Bioequivalence Between a New Omalizumab Prefilled Syringe With an Autoinjector or with a Needle Safety Device Compared with the Current Prefilled Syringe: A Randomized Controlled Trial in Healthy Volunteers.

Omalizumab is an anti-IgE monoclonal antibody currently approved for the treatment of asthma, nasal polyps/chronic rhinosinusitis with nasal polyps, and chronic spontaneous urticaria. Omalizumab is available as an injection in a prefilled syringe (PFS) with a needle safety device (NSD). New product configurations were developed to reduce the number of injections per dose administration, improve patient convenience and treatment compliance. The objective of this randomized open-label 12-week study was to demonstrate pharmacokinetic bioequivalence between (1) new PFS with autoinjector (PFS-AI), (2) new PFS-NSD configuration, and (3) current PFS-NSD configuration. Each new configuration was considered bioequivalent to the current configuration if the confidence intervals (CIs) for the geometric mean ratios (GMR) were contained in the 0.80-1.25 range for maximum concentration (Cmax), area under the concentration-time curve until the last quantifiable measurement (AUClast), and AUC extrapolated to infinity (AUCinf). Safety was assessed throughout the study. In total, 193 healthy volunteers were randomized at 1:1:1 ratio to omalizumab 1×300 mg/2 mL via new PFS-AI (n = 66), omalizumab 1×300 mg/2 mL via new PFS-NSD (n = 64), or omalizumab 2×150 mg/1 mL via current PFS-NSD (n = 63). Comparing new PFS-AI versus current PFS-NSD, the GMRs were: Cmax, 1.085; AUClast, 1.093; AUCinf, 1.100. Comparing new PFS-NSD versus current PFS-NSD, the GMRs were: Cmax, 1.006; AUClast, 1.016; AUCinf, 1.027. The 95% CIs for all GMR parameters were contained within the 0.80-1.25 range. Safety findings were consistent with the known safety profile of omalizumab. Single-dose omalizumab administered as the new PFS-AI or new PFS-NSD was bioequivalent to the current PFS-NSD.

A Study to Evaluate Relative Bioavailability, Food Effect, and Pharmacodynamics of Tropifexor, a Farnesoid X Receptor Agonist, in Healthy Participants.

This open-label, randomized, 3-treatment, 3-period, 6-sequence, crossover study in healthy subjects compared the pharmacokinetic and pharmacodynamic properties of a lipid-based (soft gelatin capsule) prototype final market image (pFMI) formulation of tropifexor (90-µg) to its clinical service form (CSF) and assessed the food effect for the pFMI formulation. In the fasted state, drug exposure was higher for the pFMI. The geometric mean ratios for pFMI versus CSF of peak concentration and area under the concentration-time curve were 2.0 and 1.5, respectively. No food effect was apparent for the pFMI formulation, and the geometric mean ratios for pFMI fed versus pFMI fasted of peak concentration and area under concentration-time curve were 1.0 and 1.0 respectively. Despite having lower systemic exposure, the CSF formulation provided a higher pharmacological response for the gut biomarker fibroblast growth factor 19. Under fasted conditions, fibroblast growth factor 19 maximum change from baseline serum concentration after drug administration and area under the change from baseline serum concentration-time curve from time 0 to 24 hours were 36% for CSF and 12% for FMI. For a second biomarker, serum 7-alpha hydroxy-4-cholest-3-one, the pharmacological activity was comparable between CSF (fasted) and pFMI (both fasted and fed states). The pFMI offers advantages over the CSF in terms of insensitivity to food effect, lower intersubject variability, and overcoming solubility limitations.

Drug-Drug Interaction Studies to Evaluate the Effect of Inhibition of UGT1A1 and CYP3A4 and Induction of CYP3A4 on the Pharmacokinetics of Tropifexor in Healthy Subjects.

