Comparison of the effect of lansoprazole and omeprazole on intragastric acidity and gastroesophageal reflux in patients with gastroesophageal reflux disease

A prospective study of the pharmacokinetics of itraconazole solution was performed in 11 patients who underwent allogeneic BMT (day of BMT = day 0) after a conditioning regimen including total body irradiation (TBI). Itraconazole solution (400 mg once a day) was given 7 days before BMT and continued up to the end of neutropenia unless another antifungal treatment was necessary. Blood samples were collected before itraconazole intake (Cmin) and 4 h later (Cmax) every other day for assays of itraconazole (ITRA) and its active metabolite hydroxy-itraconazole (OH-ITRA). The mean values of Cmin ITRA and OH-ITRA, respectively, were 287 +/- 109 ng/ml and 629 +/- 227 ng/ml at day -1 and 378 +/- 147 ng/ml and 725 +/- 242 ng/ml at day +1. The maximum Cmin values were observed at day +3. Six patients at day -1 (54%) and 8 at day +1 (72%) had satisfactory residual plasma concentrations of at least 250 ng/ml of unchanged ITRA. From day +1 to day +9, eight patients discontinued the itraconazole treatment, five of them had satisfactory plasma residual concentrations at this time. This work shows a good bioavailability of itraconazole oral solution during the early phase after allogeneic BMT, but more data are needed for the late phases.     

Oral ganciclovir dosing in transplant recipients and dialysis patients based on renal function

BACKGROUND: An oral formulation of ganciclovir (GCV) was recently approved for the prevention of cytomegalovirus disease in solid organ transplant recipients. This study was designed to determine the bioavailability of GCV and to test a dosing algorithm in transplant and dialysis patients with different levels of renal function. METHODS: Pharmacokinetic studies were carried out in 23 patients who were either a recipient of an organ transplant or on hemodialysis. Drug dosing was established by the following algorithm based on calculated creatinine clearance (CrCl): CrCl = [(140-age) x body weight]/(72 x Cr) x 0.85 for women that is, CrCl >50 ml/min, 1000 mg every 8 hr; CrCl of 25-50 ml/min, 1000 mg every 24 hr; CrCl of 10-24 ml/ min, 500 mg every day; CrCl < 10 ml/min (or on dialysis), 500 mg every other day after dialysis. GCV was taken within 30 min after a meal. The patients received oral GCV for between 12 days and 14 weeks. Serum specimens (or plasma from patients on hemodialysis) obtained at steady state were analyzed for GCV concentrations by high-performance liquid chromatography. In nine of the transplant recipients, absolute bioavailability was determined by comparing GCV levels after single oral and intravenous doses of GCV. RESULTS: The following GCV concentrations (mean +/-SD) were determined: with CrCl of > or =70 ml/min, the minimum steady-state concentration (Cmin) and maximum concentration (Cmax) were 0.78+/-0.46 microg/ml and 1.42+/-0.37 microg/ml, respectively, with a 24-hr area under the concentration time curve (AUC0-24) of 24.7+/-7.8 microg x hr/ml; with CrCl of 50-69 ml/min, the Cmin and Cmax were 1.93+/-0.48 and 2.57+/-0.39 microg/ml, respectively, with an AUC0-24 of 52.1+/-10.1 microg x hr/ml; with CrCl of 25-50 ml/min, the Cmin and Cmax were 0.41+/-0.27 and 1.17+/-0.32 microg/ml, respectively, with an AUC0-24 of 14.6+/-7.4 microg x hr/ml. For one patient with a CrCl of 23.8 ml/min, the Cmin and Cmax were 0.32 and 0.7 microg/ml, respectively, with an AUC0-24 of 10.7 microg x hr/ml. With CrCl of <10 ml/min, the mean Cmin and Cmax were 0.75+/-0.42 and 1.59+/-0.55 microg/ml, respectively, with a mean AUC0-24 of 64.6+/-18.8 microg x hr/ml. Absolute bioavailability, for the nine patients so analyzed, was 7.2+/-2.4%. For those patients with end-stage renal failure, GCV concentrations fell during dialysis from a mean of 1.47+/-0.48 microg/ml before dialysis to 0.69+/-0.38 microg/ml after dialysis. CONCLUSIONS: The bioavailability of oral GCV in transplant patients was similar to that observed in human immunodeficiency virus-infected patients. However, levels between 0.5 and 1 microg/ml (within the IC50 of most cytomegalovirus isolates) could be achieved with tolerable oral doses. The proposed dosing algorithm resulted in adequate levels for patients with CrCl greater than 50 ml/min and for patients on dialysis. For patients with CrCl between 10 and 50 ml/min, the levels achieved were low and these patients would likely benefit from increased doses.     

