In vitro-in vivo correlation (IVIVC) models for metformin after administration of modified-release (MR) oral dosage forms to healthy human volunteers.

The objective of the current study was to develop and evaluate the internal predictability for level C and A in vitro-in vivo correlation (IVIVC) models for prototype modified-release (MR) dosage forms of metformin. In vitro dissolution data for metformin were collected for 22 h using a USP II (paddle) method. In vivo plasma concentration data were obtained from 8 healthy volunteers after administration of immediate-release (IR) and MR dosage forms of metformin. Linear level C IVIVC models were developed using dissolution data at 2.0 and 4.0 h and in vitro mean dissolution time (MDT). A deconvolution-based level A model was attempted through a correlation of percent in vivo input obtained through deconvolution and percent in vitro dissolution obtained experimentally. Further, basic and extended convolution level A IVIVC models were attempted for metformin. Internal predictability for the IVIVC models was assessed by comparing observed and predicted values for C(max) and AUC(INF). The results suggest that highly predictive level C models with prediction errors (%PE) of <5% could be developed. Mean percent in vivo input for metformin was incomplete from all formulations and did not exceed 35% of dose. The deconvolution-based level A models for all MR formulations were curvilinear. However, a unique IVIVC model applicable to all MR formulations could not be developed using the deconvolution approach. The basic convolution level A model, which used in vitro dissolution as the in vivo input, had %PE values as high as 103%. Using an extended convolution approach, which modeled the absorption of metformin using a Hill function, a level A IVIVC model with %PE as low as 11% was developed. In conclusion, the current work indicates that level C and A IVIVC models with good internal predictability may be developed for a permeability- and absorption window-limited drug such as metformin.

Effect of altered gastric emptying and gastrointestinal motility on metformin absorption.

AIMS: The purpose of this in vivo human study was to assess the effect of altered gastric emptying and gastrointestinal motility on the absorption of metformin in healthy subjects. METHODS: An open-label, three treatment, three period crossover study was conducted in 11 healthy volunteers. Each subject received 550 mg metformin hydrochloride in solution alone; 5 min after a 10 mg i.v. dose of metoclopramide; and 30 min after a 30 mg oral dose of propantheline. Metformin solution was radiolabeled by the addition of 99mTc-DTPA. The gastrointestinal transit of the solution was monitored by gamma scintigraphy and the pharmacokinetic data were correlated with the scintigraphic findings. RESULTS: Scintigraphic data indicated that pretreatment with metoclopramide decreased gastric emptying time and increased gastrointestinal motility while pretreatment with propantheline had the opposite effect. The systemic disposition of metformin was not altered by pretreatment with metoclopramide and propantheline, as judged by unchanged renal clearance and elimination half-life of metformin. Extent of metformin absorption was essentially unchanged after pretreatment with metoclopramide. However, AUC(0,infinity) and % UR (percent dose excreted unchanged in urine) generally increased with increase in gastric emptying time and small intestinal transit times. GI overlay plots showed that the absorption phase of metformin plasma profile always coincided with gastric emptying and the beginning of decline of metformin plasma concentrations was usually associated with the colon arrival. Only in cases where the intestinal transit was drastically prolonged by propantheline pretreatment, was a decline in plasma levels observed prior to colon arrival. CONCLUSIONS: Metformin is primarily absorbed from the small intestine. The extent of metformin absorption is improved when the gastrointestinal motility is slowed. These findings have significant implications in the design of a metformin modified release dosage form.

In-vitro in-vivo correlation models for glibenclamide after administration of metformin/glibenclamide tablets to healthy human volunteers.