Tropifexor, a farnesoid X receptor agonist, is currently under clinical development for the treatment of nonalcoholic steatohepatitis. Tropifexor undergoes glucuronidation by uridine 5'-diphosphoglucuronosyltransferase (UGT) 1A1 and oxidation by cytochrome P450 (CYP) 3A4, as reported in in vitro studies. Here, we report the results from 2 drug-drug interaction studies. Study 1 enrolled 20 healthy subjects to investigate the effect of the UGT1A1 inhibitor atazanavir (ATZ) on tropifexor pharmacokinetics (PK). Study 2 had 2 cohorts with 16 healthy subjects each to investigate the effect of the strong CYP3A4 inhibitor itraconazole and strong CYP3A4 inducer rifampin on the PK of tropifexor. Coadministration of ATZ reduced the maximum plasma concentration (Cmax ) of tropifexor by 40%; however, it did not lead to increased exposure of tropifexor (both area under the plasma concentration-time curve [AUC] from time 0 to the last quantifiable concentration [AUClast ] and AUC from time 0 to infinity [AUCinf ] reduced by only 10%), suggesting minor relevance of the UGT1A1 pathway for clearance of tropifexor and no expected drug-drug interactions based on UGT1A1 inhibition. Inhibition of CYP3A4 by itraconazole increased the Cmax of tropifexor by only 9% and exposure (both AUClast and AUCinf ) by 47%, suggesting a weak effect of strong CYP3A4 inhibitors on tropifexor PK. Inducing CYP3A4 with rifampin decreased Cmax (55%) and AUC (AUClast by 79% and AUCinf by 77%). Coadministration of tropifexor with either ATZ, itraconazole, or rifampin was well tolerated.

Novel Bruton's tyrosine kinase inhibitor remibrutinib: Assessment of drug-drug interaction potential as a perpetrator of cytochrome P450 enzymes and drug transporters and the impact of covalent binding on possible drug interactions.

PURPOSE: Pharmacokinetic drug-drug interactions (DDIs) are investigated to ensure safety for patients receiving concomitant medications. Here, we present a strategy to characterise the DDI potential of remibrutinib, as an inhibitor of drug-metabolising enzymes and drug transporters, and as an inducer. Initial in vitro studies were performed, followed by a biomarker-based assessment of induction in a first in human study, concluded by a clinical study to verify initial results. Remibrutinib is a covalent inhibitor of Bruton's Tyrosine kinase (BTKi) carrying a reactive acrylamide moiety (warhead), thus the potential contribution of covalent binding (off-target) to observed interactions was investigated as this could lead to prolonged and more potent drug interactions. METHODS: DDI assessment was focused on the putative inhibition of key metabolic enzymes (Cytochrome P450, CYP), drug transporters and a potential effect on oral contraceptives (OC) by induction of enzymes that are involved in their clearance (CYP3A4). The impact of covalent binding was assessed by synthesising an identical reference molecule but with an inactivated warhead. RESULTS: An interaction potential of limited clinical relevance was revealed for remibrutinib for CYP enzymes and drug transporters. The reactive warhead of remibrutinib had no impact on CYP enzyme and transporter inhibition, including time-dependent inhibition of CYP3A4, but may increase the induction potential of remibrutinib. CONCLUSIONS: Observed inhibition of metabolic enzymes indicated that remibrutinib is a weak inhibitor of CYP3A4 and CYP2C9 and is not a clinically relevant inhibitor of uptake and efflux transporters, except for intestinal P-glycoprotein and breast cancer resistance protein inhibition. OC may be safely administered and are effective when given with pharmacologically relevant doses of remibrutinib.

Pharmacokinetics of Tropifexor, a Potent Farnesoid X Receptor Agonist, in Participants With Varying Degrees of Hepatic Impairment.