Enhanced bioavailability of itraconazole in hydroxypropyl-beta-cyclodextrin solution versus capsules in healthy volunteers

The bioavailabilities and bioequivalences of single 200-mg doses of itraconazole solution and two capsule formulations were evaluated in a crossover study of 30 male volunteers. The two capsule formulations were bioequivalent. The bioavailabilities of the solutions itraconazole and hydroxyitraconazole were 30 to 33% and 35 to 37% greater, respectively, than those of either capsule. However, the maximum concentrations of the drug in plasma (Cmax), the times to Cmax, and the terminal half-lives were comparable for all three formulations. These data indicate that the bioavailabilities of itraconazole and hydroxyitraconazole are enhanced when administered as an oral solution instead of capsules.     

Metoclopramide plasma concentration in neonates

During the course of a multiple-dose metoclopramide (M) oral treatment, M plasma concentrations were measured just before (Cmin) and 1 hour after the administration (C1h) at steady-state in 5 (3 premature and 2 term) neonates. Mean Cmin was equal to 91.6 +/- 45.5 ng/ml and higher than C1h (87.4 +/- 43.2 ng/ml), but not significantly. A significant negative correlation was found between Cmin plasma concentration and gestational age as well as with postconceptional age, suggesting that the lower the gestational and postconceptional age, the lower the metoclopramide dosage should be.     

Are there special considerations in the prescription of serotonin reuptake inhibitors for women?

The aim of this study was to evaluate and compare the pharmacokinetics of naftidrofuryl (CAS 3200-06-4) after single oral administration of a 200 mg naftidrofuryl tablet (Praxilene) in Caucasian male and female elderly healthy volunteers versus young healthy volunteers. Thirty healthy volunteers were included in a randomised phase I trial in 3 parallel groups of 10 subjects aged 18-35 years (group 1), 60-70 years (group 2) and 70-80 years (group 3). Blood samples were taken over a period of 24 h after dosing for evaluation of the pharmacokinetics of naftidrofuryl. The Cmax, tmax, AUC0-t parameters were measured and t1/2 and AUC0-alpha were calculated by a model independent method. The mean (+/- SD) pharmacokinetic parameters of naftidrofuryl after single oral administration of 200 mg of naftidrofuryl for group 1 were as follows: tmax 3.5 h (median), Cmax 284 +/- 136 ng/ml, t1/2 3.69 +/- 1.30 h, AUC0-t 1865 +/- 905 h.ng/ml and AUC0-inf 2055 +/- 901 h.ng/ml; for group 2: tmax 2.75 h (median), Cmax 282 +/- 165 ng/ml, t1/2 3.03 +/- 1.08 h, AUC0-t 1783 +/- 1147 h.ng/ml and AUC0-inf 1856 +/- 1158 h.ng/ml; for group 3: tmax 2.5 h (median), Cmax 271 +/- 86 ng/ml, t1/2 3.50 +/- 1.29 h, AUC0-t 1742 +/- 544 h.ng/ml and AUC0-inf 1834 +/- 549 h.ng/ml. Statistical analysis was performed on the pharmacokinetic parameters with one-way ANOVA in order to compare each age group. The results of the pharmacokinetic and statistical analysis showed no significant difference between each age group. The mean pharmacokinetic parameters of naftidrofuryl after single oral administration of 200 mg of naftidrofuryl in the whole population were as follows: tmax 2.75 h (median), for Cmax 279 +/- 128 ng/ml, t1/2 3.41 +/- 1.22 h, AUC0-t 1797 +/- 870 h.ng/ml for AUC0-inf 1910 +/- 877 h.ng/ml. In conclusion, advanced age did not appear to influence the pharmacokinetic profile of oral naftidrofuryl, and therefore it is not necessary to adjust the dosage of naftidrofuryl in this population.     