In this study, level C and A in-vitro in-vivo correlation (IVIVC) models were developed for glibenclamide. In-vitro dissolution data were collected for the glibenclamide component of three metformin/glibenclamide tablets using a USP Type II apparatus. In-vivo plasma concentration data were obtained after administration of the prototype formulations to 24 healthy volunteers and subject to deconvolution analysis to obtain percentage in-vivo absorbed profiles. Multiple linear level C models were developed for CMAX and AUC(0-48) using percentage in-vitro dissolved data at 10, 45 and 120 min. Initially, the level A model was constructed for the first 2 h only, based on availability of in-vitro data. Another level A model was attempted using a time-scaled approach, with percentage in-vivo absorbed at time t and percentage in-vitro dissolved at time t/I as the correlating data. Internal predictability was evaluated for the level C and time-scaled level A models. For all level C approaches, linear regression models with r2 > 0.99 were determined. The prediction errors (% PE) for Cmax and AUC(0-48) were less than 1% for all formulations at all three chosen time points. The deconvolution analysis indicated biphasic absorption for glibenclamide, with one phase occurring at 2-3h and another at 6-12h after dose administration. The level A model using 2-h data was not unique for all formulations and was therefore not developed. The time-scaling factor I correlated highly (r2 = 0.99) with in vitro mean dissolution time (MDT). A linear regression time scaled model (r2 = 0.97) was successfully developed using in-vitro and in-vivo data from all 3 formulations. However, the internal predictability of the time-scaled model was poor, with % PE values for Cmax and AUC(0-48) being as much as 30.5% and 18.7%, respectively. The results indicate that level C models have good internal predictability. Though a time-scaled level A IVIVC model was successfully developed, the model was found to have poor internal predictability.

Disposition of radiolabeled ifetroban in rats, dogs, monkeys, and humans.

Ifetroban is a potent and selective thromboxane receptor antagonist. This study was conducted to characterize the pharmacokinetics, absolute bioavailability, and disposition of ifetroban after i.v. and oral administrations of [14C]ifetroban or [3H]ifetroban in rats (3 mg/kg), dogs (1 mg/kg), monkeys (1 mg/kg), and humans (50 mg). The drug was rapidly absorbed after oral administration, with peak plasma concentrations occurring between 5 and 20 min across species. Plasma terminal elimination half-life was approximately 8 h in rats, approximately 20 h in dogs, approximately 27 h in monkeys, and approximately 22 h in humans. Based on the steady-state volume of distribution, the drug was extensively distributed in tissues. Absolute bioavailability was 25, 35, 23, and 48% in rats, dogs, monkeys, and humans, respectively. Renal excretion was a minor route of elimination in all species, with the majority of the dose being excreted into the feces. After a single oral dose, urinary excretion accounted for 3% of the administered dose in rats and dogs, 14% in monkeys, and 27% in humans, with the remainder excreted in the feces. Extensive biliary excretion was observed in rats with the hydroxylated metabolite at the C-14 position being the major metabolite observed in rat bile. Ifetroban was extensively metabolized after oral administration. Approximately 40 to 50% of the radioactivity in rat and dog plasma was accounted for by parent drug whereas, in humans, approximately 60% of the plasma radioactivity was accounted for by ifetroban acylglucuronide.

Pharmacokinetics and bioavailability of a metformin/glyburide tablet administered alone and with food.

Two randomized crossover studies were conducted to evaluate the pharmacokinetics (including food effect) of fixed-combination metformin/glyburide tablets. Pharmacokinetics and bioavailability of two strengths (500 mg/2.5 mg and 500 mg/5 mg) of metformin/glyburide tablets were assessed relative to coadministered metformin and glyburide tablets in study 1. The effect of a high-fat meal on the bioavailability of a metformin/glyburide (500 mg/5 mg) tablet was assessed relative to the fasted condition in study 2. The fixed combination metformin/glyburide tablets showed bioequivalence for the metformin component with the reference metformin tablet and comparable bioavailability for the glyburide component with the reference glyburide tablet. Food does not appear to affect the bioavailability of either component to an appreciable extent.

Pharmacokinetics of buspirone following oral administration to rhesus monkeys.