Tropifexor, a non-bile acid farnesoid X receptor (FXR) agonist, has dose-proportional pharmacokinetics and no obvious major enterohepatic circulation. This open-label study investigated the effect of hepatic impairment (HI), as determined by Child-Pugh grade, on tropifexor's pharmacokinetics, safety, and tolerability following a 200-µg dose in the fasted state. Blood samples were collected through 168 hours after dosing for quantification and plasma protein-binding determination. Total tropifexor exposure was comparable across participants with HI vs those with normal hepatic function. Tropifexor was highly protein bound (>99%) in human plasma across participants of all groups. The average unbound fractions (percentage free) were 0.14% in participants with normal hepatic function and mild HI, which increased to 0.17% and 0.24% in participants with moderate and severe HI, respectively. Similar unbound drug exposure was noted in participants with mild HI and normal hepatic function. Participants with moderate HI (N = 8) had a 1.6-fold increase in unbound exposure (area under the plasma concentration-time curve from time 0 to infinity [AUCinf,u ]) and a 1.3-fold increase in maximal exposure (Cmax,u ) vs those with normal hepatic function (geometric mean ratio: AUCinf,u , 1.64 [90%CI, 1.25-2.16]; Cmax,u , 1.30 [90%CI, 0.96-1.76]). Participants with severe HI (N = 8) had a 1.6-fold increase in AUCinf,u (1.61 [90%CI, 1.04-2.49]) and comparable Cmax,u (1.02 [90%CI, 0.60-1.72]) compared to participants with normal hepatic function. Tropifexor was well tolerated. The relative insensitivity of tropifexor to HI offers the potential to treat patients with severe liver disease without dose adjustment.

Clinical Investigation of Metabolic and Renal Clearance Pathways Contributing to the Elimination of Fevipiprant Using Probenecid as Perpetrator.

Fevipiprant, an oral, nonsteroidal, highly selective, reversible, and competitive prostaglandin D2 receptor 2 antagonist, is eliminated by glucuronidation and by direct renal excretion predominantly via organic anion transporter (OAT) 3. This study aimed to assess the effect of simultaneous UDP-glucuronosyltransferase (UGT) and OAT3 inhibition by probenecid on the pharmacokinetics of fevipiprant and its acyl glucuronide (AG) metabolite to support the dosing recommendation of fevipiprant in the presence of drugs inhibiting these pathways; however, phase III clinical trial results did not support its submission. This was a single-center, open-label, single-sequence, two-period crossover study in healthy subjects. Liquid chromatography with tandem mass spectrometry was used to measure concentrations of fevipiprant and its AG metabolite in plasma and urine. In the presence of probenecid, the mean maximum concentrations of fevipiprant increased approximately 1.7-fold, and the area under the concentration-time curve in plasma increased approximately 2.5-fold, whereas the mean apparent volume of distribution and the AG metabolite:fevipiprant ratio decreased. The apparent systemic clearance decreased by approximately 60% and the renal clearance decreased by approximately 88% in the presence of probenecid. Using these data and those from previous studies, the relative contribution of OAT and UGT inhibition to the overall effect of probenecid was estimated. Furthermore, a general disposition scheme for fevipiprant was developed, showing how a perpetrator drug such as probenecid, which interferes with two key elimination pathways of fevipiprant, causes only a moderate increase in exposure and allows estimation of the drug-drug inhibition when only one of the two pathways is inhibited. SIGNIFICANCE STATEMENT: In this drug-drug interaction (DDI) study, probenecid was used as a tool to inhibit both glucuronidation and active renal secretion of fevipiprant. The combination of plasma and urine pharmacokinetic data from this study with available data allowed the development of a quantitative scheme to describe the fate of fevipiprant in the body, illustrating why the DDI effect on fevipiprant is weak-to-moderate even if a perpetrator drug inhibits several elimination pathways.

In vitro and in vivo metabolism of a novel chymase inhibitor, SUN13834, and the predictability of human metabolism using mice with humanized liver.

