI- and PCI-mass spectra. Although distinct positions of the hydroxyl groups could not be determined, the presence of each two cis/trans-isomeric pairs of differently monohydroxylated metabolites may be assumed. Results reported here suggest, that screening horses for parent doxepin should be completed by analysis of its major isomeric metabolites, desmethyldoxepin and hydroxydoxepin, providing MS data specific enough for confirmatory analysis.

New findings in pharmacological effects induced by antihistamines: from PET studies to knock-out mice.

Antihistamines are efficacious drugs to be used for the symptomatic relief of allergic diseases. The safety issue of antihistamines is of central importance because of their widespread use in current medical practice. To better understand the pharmacological effects of antihistamines on the central nervous system (CNS), we used two kinds of new methods, positron emission tomography (PET) and gene targeting regarding on histamine H1 receptors. The histamine H1 receptor occupancy was examined in young male volunteers with[11C]-doxepin (a potent H1 antagonist) after the oral or intravenous administration of antihistamines. In other studies, the cognitive performance was also measured tachistoscopically before and after taking antihistamines. The mutant mice lacking H1 receptors were used in the behavioural and neurochemical experiments to re-evaluate the role of H1 receptors. The H1-receptor occupancy in the human frontal cortex caused by antihistamines is significantly correlated with the reported values of incidence of sleepiness in clinical trials, and the occupancy is well proportional to the impaired cognitive performance. The behavioural studies of the H1-receptor knock-out mice confirmed the role of H1 receptors in arousal, the sleep-wake cycle, locomotion, nociception and aggressive behaviour. The pharmacological effects induced by H1 antagonism were re-evaluated by the PET and gene-targetting. Although any serious effects could not be observed in mice by the destruction of the H1-receptor gene, the cognitive performance was impaired in humans after taking first generation antihistamines in recommended doses.

Adverse effects in a newborn infant breast-fed by a mother treated with doxepin.

OBJECTIVE: To report adverse effects in a newborn infant whose mother had been treated with doxepin during pregnancy and while breast-feeding. CASE SUMMARY: The nine-day-old white boy was admitted because of poor sucking and swallowing, with muscle hypotonia and vomiting. He was drowsy and had lost 150 g. At the time of admission, he was breast-fed by his mother who was being treated with doxepin 35 mg/d. Samples of plasma and breast milk were taken and analyzed by HPLC and fluorescence polarization immunoassay. The amount of doxepin and N-desmethyldoxepin (DDP) ingested via breast-feeding was approximately 10-20 micrograms/kg/d (i.e., only 2.5% of the weight-adjusted dose of the mother). Doxepin was detectable in small amounts in the infant's plasma (approximately 10 micrograms/L); DDP was below the lower limit of detection of 10 micrograms/L. All adverse effects subsided within 48 hours after breast-feeding was stopped. DISCUSSION: Despite the small doses of doxepin and its active metabolite ingested by breast-fed babies, there is a risk of accumulation and resultant adverse effects. In newborns, the metabolic activity is considerably decreased and may be further reduced by hyperbilirubinemia. CONCLUSIONS: Available data suggest that women treated with doxepin should breast-feed their infants with great caution, if at all, although much larger databases are needed to confirm this.

Stereoselective measurement of E- and Z-doxepin and its N-desmethyl and hydroxylated metabolites by gas chromatography-mass spectrometry.

A stereoselective method of analysis of the antidepressant drug doxepin (DOX, an 85:15% mixture of E-Z stereoisomers), its principal metabolites E- and Z-N-desmethyldoxepin (desDOX) and ring-hydroxylated metabolites in microsomal incubation mixtures is described. DOX and its metabolites were extracted from alkalinised incubation mixtures by either: 9:1 hexane-propan-2-ol (method 1) or 1:1 hexane-dichloromethane (method 2), derivatised with trifluoroacetic anhydride and analysed by GC-MS with selected ion monitoring. Both methods were suitable for the analysis of individual desDOX isomers as indicated by correlation coefficients of > or = 0.999 for calibration curves constructed between 50 and 2500 nM, and good within-day precision at 125 nM (C.V. < or = 14%) and 1000 nM (C.V. < or = 8%). Method 1, however, was unsuitable for the analysis of ring-hydroxylated metabolites of DOX, whereas the hydroxylated metabolites of E-DOX and E-desDOX (generated in situ) were extracted by method 2 with a C.V. of ca. 13%. This is the first assay method that permits the simultaneous measurement of desDOX and hydroxylated metabolites of DOX in microsomal mixtures.

Doxepin and its metabolites in plasma and cerebrospinal fluid in depressed patients.

Little information exists on the concentrations of antidepressants and their metabolites in CSF. We measured plasma and CSF levels of trans-doxepin (trans-DOX) and DOX metabolites in 12 depressed patients treated with DOX (250 mg/day) for 6 days. Spinal taps and blood samples were taken on day 7, 10 h after drug administration. Trans-DOX, cis-desmethyldoxepin (cis-DM-DOX), trans-desmethyldoxepin (trans-DM-DOX) and di-desmethyldoxepin (DDM-DOX) were analyzed in CSF and plasma samples by HPLC with column-switching. Although DOX was given as a mixture of 85% trans-DOX and 15% of the pharmacologically more active cis-DOX, we found similar amounts of cis-DM-DOX and trans-DM-DOX in plasma (59.8 +/- 45.1 versus 72.0 +/- 60.0 ng/ml; NS), suggesting that isomerization of DOX had taken place. Trans-DOX and DOX metabolites could be detected in CSF of most patients. Relatively low CSF concentrations of the active metabolite cis-DM-DOX were measured. Clinical efficacy, as assessed by HAMD scores, was not significantly related to plasma or CSF concentrations of trans-DOX or its metabolites. Trans-DOX and DOX metabolites were distributed differently between plasma and CSF. It is concluded that isomerization of DOX is not only relevant for neuronal uptake inhibition, but also for the transport of the metabolites.