Dialysis clearance of buflomedil in hemodialysed patients

Buflomedil (CAS 55837-25-7, Fonzylane) is a peripherally vasoactive drug which improves nutritional blood flow in ischaemic tissue of patients with peripheral vascular disease by the way of an increase of perfusion in the microcirculation. Ten hemodialysed patients with chronic renal failure treated with intravenous infusion of 400 mg of buflomedil during 4 h of dialysis were included in the first study. This study was carried out to determine the dialysis plasma clearance and the amount of drug dialysed during the first intravenous administration of buflomedil. The dialysis clearance calculated from the amount recovered in dialysate was (mean +/- SD) 25.4 +/- 25.6 ml/min. The drug recovery resulting from hemodialysis represented a small fraction of the dose (< or = 5%). A second study was carried out to determine the accumulation of buflomedil in chronic hemodialysed patient. The drug concentration were measured before and at the end (4 h) of the infusion of buflomedil in six other patients maintained on intermittent hemodialysis (3 per week) for 4 weeks. The average Cmin and Cmax were stable during the 12 successive dialyses (mean +/- SD intervals were between 0.36 +/- 0.53 and 0.66 +/- 0.79 microgram/ml for Cmin and between 5.15 +/- 2.19 and 7.37 +/- 1.76 micrograms/ml for Cmax), showing no trend of accumulation of buflomedil. These results agree with the pharmacokinetics of the drug which is mainly metabolised in the liver and has a low renal clearance. Dialysis is unable to modify significantly the plasma concentration of the drug in regularly dialysed patients.     

Circadian variation of tacrolimus disposition in liver allograft recipients

The aim of this study was to characterize the circadian variation of oral tacrolimus disposition in 8 stable liver allograft recipients. In the steady state, a total of 23 blood samples was taken before and after tacrolimus administration during a 24-hr period and the pharmacokinetic parameters were compared. The area under the curve (AUC) of tacrolimus after the morning dose was significantly larger than after the evening dose (211+/-43 ng x hr/ml [morning] vs. 179+/-45 ng x hr/ml [evening], P=0.02). The time to peak (Tmax) was significantly shorter after the morning dose than after the evening dose (1.6+/-0.7 hr [morning] vs. 2.9+/-0.6 hr [evening], P=0.002). The peak (Cmax) was significantly higher after the morning dose than after the evening dose (32.2+/-10.2 ng/ml [morning] vs. 19.1+/-4.3 ng/ml [evening], P=0.003). However, the trough (Cmin) was not significantly different between the morning dose and the evening dose (13.1+/-3.9 ng/ml [morning] vs. 13.3+/-4.4 ng/ml [evening], P=0.4). This study demonstrated that tacrolimus disposition in liver transplant patients was determined by administration time.     

Detection of the change point in oxygen uptake during an incremental exercise test using recursive residuals: relationship to the plasma lactate accumulation and blood acid base balance

BACKGROUND: Lovastatin is oxidized by cytochrome P4503A to active metabolites but pravastatin is active alone and is not metabolized by cytochrome P450. Diltiazem, a substrate and a potent inhibitor of cytochrome P4503A enzymes, is commonly coadministered with cholesterol-lowering agents. METHODS: This was a balanced, randomized, open-label, 4-way crossover study in 10 healthy volunteers, with a 2-week washout period between the phases. Study arms were (1) administration of a single dose of 20 mg lovastatin, (2) administration of a single dose of 20 mg pravastatin, (3) administration of a single dose of lovastatin after administration of 120 mg diltiazem twice a day for 2 weeks, and (4) administration of a single dose of pravastatin after administration of 120 mg diltiazem twice a day for 2 weeks. RESULTS: Diltiazem significantly (P < .05) increased the oral area under the serum concentration-time curve (AUC) of lovastatin from 3607 +/- 1525 ng/ml/min (mean +/- SD) to 12886 +/- 6558 ng/ml/min and maximum serum concentration (Cmax) from 6 +/- 2 to 26 +/- 9 ng/ml but did not influence the elimination half-life. Diltiazem did not affect the oral AUC, Cmax, or half-life of pravastatin. The average steady-state serum concentrations of diltiazem were not significantly different between the lovastatin (130 +/- 58 ng/ml) and pravastatin (110 +/- 30 ng/ml) study arms. CONCLUSION: Diltiazem greatly increased the plasma concentration of lovastatin, but the magnitude of this effect was much greater than that predicted by the systemic serum concentration, suggesting that this interaction is a first-pass rather than a systemic event. The magnitude of this effect and the frequency of coadministration suggest that caution is necessary when administering diltiazem and lovastatin together. Further studies should explore whether this interaction abrogates the efficacy of lovastatin or enhances toxicity and whether it occurs with other cytochrome P4503A4-metabolized 3-hydroxy-3-methylglutaryl-coenzyme A reductase inhibitors, such as simvastatin, fluvastatin, and atorvastatin.     

