Pharmacokinetics, metabolism and excretion of an inhibitor of inducible nitric oxide synthase, L-NIL-TA, in dog

1. The pharmacokinetics, metabolism and excretion of L-NIL-TA, an inducible nitric oxide synthase inhibitor, were investigated in dog. 2. The dose of [14C]L-NIL-TA was rapidly absorbed and distributed after oral and intravenous administration (5 mg kg-1), with Cmax of radioactivity of 6.45-7.07 microg equivalents g-1 occurring at 0.33-0.39-h after dosing. After oral and intravenous administration, radioactivity levels in plasma then declined with a half-life of 63.1 and 80.6-h, respectively. 3. Seven days after oral and intravenous administrations, 46.4 and 51.5% of the radioactive dose were recovered in urine, 4.59 and 2.75% were recovered in faeces, and 22.4 and 22.4% were recovered in expired air, respectively. The large percentages of radioactive dose recovered in urine and expired air indicate that [14C]L-NIL-TA was well absorbed in dogs and the radioactive dose was cleared mainly through renal elimination. The mean total recovery of radioactivity over 7 days was approximately 80%. 4. Biotransformation of L-NIL-TA occurred primarily by hydrolysis of the 5-aminotetrazole group to form the active drug L-N6-(1-iminoethyl)lysine (NIL or M3), which was further oxidized to the 2-keto acid (M5), the 2-hydroxyl acid (M1), an unidentified metabolite (M2) and carbon dioxide. The major excreted products in urine were M1 and M2, representing 22.2 and 21.2% of the dose, respectively.     

Pharmacokinetics,metabolism, and excretion of nefopam,a dual reuptake inhibitor in healthy male volunteers

1.?The disposition of nefopam, a serotonin–norepinephrine reuptake inhibitor, was characterized in eight healthy male volunteers following a single oral dose of 75?mg [¹⁴C]-nefopam (100 μCi). Blood, urine, and feces were sampled for 168 h post-dose.

2.?Mean (±?SD) maximum blood and plasma radioactivity concentrations were 359?±?34.2 and 638?±?64.7 ngEq free base/g, respectively, at 2 h post-dose. Recovery of radioactive dose was complete (mean 92.6%); a mean of 79.3% and 13.4% of the dose was recovered in urine and feces, respectively.

3.?Three main radioactive peaks were observed in plasma (metabolites M2 A-D, M61, and M63). Intact [¹⁴C]-nefopam was less than 5% of the total radioactivity in plasma. In urine, the major metabolites were M63, M2 A-D, and M51 which accounted for 22.9%, 9.8%, and 8.1% of the dose, respectively. An unknown entity, M55, was the major metabolite in feces (4.6% of dose). Excretion of unchanged [¹⁴C]-nefopam was minimal.     

Biotransformation and mass balance of faldaprevir,a hepatitis C NS3/NS4 protease inhibitor in rats

Abstract

1.?The metabolism, pharmacokinetics, excretion and tissue distribution of a hepatitis C NS3/NS4 protease inhibitor, faldaprevir, were studied in rats following a single 2?mg/kg intravenous or 10?mg/kg oral administration of [¹⁴C]-faldaprevir.

2.?Following intravenous dosing, the terminal elimination t_1/2 of plasma radioactivity was 1.75?h (males) and 1.74?h (females). Corresponding AUC_0–∞, CL and V_ss were 1920 and 1900?ngEq?·?h/mL, 18.3 and 17.7?mL/min/kg and 2.32 and 2.12?mL/kg for males and females, respectively.

3.?After oral dosing, t_1/2 and AUC_0–∞ for plasma radioactivity were 1.67 and 1.77?h and 11?300 and 17?900 ngEq?·?h/mL for males and females, respectively.

4.?In intact rats, ≥90.17% dose was recovered in feces and only ≤1.08% dose was recovered in urine for both iv and oral doses. In bile cannulated rats, 54.95, 34.32 and 0.27% dose was recovered in feces, bile and urine, respectively.

5.?Glucuronidation plays a major role in the metabolism of faldaprevir with minimal Phase I metabolism.

6.?Radioactivity was rapidly distributed into tissues after the oral dose with peak concentrations of radioactivity in most tissues at 6?h post-dose. The highest levels of radioactivity were observed in liver, lung, kidney, small intestine and adrenal gland.     

Absorption,metabolism and excretion of darexaban (YM150), a new direct factor Xa inhibitor in humans

1.?The absorption, metabolism and excretion of darexaban (YM150), a novel oral direct factor Xa inhibitor, were investigated after a single oral administration of [¹⁴C]darexaban maleate at a dose of 60?mg in healthy male human subjects.