Pharmacokinetics of buspirone and its active metabolite, 1-pyrimidinyl piperazine (1-PP) following oral administration were assessed in rhesus monkeys at doses used in chronic toxicology studies. The study was conducted over four periods in three male and three female rhesus monkeys. In the first three periods, buspirone hydrochloride solution was administered in a randomized manner by oral gavage at doses (expressed as buspirone free base) of 12.5, 25 and 50 mg kg(-1) once a day on days 1 and 7 and twice a day on days 2-6. In the last period, all monkeys received 25 mg kg(-1) buspirone as a single daily dose for 7 days. Serial plasma samples were collected for analysis of buspirone and 1-PP on days 1 and 7 in the first three periods and on day 7 in the last period for assessment of single dose and steady-state pharmacokinetics. Inter-animal variability in the pharmacokinetics of buspirone was high. Examination of Cmin vs time plots revealed that the steady state was attained by day 7 except for one monkey who demonstrated much higher Cmin values. For buspirone, dose proportionality was concluded for both Cmax and AUC on day 1 but not on day 7. The accumulation factor on day 7 for buspirone was nearly 5 for Cmax and 7 for AUC when compared with day 1. For 1-PP, dose proportionality was concluded except for Cmax in male monkeys on day 7. In contrast to buspirone, 1-PP showed less than 2-fold accumulation in Cmax and AUC values on day 7 compared with those on day 1. Exposure at a dose of 25 mg kg(-1) once daily was in between the 125 mg kg(-1) and 25 mg kg(-1) twice-a-day regimens. These results document dose-dependency in the steady-state pharmacokinetics of buspirone in rhesus monkeys.

The effects of age and gender on the pharmacokinetics of irbesartan.

AIMS: Single dose pharmacokinetics and safety of irbesartan, an angiotensin II receptor antagonist, were evaluated in healthy young and elderly male and female subjects. METHODS: Irbesartan was administered as two 25 mg capsules after a 10 h fast to 12 young men, 12 young women, 12 elderly men and 12 elderly women. Serial blood and urine sample were collected up to 96 h after the dose. Plasma and urine samples were analysed for irbesartan by h.p.l.c./fluorescence methods. RESULTS: No statistically significant gender effects were observed in peak plasma concentration (Cmax), area under the curve (AUC), and terminal elimination half-life (t1/2) of irbesartan. The geometric mean AUC and Cmax increased by about 43% and 49%, respectively, in the elderly subjects. Also the time to peak was significantly shorter in the elderly subjects compared with that observed in the young subjects. Renal clearance ofirbesartan was significantly reduced in the elderly females but this reduction is not likely to be of any clinical relevance since less than 3% of the administered dose of irbesartan is excreted unchanged in the urine. CONCLUSIONS: Although there was an effect of age on the pharmacokinetics of irbesartan, based on the safety and efficacy profile, no adjustment in irbesartan dosage is necessary with respect to age or gender.

In vivo evaluation of the absorption and gastrointestinal transit of avitriptan in fed and fasted subjects using gamma scintigraphy.

The study was conducted to assess the bioavailability of avitriptan after a standard high fat meal, in relation to gastrointestinal transit. Six healthy male subjects were enrolled in a four-period study with a partial replicate design where each was administered 150-mg avitriptan capsule (i) after an overnight fast, (ii) 5 min after a standard high-fat breakfast, and (iii) 4 hr after a standard high fat breakfast. The treatment administered in Period 3 was repeated in Period 4 to assess intrasubject variations in pharmacokinetics and gastrointestinal (GI) transit. Avitriptan capsules were specially formulated with nonradioactive samarium chloride hexahydrate which was neutron-activated to gamma-emitting samarium before dosing. Serial blood samples were collected for analysis of avitriptan up to 24-hr postdose, and serial scintigraphic images were obtained to assess the plasma concentration-time profile in relation to the GI transit of the avitriptan capsule contents. Bioavailability of avitriptan was reduced when administered in the fed condition but only the decrease in AUC(INF) was statistically significant. Tmax was significantly delayed between the fed conditions and the fasted condition. Qualitative appearance of plasma concentration-time profiles for avitriptan could be related to the manner in which the drug emptied from the stomach. It was also apparent that avitriptan exerted a secondary pharmacologic effect that temporarily suspended gastric emptying in the fasted treatment. Thus, when gastric emptying was interrupted and then resumed, the net result was a double peak in some of the individual plasma concentration profiles. Scintigraphic analysis also demonstrated that upon emptying from the stomach, avitriptan was rapidly absorbed from the upper small intestine. In the fed state, gastric emptying was slow and continuous resulting in extended absorption and a lower occurrence of double peaks. Qualitatively, the intrasubject variability in Cmax and AUC could be explained by the intrasubject variability in gastric emptying in both fasted and fed conditions.

