Fluphenazine plasma level monitoring for patients receiving fluphenazine decanoate.

BACKGROUND: Finding a dose of an antipsychotic for maintenance therapy that is both safe and effective can be difficult because clinicians are unable to titrate dose against clinical response in patients who are already stable. Therapeutic monitoring of antipsychotic plasma levels has the potential for helping clinicians in dosage selection. With this in mind, we evaluated the usefulness of monitoring fluphenazine plasma levels for patients with schizophrenia who were receiving maintenance treatment with fluphenazine decanoate. METHOD: Thirty-one patients with schizophrenia were randomly assigned to low, medium, or high (0.1-0.3, 0.3-0.6, 0.6-1.0 ng/ml) plasma levels of fluphenazine. The dose of fluphenazine decanoate was adjusted in order to maintain patients in their assigned range. Side effects, psychopathology, and psychotic exacerbations were measured during the year following randomization. RESULTS: All of the psychotic exacerbations occurred during the first eight weeks following randomization, before patients had adequate time to reach their plasma level assignments. We did not find a relationship between plasma levels of fluphenazine and clinical outcomes or side effects. CONCLUSION: Our results do not provide support for the usefulness of monitoring fluphenazine plasma levels for patients receiving fluphenazine decanoate.

Clinical outcome following neuroleptic discontinuation in patients with remitted recent-onset schizophrenia.

OBJECTIVE: The goal of this report was to examine the clinical course following neuroleptic discontinuation of patients with recent-onset schizophrenia who had been receiving maintenance antipsychotic treatment for at least 1 year. METHOD: Fifty-three volunteer patients with recent-onset schizophrenia who had been clinically stabilized on a maintenance regimen of fluphenazine decanoate for a mean of 16.7 months had their antipsychotic medications withdrawn under clinical supervision. Participants initially entered a 24-week, double-blind crossover trial in which fluphenazine and placebo were administered for 12 weeks each. For those who did not experience symptom exacerbation or relapse during this period, fluphenazine was openly withdrawn; participants were then followed for up to 18 additional months. RESULTS: When a low threshold for defining symptom reemergence was used, 78% (N=39 of 50) of the patients experienced an exacerbation or relapse within 1 year; 96% (N=48 of 50) did so within 2 years. Mean time to exacerbation or relapse was 235 days. When hospitalization was used as a relapse criterion, only six of 45 of individuals (13%) experiencing an exacerbation or relapse who continued in treatment in the clinic were hospitalized, demonstrating the sensitivity of the psychotic exacerbation criterion. CONCLUSIONS: The vast majority of clinically stable individuals with recent-onset schizophrenia will experience an exacerbation or relapse after antipsychotic discontinuation, even after more than a year of maintenance medication. However, clinical monitoring and a low threshold for reinstating medications can prevent hospitalization for the majority of these patients.

Simultaneous determination of clozapine and its N-desmethyl and N-oxide metabolites in plasma by liquid chromatography/electrospray tandem mass spectrometry and its application to plasma level monitoring in schizophrenic patients.

A liquid chromatography tandem mass spectrometry (LC-MS-MS) assay method for the simultaneous determination of clozapine and its N-desmethyl (norclozapine) and N-oxide metabolites in human plasma is described. The compounds were extracted from plasma by a single step liquid-liquid extraction procedure and analyzed using a high performance liquid chromatography electrospray tandem mass spectrometer system. The compounds were eluted isocratically on a C-18 column, ionized using positive ion atmospheric pressure electrospray ionization method by a TurboIonspray source and analyzed using multiple reaction monitoring mode. The ion transitions monitored were m/z 327 --> m/z 270 for clozapine, m/z 313 --> m/z 192 for norclozapine, m/z 343 --> m/z 256 for clozapine-N-oxide and m/z 421--> m/z 201 for internal standard. The standard curves of clozapine, norclozapine and clozapine-N-oxide were linear over the range of 1 ng/ml to 1000 ng/ml when 0.5 ml of plasma was used for the analysis (r(2) >0.998). Three pooled plasma samples collected from patients who were treated with clozapine were used as long-term quality control samples to check the validity of spiked standard curve samples made at various times. The intra- and inter-assay variations for the spiked standard curve and quality control samples were less than 14%. These variations for the long-term patient quality control samples were less than 11%. The LC-MS-MS assay for simultaneous determination of clozapine, norclozapine and clozapine-N-oxide reported here is highly specific, sensitive, accurate and rapid. This method is currently being used for the plasma level monitoring of clozapine and its N-desmethyl and N-oxide metabolites in patients treated with clozapine. The plasma levels of clozapine, norclozapine and clozapine-N-oxide varied widely within and among patients. The data revealed that the norclozapine and clozapine N-oxide metabolites were present at about 58%+/-14% and 17%+/-6% of clozapine concentrations in plasma, respectively.

