Role of CYP2B6 in stereoselective human methadone metabolism.

BACKGROUND: Metabolism and clearance of racemic methadone are stereoselective and highly variable, yet the mechanism remains largely unknown. Initial in vitro studies attributed methadone metabolism to cytochrome P4503A4 (CYP3A4). CYP3A4 was also assumed responsible for methadone clearance in vivo. Nevertheless, recent clinical data do not support a primary role for CYP3A4 and suggest that CYP2B6 may mediate methadone clearance. Expressed CYP2B6 and also CYP2C19 N-demethylate methadone in vitro. This investigation tested the hypothesis that CYPs 2B6, 3A4, and/or 2C19 are responsible for stereoselective methadone metabolism in human liver microsomes and in vivo. METHODS: N-demethylation of racemic methadone and individual enantiomers by expressed CYPs 2B6, 2C19, and 3A4 was evaluated. Stereoselective microsomal methadone metabolism was quantified, compared with CYP 2B6 and 3A4 content, and probed using CYP isoform-selective inhibitors. A crossover clinical investigation (control, CYP2B6 and CYP3A4 induction by rifampin, CYP3A inhibition by troleandomycin and grapefruit juice) evaluated stereoselective methadone disposition. RESULTS: At clinical concentrations, methadone enantiomer N-demethylation by recombinant CYPs 2B6, 3A4, and 2C19 was S > R, S = R, and S << R. Greater stereoselective metabolism (S > R) occurred in livers expressing high levels of CYP2B6 compared with CYP3A4. Clopidogrel, troleandomycin, and (+)-N-3-benzyl-nirvanol, selective inhibitors of CYPs 2B6, 3A4, and 2C19, respectively, inhibited microsomal methadone metabolism by 50-60%, 20-30%, and less than 10%. Only inhibition by clopidogrel was stereoselective. Clinically, rifampin diminished both R- and S-methadone plasma concentrations, but troleandomycin and grapefruit juice altered neither R- nor S-methadone concentrations. Plasma R/S-methadone ratios were increased by rifampin but unchanged by CYP3A inhibition. CONCLUSIONS: These results suggest a significant role for CYP2B6, but not CYP3A, in stereoselective human methadone metabolism and disposition.

Enantiomeric metabolic interactions and stereoselective human methadone metabolism.

Methadone is administered as a racemate, although opioid activity resides in the R-enantiomer. Methadone disposition is stereoselective, with considerable unexplained variability in clearance and plasma R/S ratios. N-Demethylation of methadone in vitro is predominantly mediated by cytochrome P450 CYP3A4 and CYP2B6 and somewhat by CYP2C19. This investigation evaluated stereoselectivity, models, and kinetic parameters for methadone N-demethylation by recombinant CYP2B6, CYP3A4, and CYP2C19, and the potential for interactions between enantiomers during racemate metabolism. CYP2B6 metabolism was stereoselective. CYP2C19 was less active, and stereoselectivity was opposite that for CYP2B6. CYP3A4 was not stereoselective. With all three isoforms, enantiomer N-dealkylation rates in the racemate were lower than those of (R)-(6-dimethyamino-4,4-diphenyl-heptan-3-one) hydrochloride (R-methadone) or (S)-(6-dimethyamino-4,4-diphenyl-heptan-3-one) hydrochloride (S-methadone) alone, suggesting an enantiomeric interaction and mutual metabolic inhibition. For CYP2B6, the interaction between enantiomers was stereoselective, with S-methadone as a more potent inhibitor of R-methadone N-demethylation than R-of S-methadone. In contrast, enantiomer interactions were not stereoselective with CYP2C19 or CYP3A4. For all three cytochromes P450, methadone N-demethylation was best described by two-site enzyme models with competitive inhibition. There were minor model differences between cytochromes P450 to account for stereoselectivity of metabolism and enantiomeric interactions. Changes in plasma R/S methadone ratios observed after rifampin or troleandomycin pretreatment in humans in vivo were successfully predicted by CYP2B6- but not CYP3A4-catalyzed methadone N-demethylation. CYP2B6 is a predominant catalyst of stereoselective methadone metabolism in vitro. In vivo, CYP2B6 may be a major determinant of methadone metabolism and disposition, and CYP2B6 activity and stereoselective metabolic interactions may confer variability in methadone disposition.