1. A novel oral chymase inhibitor, SUN13834, is under clinical development for the treatment of atopic dermatitis (AD). In this study, in vitro and in vivo metabolic profiles of SUN13834 were compared between severe combined immunodeficiency (SCID) mice, chimeric mice with humanized liver and humans. 2. In in vitro experiments using liver microsomes, predominant metabolites of SUN13834 were glucuronide (MG-1) in SCID mice and hydroxylated metabolite (M-3) in chimeric mice and humans. 3. After a single oral dose of [(14)C]SUN13834 to SCID and chimeric mice, glucuronidation was the major metabolic pathway in SCID mice, while the parent compound, ring opening form (M-5), O-demethylated form of M-5 (M-6) and glucuronidation of M-6 (M-6G) were detected at higher levels in chimeric mice compared to SCID mice. 4. When AD patients were orally treated using SUN13834 for 28 days, the parent compound had the highest concentration in plasma, and M-6, M-6G, M-5 and MG-1 were identified as major metabolites. 5. This is the first report of SUN13834 metabolic information in human. In addition, based on similarities in metabolic profiles between chimeric mice and humans, it was concluded that chimeric mice are useful for predicting SUN13834 metabolism in humans during early stages of drug development.

Development of a dry powder inhaler, the Ultrahaler, containing triamcinolone acetonide using in vitro-in vivo relationships.

Triamcinolone acetonide (TAA) is safe and effective corticosteroid that is marketed as an MDI (metered dose inhaler) (Azmacort) for the treatment of asthma. A novel dry powder inhaler (DPI), the Ultrahaler, has been developed to deliver Azmacort as another alternative to provide non-CFC formulation for the asthmatic patients. The Ultrahaler is breath actuated and, unlike MDI, does not require coordination of inhalation with the actuation of the device. However, with the Ultrahaler device, like any dry powder inhalation device, the challenge was the on-target and uniform delivery of the drug at the site of action (lungs) with different dose strengths. Due to the complexities of oral inhaled formulations and the topical nature of drug delivery to the lung for efficacy, the reformulation requires careful consideration and support throughout their development, using a combination of in vitro and in vivo studies. This paper describes in vitro studies and two clinical pharmacokinetic studies conducted in a sequence that helped to establish optimum doses for the Ultrahaler. In vitro data were used to guide the initial selection of doses that were then compared in vivo using a pharmacokinetic study with a charcoal block. The in vitro tests included quantifying the target-delivered dose, dose uniformity throughout the life of the device, and the particle size distribution. Particle size distribution was measured using multistage liquid impinger (MSLI) or the Andersen Cascade Impactor (ACI). For in vitro testing, TAA was measured by HPLC methods. Based on the preliminary in vitro data for the respirable fraction, dose strengths with an MDI and the Ultrahaler for the first study were determined. The in vivo assessment consisted of a four-way crossover study following oral inhalation using both MDI (75 and 225 microg/actuation, reference treatment) and comparable respirable doses in the DPI (130 and 360 microg/actuation) devices in healthy volunteers in the presence (lung deposition) and absence (lung and oropharynx deposition) of the charcoal block. Plasma TAA concentrations were determined using a radioimmunoassay (RIA) method. The in vitro data also showed dose proportionality with DPI formulation, and the doses delivered were within 13% of the target doses. A measure of dose uniformity, the relative standard deviation (%RSD) of dose, was less than 15%. Plasma TAA exposure of DPI formulations was compared with that of MDI formulations. Mean ratios (DPI/MDI) of the AUCinf were close to unity for the lower dose strength. However, for the higher dose strength, plasma exposure was higher with the Ultrahaler formulation as compared with the MDI formulation (mean AUCinf DPI/MDI ratios: 1.96). These differences seem to be due to less than proportional increases in the MDI formulation. Based on these results and using the higher dose strength of the MDI as the comparator, the new dose strengths of the Ultrahaler were chosen, ie, 100, 225, and 450 mug/actuation. Plasma TAA concentrations were measured by LC/MS/MS methods. The mean TAA concentrations and AUCinf and Cmax values increased in a dose-proportional manner with an increase in dose for the DPI formulation. The pharmacokinetic parameters showed low variability (10%-33%). Fine particle mass (in vitro testing) and TAA exposure in plasma following DPI administration were compared. Fine particle performance in vitro related well with in vivo pharmacokinetic performance (R=AUCinf-0.9998, Cmax-0.9956). In conclusion, in vitro and in vivo data were in agreement and good control over the target-dose delivery and dose proportionality could be achieved in the early stages of the development of the Ultrahaler device and were critical in guiding and ensuring the success of the reformulation efforts for Azmacort.

