Liquid chromatography/tandem mass spectrometry method for determination of olanzapine and N-desmethylolanzapine in human serum and cerebrospinal fluid.

A validated, accurate and sensitive LC-MS/MS method for determination of olanzapine and its metabolite N-desmethylolanzapine has been developed. The analytes were quantified by tandem mass spectrometry operating in positive electrospray ionization mode with multiple reaction monitoring. Olanzapine and desmethylolanzapine were extracted from serum or cerebral spinal fluid samples, 200 microl, with tert-butyl methyl ether using olanzapine-D3 as internal standard. Calibrations for olanzapine and desmethylolanzapine were linear within the selected range of 0.2-30 ng/ml (6-96 nM) in cerebral spinal fluid and for olanzapine in plasma, in the range of 5-100 ng/ml (16-320 nM). The method was successfully used for the analysis of samples from patients treated with olanzapine in the dose range of 2.5-25mg/day.

HPLC determination of pirenzepine dihydrochloride in rabbit aqueous humor.

Pirenzepine was considered as a pharmacologic agent of preventing form-deprivation myopia. To assess the ocular bioavailability of pirenzepine, a HPLC method for determination of pirenzepine in rabbit aqueous humor was developed. An HPLC system was used in the reverse phase mode for the determination of pirenzepine. A Luna RP18 5 microm 4.6 mm x 150 mm column was employed at 35 degrees C. The mobile phase was methanol/0.02 M KH2PO4/sodium 1-pentanesulfonate (350/650/1, v/v/m, pH was adjusted to 8.0 by dropping 1M NaOH). The flow rate was 1 ml/min. Pirenzepine was monitored at 280 nm. Sample treatment procedure consists of deproteinisation with methanol. Calibration curves fitted by plotting the peak area versus concentration were linear in the range 20-400 ng/ml. The limit of quantification (LOQ) of present method was 20 ng/ml. Within-day and inter-day coefficient of variation was lower than 10%. Analytical recoveries were determined as 92.4, 95.4 and 101.4% at concentrations of 40, 200 and 400 ng/ml. In conclusion, this HPLC method using a simple sample treatment procedure appears suitable for monitoring ocular concentration of pirenzepine.

Transfer of olanzapine into breast milk, calculation of infant drug dose, and effect on breast-fed infants.

OBJECTIVE: This study characterized infant drug doses and breast-milk-to-plasma area-under-the-curve ratios for olanzapine and determined plasma concentrations and effects of this drug on breast-feeding infants. METHOD: Seven mother-infant nursing pairs were studied. Olanzapine was measured in plasma and milk with high-performance liquid chromatography over a dose interval (for six patients) or at a single time after dose ingestion (for one patient) at steady state. Infant drug exposure was estimated as the product of an assumed milk production rate and average drug concentration in milk, normalized to body weight, and expressed as a percentage of maternal drug dose, normalized to body weight. RESULTS: The median infant dose of olanzapine ingested through milk was 1.02% of the maternal dose; the median milk-to-plasma area-under-the-curve ratio was 0.38 for the six patients with data collected over the dose interval. Corresponding values in the patient with single-point data were 1.13% and 0.75. Olanzapine was not detected in the plasma of the six infants with an evaluable plasma sample. All of the infants were healthy and experienced no side effects. CONCLUSIONS: Breast-fed infants were exposed to a calculated olanzapine dose of approximately 1%-well below the 10% notional level of concern. In infant plasma, olanzapine was below the detection limit; there were no adverse effects on the infants. These data support the use of olanzapine during breast-feeding. However, the authors recommend that breast-fed infants be monitored closely and the decision to breast-feed be made after individual risk-benefit analysis.

Quantitation of olanzapine in tablets by HPLC, CZE, derivative spectrometry and linear voltammetry.