New insights into the mechanism of methoxyflurane nephrotoxicity and implications for anesthetic development (part 1): Identification of the nephrotoxic metabolic pathway.

BACKGROUND: Methoxyflurane nephrotoxicity results from biotransformation; inorganic fluoride is a toxic metabolite. Concern exists about potential renal toxicity from volatile anesthetic defluorination, but many anesthetics increase fluoride concentrations without consequence. Methoxyflurane is metabolized by both dechlorination to methoxydifluoroacetic acid (MDFA, which may degrade to fluoride) and O-demethylation to fluoride and dichloroacetatic acid. The metabolic pathway responsible for methoxyflurane nephrotoxicity has not, however, been identified, which was the aim of this investigation. METHODS: Experiments evaluated methoxyflurane metabolite formation and effects of enzyme induction or inhibition on methoxyflurane metabolism and toxicity. Rats pretreated with phenobarbital, barium sulfate, or nothing were anesthetized with methoxyflurane, and renal function and urine methoxyflurane metabolite excretion were assessed. Phenobarbital effects on MDFA metabolism and toxicity in vivo were also assessed. Metabolism of methoxyflurane and MDFA in microsomes from livers of pretreated rats was determined in vitro. RESULTS: Phenobarbital pretreatment increased methoxyflurane nephrotoxicity in vivo (increased diuresis and blood urea nitrogen and decreased urine osmolality) and induced in vitro hepatic microsomal methoxyflurane metabolism to inorganic fluoride (2-fold), dichloroacetatic acid (1.5-fold), and MDFA (5-fold). In contrast, phenobarbital had no influence on MDFA renal effects in vivo or MDFA metabolism in vitro or in vivo. MDFA was neither metabolized to fluoride nor nephrotoxic. Barium sulfate diminished methoxyflurane metabolism and nephrotoxicity in vivo. CONCLUSIONS: Fluoride from methoxyflurane anesthesia derives from O-demethylation. Phenobarbital increases in methoxyflurane toxicity do not seem attributable to methoxyflurane dechlorination, MDFA toxicity, or MDFA metabolism to another toxic metabolite, suggesting that nephrotoxicity is attributable to methoxyflurane O-demethylation. Fluoride, one of many metabolites from O-demethylation, may be toxic and/or reflect formation of a different toxic metabolite. These results may have implications for interpreting anesthetic defluorination, volatile anesthetic use, and methods to evaluate anesthetic toxicity.

Sensitivity of intravenous and oral alfentanil and pupillary miosis as minimally invasive and noninvasive probes for hepatic and first-pass CYP3A activity.

This investigation determined the ability of alfentanil miosis and single-point concentrations to detect various degrees of CYP3A inhibition. Results were compared with those for midazolam, an alternative CYP3A probe. Twelve volunteers were studied in a randomized 4-way crossover, targeting 12%, 25%, and 50% inhibition of hepatic CYP3A. They received 0, 100, 200, or 400 mg oral fluconazole, followed 1 hour later by 1 mg intravenous midazolam and then 15 microg/kg intravenous alfentanil 1 hour later. The next day, they received fluconazole, followed by 3 mg oral midazolam and 40 microg/kg oral alfentanil. Dark-adapted pupil diameters were measured coincident with blood sampling. Area under the plasma concentration-time curve (AUC) ratios (fluconazole/control) after 100, 200, and 400 mg fluconazole were (geometric mean) 1.3*, 1.4*, and 2.0* for intravenous midazolam and 1.2*, 1.6*, and 2.2* for intravenous alfentanil (*significantly different from control), indicating 16% to 21%, 31% to 36%, and 43% to 53% inhibition of hepatic CYP3A. Single-point concentration ratios were 1.5*, 1.8*, and 2.4* for intravenous midazolam (at 5 hours) and 1.2*, 1.6*, and 2.2* for intravenous alfentanil (at 4 hours). Pupil miosis AUC ratios were 0.9, 1.0, and 1.2*. After oral dosing, plasma AUC ratios were 2.3*, 3.6*, and 5.3* for midazolam and 1.8*, 2.9*, and 4.9* for alfentanil; plasma single-point ratios were 2.4*, 4.5*, and 6.9* for midazolam and 1.8*, 2.9*, and 4.9* for alfentanil, and alfentanil miosis ratios were 1.1, 1.9*, and 2.7*. Plasma concentration AUC ratios of alfentanil and midazolam were equivalent for detecting hepatic and first-pass CYP3A inhibition. Single-point concentrations were an acceptable surrogate for formal AUC determinations and as sensitive as AUCs for detecting CYP3A inhibition. Alfentanil miosis could detect 50% to 70% inhibition of CYP3A activity, but was less sensitive than plasma AUCs. Further refinements are needed to increase the sensitivity of alfentanil miosis for detecting small CYP3A changes.

