Prediction of drug interaction between oral adsorbent AST-120 and concomitant drugs based on the in vitro dissolution and in vivo absorption behavior of the drugs.

PURPOSE: AST-120 is used to decrease the abundance of serum uremic toxins in treatment of chronic kidney disease; however, it could also adsorb concomitantly administered drugs. This study aimed to develop a prediction method for drug interaction between AST-120 and concomitantly administered drugs based on in vitro dissolution and in vivo absorption behavior. METHODS: Sixty-eight drugs were selected for the analysis. For each drug, theoretical dissolution (R d) and absorption (R a) rates at estimated dosing intervals (1, 30, 60, 90, 120, and 240 min) were calculated using the Noyes-Whitney formula and compartment analysis, respectively. The optimal thresholds for R d and R a (R dth and R ath) were estimated by comparing the results with those of previous drug interaction studies for six drugs. Four drug interaction risk categories for 68 drugs at each dose interval were defined according to the indices of dissolution and absorption against their thresholds. RESULTS: The in vitro dissolution and in vivo absorption behavior of the selected drugs were well fitted to the Noyes-Whitney formula and one- or two-compartment models. The optimal R dth and R ath that gave the highest value of consistency with the equivalence of drug interaction studies were 90 and 30 %, respectively. As the dosing intervals were lengthened, the number of drugs classified into the low-risk categories increased. CONCLUSION: A new drug interaction prediction method based on the pharmacokinetic parameters of drugs was developed. The new model is useful for estimating the risk of drug interaction in clinical practice when AST-120 is used in combination with other drugs.

Determination of domperidone in human plasma using high performance liquid chromatography with fluorescence detection for clinical application.

A simple and reliable method for the determination of domperidone in human plasma has been developed. Plasma samples (1mL) were pre-purified by a solid-phase extraction with Bond Elut(®) C18. The separation was achieved with XBridge™ C18 column (150mm×4.6mm i.d., 5µm) at 40°C. The mobile phase was a mixture of acetonitrile and 10mM ammonium acetate buffer (36:64, v/v), adjusted to pH 9.4 with 20% ammonium solution at a flow rate of 1.0mL/min. The peak was detected using fluorescence detector at excitation 282nm and emission 328nm. Retention times for domperidone and internal standard (propranolol) were 8.3min and 11.2min, respectively. The method showed a good linearity (r>0.999), precision (relative standard deviations <10.6%), and extraction recovery (85.7-99.7%) over a concentration of 1-100ng/mL. The lower limit of quantification (LLOQ) was 1.0ng/mL. This proposed method was successfully applied to a pharmacokinetic interaction study of domperidone in healthy Japanese volunteers.

The effect of experimentally induced sleep disturbance on the pharmacokinetics of lorazepam in healthy volunteers.

The aim of this study was to evaluate the effect of sleep disturbance on the pharmacokinetics, especially on the absorption, of lorazepam in humans. Eight healthy male volunteers received a single oral dose of lorazepam 1 mg before sleep on two occasions in a cross-over design. In either of the two doses, subjects were intermittently exposed to noise for 1.5 hours after oral lorazepam administration. Plasma lorazepam concentrations were measured by HPLC. The exposure to noise significantly prolonged tmax (control vs. noise: 2.0 vs. 3.0 hours) and significantly decreased AUC of lorazepam in the absorption phase. The reduction was 54% (95% CI, 15 - 75%) and 24% (3 - 40%) for AUC (0 - 1 hours) and AUC (0 - 3 hours), respectively. No significant changes were observed in other pharmacokinetic parameters. The results of this study suggest that the onset of drug action after oral lorazepam administration can be altered by sleep disturbance.

[Determination of triazolam and midazolam in human plasma using gas chromatography with microelectron capture detection for clinical application].