Polycystic ovary syndrome - from gynaecological curiosity to multisystem endocrinopathy

In order to study the effect of cytochrome P-450 isozyme induction on the pharmacokinetics and metabolism of diltiazem (DTZ), male Sprague-Dawley rats weighing 300-600 g were randomly assigned to two groups. The enzyme induction group (n = 4) received phenobarbital 60 mg/kg i.p. once daily for 4 days, whereas the control group (n = 6) received normal saline for the same duration. Each rat then received a single oral dose of DTZ in solution (20 mg/kg). Blood samples (0.5 ml) were collected from each rat via an implanted polyethylene catheter (0.040" i.d.) in the right carotid artery at 0 (just before dosing), 0.25, 0.5, 1,2,3,4,6,8 and 10 h post-dose. Arterial plasma concentrations of DTZ and its metabolites M(A), M1, M2, M4 and M6 were determined by HPLC. Pharmacokinetics parameters were calculated using non-linear regression. The results showed that both mean Cmax and AUC of DTZ were lower (871.6 vs 79.8 ng/ml; 1171 vs 101.9 ng-h/ml), but the mean Cmax of the primary metabolites M1 and M(A) was higher after phenobarbital (M1 413.0 vs 648.9 ng/ml; M(A) 683.0 vs 814.8 ng/ml). The highest increase was seen in the mean Cmax and AUC of the secondary metabolite M2 (837.5 vs 2585.7 ng/ml; 3312.1 vs 13156.5 ng-h/ml). In contrast, plasma concentrations of the O-desmethylated metabolites M4 and M6 did not increase after phenobarbital. These results suggest that both deacetylation and N-demethylation of DTZ in rats are catalyzed by drug metabolizing enzymes inducible by phenobarbital.     

Cryptococcal meningitis: the place of itraconazole

Itraconazole, an orally active broad-spectrum triazole antimycotic, has demonstrated anti-Cryptococcus activity in vitro and in animal models of cryptococcal meningitis. The drug has been used by a number of clinical groups for the treatment of cryptococcal meningitis, predominantly in AIDS patients. A problem that has been found with ketoconazole is the relatively low absorption of the drug in AIDS patients. This has resulted in ketoconazole plasma levels below the MIC90 (1-5 micrograms ml-1) needed to eliminate Cryptococcus neoformans. In addition, tissue levels of ketoconazole are lower than plasma levels. For itraconazole, the required MIC90 for Cr. neoformans is 0.1 microgram ml-1, and the plasma levels in AIDS patients receiving 200-400 mg daily, even in the case of reduced absorption, are well above this MIC90. The itraconazole levels in the brain and in the meninges are higher than the plasma levels. Consequently, itraconazole has been considered a valid candidate for studies in patients with cryptococcal meningitis. Various treatment modalities have been used: primary oral therapy alone or in combination with amphotericin B or 5-fluorocytosine (5-FC); maintenance oral therapy after initial treatment with amphotericin B (with or without 5-FC); and first-line intravenous treatment in severely ill patients. The results were evaluated in four different groups. When the drug was given as primary oral therapy without combination with amphotericin B or 5-FC, the results depended greatly on the dose administered and on the life expectancy of the patient at inclusion. In general, daily doses of 400 mg were better than 200-mg doses.(ABSTRACT TRUNCATED AT 250 WORDS)     

Pharmacokinetic interaction between itraconazole and rifampin in Yucatan miniature pigs

The objective of this study was to examine the effects of rifampin on itraconazole pharmacokinetics, at steady state, in three Yucatan miniature pigs. Daily for 3 weeks, the pigs received 200 mg of itraconazole orally at the beginning of each meal, and for the following 2 weeks they received itraconazole orally combined with intravenous administration of rifampin at 10 mg/kg/day. Coadministration of rifampin resulted in an 18-fold decrease in the maximum concentration of itraconazole in serum, from 113.0 (standard deviation [SD] 17.2) to 6.2 (SD, 3.9) ng/ml and a 22-fold decrease in the area under the concentration-time curve, from 1,652.7 (SD, 297.7) to 75.6 (SD, 30.0) ng.h/ml. The active metabolite of itraconazole, hydroxyitraconazole, was undetectable. This study demonstrates that rifampin affects itraconazole kinetics considerably at steady state in this miniature-pig model, probably by inducing hepatic metabolism of itraconazole.     