Pharmacogenetic determinants of human liver microsomal alfentanil metabolism and the role of cytochrome P450 3A5.

BACKGROUND: There is considerable unexplained interindividual variability in the clearance of alfentanil. Alfentanil undergoes extensive metabolism by cytochrome P4503A4 (CYP3A4). CYP3A5 is structurally similar to CYP3A4 and metabolizes most CYP3A4 substrates but is polymorphically expressed. Livers with the CYP3A5*1 allele contain higher amounts of the native CYP3A5 protein than livers homozygous for the mutant CYP3A5*3 allele. This investigation tested the hypothesis that alfentanil is a substrate for CYP3A5 and that CYP3A5 pharmacogenetic variability influences human liver alfentanil metabolism. METHODS: Alfentanil metabolism to noralfentanil and N-phenylpropionamide was determined in microsomes from two groups of human livers, characterized for CYP3A4 and CYP3A5 protein content: low CYP3A5 (2.0-5.2% of total CYP3A, n = 10) and high CYP3A5 (46-76% of total CYP3A, n = 10). Mean CYP3A4 content was the same in both groups. The effects of the CYP3A inhibitors troleandomycin and ketoconazole, the latter being more potent toward CYP3A4, on alfentanil metabolism were also determined. RESULTS: In the low versus high CYP3A5 livers, respectively, noralfentanil formation was 77 +/- 31 versus 255 +/- 170 pmol . min . mg, N-phenylpropionamide formation was 8.0 +/- 3.1 versus 20.5 +/- 14.0 pmol . min . mg, and the metabolite ratio was 9.5 +/- 0.4 versus 12.7 +/- 1.4 (P < 0.05 for all). There was a poor correlation between alfentanil metabolism and CYP3A4 content but an excellent correlation when CYP3A5 (i.e., total CYP3A content) was considered (r = 0.81, P < 0.0001). Troleandomycin inhibited alfentanil metabolism similarly in the low and high CYP3A5 livers; ketoconazole inhibition was less in the high CYP3A5 livers. CONCLUSION: In microsomes from human livers expressing the CYP3A5*1 allele and containing higher amounts of CYP3A5 protein, compared with those with the CYP3A5*3 allele and little CYP3A5, there was greater alfentanil metabolism, metabolite ratios more closely resembled those for expressed CYP3A5, and inhibitors with differing CYP3A4 and CYP3A5 selectivities had effects resembling those for expressed CYP3A5. Therefore, alfentanil is metabolized by human liver microsomal CYP3A5 in addition to CYP3A4, and pharmacogenetic variability in CYP3A5 expression significantly influences human liver alfentanil metabolism in vitro. Further investigation is warranted to assess whether the CYP3A5 polymorphism is a factor in the interindividual variability of alfentanil metabolism and clearance in vivo.

Metabolism of alfentanil by cytochrome p4503a (cyp3a) enzymes.