Oral bioavailability and disposition characteristics of irbesartan, an angiotensin antagonist, in healthy volunteers.

Absolute oral bioavailability and disposition characteristics of irbesartan, an angiotensin II receptor antagonist, were investigated in 18 healthy young male volunteers. Subjects received [14C] irbesartan as a 30-minute intravenous infusion (50 mg), [14C] irbesartan orally as a solution (50 mg or 150 mg), or irbesartan capsule (50 mg). Irbesartan was rapidly and almost completely absorbed after oral administration, and exhibited a mean absolute oral bioavailability of 60% to 80%. Mean total body clearance was approximately 157 mL/min, and renal clearance was 3.0 mL/min. Volume of distribution at steady state was 53 L to 93 L, and terminal elimination half-life was approximately 13 to 16 hours. Hepatic extraction ratio was low (0.2). There were no major circulating metabolites, and approximately 80% of total plasma radioactivity was attributable to unchanged irbesartan. Regardless of route of administration, approximately 20% of dose was recovered in urine and the remainder in feces.

Evaluation of the effect of food on the pharmacokinetics of avitriptan.

Bioavailability of avitriptan was found to decrease significantly when administered 5 min after a standard high fat meal. The studies described herein were carried out to gain insight into the mechanism of this food effect. A series of studies were conducted in humans to assess the effect of timing of meal, type of meal, gastric pH, change in the formulation and dose on the bioavailability of avitriptan. Avitriptan was administered as a 50 mg capsule under fasted condition and at 30 min, 1, 2 and 4 h after a standard high fat meal. The reduction in avitriptan bioavailability persisted even at 4 h post high fat meal, although as the time interval between the meal and dose increased, the effect of meal tended to decrease. Bioavailability of avitriptan also decreased significantly when the drug was administered after a high protein and a high carbohydrate meal. Elevation in gastric pH caused by food was not found to be responsible for the food-related decrease in bioavailability of avitriptan since ranitidine pretreatment did not lead to a decrease in bioavailability. When administered as a 50 mg 14C-labeled solution after a standard high fat meal, bioavailability of avitriptan decreased although the decrease was less compared with that observed for a capsule dosage form. Plasma concentrations and cumulative urinary excretion of total radioactivity also decreased in the fed condition, indicating the absorption of avitriptan was affected. The decrease in avitriptan AUC was somewhat more pronounced than the decrease in the exposure to the total radioactivity suggesting a food-related increase in the first-pass metabolism of avitriptan. Effect of the standard high fat meal on avitriptan administered as a 150 mg capsule was similar to that observed at the 50 mg dose. Overall, the results indicate that bioavailability of avitriptan is significantly reduced irrespective of the type of meal, dose and dosage form and the effect persists for as long as 4 h post meal. Thus, it appears that avitriptan absorption and bioavailability are highly sensitive to presence of food in the stomach and any food-related changes in gastric emptying time and gastrointestinal motility.

Lack of effect of food on the oral bioavailability of irbesartan in healthy male volunteers.

This study was conducted to evaluate the effects of a high-fat meal on the oral bioavailability of an 300-mg irbesartan tablet in healthy male volunteers. Sixteen healthy young male volunteers participated in this single-center, open-label, single-dose, crossover study. Each volunteer received a single 300-mg irbesartan tablet under fasted conditions and 5 minutes after a high-fat breakfast, with administrations separated by a 7-day washout period. Serial blood samples were collected over a 72-hour period, and plasma samples were analyzed for irbesartan using a validated high-performance liquid chromatography/fluorescence procedure. Food had no statistically significant effects on the peak concentration (Cmax) and area under the concentration-time curve (AUC) of irbesartan. The presence of food was associated with a slightly prolonged time to maximum concentration (tmax) and half-life (t1/2), but the differences were not statistically significant. The results of this study indicate that food does not affect the bioavailability of irbesartan. Thus, irbesartan can be administered without regard to meals.