2.?[¹⁴C]Darexaban was rapidly absorbed, with both blood and plasma concentrations peaking at approximately 0.75?h post-dose. Plasma concentrations of darexaban glucuronide (M1), the pharmacological activity of which is equipotent to darexaban in vitro, also peaked at approximately 0.75?h.

3.?Similar amounts of dosed radioactivity were excreted via faeces (51.9%) and urine (46.4%) by 168?h post-dose, suggesting that at least approximately half of the administered dose is absorbed from the gastrointestinal tract.

4.?M1 was the major drug-related component in plasma and urine, accounting for up to 95.8% of radioactivity in plasma. The N-oxides of M1, a mixture of two diastereomers designated as M2 and M3, were also present in plasma and urine, accounting for up to 13.2% of radioactivity in plasma. In faeces, darexaban was the major drug-related component, and N-demethyl darexaban (M5) was detected as a minor metabolite.

5.?These findings suggested that, following oral administration of darexaban in humans, M1 is quickly formed during first-pass metabolism via UDP-glucuronosyltransferases, exerting its pharmacological activity in blood before being excreted into urine and faeces.     

Disposition and metabolism of TAK-438 (vonoprazan fumarate), a novel potassium-competitive acid blocker,in rats and dogs

1.?Following oral administration of [¹⁴C]TAK-438, the radioactivity was rapidly absorbed in rats and dogs. The apparent absorption of the radioactivity was high in both species.

2.?After oral administration of [¹⁴C]TAK-438 to rats, the radioactivity in most tissues reached the maximum at 1-hour post-dose. By 168-hour post-dose, the concentrations of the radioactivity were at very low levels in nearly all the tissues. In addition, TAK-438F was the major component in the stomach, whereas TAK-438F was the minor component in the plasma and other tissues. High accumulation of TAK-438F in the stomach was observed after oral and intravenous administration.

3.?TAK-438F was a minor component in the plasma and excreta in both species. Its oxidative metabolite (M-I) and the glucuronide of a secondary metabolite formed by non-oxidative metabolism of M-I (M-II-G) were the major components in the rat and dog plasma, respectively. The glucuronide of M-I (M-I-G) and M-II-G were the major components in the rat bile and dog urine, respectively, and most components in feces were other unidentified metabolites.

4.?The administered radioactive dose was almost completely recovered. The major route of excretion of the drug-derived radioactivity was via the feces in rats and urine in dogs.     

Pharmacokinetics and metabolism of [14C]anagliptin,a novel dipeptidyl peptidase-4 inhibitor,in humans

1.?The disposition of anagliptin, an orally active, highly selective dipeptidyl peptidase-4 inhibitor, was investigated after a single oral dose of 100 mg/1.92 MBq [¹⁴C]anagliptin to six healthy men. Almost all the dose (98.2%) was recovered within 168 h: 73.2% in urine and 25.0% in faeces.

2.?Anagliptin was rapidly absorbed, with peak plasma concentrations of unchanged drug attained at a mean time of 1.8-h postdose. Mean fraction of the dose absorbed was >73%. Unchanged drug and a carboxylate metabolite (M1) were the major components in plasma, accounting for 66.0 and 23.4% of total plasma radioactivity area under the curve, respectively.

3.?Anagliptin was incompletely metabolized, with about 50% dose eliminated as unchanged drug (46.6% in urine and 4.1% in faeces). Metabolism to M1 accounted for 29.2% of the dose. No other metabolite accounted for >1% dose in excreta or yielded measurable systemic exposure. Terminal half-life of anagliptin and M1 was 4.37 and 9.88 h, respectively. Renal clearance of unbound anagliptin and unbound M1 far exceeded glomerular filtration rate, indicating active renal elimination: that might reflect the fact that anagliptin may be a substrate of OAT1, OAT3, MDR1 and MRP2, and M1 a substrate of OAT3, BCRP, MRP2 and MRP4.     

Pharmacokinetics,metabolism and excretion of [14C]-lanicemine (AZD6765), a novel low-trapping N-methyl-d-aspartic acid receptor channel blocker,in healthy subjects

Abstract

1.?(1S)-1-phenyl-2-(pyridin-2-yl)ethanamine (lanicemine; AZD6765) is a low-trapping N-methyl-d-aspartate (NMDA) channel blocker that has been studied as an adjunctive treatment in major depressive disorder. The metabolism and disposition of lanicemine was determined in six healthy male subjects after a single intravenous infusion dose of 150?mg [¹⁴C]-lanicemine.

2.?Blood, urine and feces were collected from all subjects. The ratios of C_max and AUC_(0–∞) of lanicemine to plasma total radioactivity were 84 and 66%, respectively, indicating that lanicemine was the major circulating component with T_1/2 at 16?h. The plasma clearance of lanicemine was 8.3?L/h, revealing that lanicemine is a low-clearance compound. The mean recovery of radioactivity from urine was 93.8% of radioactive dose.