The synthetic opioid alfentanil is an analgesic and an in vivo probe for hepatic and first-pass CYP3A activity. Alfentanil is a particularly useful CYP3A probe because pupil diameter change is a surrogate for plasma concentrations, thereby affording noninvasive assessment of CYP3A. Alfentanil undergoes extensive CYP3A4 metabolism via two major pathways, forming noralfentanil and N-phenylpropionamide. This investigation evaluated alfentanil metabolism in vitro to noralfentanil and N-phenylpropionamide, by expressed CYP3A5 and CYP3A7 in addition to CYP3A4, with and without coexpressed or exogenous cytochrome b(5). Effects of the CYP3A inhibitors troleandomycin and ketoconazole were also determined. Rates of noralfentanil and N-phenylpropionamide formation by CYP3A4 and 3A5 in the absence of b(5) were generally equivalent, although the metabolite formation ratio differed, whereas those by CYP3A7 were substantially less. CYP3A4 and 3A5 were equipotently inhibited by troleandomycin, whereas ketoconazole was an order of magnitude more potent toward CYP3A4. Cytochrome b(5) qualitatively and quantitatively altered alfentanil metabolism, with b(5) coexpression having a greater effect than exogenous addition. Addition or coexpression of b(5) markedly stimulated the formation of both metabolites and changed the formation of noralfentanil but not N-phenylpropionamide from apparent single-site to multisite Michaelis-Menten kinetics. These results demonstrate that alfentanil is a substrate for CYP3A5 in addition to CYP3A4, and the effects of the CYP3A inhibitors troleandomycin and ketoconazole are CYP3A enzyme-selective. Alfentanil is one of the few CYP3A substrates that is metabolized in vitro as avidly by both CYP3A4 and 3A5. Polymorphic CYP3A5 expression may contribute to inter-individual variability in alfentanil metabolism.

Evaluation of first-pass cytochrome P4503A (CYP3A) and P-glycoprotein activities using alfentanil and fexofenadine in combination.

Cytochrome P4503A (CYP3A) and P-glycoprotein (P-gp) are major determinants of oral bioavailability. Development of in vivo probe(s), for both CYP3A and P-gp, which could be administered in combination, is a current goal. Nevertheless, there is considerable overlap in CYP3A and P-gp substrate selectivities; there are few discrete probes. Alfentanil is a selective CYP3A probe but not a P-gp substrate. Fexofenadine is a P-gp probe but not a CYP3A substrate. This investigation tested the hypothesis that alfentanil and fexofenadine could be administered in combination to probe first-pass CYP3A and P-gp activities in humans. Two 3-way crossover studies were conducted in healthy volunteers. In the first protocol, subjects received oral alfentanil alone, fexofenadine alone, or fexofenadine 1 hour after alfentanil. In the second protocol, subjects abstained from citrus and apple products for 5 days and received fexofenadine alone, fexofenadine 1 hour after alfentanil, or alfentanil 4 hours after fexofenadine. An assay using solid-phase extraction and electrospray liquid chromatography/mass spectrometry was developed for the simultaneous quantification of plasma alfentanil and fexofenadine. In both protocols, alfentanil plasma concentrations and area under the concentration versus time curve (AUC) were unaffected by fexofenadine or meal composition. Fexofenadine given 1 hour after alfentanil and followed 1 hour later by a meal containing orange or apple juice had a somewhat lower AUC compared with fexofenadine alone (geometric mean ratio with and without the interacting drug = 0.73, 90% confidence interval [CI] = 0.59-1.04). Fexofenadine given 1 hour after alfentanil and followed 2 hours later by a meal not containing citrus or apple products had an AUC that was unchanged compared with fexofenadine alone (ratio = 0.91, 90% CI = 0.70-1.35). These results show that alfentanil disposition was not affected by fexofenadine. A dosing regimen was identified in which fexofenadine disposition was not affected by alfentanil. The timing and content of meals after fexofenadine had a significant effect on fexofenadine disposition. Alfentanil and fexofenadine in combination appear to be a useful probe for evaluating both first-pass CYP3A and P-gp activities in humans.

Intravenous and oral alfentanil as in vivo probes for hepatic and first-pass cytochrome P450 3A activity: noninvasive assessment by use of pupillary miosis.