Assessment of effect of food, gender, and intra-subject variability in the pharmacokinetics of avitriptan.

The objectives of this study were to assess the effect of food and gender on the pharmacokinetics of avitripan. A group of 12 healthy men and 12 healthy women was administered a single 50 mg dose of avitriptan capsule under fasting conditions and 5 min after a high-fat breakfast. The two treatments were repeated in a replicate design to assess the intra-subject variability in the pharmacokinetics of avitriptan under fasted and fed conditions. There was a 1 week washout between treatments. Serial blood samples were collected over 24 h after dosing and analyzed by a validated HPLC method for avitriptan. The mean (SD) peak concentrations (Cmax) were 168 (86.4) ng mL-1 in the fasted condition and 57.3 (34.8) ng mL-1 in the fed condition in males and females combined. The corresponding areas under the plasma concentration curve (AUC) were 335 (162) and 185 (64.5) ng h mL-1, respectively. Both Cmax and AUC were significantly reduced in the fed condition. In addition, the time to peak concentration (tmax) was significantly delayed from a median of 45 min to 2 h after the high-fat breakfast. The clinical significance of this food effect is unclear at the present time. There were no gender differences nor a gender by food interaction in the pharmacokinetics of avitriptan. The intra- and inter-subject variability (%CV) in the Cmax and AUC of avitriptan in the fasted and fed conditions ranged from 10 to 60% in male and female subjects.

A pharmacokinetic interaction study of avitriptan and propranolol.

OBJECTIVE: To assess whether a clinically significant change in the pharmacokinetics of avitriptan and propranolol is observed in healthy subjects after coadministration of the two drugs. METHODS: The pharmacokinetics of avitriptan and propranolol were investigated when the two drugs administered separately and when two 150 mg doses of avitriptan 2 hours apart were added to a steady-state regimen (80 mg twice a day) of propranolol. The pharmacokinetics of metabolites of avitriptan (N-desmethylavitriptan, methoxypyrimidinyl piperazine, and O-desmethylavitriptan) and the pharmacokinetics of 4-hydroxypropranolol were also assessed. RESULTS: Administration of avitriptan alone and together with propranolol resulted in small increases in mean blood pressure and small decreases in heart rate. Administration of propranolol resulted in lowering of blood pressure and heart rate consistent with the beta-blocking actions of propranolol. There were no changes in the pharmacokinetics of avitriptan after coadministration with propranolol. However, area under the plasma concentration-time curve (AUC) of propranolol showed a 20% increase after coadministration with avitriptan, whereas the AUC of 4-hydroxypropranolol significantly decreased. Avitriptan therefore appeared to affect the metabolism of propranolol to 4-hydroxypropranolol. The peak plasma concentration and AUC for N-desmethylavitriptan and the AUC for methoxypyrimidinyl piperazine also showed statistically significant increases (about 25%) when avitriptan was coadministered with propranolol. CONCLUSIONS: Considering the wide safety margin of propranolol, the increase in the exposure is not clinically significant. The increase in the exposure to the metabolites of avitriptan is also not considered to be clinically significant because the metabolite contribution to the pharmacologic activity or side effects is expected to be minimal. Based on these findings, avitriptan may be added to a steady-state regimen of propranolol as an abortive antimigraine therapy.

Effects of age, gender, and diurnal variation on the steady-state pharmacokinetics of BMS-181101, an antidepressant, in healthy subjects.