A method for the simple and reliable determination of triazolam and midazolam in human plasma using gas chromatography with microelectron capture detection has been developed. Samples (0.5 mL of plasma) were prepared using a simple solvent extraction with 3% isoamyl alcohol/benzene in the presence of NaOH. Two microlitres of the extract were injected onto the capillary column ((5%-phenyl)-methylpolysiloxane). The method was found to be valid in terms of selectivity, linearity, precision, accuracy, and recovery over the concentration range of 0.2 to 20 ng/mL for triazolam, and from 0.5 to 200 ng/mL for midazolam, respectively. Intra- and inter-day precisions determined at three concentrations were from 4.1 to 9.3% for triazolam and from 2.9 to 13.0% for midazolam. The accuracies were within 17.7% for triazolam and within 13.0% for midazolam. This proposed method was successfully applied to a pharmacokinetic study of triazolam or midazolam in healthy volunteers.

Apple juice greatly reduces systemic exposure to atenolol.

AIM: Fruit juice reduces the plasma concentrations of several ß-adrenoceptor blockers, likely by inhibiting OATP2B1-mediated intestinal absorption. The aim of this study was to investigate the effects of apple juice on the pharmacokinetics of atenolol. METHODS: Twelve healthy Korean volunteers with genotypes of SLCO2B1 c.1457C> T (*1/*1 (n = 6) and *3/*3 (n = 6)) were enrolled in this study. In a three-phase, one-sequence crossover study, the pharmacokinetics (PK) of atenolol was evaluated after administration of 50 mg atenolol. Subjects received atenolol with either 300 ml water, 1200 ml apple juice or 600 ml apple juice. RESULTS: Apple juice markedly reduced the systemic exposure to atenolol. The geometric mean ratios (95% confidence intervals) of apple juice : water were 0.18 (0.13, 0.25, 1200 ml) and 0.42 (0.30, 0.59, 600 ml) for the AUC(0,t(last)). In this study, the PK parameters of atenolol responded in a dose-dependent manner to apple juice. CONCLUSIONS: Apple juice markedly reduced systemic exposure to atenolol. The genetic variation of SLCO2B1 c.1457C>T had a minimal effect on the pharmacokinetics of atenolol when the drug was administered with water or apple juice.

Effect of renal impairment on the pharmacokinetics of memantine.

The effect of renal impairment on the pharmacokinetics of a single oral dose of memantine (10 mg) was determined in Japanese subjects. Subjects were assigned to four groups based on baseline creatinine clearance (CL(CR)): normal renal function (> 80 mL/min, n = 6), and mild (50 to ≤ 80 mL/min, n = 6), moderate (30 to < 50 mL/min, n = 6), and severe renal impairment (5 to < 30 mL/min, n = 7). Mean memantine maximum plasma concentration (C(max)) was similar in the groups (12.66, 17.25, 15.75, and 15.83 ng/mL, respectively), as was mean time to C(max) (6.2, 5.2, 4.3, and 5.4 h, respectively). However, exposure to memantine determined from mean area under the plasma concentration-time curve was 1.62-, 1.97-, and 2.33-times higher in subjects with mild, moderate, and severe renal impairment, respectively, as compared to controls with normal renal function. Mean memantine plasma elimination half-life increased according to increasing renal impairment (61.15, 83.00, 100.13, and 124.31 h, respectively), while mean cumulative urinary recovery of unchanged memantine in 72 h after dosing decreased according to increasing renal impairment (33.68%, 33.47%, 23.60%, and 16.17%, respectively). These results are the same as those in the previous study on caucasian individuals, when compared per body weight. It is suggested that the dose of memantine should be halved in patients with renal impairment.

Determination of celiprolol in human plasma using high performance liquid chromatography with fluorescence detection for clinical application.

A new method of analysis has been developed and validated for the determination of plasma celiprolol concentration. Plasma samples (1 ml) were pre-purified by solid-phase extraction with Bond Elut C18. The separation was achieved with XBridge C18 column (150 mm × 3.0mm i.d., 3.5 µm) at 35 °C using a mixture of acetonitrile and 10mM ammonium acetate buffer (pH 10.5) (34:66, v/v) under isocratic conditions at a flow rate of 0.4 ml/min. The peak was detected using a fluorescence detector at excitation 250 nm and emission 482 nm. Retention times for the internal standard (acebutolol) and celiprolol were 4.2 min and 6.3 min, respectively. Calibration curves were linear over the range of 1.0-1000 ng/ml (r>0.999), with a limit of quantification at 1.0 ng/ml. Intra- and inter-assay precision (relative standard deviation) were less than 13.3% and the accuracy (relative error) was -5.1% to 11.5% at four different concentrations. This proposed method was successfully applied to a study of pharmacokinetic interactions between celiprolol and apple juice in humans.