Fluphenazine levels during maintenance treatment of recent-onset schizophrenia: relation to side effects, psychosocial function and depression.

RATIONALE: The utility of fluphenazine levels during maintenance treatment of schizophrenia is still unclear. OBJECTIVES: This study investigated the relationship between fluphenazine levels and a variety of clinical measures during maintenance treatment of schizophrenia. METHODS: Fluphenazine levels, side effects, depression and psychosocial outcome were measured at five time points over approximately 1 year in 59 recent onset schizophrenic patients treated with a maintenance dose of injectable fluphenazine decanoate. Negative symptoms were evaluated at the 1-year endpoint. RESULTS: Fluphenazine levels showed marked intraindividual variability even when measurements were restricted to the second 6 months of treatment, by which time steady state levels should have been achieved. No consistent relationship was found between fluphenazine levels and any of the outcome measures. CONCLUSIONS: The results of this study suggest that fluphenazine plasma levels do not routinely add relevant clinical information beyond that of dose in evaluating potential side effects or negative consequences during maintenance treatment with the decanoate form of the medication.

Simultaneous determination of risperidone and 9-hydroxyrisperidone in plasma by liquid chromatography/electrospray tandem mass spectrometry.

A simple and highly sensitive liquid chromatographic/electrospray tandem mass spectrometric (LC/MS/MS) assay was developed for the simultaneous determination of risperidone (RSP) and its major circulating metabolite 9-hydroxyrisperidone (9-OH-RSP) in the plasma of humans and rats. A simple one-step solvent extraction with 15% methylene chloride in pentane was used to isolate the compounds from plasma. The compounds were eluted from a phenyl-hexyl column and detected with a Perkin-Elmer SCIEX API2000 triple-quadrupole mass spectrometer using positive ion atmospheric pressure electrospray ionization and multiple reaction monitoring. The assay was linear over the range 0.1-100 ng ml(-1) when 0.5 ml of plasma was used in the extraction. The overall intra- (within-day) and inter- (between days) assay variations were < 11%. The variations in the concentrations of two long-term quality control samples from pooled patient plasma samples analyzed over a period of 6 months were approximately 10%. The analysis time for each sample was 4 min and more than 100 samples could be analyzed in one day by running the system overnight. The assay is simple, highly sensitive, selective, precise and fast. This method is being used for the therapeutic drug monitoring of schizophrenic patients treated with RSP and to study the pharmacokinetics and tissue distribution of RSP and 9-OH-RSP in rats.

Pharmacokinetics and tissue distribution of olanzapine in rats.