OBJECTIVES: To investigate the effects of age, gender, and diurnal variation on the safety, tolerability, and steady-state pharmacokinetics of BMS-181101, an antidepressant, in humans. METHODS: This was a multiple-dose parallel-design study in 51 healthy subjects (12 young and 12 elderly men and 12 young and 15 elderly women). Each subject received a 15 mg oral dose of BMS-181101 every 12 hours on days 1 through 6 and one dose on day 7. After the evening dose on day 6 and morning dose on day 7, serial blood samples were collected at specified times after administration. Plasma was analyzed for BMS-181101 with use of an HPLC method. RESULTS: Male subjects tolerated BMS-181101 better than female subjects. The mean values for area under the plasma concentration-time curve over the dosing interval tau (AUC tau; 58.8 to 102.4 ng.hr/ml) and elimination half-life t1/2; 5.7 to 10.4 hours) for the elderly subjects were significantly greater than those for the young subjects (39.0 to 64.3 ng.hr/ml and 3.2 to 4.5 hours). The mean values for peak plasma concentration (Cmax; 14.7 to 25.2 ng/ml) and AUC tau (52.4 to 102.4 ng.hr/ml) for the women were significantly greater than those for the men (9.08 to 15.3 ng/ml and 39.0 to 73.6 ng.hr/ml). The mean values for Cmax (14.7 to 25.2 ng/ml) and AUC tau (54.8 to 102.4 ng.hr/ml) on the morning of day 7 were significantly greater than those after the evening dose on day 6 (9.08 to 17.3 ng/ml; 39.0 to 83.4 ng.hr/ml). CONCLUSIONS: An initial lower dose or appropriate titration of daily doses of BMS-181101 may be necessary for the treatment of elderly and female subjects, and the pharmacokinetics of BMS-181101 exhibited significant diurnal effects.

Clinical pharmacokinetics of nefazodone.

Nefazodone is a new antidepressant drug, chemically unrelated to the tricyclic, tetracyclic or selective serotonin uptake inhibitors. Nefazodone blocks the serotonin 5-HT2 receptors and reversibly inhibits serotonin reuptake in vivo. Nefazodone is completely and rapidly absorbed after oral administration with a peak plasma concentration observed within 2 hours of administration. Nefazodone undergoes significant first-pass metabolism resulting in an oral bioavailability of approximately 20%. Although there is an 18% increase in nefazodone bioavailability with food, this increase is not clinically significant and nefazodone can be administered without regard to meals. Three pharmacologically active nefazodone metabolites have been identified: hydroxy-nefazodone, triazoledione and m-chlorophenylpiperazine (mCPP). The pharmacokinetics of nefazodone are nonlinear. The increase in plasma concentrations of nefazodone are greater than would be expected if they were proportional to increases in dose. Steady-state plasma concentrations of nefazodone are attained within 4 days of the commencement of administration. The pharmacokinetics of nefazodone are not appreciably altered in patients with renal or mild-to-moderate hepatic impairment. However, nefazodone plasma concentrations are increased in severe hepatic impairment and in the elderly, especially in elderly females. Lower doses of nefazodone may be necessary in these groups. Nefazodone is a weak inhibitor of cytochrome P450 (CYP) 2D6 and does not inhibit CYP1A2. It is not anticipated that nefazodone will interact with drugs cleared by these isozymes. Indeed, nefazodone did not affect the pharmacokinetics of theophylline, a compound cleared by CYP1A2. Nefazodone is metabolised by and inhibits CYP3A4. Clinically significant interactions have been observed between nefazodone and the benzodiazepines triazolam and alprazolam, cyclosporin and carbamazepine. The potential for a clinically significant interaction between nefazodone and other drugs cleared by CYP3A4 (e.g. terfenadine) should be considered before the coadministration of these compounds. There was an increase in haloperidol plasma concentrations when coadministered with nefazodone; nefazodone pharmacokinetics were not affected after coadministration. No clinically significant interaction was observed when nefazodone was administered with lorazepam, lithium, alcohol, cimetidine, warfarin, theophylline or propranolol.

Lack of effect of food on the steady state pharmacokinetics of BMS-181101, an antidepressant, in healthy subjects.