Semen quality of industrial workers occupationally exposed to chromium.

A total of sixty-one subjects occupationally exposed to chromium in an industry which manufactures chromium sulphate and fifteen control subjects from a nearby industry which does not manufacture any chromium related compounds were studied. The history of each subject was recorded on pre-designed form through interview and a routine medical examination was carried out. Blood samples (5-6 ml) were collected for the estimation of chromium and semen samples were collected for semen analysis and the determination of copper and zinc levels in the seminal plasma. Clinical examination revealed nasal perforation in 10 subjects (out of 61) in the exposed group as compared to none in the control group. A significantly higher level of chromium was observed in the blood of the exposed workers as compared to the control. The concentration of zinc in seminal plasma was lower while the level of copper was higher in the exposed group as compared to the control. However, these changes were not statistically significant. Statistically significant higher numbers of morphologically abnormal sperms were noticed in the exposed group with respect to the control. Further analysis of the data indicated that about 53% of the exposed subjects showed less than 30% normal forms as compared to 10% in control subjects. However, no significant alterations in semen volume, liquefaction time, mean pH value, sperm viability, concentration or motility, were noticed between chromium exposed and unexposed workers. The data also indicates that exposure to chromium has some effect on human sperm as a significant positive correlation (r=0.301) was observed between percentages of abnormal sperm morphology and blood chromium levels (p=0.016) after pooling all the data of the control and exposure groups.

Pharmacokinetics, pharmacodynamics, and safety of a lipid-lowering adenosine A1 agonist, RPR749, in healthy subjects.

RPR749 and its methylated metabolite are orally active and selective adenosine A(1) agonists that can inhibit lipolysis and lower plasma triglyceride levels in a variety of animal models. RPR749 also appears to lower free fatty acid (FFA) and insulin levels and may have additional lipid-modifying effects. This double-blind, single increasing-dose, placebo-controlled, parallel group, randomized study, the first done in humans, evaluated the safety, pharmacokinetics, and pharmacodynamics (effect on FFA) after a single oral dose of up to 200 mg RPR749 or placebo. Six parallel groups of 8 healthy men (6 active and 2 placebo/group) were enrolled in the study. Plasma samples were collected for up to 72 hours post-dose. RPR749 and its metabolite RPR772 concentrations were measured by a validated LC/MS/MS method with a minimal quantifiable limit of 1 ng/mL. RPR749 was safe and well tolerated as a single oral dose up to 200 mg. The mean plasma concentrations of RPR749 were approximately 30-fold higher than the mean RPR772 plasma concentrations. The mean terminal half-life (t(1/2)) of RPR749 and RPR772 were similar (approximately 16.4 hours). Mean values for serum insulin, triglycerides, glycerol, and blood glucose remained within normal ranges. Mean FFA concentrations in serum decreased in all treatment groups with the maximal decrease in the 200-mg dose group. In conclusion, RPR749 has the ability to reduce circulating levels of FFA that can be related to plasma RPR749 concentrations and thus possesses pharmacological properties that may be beneficial in treating coronary artery diseases and hyperlipidemia.

Estimating mass balance for inhaled drugs in humans: an example with a VLA-4 antagonist, IVL745.