Effects of dosing interval on the pharmacokinetic and pharmacodynamic interactions between the oral adsorbent AST-120 and triazolam in humans.

OBJECTIVE: The objective of this study was to evaluate the pharmacokinetic and pharmacodynamic interactions between the oral adsorbent AST-120 and triazolam. METHODS: In this randomized, cross-over study, 12 healthy volunteers received a single oral dose of triazolam 0.25 mg alone or with AST-120 2 g given 0, 30 or 60 min before triazolam administration. RESULTS: The area under the plasma triazolam concentration-time curve (AUC(0-∞)) significantly decreased with simultaneous AST-120 + triazolam (alone vs simultaneous: 10.9 ± 6.0 vs 6.4 ± 2.6 ng·h/mL, p = 0.003). Triazolam-induced impairment in psychomotor performance assessed by the digit symbol substitution test was significantly attenuated when AST-120 was administered simultaneously. No significant changes in pharmacokinetic and pharmacodynamic parameters were observed when AST-120 was given 30 or 60 min before triazolam administration. CONCLUSIONS: Administering AST-120 simultaneously with triazolam affects the pharmacokinetics and pharmacodynamics of triazolam. Dosing AST-120 at least 30 min before triazolam administration may avoid these interactions.

Itraconazole and domperidone: a placebo-controlled drug interaction study.

PURPOSE: To determine the influence of itraconazole on the pharmacokinetics, and the CNS and prolactin-elevating effects of domperidone in humans. METHODS: Fifteen healthy volunteers received either itraconazole (200 mg daily) or placebo for 5 days with a double blind, randomized, cross-over design. A single oral 20-mg dose of domperidone was administered to subjects on day 5. Plasma domperidone and serum prolactin concentrations were measured. The effects of domperidone on CNS were also assessed using self-rating scales and electroencephalography. RESULTS: Itraconazole significantly increased domperidone AUC(0-∞) (3.2-fold) and C(max) (2.7-fold) compared with placebo, but had no significant effect on the elimination half-life of domperidone. The CNS effects of domperidone assessed by self-rating of mood and electroencephalography, and the prolactin-elevating effect, were not significantly affected by itraconazole. A counterclockwise hysteresis was evident in the relationship between plasma domperidone and serum prolactin concentrations. Itraconazole shifted the hysteresis to the right. Concentration-effect modeling procedures yielded a significant linear relationship between hypothetical effect site domperidone concentrations and prolactin levels. Itraconazole reduced the slope of the linear relationship. CONCLUSIONS: Itraconazole significantly increased plasma domperidone concentrations. The interaction is probably mainly due to a reduced first pass elimination by inhibition of CYP3A and/or MDR1. The clinical significance of the altered relationship between domperidone concentrations and prolactin levels caused by itraconazole is still to be determined.

The effects of the SLCO2B1 c.1457C > T polymorphism and apple juice on the pharmacokinetics of fexofenadine and midazolam in humans.