Four analytical methods have been developed for the quality control of pharmaceutical formulations containing the novel antipsychotic drug, olanzapine: high performance liquid chromatography (HPLC), capillary zone electrophoresis (CZE), derivative spectrometry and linear voltammetry. All methods require only a simple extraction procedure of olanzapine from the tablets before analysis. HPLC with ultraviolet detection at 260 nm is carried out with a C8 column and a mobile phase constituted of acetonitrile and aqueous tetramethylammonium perchlorate. CZE is performed in an uncoated capillary with phosphate buffer, pH 3.0, as the background electrolyte, with UV detection at 214 nm. Spectrophotometry uses the derivative of the spectrum at 298 nm. In linear voltammetric method (LSV) the current intensity of the oxidation wave at +495 mV is measured. All methods gave similar results in terms of precision and accuracy. For HPLC and CZE, repeatability and intermediate precision, expressed by the RSD was better than 1.8%. The accuracy, resulting from recovery experiments, was between 99.9 and 101.1%. Spectrometry and voltammetry gave slightly higher RSD values (up to 2.9%) and a larger variation of the accuracy (the recovery was between 97.8 and 102.6%). However, the requirements for quantitative analysis are fulfilled for all methods.

[Study of the detection characteristics of clozapine, N-desmethyl clozapine and olanzapine with high performance liquid chromatograph-electrochemical detector].

In order to analyze clozapine, N-desmethyl clozapine and olanzapine, their detection characteristics with high performance liquid chromatograph-electrochemical detector (HPLC-ECD) were investigated. The separation was performed on an ODS-3 column with the mobile phase of methanol and 0.1 mol/L phosphate buffer(60:40, V/V). The retention times of clozapine, N-desmethyl clozapine and olanzapine were all prolonged with higher pH of the mobile phase. These three compounds could be separated on the baseline at pH 4.56 and 5.56. The relationships of peak heights and detection voltages shown typical "S" shaped curves, and these curves shifted to the left with higher pH. To get stable detection current, the detection voltages for clozapine, N-desmethyl clozapine and olanzapine must be higher than 0.60 V, 0.60 V and 0.35 V at pH 4.56, and 0.48 V, 0.48 V and 0.30 V at pH 5.56, respectively. The typical "S" shaped ampere-volt curves were very important for the selection of suitable voltage for quantitative detection, and could be used for the qualitative detection of these three compounds.

Determination of olanzapine in human breast milk by high-performance liquid chromatography with electrochemical detection.

A reversed-phase high-performance liquid chromatographic-electrochemical assay was developed and validated for the quantification of olanzapine in human breast milk. The assay involved a solid-phase extraction (SPE) of olanzapine and its internal standard on a Bond Elut Certify LRC mixed-mode cartridge. After conditioning of the SPE cartridge, human milk (1 ml) was passed through the cartridge. The cartridge was washed with five separate washing steps to remove endogenous compounds, and the analytes were eluted with ethyl acetate-ammonium hydroxide (98:2, v/v) solution. The eluate was evaporated to dryness (gentle stream of nitrogen at 40 degrees C), and the residue was dissolved in mobile phase. The extract was injected onto a YMC basic column (150 mmx4.6 mm I.D., 5 microm particle size) at a flow-rate of 1 ml/min. A mixture of 75 mM phosphate buffer, pH 7.0-acetonitrile-methanol (48:26:26, v/v/v) was used as the mobile phase. Standard curves with a lower limit of quantitation of 0.25 ng/ml of olanzapine were linear (r2> or =0.9992) over a range of 0.25-100 ng/ml. Based on the analysis of quality control (QC) samples, the average inter-day accuracy (RE) was 99.0% with an average precision (CV) of 6.64% over the entire range. The stability of olanzapine in human milk was established after three freeze-thaw-heat cycles and storage at -70 degrees C for 10 months. The validated method was used to measure olanzapine concentrations in human milk during a clinical trial.

Determination of olanzapine in a postmortem case.