3.?In urine samples, 10 metabolites of lanicemine were identified. Among which, an O-glucuronide conjugate (M1) was the most abundant metabolite (～11% of the dose in excreta). In plasma, the circulatory metabolites were identified as a para-hydroxylated metabolite (M1), an O-glucuronide (M2), an N-carbamoyl glucuronide (M3) and an N-acetylated metabolite (M6). The average amount of each of metabolite was less than 4% of total radioactivity detected in plasma or urine.

4.?In conclusion, lanicemine is a low-clearance compound. The unchanged drug and metabolites are predominantly eliminated via urinary excretion.     

Absorption,distribution, metabolism and excretion (ADME) of the ALK inhibitor alectinib: results from an absolute bioavailability and mass balance study in healthy subjects

1.?Alectinib is a highly selective, central nervous system-active small molecule anaplastic lymphoma kinase inhibitor.

2.?The absolute bioavailability, metabolism, excretion and pharmacokinetics of alectinib were studied in a two-period single-sequence crossover study. A 50?μg radiolabelled intravenous microdose of alectinib was co-administered with a single 600?mg oral dose of alectinib in the first period, and a single 600?mg/67?μCi oral dose of radiolabelled alectinib was administered in the second period to six healthy male subjects.

3.?The absolute bioavailability of alectinib was moderate at 36.9%. Geometric mean clearance was 34.5?L/h, volume of distribution was 475?L and the hepatic extraction ratio was low (0.14).

4.?Near-complete recovery of administered radioactivity was achieved within 168?h post-dose (98.2%) with excretion predominantly in faeces (97.8%) and negligible excretion in urine (0.456%). Alectinib and its major active metabolite, M4, were the main components in plasma, accounting for 76% of total plasma radioactivity. In faeces, 84% of dose was excreted as unchanged alectinib with metabolites M4, M1a/b and M6 contributing to 5.8%, 7.2% and 0.2% of dose, respectively.

5.?This novel study design characterised the full absorption, distribution, metabolism and excretion properties in each subject, providing insight into alectinib absorption and disposition in humans.     

The biological fate of decabromodiphenyl ethane following oral,dermal or intravenous administration

1.?It was important to investigate the disposition of decabromodiphenyl ethane (DBDPE) based on concerns over its structural similarities to decabromodiphenyl ether (decaBDE), high potential for environmental persistence and bioaccumulation, and high production volume.

2.?In the present study, female Sprague Dawley rats were administered a single dose of [¹⁴C]-DBDPE by oral, topical or IV routes. Another set of rats were administered 10 daily oral doses of [¹⁴C]-DBDPE. Male B6C3F1/Tac mice were administered a single oral dose.

3.?DBDPE was poorly absorbed following oral dosing, with 95% of administered [¹⁴C]-radioactivity recovered in the feces unchanged, 1% recovered in the urine and less than 3% in the tissues at 72?h. DBDPE excretion was similar in male mice and female rats. Accumulation of [¹⁴C]-DBDPE was observed in liver and the adrenal gland after 10 daily oral doses to rats.

4.?Rat and human skin were used to assess potential dermal uptake of DBDPE. The dermis was a depot for dermally applied DBDPE; conservative estimates predict ～14?±?8% of DBDPE may be absorbed into human skin in vivo; ～7?±?4% of the parent chemical is expected to reach systemic circulation following continuous exposure (24?h).

5.?Following intravenous administration, ～70% of the dose remained in tissues after 72?h, with the highest concentrations found in lung (1223?±?723?pmol-eq/g), spleen (1096?±?369?pmol-eq/g) and liver (366?±?98?pmol-eq/g); 5?±?1% of the dose was recovered in urine and 26?±?4% in the feces.     

Pharmacokinetics and metabolite profiling of fimasartan,a novel antihypertensive agent,in rats

Abstract

1.?The objectives of this study were to evaluate the pharmacokinetics and metabolism of fimasartan in rats.

2.?Unlabeled fimasartan or radiolabeled [¹⁴C]fimasartan was dosed by intravenous injection or oral administration to rats. Concentrations of unlabeled fimasartan in the biological samples were determined by a validated LC/MS/MS assay. Total radioactivity was quantified by liquid scintillation counting and the radioactivity associated with the metabolites was analyzed by using the radiochemical detector. Metabolite identification was conducted by product ion scanning using LC/MS/MS.