INTRODUCTION: Systemic clearance of intravenous (IV) alfentanil (ALF) is an in vivo probe for hepatic cytochrome P450 (CYP) 3A activity, miosis is a surrogate for plasma ALF concentrations, and IV ALF miosis is a noninvasive probe for hepatic CYP3A. This investigation characterized the bioavailability and first-pass metabolism of oral ALF and tested the hypotheses that (1) first-pass ALF clearance reflects first-pass CYP3A activity, (2) miosis after oral ALF will reflect intestinal and hepatic CYP3A activity, and (3) miosis can approximate plasma concentration-based pharmacokinetic measures for IV and oral ALF as a noninvasive in vivo probe for hepatic and first-pass CYP3A activity and drug interactions. Results were compared with those for midazolam (MDZ), an alternative CYP3A probe. METHODS: Ten volunteers were studied by use of a randomized, 9-way, crossover design after administration of rifampin (INN, rifampicin) (hepatic and intestinal CYP3A induction), troleandomycin (TAO) (hepatic and intestinal CYP3A inhibition), grapefruit juice (selective intestine CYP3A inhibition), or nothing (control). For each condition, they received 1 mg IV MDZ and then 15 microg/kg IV ALF, as well as 3 mg oral MDZ and then oral ALF (23 or 60 microg/kg) on another day. Plasma concentrations were determined by liquid chromatography-mass spectrometry. Dark-adapted pupil diameters were measured coincident with blood sampling. ALF effect was analyzed similarly to concentration to yield an effect "clearance" (Dose/Area under the pupil diameter change versus time curve). RESULTS: Bioavailability (Foral), hepatic extraction (EH), and intestinal availability (FG) were 0.26 +/- 0.08, 0.52 +/- 0.09, and 0.56 +/- 0.20, respectively, for MDZ and 0.42 +/- 0.15, 0.28 +/- 0.09, and 0.56 +/- 0.18, respectively, for ALF. Oral clearance (CL/F) was 34.7 +/- 12.8 and 10.9 +/- 3.5 mL.kg -1.min -1 , respectively, for MDZ and ALF. After rifampin, TAO, and grapefruit juice, ALF F oral was 0.04 +/- 0.02 (P <.05, versus control), 0.99 +/- 0.18 (P <.05, versus control), and 0.62 +/- 0.18 (P <.05, versus control), respectively; E H was 0.69 +/- 0.14 (P < .05, versus control), 0.04 +/- 0.01 (P <.05, versus control), and 0.26 +/- 0.08, respectively; F G was 0.16 +/- 0.10 (P <.05, versus control), 1.0 +/- 0.2 (P <.05, versus control), and 0.85 +/- 0.30 (P <.05, versus control), respectively; CL/F was 339 +/- 233 (P <.05, versus control), 0.62 +/- 0.26 (P <.05, versus control), and 6.7 +/- 2.5 (P <.05, versus control), respectively, and effect clearance was 2.1 +/- 1.1 (P <.05, versus control), 0.087 +/- 0.056 (P <.05, versus control), and 0.54 +/- 0.30 (0.73 +/- 0.43 mg.mm -1.h -1 in controls), respectively. There were significant correlations between ALF and MDZ systemic clearances (r2= 0.92), EH (r2=0.93), and CL/F (r2= 0.97), as well as between oral ALF effect (miosis) clearance and oral clearance (r2=0.59). CONCLUSIONS: ALF and MDZ have similar intestinal extraction but low and intermediate hepatic extraction, respectively. Systemic and oral clearances of ALF are excellent in vivo probes for hepatic and first-pass CYP3A activities and drug interactions. Miosis was an acceptable surrogate for plasma ALF. ALF miosis may be a suitable noninvasive in vivo probe for both hepatic and first-pass CYP3A.

Role of hepatic and intestinal cytochrome P450 3A and 2B6 in the metabolism, disposition, and miotic effects of methadone.