The effect of food on the pharmacokinetics of BMS-181101, a new anti-depressant under development, was investigated in 12 healthy male volunteers at steady state. Each subject received a 15 mg oral dose of BMS-181101 twice a day (q 12 h) for 11 days and a morning dose of BMS-181101 on day 12. Six subjects were randomly assigned to receive BMS-181101 under fasted conditions from days 1 to 6 and then crossed over to fed conditions from days 7 to 12. The other six subjects received the reverse conditions, fed for days 1-6 and fasted for days 7-12. Serial blood samples were collected up to 12 h on days 6 and 12 following the administration of the morning dose. In addition, trough blood samples were collected on days 4, 5, 10, and 11 prior to the morning dose. Plasma samples were analyzed for intact BMS-181101 using a validated high-performance liquid chromatography method with an electrochemical detector. BMS-181101 was well tolerated both with and without ingestion of food. The statistical evaluation of the Cmin values indicated that steady state of BMS-181101 was achieved by the fourth day of dosing regardless of whether the subject was fasted or fed. When BMS-181101 was administered with food, Cmax was reduced by about 25% and tmax was prolonged by 1 h. However, AUCtau, t1/2, and time to attain steady state of BMS-181101 were not altered by ingestion of food. In summary, BMS-181101 can be given with food without adversely impacting the safety or pharmacokinetic profiles of the drug.

Disposition of [14C]avitriptan in rats and humans.

Avitriptan is a new 5-HT1-like agonist with abortive antimigraine properties. The study was conducted to characterize the pharmacokinetics, absolute bioavailability, and disposition of avitriptan after intravenous (iv) and oral administrations of [14C]avitriptan in rats and oral administration of [14C]avitriptan in humans. The doses used were 20 mg/kg iv and oral in the rat, 10 mg iv in humans, and 50 mg oral in humans. The drug was rapidly absorbed after oral administration, with peak plasma concentrations occurring at 0.5 hr postdose. Absolute bioavailability was 19.3% in rats and 17.2% in humans. Renal excretion was a minor route of elimination in both species, with the majority of the dose being excreted in the feces. After a single oral dose, urinary excretion accounted for 10% of the administered dose in rats and 18% of the administered dose in humans, with the remainder excreted in the feces. Extensive biliary excretion was observed in rats. Avitriptan was extensively metabolized after oral administration, with the unchanged drug accounting for 32% and 22% of the total radioactivity in plasma in rats and humans, respectively. Plasma terminal elimination half-life was approximately 1 hr in rats and approximately 5 hr in humans. The drug was extensively distributed in rat tissues, with a tendency to accumulate in the pigmented tissues of the eye.

Assessment of dose proportionality, absolute bioavailability, and immunogenicity response of CTLA4Ig (BMS-188667), a novel immunosuppressive agent, following subcutaneous and intravenous administration to rats.

PURPOSE: The objectives of this study were: to delineate the pharmacokinetics of CTLA4Ig in rats after single and multiple intravenous (IV) and subcutaneous (SC) doses; to assess the relationship of the pharmacokinetic parameters of CTLA4Ig vs dose; to calculate the SC absolute bioavailability; and to assess the antibody response of CTLA4Ig. METHODS: A total of 48 (24 male and 24 female) Sprague Dawley rats were divided into eight treatments with 3 rats per gender in each group: a single dose of 10, 80, or 200 mg/kg of CTLA4Ig given either IV or SC and a repeated dose of 10 mg/kg (once every other day for 7 doses over 13 days) given either SC or IV. Serial blood samples were collected up to 43 days after single dose administration and up to 50 days following the administration of the last multiple dose on day 13. The serum concentration of CTLA4Ig and anti-CTLA4Ig antibodies were measured using ELISA assays. RESULTS: After single IV doses, Cmax and AUCinf increased in a dose proportional manner; CL appeared to be dose independent, while both Vss and T1/2 increased as the administered dose increased. Following single SC doses, Cmax and AUCinf increased in a linear manner but not proportionally; mean Tmax values were prolonged but similar among the three dose levels, while T1/2 increased as the administered dose increased. The absolute SC bioavailability of CTLA4Ig decreased as the dose increased from 10 (62.5%), 80 (55.7%), and 200 mg/kg (41.1%). Comparison of the AUCtau values between the first and last doses suggested an accumulation (3.1-4.7) of CTLA4Ig. However, regardless of the route of dosing, AUCtau after the last dose were comparable to AUCinf values following the single dose. Anti-CTLA4Ig antibodies were detected at the 10 mg/kg dose level after single or multiple doses for both routes of administration. However, regardless of single or multiple doses, antibody titers were relatively greater for the SC compared to the IV administration. CONCLUSIONS: The key findings of this study were: (i) the elimination characteristics of CTLA4Ig were comparable between the SC and IV routes; (ii) the repeated dosing did not alter the pharmacokinetics of CTLA4Ig; (iii) the SC absolute bioavailability tended to decrease as the administered dose increased; and (iv) a greater formation of anti-CTLA4Ig antibodies was observed after SC compared to IV at a single 10 mg/kg dose level; however, after multiple dosing, the formation of antibodies from either of the two routes was relatively slower, and (v) during the study period, no antibodies were observed at either the 80 or 200 mg/kg dose levels regardless of the route of administration.