OBJECTIVE: The objective was to determine the effects of the SLCO2B1 c.1457C> T polymorphism and apple juice on the pharmacokinetics of fexofenadine and midazolam in humans. METHODS: Individuals were divided based on the genotype of SLCO2B1 c.1457C> T (n = 14, c.[1457C]+ c.[= ] 5,c.[1457C]+ c.[1457C> T] 5, and c.[1457C> T]+c.[1457C> T] 4). The oral pharmacokinetics of 60 mg fexofenadine and 5mg midazolam were assessed with water or apple juice (1200 ml/day) in a randomized crossover study. OATP2B1-mediated uptake of fexofenadine and midazolam was evaluated with Xenopus laevis oocyte gene-expression system. RESULTS: When fexofenadine was administered with water, subjects with c.[1457C> T] allele showed a significant decrease in fexofenadine in the area under the plasma concentration-time curve (AUC) compared with c.[1457C] + c[= ] subjects (1110 ± 347 vs. 1762 ± 542 ng . h/ml, P< 0.05). When administered with apple juice, a significant decrease in the fexofenadine AUC was observed compared with water (1342 ± 519 vs. 284 ± 79.2 ng . h/ml, P < 0.05). The apple juice induced decrease in fexofenadine AUC was significantly lower in subjects carrying the c.[1457C> T] allele. Neither the genotype nor the apple juice showed significant effects on the pharmacokinetics of midazolam except for a marginally significant decrease in Cmax after administration with apple juice. The uptake of fexofenadine by OATP2B1 cRNA-injected oocytes was significantly higher than that by water-injected oocytes. Apple juice, but not midazolam, significantly decreased the uptake of fexofenadine by OATP2B1 cRNA-injected oocytes. CONCLUSION: The results suggest that fexofenadine is a substrate of OATP2B1, and the transport function of OATP2B1 is subject to the genotype of SLCO2B1 c.1457C> T and apple juice. It is likely that apple juice has little effect on CYP3A.

The recovery time-course of CYP3A after induction by St John's wort administration.

WHAT IS ALREADY KNOWN ABOUT THIS SUBJECT: St John's wort causes the induction of CYP3A. Little is known about how long the effect remains after cessation of St John's wort. WHAT THIS STUDY ADDS: The in vivo CYP3A activity returns progressively to the basal level approximately 1 week after cessation of St John's wort administration AIMS: To examine the recovery time course of CYP3A after enzyme induction by St John's wort administration. METHODS: The subjects were 12 healthy men, aged 20-33 years. On the first day, they received an oral dose of midazolam 5 mg without St John's wort (day -14). From the next day, they took St John's wort for 14 days. On the last day of St John's wort treatment (day 0) and 3 and 7 days after completion of St John's wort treatment (days 3 and 7), they received the same dose of midazolam. On each day, blood samples were obtained until 8 h after midazolam administration. Plasma concentrations of midazolam were measured by HPLC. Pharmacokinetic parameters of midazolam were determined using noncompartmental analysis. RESULTS: Apparent oral clearance of midazolam was significantly increased after St John's wort administration from 65.3 +/- 8.4 l h(-1) (day -14) to 86.8 +/- 17.3 l h(-1) (day 0). It returned to the control level 7 days after the completion of St John's wort (day 7, 59.7 +/- 3.8 l h(-1)). No significant difference in the elimination half-life between the four periods of the study was observed. The changes in apparent oral clearance after St John's wort discontinuation indicated that CYP3A activity recovers from enzyme induction with an estimated half-life of 46.2 h. CONCLUSIONS: CYP3A activity induced by St John's wort administration progressively returns to the basal level after approximately 1 week. This finding may provide useful information to avoid clinically significant interactions of St John's wort with CYP3A substrates.

Effect of the treatment period with erythromycin on cytochrome P450 3A activity in humans.

The aim of the present study was to estimate the time course change in cytochrome P450 3A (CYP3A) activity during repeated doses of erythromycin. Twelve healthy male volunteers participated in this randomized, 4 x 4 Latin square design study. The pharmacokinetics of a single oral dose of midazolam, a probe for CYP3A activity, were assessed in 4 conditions: (1) midazolam (5 mg) without erythromycin (EM0), (2) erythromycin 2 days + midazolam (2.5 mg) (EM2), (3) erythromycin 4 days + midazolam (2.5 mg) (EM4), and (4) erythromycin 7 days + midazolam (2.5 mg) (EM7). The dose of erythromycin was 800 mg/d. Erythromycin produced a 2.3-, 3.4-, and 3.4-fold increase in dose-corrected area under the curve of midazolam for EM2, EM4, and EM7, respectively, as compared with EM0 (P <.05/6). A significant prolongation of terminal half-life was observed in EM4 and EM7. The relationship between the duration of erythromycin treatment and total clearance of midazolam indicated that a plateau level of CYP3A inhibition can be achieved by 4 days or more of erythromycin treatment. The repeated treatment with erythromycin yields CYP3A inhibition in a duration-dependent manner. A 4-day course of erythromycin treatment produces 90% or more of the maximal inhibition of CYP3A in humans.