Pharmacokinetics, safety, and tolerability of ascending single doses of moxifloxacin, a new 8-methoxy quinolone, administered to healthy subjects

The pharmacokinetics of moxifloxacin were investigated in six studies after oral administration of 50, 100, 200, 400, 600, and 800 mg. Eight healthy male volunteers were included in each study. With doses of up to 200 mg the study was performed as a double-blind, randomized group comparison (n = 6 verum and n = 2 matched placebo); with the higher doses the study was conducted with a double-blind, randomized, crossover design. Safety and tolerability were assessed by evaluation of vital signs, electrocardiograms, electroencephalograms, clinical chemistry parameters, results of urinalysis, and adverse events. The drug was well tolerated. The concentrations of moxifloxacin in plasma, urine, and saliva were determined by a validated high-pressure liquid chromatography assay with fluorescence detection. In addition, plasma and urine samples were analyzed by a bioassay. A good correlation between both methods was seen, indicating an absence of major active metabolites. The mean maximum concentrations of moxifloxacin in plasma (Cmax) ranged from 0.29 mg/liter (50-mg dose) to 4.73 mg/liter (800-mg dose) and were reached 0.5 to 4 h following drug administration. After reaching the Cmax, plasma moxifloxacin concentrations declined in a biphasic manner. Within 4 to 5 h they fell to about 30 to 55% of the Cmax, and thereafter a terminal half-life of 11 to 14 h accounted for the major part of the area under the concentration-time curve (AUC). During the absorption phase concentrations in saliva were even higher than those in plasma, whereas in the terminal phase a constant ratio of the concentration in saliva/concentration in plasma of between 0.5 and 1 was observed, indicating a correlation between unbound concentrations in plasma and levels in saliva (protein binding level, approximately 48%). AUC and Cmax increased proportionally to the dose over the whole range of doses investigated. Urinary excretion amounted to approximately 20% of the dose. Data on renal clearance (40 to 51 ml/min/1.73 m2) indicated partial tubular reabsorption of the drug. The pharmacokinetic parameters derived from compartmental and noncompartmental analyses were in good agreement. The kinetics could be described best by fitting the data to a two-compartment body model.     

Pharmacokinetics of orally administered estradiol valerate. Results of a single-dose cross-over bioequivalence study in postmenopausal women

A randomized, single-dose cross-over study in 32 postmenopausal women was performed to demonstrate bioequivalence of two estradiol valerate containing formulations (first sequence of Klimonorm as test preparation). The serum levels of estradiol, free and conjugated estrone were measured until 48 h after an oral dosage of 4 mg estradiol valerate (CAS 979-32-8). The mean AUC(0-48) of estradiol was calculated as 1006.6 +/- 479.4 h x pg x ml-1 (Test) and 1015.2 +/- 555.2 h x pg x ml-1 (Reference). The corresponding (AUC(0-48) of the active metabolite, free estrone, exceeded that of estradiol at 3578.3 h x pg x ml-1 (Test) and 3485.1 h x pg x ml-1 (Reference). Much higher was the AUC(0-48) for conjugated estrone at 132.4 h x ng x ml-1 (Test) and 133.6 h x ng x ml-1 (Reference). Mean estradiol Cmax values of 39.8 +/- 17.7 pg/ml (Test) and 42.9 +/- 21.0 pg/ml (Reference) were attained 8.2 +/- 4.5 h (Test) and 10.0 +/- 5.9 h (Reference) after the administration of 4 mg estradiol valerate. Maximal free estrone concentrations of 163 pg/ml (Test) and 174.3 pg/ml (Reference) were reached after 7.2 h (Test) and 7.5 h (Reference). Maximal conjugated estrone concentrations of 15.5 ng/ml (Test) and 16.2 ng/ml (Reference) were reached after 2.4 h (Test) and 2.0 h (Reference). The terminal elimination half-life of estradiol was calculated at 16.9 +/- 6.0 h (Test) and 15.0 +/- 4.8 h (Reference), that of free estrone at 16.3 h (Test) and 13.5 h (Reference), that of conjugated estrone at 11.8 h (Test) and 10.6 h (Reference). After logarithmic transformation, the 90% confidence intervals of the AUC(0-48) and Cmax ratios for estradiol and also for the metabolites (free and conjugated estrone) were within the acceptance ranges for bioequivalence. Therefore the test preparation and the reference preparation are bioequivalent.     