The single dose pharmacokinetics of olanzapine in rats, following an oral dose and its distribution in the brain and other tissues after repeated oral and intra-peritoneal (i.p.) administration, were studied. Olanzapine in plasma, brain, liver, lung, kidney, spleen and fat was assayed at predose, 0.25, 0.5, 1, 2, 5, 12, 24, 36, 48 h postoral dose of 6 mg/kg and after daily oral and i.p. doses of 0.25, 1, 3, and 6 mg/kg/day of olanzapine for 15 consecutive days by a sensitive and specific HPLC method with electrochemical detection. Olanzapine was readily absorbed and distributed in plasma and tissues as the peak concentrations were reached within approximately 45 min after the oral dose. The terminal half-life of olanzapine in plasma was 2.5 h and in tissues it ranged from 3 to 5.2 h. The area under the concentration-time curve (AUC(last)) was lowest in plasma and largest in liver and lung. The AUC(last) of olanzapine was eight times larger in brain and three to 32 times larger in other tissues than that in plasma. After repeated oral doses, the plasma and tissue concentrations of olanzapine were generally higher than those after repeated i.p. doses. The liver and spleen had the highest concentrations after oral and i.p doses, respectively. In both cases, the tissue concentrations were four- to 46-fold higher than that in plasma and correlated with administered doses. Likewise, plasma concentrations strongly correlated with the simultaneous brain and tissue concentrations (r(2)>0.908, p<0.0001). On average, the brain levels were 6.3-13.1 and 5.4-17.6 times higher than the corresponding plasma level after oral and i.p. doses, respectively. The tissue to plasma level ratio of olanzapine was higher in other tissues. The data indicated that olanzapine is rapidly absorbed and widely distributed in the tissues of rats after oral and i.p. administration. The plasma concentration appears to predict the simultaneous concentration in brain and other tissues. There was no marked localized accumulation of olanzapine in any of the regions of the rat brain.

Distribution after repeated oral administration of different dose levels of risperidone and 9-hydroxy-risperidone in the brain and other tissues of rat.

Rats were treated with daily oral doses of 1, 4, and 6 mg/kg risperidone (RSP) and its metabolite, 9-hydroxy-risperidone (9-OH-RSP), for 15 consecutive days. Concentrations of RSP and 9-OH-RSP were measured in plasma, brain, liver, kidney, lungs and fat tissue by high-performance liquid chromatography with electrochemical detection. Non-specific distribution of RSP and 9-OH-RSP in various brain regions was also studied after administration of 6 mg/kg per day oral dose for 15 days. After RSP treatment, concentrations of 9-OH-RSP were higher than those of RSP in plasma and tissues except in brain, where both compounds were present in nearly equal concentrations. Similarly, after 9-OH-RSP treatment, levels of 9-OH-RSP were higher than levels of either RSP or 9-OH-RSP or the sum of RSP and 9-OH-RSP levels measured after treatment with RSP. There was a moderate relationship between RSP dose and tissue levels of RSP and 9-OH-RSP (all rs > or = 0.62, P < 0.01), except in fat. There was also a strong relationship between the dose and tissue levels of 9-OH-RSP (all rs > or = 0.68, P < 0.005). A significant relationship was found between plasma levels of RSP and brain levels of RSP and 9-OH-RSP (all rs > or = 0.57, P < 0.03) after treatment with RSP. After 9-OH-RSP treatment, a much stronger relationship was observed between plasma and brain 9-OH-RSP levels (rs > or = 0.90, P < 0.005). The plasma concentrations of RSP and 9-OH-RSP appear to reflect their concentrations in brain. The tissue-to-plasma ratios of RSP and 9-OH-RSP were relatively low compared to other antipsychotics. In liver, kidney and lung the tissue to plasma ratio for RSP and 9-OH-RSP after treating with RSP ranged from 0.85 to 3.4. The brain to plasma ratio for RSP and 9-OH-RSP was several-fold lower than that in peripheral tissues. After RSP administration, the mean brain to plasma level ratio for RSP was 0.22, and for 9-OH-RSP to it was 0.04. The brain to plasma ratio of 9-OH-RSP after giving 9-OH-RSP was similarly low (0.04). The low brain/plasma ratio of high potency RSP and 9-OH-RSP may in part be due to their low lipophilicity, log P = 3.04 and 2.32, respectively, resulting in limited non-specific accumulation in brain tissue.

Plasma concentrations of risperidone and its 9-hydroxy metabolite and their relationship to dose in schizophrenic patients: simultaneous determination by a high performance liquid chromatography with electrochemical detection.