IVL745 is an inhaled VLA-4 antagonist developed for the treatment of asthma. Following inhalation (Inh), a fraction of the drug is deposited in the oropharynx, and the rest is deposited in the lungs. For inhaled drugs, it is technically and ethically difficult to formulate and administer radiolabeled drugs. Hence, if the drug is metabolically stable in the lungs, mass balance and metabolism of inhaled drugs, such as IVL745, can be determined by administering radiolabeled intravenous (IV) and oral drugs and by comparing with the data following Inh administration. The study was a three-period crossover design in 6 healthy subjects to evaluate the absorption, distribution, metabolism, and elimination following IV and oral administration of (14)C-IVL745 (4 mg/50 microCi) and inhaled (10-mg) dose. Serial sampling of blood and excreta was performed maximally up to 168 hours postdose. Plasma IVL745 concentrations were determined using a liquid chromatography tandem mass spectrometry (LC/MS/MS) method with a minimum quantifiable limit of 10 pg/mL. Overall, the drug was safe and well tolerated. The recovery of the radioactive dose varied from 94.8% to 117% for both IV and oral administration. Following IV administration, 90.2% of the radioactive dose was recovered in the feces, suggesting extensive biliary excretion of the drug. After oral administration, 99.7% of the radioactivity was recovered in the feces, and no radioactivity was detected in plasma, suggesting lack of absorption of the drug. Negligible (14)C-radioactivity concentrations were observed in the red blood cell fractions. The mean t(1/2) values were 1.6, 1.5, and 4.4 hours following IV, oral, and Inh administration, respectively. The oral bioavailability of IVL745 was low (< 2%), and the inhaled bioavailability was 26%. The volume of distribution at steady state (V(ss)) was low (19.0 L). The predicted blood clearance of IVL745 was 86 L/h, which was comparable to the commonly used liver blood flow value of 90 L/h. Only a minor fraction of the dose was excreted in the urine with low to moderate renal clearance. The parent drug accounted for 77% to 89% of the dosed radioactivity in excreta. Two major metabolites observed in excreta were mono-o-desmethyl IVL745 and di-o-desmethyl IVL745. The data showed that the drug had negligible oral bioavailability, low oral absorption, 26% inhaled bioavailability, low extent of metabolism, high biliary excretion, and low renal clearance. This knowledge may aid in the prediction of potentially relevant drug-drug interactions and dosing adjustments in high-risk populations for IVL745.

Pharmacoscintigraphic comparison of HMR 1031, a VLA-4 antagonist, in healthy volunteers following delivery via a nebulizer and a dry powder inhaler.

A pharmacoscintigraphic study was conducted to compare the dose deposition of HMR 1031 from the existing nebulizer formulation and the new Ultrahaler device to help determine the doses for future phase 2 trials. This was a single-dose, open-label, randomized, two-way crossover study in which HMR 1031 (3 mg) was delivered by the Ultrahaler and the Pari LC Star nebulizer to 12 healthy male subjects. For both treatments, the formulations were radiolabeled with technetium-99m pertechnetate such that a maximum of 10 MBq was delivered on each study day. Scintigraphic images were acquired immediately after dosing to estimate the percentage of the dose delivered to the lungs and oropharynx. Serial plasma samples were collected up to 12 hours post-dose on each occasion and analyzed for HMR 1031 by a LC/MS/MS method with a lower limit of quantitation of 10 pg/mL (0.01 ng/mL). Pharmacokinetic parameters were calculated for HMR 1031 using noncompartmental methods. No serious adverse events were reported. The systemic absorption of HMR 1031 following inhalation administration was relatively rapid, with median T(max) values of 0.5 hours and 1.0 hours post-dose after administration via Ultrahaler and nebulizer, respectively. The mean plasma AUC(0-12) (Ultrahaler, 15.8 ng*h/mL; nebulizer, 11.1 ng*h/mL) and C(max) (Ultrahaler, 4.96 ng/mL; nebulizer, 2.28 ng/mL) values were approximately 42% and 118% higher for the Ultrahaler compared with the nebulizer. The mean terminal half-life of HMR 1031 was similar after administration from both devices (2.91 and 3.18 hours). Based on the scintigraphic data, the lung deposition of HMR 1031 after administration by Ultrahaler (24.6% of the administered dose) was approximately 37% higher compared with the lung deposition from the nebulizer (18.0% of the administered dose). This observation was in agreement with the relative difference in the plasma AUC values achieved after administration of the two formulations. The in vivo results based on the scintigraphic data were also comparable with those from in vitro studies for the Ultrahaler. Based on the ratio of the dose delivered by both the formulations, the required doses for the future Ultrahaler formulation can be predicted.

Effect of food on pharmacokinetics of an inhaled drug: a case study with a VLA-4 antagonist, HMR1031.