BACKGROUND: The disposition of the long-acting opioid methadone, used to prevent opiate withdrawal and treat short- and long-lasting pain, is highly variable. Methadone undergoes N -demethylation to the primary metabolite 2-ethyl-1,5-dimethyl-3,3-diphenylpyrrolinium (EDDP), catalyzed in vitro by intestinal, hepatic, and expressed cytochrome P450 (CYP) 3A4. However, the role of CYP3A4 in human methadone disposition in vivo is unclear. This investigation tested the hypothesis that CYP3A induction (or inhibition) would increase (or decrease) methadone metabolism and clearance in humans. METHODS: Healthy volunteers were studied in a randomized, balanced, 4-way crossover study. They received intravenous (IV) midazolam (to assess CYP3A4 activity) and then simultaneous oral deuterium-labeled and IV unlabeled methadone after pretreatment with rifampin (INN, rifampicin) (hepatic/intestinal CYP3A induction), troleandomycin (hepatic/intestinal CYP3A inhibition), grapefruit juice (selective intestinal CYP3A inhibition), or nothing. Methadone effects were measured by dark-adapted pupil diameter. CYP isoforms catalyzing methadone metabolism by human liver microsomes and expressed CYPs in vitro were also evaluated. RESULTS: Methadone had high oral bioavailability (70%) and low intestinal (22%) and hepatic (9%) extraction, and there was a significant correlation ( r = 0.94, P <.001) between oral bioavailability and intestinal (but not hepatic) availability. Rifampin decreased bioavailability and oral and IV methadone plasma concentrations and increased IV clearance (4.42 +/- 1.00 mL. kg -1. min -1 versus 1.61 +/- 0.67 mL. kg -1. min -1, P <.05) and oral clearance (8.50 +/- 3.68 mL. kg -1. min -1 versus 2.05 +/- 0.92 mL. kg -1. min -1, P <.05), EDDP/methadone area under the curve (AUC) ratios, EDDP formation clearances, and hepatic extraction (0.27 +/- 0.06 versus 0.09 +/- 0.04, P <.05). Troleandomycin and grapefruit juice decreased the EDDP/methadone AUC ratio after oral methadone (0.17 +/- 0.10 and 0.14 +/- 0.06 versus 0.27 +/- 0.20, P <.05) but not IV methadone and had no effect on methadone plasma concentrations, IV clearance (1.29 +/- 0.41 mL. kg -1. min -1 and 1.48 +/- 0.55 mL. kg -1. min -1 ) or oral clearance (2.05 +/- 1.52 mL. kg -1. min -1 and 1.89 +/- 1.07 mL. kg -1. min -1 ), or other kinetic parameters. There was no correlation between methadone clearance and hepatic CYP3A4 activity. Pupil diameter changes reflected plasma methadone concentrations. In vitro experiments showed a predominant role for both CYP3A4 and CYP2B6 in liver microsomal methadone N -demethylation. CONCLUSION: First-pass intestinal metabolism is a determinant of methadone bioavailability. Intestinal and hepatic CYP3A activity only slightly affects human methadone N -demethylation but has no significant effect on methadone concentrations, clearance, or clinical effects. Greater rifampin effects, compared with troleandomycin and grapefruit juice, on methadone disposition suggest a major role for intestinal transporters and for other CYPs, such as CYP2B6. Interindividual variability and drug interactions affecting intestinal transporter and hepatic CYP3A and CYP2B6 activity may alter methadone disposition.

Bioavailabilities of rectal and oral methadone in healthy subjects.

AIMS: Rectal administration of methadone may be an alternative to intravenous and oral dosing in cancer pain, but the bioavailability of the rectal route is not known. The aim of this study was to compare the absolute rectal bioavailability of methadone with its oral bioavailability in healthy humans. METHODS: Seven healthy subjects (six males, one female, aged 20-39 years) received 10 mg d(5)-methadone-HCl rectally (5 ml in 20% glycofurol) together with either d(0)-methadone intravenously (5 mg) or orally (10 mg) on two separate occasions. Blood samples for the LC-MS analyses of methadone and it's metabolite EDDP were drawn for up to 96 h. Noninvasive infrared pupillometry was performed at the same time as blood sampling. RESULTS: The mean absolute rectal bioavailability of methadone was 0.76 (0.7, 0.81), compared to 0.86 (0.75, 0.97) for oral administration (mean (95% CI)). Rectal absorption of methadone was more rapid than after oral dosing with Tmax values of 1.4 (0.9, 1.8) vs. 2.8 (1.6, 4.0) h. The extent of formation of the metabolite EDDP did not differ between routes of administration. Single doses of methadone had a duration of action of at least 10 h and were well tolerated. CONCLUSIONS: Rectal administration of methadone results in rapid absorption, a high bioavailability and long duration of action. No evidence of presystemic elimination was seen. Rectal methadone has characteristics that make it a potential alternative to intravenous and oral administration, particularly in cancer pain and palliative care.

Disposition and miotic effects of oral alfentanil: a potential noninvasive probe for first-pass cytochrome P4503A activity.