Olanzapine, a new antipsychotic agent, was approved by the U.S. Food and Drug Administration in 1996 for use in the treatment of schizophrenia. It is structurally similar to clozapine, has a low incidence of extrapyramidal effects, and is effective in treating both the positive and negative symptoms of schizophrenia. This paper describes the determination of olanzapine in biological specimens obtained from the autopsy of a 35-year-old white male found dead in bed at a psychiatric facility. In the months prior to his death, the deceased was prescribed multiple medications, including olanzapine. Olanzapine was identified qualitatively by full scan gas chromatography-mass spectrometry, with quantitative analysis performed by liquid-liquid extraction followed by dual-column gas chromatography. The following concentrations were determined in the specimens analyzed: heart blood, 550 ng/mL; bile, 6346 ng/mL; and gastric contents, 157 ng/mL. Vitreous humor, cerebrospinal fluid, and urine specimens were negative. Although steady-state plasma concentrations of 10-25 ng/mL olanzapine have been reported, effective levels are known to be highly variable and a plasma concentration of 300 ng/mL has been tolerated without adverse effects. Based upon the autopsy, toxicological findings, and case investigation, the cause of death was determined to be intramyocardial arteriosclerosis with severe stenosis of the nodal artery due to hypertensive cardiovascular disease, and the manner was natural.

Prevention of morphine-induced muscarinic (M2) receptor adaptation suppresses the expression of withdrawal symptoms.

Treatment of opiate addiction is generally directed at the suppression of withdrawal symptoms through maintenance of the 'addicted' state with methadone. Yet relatively little is known regarding the neural substrates that contribute to, and maintain the prolonged state of withdrawal experienced by addicts. Opiates can profoundly alter the dynamics of brain and peripheral cholinergic systems, and central administration of anticholinergic drugs in dependent rats has been shown to decrease the expression of precipitated withdrawal symptoms. The purpose of this study was to determine whether the adaptive changes to M2 muscarinic receptors in autonomic centers are linked to the expression of withdrawal phenomena. During the peak period of withdrawal, there was a significant increase in both the expression of M2 muscarinic receptors and its corresponding mRNA within the rostral ventrolateral medulla, a primary vasomotor region. That most of these changes in receptor expression were adaptive in nature was suggested by the fact that when the acetylcholinesterase inhibitor DFP was co-administered with morphine, both the increased mRNA expression and the appearance of withdrawal symptoms were inhibited. Thus, interference with morphine-induced M2 muscarinic receptor adaptation in critical brain regions was correlated with a reduction in the development of physical dependence.

Characterization of olanzapine (LY170053) in human liver slices by liquid chromatography/tandem mass spectrometry.

Olanzapine metabolism was investigated using incubation of olanzapine with human liver slices. The intent of the investigation was to identify olanzapine metabolites and determine if the human liver slice incubations could potentially produce quantities of the olanzapine glucuronides for future studies. Along with known Phase 1 olanzapine metabolites, N-desmethyl-, 2-hydroxymethyl-, and 4'-N-oxide-, a new hydroxylated species was detected. Detection of Phase 2 metabolites included known N-10-glucuronides, a quaternary glucuronide and a novel glucuronide conjugate. This investigation showed the feasibility of using human liver slices to produce sufficient quantities of olanzapine glucuronides for further studies.

Attenuation of muscarinic receptor-G-protein interaction in Alzheimer disease.