A pharmacokinetic study of intravenous itraconazole followed by oral administration of itraconazole capsules in patients with advanced human immunodeficiency virus infection

A randomized, open-label, comparative study was conducted in 30 male patients with moderately advanced human immunodeficiency virus (HIV) infection to examine the pharmacokinetics of an investigational intravenous preparation of itraconazole compared with pharmacokinetics after administration of itraconazole capsules. The study also assessed whether adequate plasma concentrations of itraconazole could be rapidly achieved with the intravenous formulation and then maintained after cessation of intravenous therapy with itraconazole capsules. All patients received 200 mg intravenous itraconazole as a 1-hour infusion in 40% hydroxypropyl-beta-cyclodextrin (HP-beta-CD) vehicle twice daily for 2 days, and then 200 mg intravenously once daily for 5 days. Patients then received itraconazole capsules, either 200 mg twice daily or 200 mg once daily for 28 days. Steady-state plasma concentrations of itraconazole were reached by day 3 with intravenous infusion, a much shorter time than observed with administration of itraconazole capsules. Steady-state concentrations of itraconazole and hydroxyitraconazole were effectively maintained during the rest of the intravenous infusions of itraconazole. Oral follow-up with administration of 200-mg capsules once daily could not maintain the plasma concentrations of itraconazole and hydroxyitraconazole obtained at the end of the intravenous treatment, whereas twice-daily oral administration maintained or increased these concentrations. Mean plasma concentrations of itraconazole and hydroxyitraconazole on day 7 were similar to those on day 36 in the twice-daily group. Mean renal clearance was comparable to mean total body clearance, and approximately 93% to 101% of the HP-beta-CD was excreted unchanged in urine within 12 hours of administration. The HP-beta-CD was essentially eliminated through the kidney, and little accumulation in the body was observed in this patient population. Adverse events during the intravenous phase were most commonly associated with intravenous administration. Intravenous infusion of itraconazole for 7 days followed by administration of itraconazole capsules twice daily for 28 days is an effective dose regimen in patients with advanced HIV infection.     

Thiamine, riboflavin, folate, and vitamin B12 status of infants with low birth Weights receiving enteral nutrition

The purpose of the present study was to monitor the vitamin status of 14 low-birth-weight (LBW) infants (< 1,750 g birth weight) at 2 weeks and an additional four infants at 3 weeks who were receiving an enteral formula providing 247 micrograms/100 kcal thiamine, 617 micrograms/100 kcal riboflavin, 37 micrograms/100 kcal folate, and 0.55 micrograms/100 kcal vitamin B12. The mean birth weight of the 18 infants was 1,100 +/- 259 g, and mean gestational age was 29 +/- 2 weeks. Weekly blood, 24-h urine collections, and dietary intake data were obtained. For thiamine, red blood cell (RBC) transketolase activity was within the normal range for all infants. For riboflavin, RBC glutathione reductase activity was normal for all infants except one. We calculated from intake and urinary excretion data that these infants require 225 micrograms/100 kcal thiamine and 370 micrograms/100 kcal riboflavin, respectively. Mean plasma folate levels were 21 +/- 11 ng/ml at 2 weeks and 18 +/- 5 ng/ml at 3 weeks. RBC folate levels were 455 +/- 280 ng/ml at 2 weeks and 391 +/- 168 ng/ml at 3 weeks. All folate blood values were normal, except for one subject with an elevated level (59 ng/ml). Vitamin B12 plasma values were 737 +/- 394 pg/ml at 2 weeks and 768 +/- 350 pg/ml at 3 weeks, and all values were normal except for three infants with elevated values. In conclusion, appropriate vitamin status was maintained during this short observational period, during administration of this enteral formula; however, riboflavin concentrations in the enteral feed may be excessive.     

Cholecystokinin-8 regulation of NGF concentrations in adult mouse brain through a mechanism involving CCK(A) and CCK(B) receptors

STUDY OBJECTIVE: To assess the potential for a drug-drug interaction between valspodar, a P-glycoprotein (mdrl) modulator used as a chemotherapy adjunct, and dexamethasone, widely included in oncology antiemetic regimens. DESIGN: Randomized, open-label, three-period crossover study. SETTING: Clinical pharmacology research center. SUBJECTS: Eighteen healthy men volunteers (age 25.8+/-3.5 yrs, weight 71.6+/-10.3 kg). INTERVENTIONS: Subjects received single fasting oral doses of valspodar 400 mg, dexamethasone 8 mg, and both drugs concomitantly with 2- to 3-week washout phases between administrations. MEASUREMENTS AND MAIN RESULTS: Lack of a pharmacokinetic drug-drug interaction with respect to valspodar was conclusively demonstrated for both Cmax,b (2.3+/-0.4 vs 2.4+/-0.5 microg/ml) and AUCb (19.8+/-4.8 vs 19.6+/-4.9 microg x hr/ml) inasmuch as bioequivalence criteria were satisfied when comparing administration alone with coadministration, respectively. Although no changes in the rate of dexamethasone absorption were noted on coadministration with valspodar (Cmax 88+/-23 vs 91+/-20 ng/ml), overall exposure was significantly increased by 24% on average (AUC 400+/-87 vs 494+/-90 ng x hr/ml). Regression analysis of valspodar Cmax,b and AUCb during coadministration versus the extent of the interaction (percentage increase in dexamethasone AUC) did not reveal a concentration-effect relationship (p=0.7299 and 0.9718, respectively). CONCLUSION: Given dexamethasone's wide therapeutic index and the short duration of coadministration foreseen for these drugs in a clinical setting (maximum 1 wk/chemotherapy cycle), the 24% increase in dexamethasone's AUC is unlikely to be relevant. Thus no alterations in valspodar or dexamethasone dosages appear warranted when the two drugs are coadministered. Multiple-dose experience in patients would be desirable to confirm these conclusions.     