BACKGROUND AND OBJECTIVES: Systemic clearance of the opioid alfentanil after intravenous administration is an excellent in vivo probe for hepatic cytochrome P4503A (CYP3A) activity and drug interactions. Alfentanil effect (miosis) is a surrogate for plasma alfentanil concentrations, and alfentanil effect kinetics may be a suitable noninvasive probe for hepatic CYP3A. Oral alfentanil might be a probe for first-pass CYP3A activity; however, it is not used clinically, and oral alfentanil disposition is unknown. This investigation evaluated the disposition and miotic effects of oral alfentanil. METHODS: Ten healthy volunteers were studied in a dose-escalation fashion, receiving 23, 30, 43, and 75 microg/kg oral alfentanil on different days. Dark-adapted pupil diameter was measured at the time of venous blood sampling. Alfentanil was quantified by liquid chromatography-mass spectrometry. Plasma concentrations of alfentanil and pupil diameter change versus time data were analyzed by noncompartmental modeling. RESULTS: Alfentanil was rapidly absorbed (time to maximum concentration [T(max)], 0.7 +/- 0.5 hour). Mean values for area under the plasma concentration-time curve extrapolated to infinity (AUC( infinity )) (27 +/- 14, 38 +/- 22, 57 +/- 31, and 105 +/- 59 ng x h x mL(-1)) and maximum concentration (16 +/- 8, 23 +/- 16, 31 +/- 18, and 50 +/- 22 ng/mL) were linear with dose, although there was considerable interindividual variability. T(max), elimination half-life (1.0 +/- 0.2 hours), total body clearance after oral administration (20 +/- 18 mL x kg(-1) x min(-1)), and dose-normalized AUC(infinity ) were independent of dose. Dose-dependent alfentanil disposition was mirrored by commensurate changes in clinical effect, although miosis was variable and not detectable in all subjects at the lowest dose. Mean miosis AUC (AUEC) and peak miosis were log-dose linear. Effect half-life (1.3 +/- 0.9 hours) was similar to plasma half-life. CONCLUSION: Oral alfentanil is rapidly absorbed, exhibits linear and dose-independent kinetics, and undergoes substantial first-pass metabolism. Oral alfentanil may be a suitable probe for first-pass CYP3A activity. Alfentanil effect (miosis) may be an acceptable surrogate for plasma alfentanil concentrations. Oral alfentanil effect may be a noninvasive surrogate for conventional pharmacokinetics. Further studies are warranted to determine whether oral alfentanil and alfentanil effect kinetics may be a suitable noninvasive in vivo probe for first-pass CYP3A activity.

Disposition of nasal, intravenous, and oral methadone in healthy volunteers.

OBJECTIVE: Nasal administration of many opioids demonstrates rapid uptake and fast onset of action. Nasal administration may be an alternative to intravenous and oral administration of methadone and was therefore studied in human volunteers. METHODS: The study was approved by the Institutional Review Board of the University of Washington, Seattle. Eight healthy volunteers (6 men and 2 women) aged 19 to 33 years were enrolled after informed written consent was obtained. Subjects received 10 mg methadone hydrochloride nasally, orally, or intravenously on 3 separate occasions in a crossover design. Nasal methadone (50 mg/mL in aqueous solution) was given as a 100-microL spray in each nostril (Pfeiffer BiDose sprayer). Blood samples for liquid chromatography-mass spectrometry analyses of methadone and the metabolite 2-ethyl-1,5-dimethyl-3,3-diphenylpyrrolinium were drawn for up to 96 hours. The methadone effect was measured by noninvasive infrared pupilometry coincident with blood sampling. RESULTS: Nasal uptake of methadone was rapid, with maximum plasma concentrations occurring within 7 minutes. The maximum effects of intravenous, nasal, and oral methadone, on the basis of dark-adapted pupil diameter, were reached in about 15 minutes, 30 minutes, and 2 hours, respectively. The respective durations were 24, 10, and 8 hours. Both nasal and oral bioavailabilities were 0.85. Subjects reported that nasal methadone caused a burning sensation. CONCLUSIONS: Nasal administration of methadone results in rapid absorption and onset of effect and high bioavailability, which was greater than that reported for other nasal opioids, with a similar duration of effect. Nasal administration may be an alternative route of methadone administration; however, improved formulations are desirable to reduce nasal irritation.