A simple, sensitive and accurate method for the simultaneous determination of risperidone (RSP) and its 9-hydroxy metabolite (9-OH-RSP) in human plasma is described. The relationship between dose of RSP and the plasma concentration of RSP and 9-OH-RSP in a clinical situation is discussed. Both compounds were isolated from plasma by a simple one-step liquid-liquid extraction with 15% methylene chloride in pentane. High-performance liquid chromatography separations were made on a cyano column and the compounds were detected by electrochemical detector. The method had sufficient sensitivity to determine RSP and 9-OH-RSP accurately at concentrations as low as 0.25 ng/ml when 1 ml of plasma is used for the analysis. The assay determinations were accurate, precise and consistent with a coefficient of variation less than 15%. Commonly co-administered drugs and other antipsychotics did not interfere with the analysis of either RSP or 9-OH-RSP There were large variations in inter- and intra-individual values of plasma concentrations of RSP and 9-OH-RSP. The 9-OH-RSP appears to be the major circulating active moiety and its plasma concentrations were, on the average 22 fold higher than that of RSP in schizophrenic patients treated with RSP. The ratio of RSP/9-OH-RSP concentrations suggested that three of the patients may have deficiency in cytochrome P450 enzyme CYP 2D6. The plasma concentrations of RSP showed a weak relationship with the administered daily oral dose (r = 0.4684, p = 0.01, n = 215). However, there was a good relationship between the daily dose of RSP and the plasma concentration of 9-OH-RSP (r = 0.6654, p = 0.01, n = 280) or the total active moiety, sum of RSP and 9-OH-RSP concentrations (r = 0.7041, p = 0.0005, n = 280). The measurement of the total active moiety in plasma of schizophrenic patients may be useful for assessing the relationship between dose and plasma concentration and dose and clinical outcome of patients rather than measuring RSP alone.

Plasma level monitoring of olanzapine in patients with schizophrenia: determination by high-performance liquid chromatography with electrochemical detection.

A sensitive high-performance liquid chromatography method with electrochemical detection for the determination of olanzapine in human plasma is described. Olanzapine from plasma samples was isolated by a simple one-step liquid--liquid extraction with 15% methylene chloride in pentane with an extraction recovery of approximately 94% of the total olanzapine in plasma. The compound was separated on a cyano column. Under the conditions described, commonly coadministered drugs and other common antipsychotic drugs did not interfere with the analysis of olanzapine. The lower limit of determination of the assay was 0.25 ng of olanzapine per ml when 1 ml of plasma was used for the analysis. The interaassay and intraassay variance was (CV%) less than 10%. The standard curve was linear within the range of 0.25 to 50 ng/ml of olanzapine. This method has been used for the determination of plasma levels of olanzapine in patients with schizophrenia who were treated with daily oral doses of 10, 15, and 20 mg of olanzapine. The results indicate that the plasma level of olanzapine increases linearly with the administered daily oral dose (r = 0.6889, p = 0.01).

Chronic haloperidol-induced changes in regional dopamine release and metabolism and neurotensin content in rats.

Chronic neuroleptic administration has previously been shown to alter in vivo measures of dopaminergic function and lead to regionally selective increases in neurotensin levels. In the current study, female rats were administered chronic haloperidol for 6 months via subcutaneous silastic implants. After 24 weeks of administration, microdialysis probes were inserted into the lateral caudate putamen and the medial prefrontal cortex. Basal samples were collected prior to infusion of a high K+ concentration (100 mM KCl). Extracellular concentrations of dopamine, 3,4-dihydroxyphenylacetic acid, homovanillic acid, and 5-hydroxyindoleacetic acid were assessed using HPLC. Chronic haloperidol-treated rats showed increased basal dopamine metabolite levels in the caudate putamen and an altered response to the effects of high K+ on 3,4-dihydroxyphenylacetic acid; no significant differences were seen with other analytes in the caudate putamen. Although basal concentrations were not different between groups in the prefrontal cortex, haloperidol-treated rats showed a significant attenuation of response to the effects of high K+ infusion on dopamine metabolite concentrations. Radioimmunoassay measurement of tissue neurotensin content showed highly significant elevations of neurotensin concentrations in the caudate putamen and nucleus accumbens, but not in other brain regions analyzed. These results suggest a confluence of altered dopamine and neurotensin function in the caudate putamen which may be related to motor side effects of haloperidol, whereas changes in prefrontal dopamine function are not associated with altered neurotensin levels.