[Communication skills for pharmaceutical care].

Effective communication skills facilitate accurate identifications of patient's problems, improvement of the level of patient's satisfaction with the care, and patient's adherence to treatment. Furthermore, a good relationship with patients based on adequate communication lessens patient's anxiety and depression. A patient has his or her own position in a society as a citizen, as a worker and as a family member. A disease threatens such a social background of a patient. We need to recognize that patients suffer not only from diseases, but also from psychosocial distress. Such recognition is the most important basis to improve medical communication that establishes good relationship with patients.

Effect of St. John's wort on the pharmacokinetics of theophylline in healthy volunteers.

The objective of this study was to investigate the effect of St. John's wort (SJW, Hypericum perforatum) on the pharmacokinetics of theophylline in healthy volunteers. Twelve healthy Japanese male volunteers participated in this randomized, open-labeled, crossover study. The subjects took an SJW caplet (300 mg) three times a day for 15 days. On day 14, they received a single oral dose of 400 mg of theophylline. They took the same dose of theophylline without SJW treatment on another occasion. Plasma and urine samples were obtained during a 48-hour period after theophylline administration. Theophylline concentrations in plasma and urine, as well as the major metabolites (13U, 1U, 3X) in urine, were measured. SJW caused no significant changes in the pharmacokinetics of theophylline in plasma. SJW administration tended to increase the ratio of 1U/the total amount excreted in urine. However, no changes in the ratio of unchanged theophylline, 13U, and 3X were observed. It is unlikely that the effect of 15 days of treatment with SJW on CYPs is sufficient to cause a change in plasma theophylline concentrations.

The effect of itraconazole on the pharmacokinetics and pharmacodynamics of bromazepam in healthy volunteers.

RATIONALE AND OBJECTIVE: Bromazepam, an anti-anxiety agent, has been reported to be metabolized by cytochrome P(450) (CYP). However, the enzyme responsible for the metabolism of bromazepam has yet to be determined. The purpose of this study was to examine whether the inhibition of CYP3A4 produced by itraconazole alters the pharmacokinetics and pharmacodynamics of bromazepam. METHODS: Eight healthy male volunteers participated in this randomized double-blind crossover study. The subjects received a 6-day treatment of itraconazole (200 mg daily) or its placebo. On day 4 of the treatment, each subject received a single oral dose of bromazepam (3 mg). Blood samplings for drug assay were performed up to 70 h after bromazepam administration. The time course of the pharmacodynamic effects of bromazepam on the central nervous system was assessed using a subjective rating of sedation, continuous number addition test and electroencephalography up to 21.5 h after bromazepam administration. RESULTS: Itraconazole caused no significant changes in the pharmacokinetics and pharmacodynamics of bromazepam. The mean (+/-SD) values of area under the plasma concentration-time curve and elimination half-life for placebo versus itraconazole were 1328+/-330 ng h/ml versus 1445+/-419 ng h/ml and 32.1+/-9.3 h versus 31.1+/-8.4 h, respectively. CONCLUSION: The pharmacokinetics and pharmacodynamics of bromazepam were not affected by itraconazole, suggesting that CYP3A4 is not involved in the metabolism of bromazepam to a major extent. It is likely that bromazepam can be used in the usual doses for patients receiving itraconazole or other CYP3A4 inhibitors.

The effect of erythromycin and clarithromycin on the pharmacokinetics of intravenous digoxin in healthy volunteers.