Cortical M1 muscarinic receptor-G-protein coupling, high-affinity, guanine nucleotide-sensitive agonist binding (Flynn et al., 1991; Warpman et al., 1993) and muscarinic receptor-stimulated [3H]PIP2 hydrolysis (Ferrari-DiLeo and Flynn, 1993) are known to be defective in Alzheimer disease. Whether this defect reflects an alteration in the M1 muscarinic receptor, its respective guanine nucleotide binding (G) protein or both is not known. This study compares the number and both basal and muscarinic receptor-mediated function of G-proteins in synaptosomal membranes from cerebral cortical samples of age-matched control subjects and Alzheimer disease patients. Immunoblotting with anti-G alpha q/11 and anti-G beta antibodies demonstrated no alteration in the number of these G-protein subunits in Alzheimer disease. Basal [35S]GTP gamma S binding and hydrolysis of [gamma-32P]GTP by high-affinity GTPase also were not significantly altered in Alzheimer disease compared to control membrane samples. However, muscarinic agonist-stimulated GTP gamma S binding and GTP hydrolysis were significantly reduced (80-100%) in Alzheimer disease cortical samples. Diminished agonist-stimulated GTP gamma S binding and GTP hydrolysis correlated with the loss of guanine nucleotide-sensitive, high-affinity agonist binding (KL/KH) ratio) to the M1 receptor subtype. These data provide further evidence for the loss of muscarinic receptor-G protein coupling in Alzheimer disease and support the hypothesis that muscarinic receptor-mediated cortical activation may be compromised in Alzheimer disease.

Evidence for cholinergic vagal afferents and vagal presynaptic M1 receptors in the ferret.

The distribution of muscarinic receptor binding was examined in the ferret brainstem vagal nuclei using the non-selective ligand [3H]quinuclidinyl benzilate and the relatively M1 receptor-selective ligand [3H]pirenzepine. The highest density of receptor sites are found in the subnucleus gelatinosus and lower levels in the other subnuclei of the nucleus of the tractus solitarius and in the area postrema and dorsal motor nucleus of the vagus nerve. Dense binding was also seen in the adjacent hypoglossal nucleus. Following unilateral cervical nodose ganglion excision binding in the subnucleus gelatinosus was attenuated ipsilateral to the lesion compared with the contralateral side. In contrast, [3H]pirenzepine binding was only seen in the subnucleus gelatinosus and in no other region at this level of the brainstem. This binding was reduced in the subnucleus as a whole by 52% ipsilateral to a cervical vagotomy. In the more rostral parts of the subnucleus gelatinosus, binding was undetectable ipsilateral to the lesion but more caudally, appreciable levels of binding persisted. This distribution parallels the known rostro-caudal variation in cross-over of vagal afferent fibres in the ferret dorsal vagal complex and indicates a presynaptic localization of [3H]pirenzepine binding sites on vagal afferent terminals. The distribution of binding of the high affinity choline uptake site blocker, [3H]hemicholinium-3, was also examined in the ferret brainstem using autoradiography. High densities of [3H]hemicholinium-3 binding were seen in the hypoglossal nucleus, the subnucleus gelatinosus and in the area postrema, with lower levels in the dorsal motor nucleus of the vagus, the trigeminal nucleus and other subnuclei of the nucleus of the tractus solitarius.(ABSTRACT TRUNCATED AT 250 WORDS)

[The characteristics of gastrozepin pharmacokinetics in patients with gastric and duodenal peptic ulcers]. / Osobennosti farmakokinetiki gastrotsepina u bol'nykh iazvennoi bolezn'iu zheludka i dvenadtsatiperstnoi kishki.

The individual variations in the blood concentrations of gastrocepine, the period of its half-life and clearance in patients with peptic ulcers of the stomach and the duodenal bulb were determined. The patients having combined forms of peptic ulcer with chronic liver diseases exhibited most often an increase of gastrocepine half-life. A new metabolite of gastrocepine was identified by using the chromato-mass-spectral analysis. The specific antibodies to gastrocepine determining the decrease of its concentration in blood and the development of the drug resistance were found.

Autoradiographic localization and biochemical characteristics of M1 and M2 muscarinic binding sites in the striatum of the cat, monkey, and human.