Distribution of fluphenazine and its metabolites in brain regions and other tissues of the rat.

Rats were given 5, 10, or 20 mg/kg oral doses of fluphenazine (FLU) dihydrochloride daily for 15 days. FLU and its sulfoxide (FL-SO), 7-hydroxy (7-OH-FLU) and N4'-oxide (FLU-NO) metabolites were assayed in plasma, liver, kidney, fat, whole brain, and brain regions by specific and sensitive radioimmunoassays (RIA). All metabolites were detected in tissues at higher levels than in plasma, and the levels increased with dose. FLU was 10- to 27-fold higher in brain regions than in plasma. Brain vs plasma levels of FLU correlated more closely than levels of its metabolites. Liver contained the highest levels of all analytes at all doses. FLU-SO was the major metabolite in brain regions (24% to 96% of FLU) and accumulated in fat 43 to 75 times more than FLU. Levels of 7-OH-FLU and FLU-NO were very low in brain (1% to 20% of FLU). FLU-SO and FLU-NO had only 1% to 3% the affinity for D1 and D2 receptors, but 7-OH-FLU had 20% the D2 and 5% the D1 affinity of FLU. The low affinity for dopamine receptors and low brain-levels of metabolites of FLU indicate that they are not likely to contribute importantly to pharmacologic responses of FLU. Also, the estimated relative "activity factor" for these compounds in the brain indicated that the contribution to neuropharmacologic activity by metabolites is less than 1% of FLU. Consequently, clinical monitoring of plasma FLU alone may be sufficient.

Effects of chronic haloperidol and clozapine treatment on neurotensin and c-fos mRNA in rat neostriatal subregions.

Previous studies have shown elevation of neurotensin neuromedin N (NT/N) and c-fos mRNA in the dorsolateral region of the rat neostriatum (DLSt) by acute administration of only typical antipsychotic drugs. However, NT/N mRNA in the nucleus accumbens-shell is enhanced acutely by several clinically efficacious antipsychotic drugs, regardless of their motor side effect liability. In the present study, induction of NT/N mRNA in the DLSt was observed again after 28 days of continuous administration (via osmotic minipumps) of haloperidol, but not clozapine. However, this response was only about 50% of that caused by acute haloperidol and c-fos mRNA levels in the DLSt were not elevated after the chronic treatment. An acute challenge of haloperidol 24 hr after chronic haloperidol treatment did not affect the tolerant response of NT neurons but caused a small increase in c-fos mRNA in the DLSt. Similar to the DLSt, chronic haloperidol (but not clozapine) significantly enhanced NT/N gene expression in the ventrolateral striatum, a region thought to be involved in abnormal oral movements, perhaps related to tardive dyskinesia. Interestingly, dopamine D2 receptor binding using [125I]iodosulpride nearly doubled in all regions of the striatum after chronic haloperidol but not clozapine. In contrast to the lateral neostriatum, NT/N mRNA expression in the nucleus accumbens-shell was elevated similarly by chronic treatment with haloperidol and clozapine to a level observed after acute haloperidol treatment. These results demonstrate further that region-specificity of NT/N mRNA regulation discriminate between typical and atypical antipsychotic drugs.

Simultaneous determination of plasma haloperidol and its metabolite reduced haloperidol by liquid chromatography with electrochemical detection. Plasma levels in schizophrenic patients treated with oral or intramuscular depot haloperidol.