Several case reports have suggested an interaction between digoxin and macrolide antibiotics. The authors investigated the effect of erythromycin and clarithromycin on the pharmacokinetics of intravenously administered digoxin (0.5 mg) in healthy subjects. Nine male subjects participated in three studies (digoxin alone, digoxin with erythromycin, and digoxin with clarithromycin). Subjects took erythromycin (800 mg per day) or clarithromycin (400 mg per day) on the day before digoxin dosing and during the kinetic study, Neither of the macrolides affected serum digoxin concentration-time curves. However, more than 1.3-fold increases in urinary digoxin excretions were observed during erythromycin and clarithromycin coadministration compared with digoxin alone. There were significant differences in renal clearance between macrolide coadministration and the control condition (digoxin alone: 98.4 ml/min; digoxin with erythromycin: 137.3 ml/min; digoxin with clarithromycin: 133.6 ml/min). In conclusion, neither erythromycin nor clarithromycin has a significant effect on serum digoxin disposition after an intravenous administration. Renal digoxin excretion is not inhibited but rather enhanced by both macrolides.

In vitro, pharmacokinetic, and pharmacodynamic interactions of ketoconazole and midazolam in the rat.

Interactions of midazolam and ketoconazole were studied in vivo and in vitro in rats. Ketoconazole (total dose of 15 mg/kg intraperitoneally) reduced clearance of intravenous midazolam (5 mg/kg) from 79 to 55 ml/min/kg (p < 0.05) and clearance of intragastric midazolam (15 mg/kg) from 1051 to 237 ml/min/kg (p < 0.05), increasing absolute bioavailability from 0.11 to 0.36 (p < 0.05). Presystemic extraction occurred mainly across the liver as opposed to the gastrointestinal tract mucosa. Midazolam increased electroencephalographic (EEG) amplitude in the beta-frequency range. Ketoconazole shifted the concentration-EEG effect relationship rightward (increase in EC(50)), probably because ketoconazole is a neutral benzodiazepine receptor ligand. Ketoconazole competitively inhibited midazolam hydroxylation by rat liver and intestinal microsomes in vitro, with nanomolar K(i) values. At a total serum ketoconazole of 2 microg/ml (3.76 microM) in vivo, the predicted reduction in clearance of intragastric midazolam by ketoconazole (to 6% of control) was slightly greater than the observed reduction in vivo (to 15% of control). However, unbound serum ketoconazole greatly underpredicted the observed clearance reduction. Although the in vitro and in vivo characteristics of midazolam in rats incompletely parallel those in humans, the experimental model can be used to assess aspects of drug interactions having potential clinical importance.

Effect of fluconazole on the pharmacokinetics and pharmacodynamics of oral and rectal bromazepam: an application of electroencephalography as the pharmacodynamic method.

Quantitative analysis of electroencephalography (EEG) is used increasingly to evaluate the pharmacodynamics of benzodiazepines. The present study aimed to apply the EEG method as well as more traditional approaches to an interaction study of bromazepam and fluconazole. Twelve healthy male volunteers participated in a randomized, double-blind, four-way crossover study. The subjects received single oral or rectal doses of bromazepam (3 mg) after 4-day pretreatment of oral fluconazole (100 mg daily) or its placebo. Plasma bromazepam concentrations were measured before and 0.5, 1, 2, 3, 4, 6, 12, 22, 46, and 70 hours after bromazepam administration. Pharmacodynamic effects of bromazepam were assessed using self-rated drowsiness, continuous number addition test, and EEG. Fluconazole caused no significant changes in pharmacokinetics and pharmacodynamics of oral or rectal bromazepam. Rectal administration significantly increased AUC (1.7-fold, p < 0.0001) and Cmax (1.6-fold, p < 0.0001) of bromazepam. These changes following rectal dose may be due to avoidance of degradation occurring in the gastrointestinal tract. Rectal bromazepam also increased the area under the effect curves assessed by EEG (p < 0.05) and subjective drowsiness (p < 0.05). EEG effects were closely correlated with mean plasma bromazepam concentrations (r = 0.92, p < 0.001 for placebo; r = 0.89, p < 0.0001 for fluconazole). Thus, the EEG method provided pharmacodynamic data that clearly reflected the pharmacokinetics of bromazepam.