HMR1031 is a potent and specific antagonist of the integrin VLA-4 (alpha4beta1) binding to vascular cell adhesion molecule-1 (VCAM-1) and fibronectin. HMR1031 is an inhaled drug being developed for the treatment of asthma using an Ultrahaler dry-powder inhalation device. A pharmacoscintigraphic study of HMR1031 suggests a lung deposition of approximately 25% and gastrointestinal tract deposition of approximately 75%. Since oral absorption may be contributing to systemic plasma concentrations, the effect of food on HMR1031 was assessed. This was a single-dose (3 mg), open-label, randomized, two-way crossover (fasted vs. fed) study in 8 healthy male subjects. Blood samples were collected at predose and up to 24 hours postdose. Plasma concentrations were determined by the LC/MS/MS method. HMR1031 was rapidly absorbed, with median tmax values of 1.0 and 0.75 hours under fasted and fed conditions, respectively. Under fasted conditions, mean AUCinfinity and Cmax values were 16.4 ng x h/mL and 4.56 ng/mL, respectively. Under fed conditions, mean AUCinfinity and Cmax values decreased to 11.7 ng x h/mL and 2.81 ng/mL, respectively. The mean terminal elimination half-life (t1/2) for both treatment groups was similar (2.7 h). HMR1031 population estimates of the apparent clearance, apparent volume of distribution, and absorption rate were 225 L/h (4.1% coefficient of variation [CV]), 44.5 L (26% CV), and 0.340 h-1 (7.0% CV), respectively. Food is a significant covariate on clearance. These data suggest that food unexpectedly decreases the systemic exposure of inhaled HMR1031 by approximately 30%, probably due to increased liver blood flow and increased biliary excretion. This decrease in systemic exposure is unlikely to affect the topical effect of the drug but may result in increased variability in plasma pharmacokinetics. The disposition and food effect of HMR1031 can be described using mixed-effect modeling.

Mass balance study of [14C]M100240, a dual angiotensin-converting enzyme/neutral endopeptidase inhibitor, in healthy male subjects.

[4S-[4alpha,7alpha(R*),12bbeta]]-7[[2-(acetylthio)-1-oxo-3-phenylpropyl]amino]-1,2,3,4,6,7,8,12b-octahydro-6-oxo-pyrido[2,1-a][2]benzazepine-4-carboxylic acid (M100240) is an acetate thioester of MDL 100,173-a dual angiotensin-converting enzyme/neutral endopeptidase inhibitor currently in phase II development. The mass balance of [(14)C]M100240 was assessed following oral administration of [(14)C]M100240. Healthy male subjects were given a single 25-mg dose of [(14)C]M100240 (50 microCi) as an oral solution under fasting conditions. Blood samples and excreta were collected postdose. (14)C-radioactivity was measured by liquid scintillation counting. Plasma concentrations of M100240 and MDL 100,173 were determined by LC/MS/MS methods. Pharmacokinetic parameters were calculated. About 98% of the total radioactive dose was recovered within 7 days of oral administration, with most of the radioactivity recovered within 72 hours. Of the recovered radioactive dose, 49.4% and 48.5% were recovered in the urine and feces, respectively. Unchanged M100240 and MDL 100,173 were not detected in the excreta. On average, 76% of the total radioactivity in the blood was associated with the plasma fraction. M100240 accounted for less than 0.06% of the (14)C-radioactivity in plasma and MDL 100,173 accounted for 15.8% (AUC( infinity )) of (14)C-radioactivity in plasma after oral dosing. These data suggest that the drug was absorbed but rapidly converted to its metabolites either presystemically or postsystemically. Up to 78% of the total radioactivity was identified as MDL 100,173. The apparent terminal elimination half-life of MDL 100,173 was longer than that of (14)C-radioactivity, attributable to assay sensitivity and the saturable binding phenomenon commonly associated with angiotensin-converting enzyme inhibitors. M100240 undergoes extensive metabolism in humans, and its metabolites are excreted relatively equally in feces and urine.