A simple and highly sensitive liquid chromatographic method with electrochemical detection for the simultaneous determination of haloperidol and its metabolite reduced haloperidol in human plasma has been developed. The sample preparation for the analysis involves a simple one-step extraction procedure with 10% methylene chloride in pentane. The compounds were separated on a cyano column maintained at a temperature of 40 degrees C and were detected electrochemically by a flow-through analytical cell kept at +0.95 V. The standard curve is linear over the range of 0.1 to 15 ng/ml and the lower limit of quantitation is 0.1 ng/ml for haloperidol and 0.25 ng/ml for reduced haloperidol which is equivalent to approximately 40 pg on column when 1 ml of plasma was used for the analysis. The lower limit of quantitation for reduced haloperidol can be extended to 0.1 ng/ml if 2 ml of plasma is used in the analysis. The coefficient of variation of the determination of plasma levels by this method over the standard curve concentration range was less than 10%. Commonly co-administered drugs and other neuroleptics used in conjunction with haloperidol did not interfere in the determination of either haloperidol or reduced haloperidol. This method has been successfully used for the determination of haloperidol and reduced haloperidol in plasma and their levels in patients treated with various doses oral haloperidol or intramuscular haloperidol decanoate are reported.

Optimal drug and behavior therapy for treatment-refractory schizophrenic patients.

Thirteen treatment-refractory schizophrenic patients (10 men and three women) who were receiving more than 50 mg/day of haloperidol and who had been hospitalized for more than 1 year successfully tolerated a mean dose reduction of 63% with consequent improvement in psychopathology and side effects. The addition of intensive behavior therapy to the optimal dose of haloperidol yielded further improvements in functional behavior, such as self-care and social interaction.

Radioimmunoassay for 7-hydroxy metabolite of fluphenazine and its application to plasma level monitoring in schizophrenic patients treated long term with oral and depot fluphenazine.

Immunization of New Zealand white rabbits with a bovine serum albumin conjugate of 7-hydroxy-N-carboxyethyl-N-deshydroxyethylfluphenazine produced highly specific antisera for 7-hydroxyfluphenazine (7-OHFLU). A radioimmunoassay (RIA) was developed using antisera from one of the rabbits that enabled for the first time the determination of plasma levels of 7-OHFLU, an active metabolite of fluphenazine (FLU), in patients treated with oral FLU dihydrochloride or i.m. FLU decanoate. The assay method provided sufficient sensitivity to determine accurately 20 pg of 7-OHFLU in 200 microliters (0.1 ng/ml) of plasma with a coefficient of variation of < 10%. The antiserum used in the RIA for 7-OHFLU demonstrated negligible cross-reactivity with FLU and its metabolites such as FLU sulfoxide, N-deshydroxyethylFLU, FLU N4'-oxide, N-deshydroxyethyl-7-OHFLU, and 7-O-glucuronide of FLU and also with other antipsychotic agents and commonly coadministered drugs. The 7-OHFLU was present in measurable amounts in all plasma samples obtained at 4-week intervals from patients receiving a daily oral dose of 5 (n = 10), 10 (n = 13), or 20 (n = 14) mg of FLU dihydrochloride. Large interindividual variations in the plasma level of FLU and 7-OHFLU were noted and the mean plasma levels ratios of 7-OHFLU/FLU at these doses were 2.07 +/- 1.08, 2.07 +/- 1.13, and 2.02 +/- 0.82, respectively.(ABSTRACT TRUNCATED AT 250 WORDS)

Metabolism of phenothiazine and butyrophenone antipsychotic drugs. A review of some recent research findings and clinical implications.

Whereas some metabolites of antipsychotic drugs are psychoactive and contribute to clinical improvement, recent studies have provided evidence that certain metabolites contribute to side-effects which can be disabling enough to negate clinical improvement as regards the psychosis. The route of administration of the drug can determine the amount of metabolite produced in the body and affect how the patient feels in response to the treatment.

Clinical perspectives of some neuroleptics through development and application of their assays.