The autoradiographic distribution of M1 and M2 muscarinic cholinergic binding sites was studied in the striatum of the cat, monkey, and human, and concurrent binding assays were carried out on striatal tissue sections from the cat. M1 sites were directly labeled with 3H-pirenzepine; M2 sites were labeled as a consequence of binding competition between pirenzepine and 3H-N-methylscopolamine. Serial section analysis with autoradiograms and stained tissue sections allowed for comparisons among M1 and M2 binding distributions and AChE staining patterns. The 2 subtypes of binding sites demonstrated distinct striatal distributions. M2 sites were virtually homogeneous except in the ventral striatum, where zones of sparse and especially dense binding were observed. Striatal M1 sites were generally more abundant than M2 sites and showed similar heterogeneity in the ventral striatum. Dorsally, however, patches of dense M1 binding were found, and proved to correspond with AChE-poor striosomes, hallmarks of striatal compartmentalization. The finding of differing distributions for the 2 subtypes of muscarinic cholinergic binding sites suggests a mechanism for the intrinsic spatial segregation of striatal cholinergic function. Further, the striosomal patterning of M1 binding indicates that certain aspects of cholinergic function in the striatum may be constrained and thus regulated by the compartmental ordering characteristic of this region of the basal ganglia.

A selective radioimmunoassay for the determination of pirenzepine in plasma and urine.

A radioimmunoassay procedure for the determination of pirenzepine in either plasma or urine was demonstrated to be both sensitive and specific as well as highly reproducible. The assay could detect levels as low as 1.25 ng/ml. The sensitivity was sufficient to allow the analysis of biological samples from both pharmacokinetic and clinical studies. The two metabolites of pirenzepine, LS 75 and LS 822, did not cross-react with the antiserum. The assay was not affected by a change in anticoagulant or by the presence of several over-the-counter or prescription drugs, even at very high levels. Samples could be frozen and stored for at least a year without affecting the analysis. Repeat analysis could be performed on samples that had been refrozen. Several thousand plasma and urine samples, including plasma samples from severely renally impaired patients, have been analyzed for pirenzepine by the RIA with no interferences having been detected.

Automated monoclonal radioimmunoassays for pirenzepine, a selective muscarinic receptor antagonist, in plasma and urine.

Sensitive and specific monoclonal radioimmunoassays (RIA) for pirenzepine, a muscarinic receptor (M1) antagonist, were developed and validated for rapid automated routine analysis of plasma and urine samples from clinical studies. Three discrete stable hybridoma clones secreting monoclonal antibodies (MAb) to pirenzepine were produced by fusing the myeloma line X63-Ag8.653 to spleen cells of BALB/c mice immunized with pirenzepine-5-N-propionate-protein conjugates. Of three carrier proteins investigated (HSA, BSA and edestin), optimal humoral immune responses and affinity of hybridoma antibody were attained using HSA. All three MAb displayed high affinity to pirenzepine (Ka = 0.6-1.2 X 10(9) l/mol) but showed differing cross-reactivities with its 4'-N-desmethyl metabolite (less than 1%, 6% and 40% respectively). The MAb with essentially zero metabolite cross-reactivity, 58-7/7, was selected for RIA development. In comparison, eight rabbit polyclonal antisera raised against pirenzepine-5-N-propionate-HSA or pirenzepine-5-N-butyrate-HSA possessed a similar range of affinities to the MAbs, but none approached MAb 58-7/7 in specificity. The bridge length had no significant effect on antisera characteristics. Competitive solid-phase RIAs for pirenzepine in human plasma and urine were established using MAb 58-7/7 and [3H]pirenzepine as tracer. All fluid transfers were automated using a programmable sample processing system (Microlab 2,000). Detection limits were 0.25 ng/ml (plasma) and 4 ng/ml (urine) in 0.1 ml sample. The coefficient of within-assay variation was 4% or better in the range 2-100 ng/ml (plasma) or 30-1,000 ng/ml (urine), the between-assay CV was 5.3% or better in the range 5-90 ng/ml (plasma) or 40-660 ng/ml (urine). Excellent correlation was observed between the plasma monoclonal RIA and the hitherto used polyclonal RIA (n = 106, r = 0.994), and between the urine monoclonal RIA and HPLC (n = 82, r = 0.998). We expect that these assays will prove valuable in pharmacokinetic and pharmacological investigations of pirenzepine.