Relationships between plasma levels of type-II phospholipase A2, PAF-acetylhydrolase, leukotriene B4, complements, endothelin-1, and thrombomodulin in patients with sepsis

We determined the plasma levels of type-II phospholipase A2 (type II PLA2), platelet-activating factor acetylhydrolase (PAFAH) leukotriene B4 (LTB4) and of several complements (C3a, C4a, and C5a), which are considered to be among the cytokines and eicosanoids involved in vascular endothelial disorders and that vary in concentration during sepsis. We investigated the relationship between those levels and those of ET-1 and TM levels in plasma. Plasma levels of type II PLA2, PAFAH, LTB4, C3a, C4a, ET-1, and TM at the time that sepsis was diagnosed in 30 patients were 218.3 +/- 179.9 ng/ml, 23.92 +/- 9.66 nmol/min/ml, 90.35 +/- 31.49 pg/ml, 838.73 +/- 2.30 pg/ml, 1951.46 +/- 1697.78 pg/ml, 6.98 +/- 4.08 pg/ml and 7.80 +/- 3.34 ng/ml, respectively. The C5a plasma level was below the limit of detection in all cases. There were significant correlations between type II PLA2 and ET-1 plasma levels (r = 0.39, p = 0.032) and C3a and ET-1 plasma levels (r = 0.60, p = 0.03). There were also significant correlations between type II PLA2 and TM levels in plasma (r = 0.76, p = 0.0017), PAFAH and TM plasma levels (r = 0.53, p = 0.037), LTB4 and TM plasma levels (r = 0.46, p = 0.016) and C4a and TM plasma levels (r = 0.58, p = 0.037). Results suggest that the elevation of type II PLA2, PAFAH, LTB4 and complement in plasma is involved in vascular endothelial disorders in patients with sepsis.     

Peptide growth factors in normal and hypertrophied bladder

The pharmacokinetics of oral zidovudine in HIV-infected children and adults are reported. Fourty-six patients were investigated. For data analysis three groups of similar size were formed: young children 4 months-4 years, n = 15 (group 1), older children up to 13 years, n = 16 (group 2) and young adults, n = 15 (group 3). After a single oral dose repeated blood samples were taken 1/2 hourly during a period of 4 hours and zidovudine concentrations in plasma were determined by high performance liquid chromatography. For better comparison of dose dependent parameters peak concentrations (Cmax) and the area under the time-concentration curves (AUC) were normalized either to the dose/body weight (bw) or the dose/body surface area (bs), respectively. Time to reach peak concentrations and mean terminal elimination half-life times (t1/2 beta = 63.4 +/- 47.6, 74.9 +/- 54.9 and 56.9 +/- 16.4 min in group 1, 2 and 3, respectively, mean +/- SD) were not significantly different between the three groups. With normalization to dose/bw young children in comparison to adults had significantly lower Cmax (2.7 +/- 1.3 vs. 4.6 +/- 2.4 mumol/l, p = 0.016) and AUC (226 +/- 108 vs. 373 +/- 224 mumol.min/l, p = 0.038). Group 2 gave intermediate values. However, with normalization to dose/bs differences in Cmax (6.5 +/- 3.3, 7.3 +/- 4.2 and 6.8 +/- 3.6 mumol/l, in group 1, 2, and 3, respectively) and AUC (563 +/- 313, 691 +/- 351 and 555 +/- 342 mumol.min/l, in group 1, 2 and 3) were not significant between the three groups. It is likely that changes in body water content with age may account for most of these differences observed. In conclusion, a similar pharmacokinetic profile was found in children older than 3 months as compared to older children or adults.     