Attempts to investigate relationships between plasma levels of neuroleptics and therapeutic outcome in schizophrenic patients have been hampered due to such factors as the chemical nature of these drugs, their metabolism, and the very heterogeneous nature of the disease states. Two clinical studies are described that investigate the relationship between plasma levels of fluphenazine (FLU) and its metabolites and therapeutic outcome in schizophrenic patients. In the first of these studies the levels of FLU and fluphenazine sulfoxide (FLUSO) in schizophrenics receiving either 5 or 25 mg of fluphenazine decanoate (FLUD) intramuscularly every 2 weeks were monitored. Patients given 25 mg of FLUD required 3 months to reach plasma level steady state. The results suggest that such patients, when being switched from the oral to the depot formulation of FLU, should continue to receive oral supplementation during the 1st 3 months after conversion. The relationship between log-transformed plasma levels at 26 and 38 weeks with subsequent psychotic exacerbation was investigated with the use of logistic regression and survival analysis. Both demonstrated significant relationships between FLU plasma levels and a risk of psychotic exacerbation at 26 and 38 weeks. The possibility of any correlations between neurological side effects and plasma concentrations were also investigated, with statistically significant correlations between FLU levels and akinesia found at 2 and 26 weeks. In the second of these studies the levels of FLU, FLUSO, 7-hydroxyfluphenazine (7-OHFLU), and fluphenazine N4'(-)-oxide (FLUNO) in schizophrenics receiving 5, 10, or 20 mg of oral fluphenazine dihydrochloride daily for 4 weeks were monitored. The relationships between log-transformed plasma levels, disabling side effects, and global improvement were examined by logistic regression for the 4-week period. The study showed a significant correlation between increases in both plasma levels and disabling side effects such that at a plasma level of 2.7 ng/ml, approximately 90% of acutely ill patients experienced disabling side effects. Conversely, the study also showed that at a plasma level of 0.67 ng/ml, 48% of patients experienced improvement without the development of disabling side effects. When relationships between metabolite levels, disabling side effects, and global improvement were examined by logistic regression, a stronger correlation between disabling side effects and FLUNO levels than between side effects and FLU levels was found.(ABSTRACT TRUNCATED AT 400 WORDS)

Determination of risperidone in plasma by high-performance liquid chromatography with electrochemical detection: application to therapeutic drug monitoring in schizophrenic patients.

A highly sensitive high-performance liquid chromatography method with electrochemical detection for the determination of risperidone in plasma has been developed. Remoxipride is used as an internal standard. A simple one-step extraction with 25% methylene dichloride in pentane is used to isolate the drug from the plasma. This is followed by high-performance liquid chromatography analysis on a cyano column with electrochemical detection. Under the experimental conditions described here, commonly coadministered drugs and other antipsychotic drugs did not interfere with the analysis of either risperidone or the internal standard. Also, the available two metabolites of risperidone did not interfere in the assay. This method has sufficient sensitivity to quantitate risperidone accurately at 0.1 ng/mL, when 1 mL of plasma was used for the analysis, with a coefficient of variation of < 9%. This method has been successfully used in the determination of plasma levels of risperidone in schizophrenic patients treated with 4-, 6-, and 8-mg oral doses per day.

Field dependent transverse relaxation rate increase may be a specific measure of tissue iron stores.

The degree to which MRI magnet field strength affects measured transverse relaxation rates (R2) defines a measure termed the field dependent R2 increase (FDRI). We report here the results of in vivo and in vitro experiments that were conducted to evaluate whether FDRI is a potentially useful measure of tissue iron stores. T2 relaxation times were obtained using two clinical MRI instruments operating at 0.5 and 1.5 Tesla, and relaxation rates (R2) were calculated as the reciprocal of T2. The in vivo experiment measured R2 in human brain frontal white matter, caudate nucleus, putamen, and globus pallidus. The FDRI was very highly correlated with published brain iron levels for the four regions examined. The in vitro experiment measured R2 in agarose gel-based phantoms containing physiologic forms and amounts proteins involved in iron storage and transport (ferritin, apoferritin, transferrin, and apotransferrin). Significant field dependence was observed only for the ferritin phantoms. The differences in the R2 values obtained at the two field strengths were striking, and were proportional to the ferritin levels of the phantoms. These studies suggest that FDRI may be a specific measure of tissue ferritin. The quantitative significance of the results to imaging and possible applications to the clinical investigation of pathologic states are discussed.