The pharmacokinetics of butorphanol and its metabolites at steady state following nasal administration in humans.

The single-dose and steady state pharmacokinetics of butorphanol and its metabolites, hydroxybutorphanol (HO-B) and norbutorphanol (NOR-B), were studied in nine healthy male volunteers. Each subject received a single 1 mg dose of butorphanol on days 1 and 6, and a 1 mg dose every 6 h (q6h) on days 2-5, via nasal administration. Serial blood and urine samples were collected for 24 h after the first dose on day 1 and for 72 h at steady state on day 6. Plasma and urine samples were analyzed for free and conjugated butorphanol, HO-B, and NOR-B. The plasma samples were analyzed using validated gas chromatography-electron capture negative chemical ionization-mass spectrometric methods and the urine samples were analyzed using a validated HPLC procedure. In the plasma, conjugated metabolites were not detected and only trace amounts of NOR-B were present. Therefore, pharmacokinetic parameters could not be estimated for NOR-B and conjugated metabolites. AUC0-->infinity of butorphanol after the first dose and AUC0-->tau at steady state were not statistically different, indicating that the kinetics of butorphanol were not significantly altered after repeated dosing. Steady state levels of butorphanol were attained within 3 days (d) of q6h dosing and the accumulation index was 1.2 for butorphanol. Due to a relatively long t1/2 of 15 h of HO-B compared to the dosing interval (q6h), the accumulation index was 6.0 for this metabolite. The evaluation of the molar plasma concentration ratio of HO-B to butorphanol as a function of time revealed that HO-B exhibits elimination-rate-limited kinetics. Similarly to butorphanol, steady state levels of HO-B were attained within 3 d of q6h dosing.

The effects of age and gender on the single dose pharmacokinetics of avitriptan administered to healthy volunteers.

The effects of age and gender on the single dose pharmacokinetics of avitriptan and its three metabolites were assessed in 15 young men, 15 young women, 15 elderly men and 15 elderly women. Avitriptan was administered as a 150-mg capsule after a 10-hour fast and serial plasma and urine samples were collected up to 36 hours after the dose. Plasma samples were analyzed for avitriptan and its metabolites, N-desmethyl avitriptan (ND048), O-desmethyl avitriptan (OD048), and methoxypyrimidinyl piperazine (MPP). Urine samples were analyzed for only avitriptan and MPP. Avitriptan was well tolerated in all four groups. The drug was rapidly absorbed with a median time to maximum plasma concentration (tmax) between 0.5 and 1.5 hours. No significant gender-related differences were found in the maximum plasma concentration (Cmax) and area under the concentration-time curve extrapolated to infinity (AUC0-infinity) of avitriptan. Renal clearance of avitriptan was significantly smaller in young women compared with young men, but this is clinically not relevant because only 2% to 3% of the total dose is excreted unchanged. Compared with the young volunteers, mean Cmax was approximately 50% higher in the elderly but there was no difference in the AUC0-infinity between the 2 age groups. Plasma concentrations of ND048, OD048, and MPP were each 50 to 100 fold lower than those of avitriptan. Hence some age- and gender-related differences found in the pharmacokinetics of avitriptan metabolites are probably not relevant in the assessment of overall safety and efficacy of avitriptan. Based on the pharmacokinetics and tolerability, no age or gender-related dose adjustment is necessary for avitriptan.