Naltrexone: disposition, metabolism, and effects after acute and chronic dosing

The disposition of naltrexone during acute and chronic administration of 100-mg oral dose was studied in 4 subjects. Following an acute dose the mean (X) peak naltrexone plasma level was 43.6 +/- 29.9 ng/ml at 1 hr and for the major biotransformation product, beta-naltrexol, was 87.2 +/- 25.0 ng/ml at 2 hr. Twenty-four hours after the dose the X levels of naltrexone and beta-naltrexol declined to 2.1 +/- 0.47 and 17.6 +/- 5.0 ng/ml, respectively. Following chronic administration and X peak plasma levels of naltrexone and beta-naltrexol rose to 46.4 +/- 18.5 and 158.4 +/- 89.9 ng/ml at 1 hr, but by 24 hr both compounds declined to levels of the same order as in the acute state at 24 hr. Plasma levels of naltrexone and beta-naltrexol measured 24 hr after the daily doses of naltrexone throughout the study indicated that steady-state equilibrium was rapidly attained and that there was no accumulation of naltrexone and beta naltrexol in the plasma after chronic treatment on 100 mg oral doses. Biexponential kinetics were observed for naltrexone and beta-naltrexol in the first 24 hr. The half-life of naltrexone and beta-naltrexol decreased slightly from the acute to thechronic study from 10.3 +/- 3.3 to 9.7 +/- 1.1 hr and from 12.7 +/- 2.6 to 11.4 +/- 2.0 hr. The plasma levels of naltrexone declined slowly from 24 through 72 hr from 2.4 to 1.7 ng/ml, with an apparent half-life of 96 hr. The renal clearance data indicate that naltrexone is partially reabsorbed while beta naltrexol is actively secreted by the kidney. During acute and chronic naltrexone administration the mean fecal excretion was 2.1% and 3.6% while urinary excretion was 38% and 70% of the dose in a 24-hr period. Opiate antagonism to 25 mg heroin challenges was nearly complete through 48 hr after naltrexone. At 72 hr the objective responses reappeared to a greater extent than the subjective ones. Correlation coefficient (r) between naltrexone plasma levels and opiate antagonism was 0.91 and between individual half-life of naltrexone and opiate antagonism it was 0.99.     

Plasma buspirone concentrations are greatly increased by erythromycin and itraconazole

BACKGROUND: The oral bioavailability of buspirone is very low as a result of extensive first-pass metabolism. Erythromycin and itraconazole are potent inhibitors of CYP3A4, and they increase plasma concentrations and effects of certain drugs, for example, oral midazolam and triazolam. The possible interactions of buspirone with erythromycin and itraconazole have not been studied before. METHODS: The pharmacokinetics and pharmacodynamics of buspirone were investigated in a randomized, double-blind, double-dummy crossover study with three phases. Eight young healthy volunteers took either 1.5 gm/day erythromycin, 200 mg/day itraconazole, or placebo orally for 4 days. On day 4, 10 mg buspirone was administered orally. Timed blood samples were collected up to 18 hours, and the effects of buspirone were measured with four psychomotor tests up to 8 hours. RESULTS: Erythromycin and itraconazole increased the mean area under the plasma concentration-time curve from time zero to infinity [AUC(0-infinity] of buspirone about sixfold (p < 0.05) and 19-fold (p < 0.01), respectively, compared with placebo. The mean peak plasma concentration (Cmax) of buspirone was increased about fivefold (p < 0.01) and 13-fold (p < 0.01) by erythromycin and itraconazole, respectively. These interactions were evident in each subject, although a striking interindividual variability in the extent of both interactions was observed. The elimination half-life of buspirone did not seem to be prolonged by either erythromycin or itraconazole. The effect of itraconazole on the Cmax and AUC(0-infinity) of buspirone was significantly (p < 0.01) greater than that of erythromycin. The greatly elevated plasma buspirone concentrations resulted in increased (p < 0.05) pharmacodynamic effects (as measured by the Digit Symbol Substitution test and the Critical Flicker Fusion test) and in side effects of buspirone. CONCLUSIONS: Both erythromycin and itraconazole greatly increased plasma buspirone concentrations, obviously by inhibiting its CYP3A4-mediated first-pass metabolism. These pharmacokinetic interactions were accompanied by impairment of psychomotor performance and side effects of buspirone. The dose of buspirone should be greatly reduced during concomitant treatment with erythromycin, itraconazole, or other potent inhibitors of CYP3A4.