3.?After oral administration of [¹⁴C]fimasartan, total radioactivity was found primarily in feces. In bile duct cannulated rats, 58.8?±?14.4% of the radioactive dose was excreted via bile after oral dosing. Major metabolites of fimasartan including the active metabolite, desulfo-fimasartan, were identified, yet none represented more than 7.2% of the exposure of the parent drug. Fimasartan was rapidly and extensively absorbed and had an oral bioavailability of 32.7–49.6% in rats. Fimasartan plasma concentrations showed a multi-exponential decline after oral administration. Double peaks and extended terminal half-life were observed, which was likely caused by enterohepatic recirculation.

4.?These results provide better understanding on the pharmacokinetics of fimasartan and may aid further development of fimasartan analogs.     

Absorption,metabolism and excretion of [14C]omarigliptin,a once-weekly DPP-4 inhibitor,in humans

1.?Omarigliptin (MARIZEV®) is a once-weekly DPP-4 inhibitor approved in Japan for the treatment of type 2 diabetes. The objective of this study was to investigate the absorption, metabolism and excretion of omarigliptin in humans.

2.?Six healthy subjects received a single oral dose of 25?mg (2.1?μCi) [^14?C]omarigliptin. Blood, plasma, urine and fecal samples were collected at various intervals for up to 20?days post-dose. Radioactivity levels in excreta and plasma/blood samples were determined by accelerator mass spectrometry (AMS).

3.?[^14?C]Omarigliptin was rapidly absorbed, with peak plasma concentrations observed at 0.5–2?h post-dose. The majority of the radioactivity was recovered in urine (～74.4% of the dose), with less recovered in feces (～3.4%), suggesting the compound was well absorbed.

4.?Omarigliptin was the major component in urine (～89% of the urinary radioactivity), indicating renal excretion of the unchanged drug as the primary clearance mechanism. Omarigliptin accounted for almost all the circulating radioactivity in plasma, with no major metabolites detected.

5.?The predominantly renal elimination pathway, combined with the fact that omarigliptin is not a substrate of key drug transporters, suggest omarigliptin is unlikely to be subject to pharmacokinetic drug-drug interactions with other commonly prescribed agents.     

Metabolic disposition of gefitinib,an epidermal growth factor receptor tyrosine kinase inhibitor,in rat,dog and man

1.?Following oral administration of [¹⁴C]-gefitinib to albino and pigmented rats, radioactivity was widely and rapidly distributed, with the highest levels being found in liver, kidney, lung and gastrointestinal tract, but with only low levels penetrating the brain. Levels of radioactivity persisted in melanin-containing tissues (pigmented eye and skin).

2.?Binding to plasma proteins was high (86–94%) across the range of species examined and was 91% in human plasma. Substantial binding occurred to both human serum albumin and α-1 acid glycoprotein.

3.?Following oral and intravenous administration of [¹⁴C]-gefitinib, excretion of radioactivity by rat, dog and human occurred predominantly via the bile into faeces, with <7% of the dose being eliminated in urine.

4.?In all three species, gefitinib was cleared primarily by metabolism. In rat, morpholine ring oxidation was the major route of metabolism, leading to the formation of M537194 and M608236 as the main biliary metabolites. Morpholine ring oxidation, together with production of M523595 by O-demethylation of the quinazoline moiety, were the predominant pathways in dog, with oxidative defluorination also occurring to a lesser degree.

5.?Pathways in healthy human volunteers were similar to dog, with O-demethylation and morpholine ring oxidation representing the major routes of metabolism.     

Disposition and pharmacokinetics of L-N6-(1-iminoethyl)lysine-5-tetrazole-amide, a selective iNOS inhibitor, in rats

The metabolism, pharmacokinetics, tissue distribution, and excretion of L-N6-(1-iminoethyl)lysine-5-tetrazole-amide (L-NIL-TA), a selective inducible NO synthase (iNOS) inhibitor, were investigated in rats. [(14)C]L-NIL-TA is extensively metabolized after either oral or IV administration with a minor amount (<1%) excreted as the prodrug. L-NIL-TA is metabolized via a single hydrolysis pathway to form the active drug, L-N6-(1-iminoethyl)lysine (L-NIL). The oxidative deamination of 2-amino group of L-NIL forms a 2-keto metabolite (M5), which further loses carbon dioxide to yield a carboxylic acid metabolite (M6). Acetylation of L-NIL and M5 resulted in the formations of metabolites M7 and M4, respectively. Complete recovery of the radioactive dose was achieved after either oral (91.2% in urine and 4.66% in feces) and IV (99.3% in urine and 5.11% in feces) administration. L-NIL-TA-related material was extensively distributed to the tissues, with the highest concentration of radioactivity being found in muscle. Maximal concentration of radioactivity was reached between 0.5 and 1 h post-dose in the majority of tissues, with the exception of muscle and skin where the maximal concentrations were achieved at 8 h post-dose.     

Absorption,distribution, metabolism and excretion of gemigliptin,a novel dipeptidyl peptidase IV inhibitor,in rats

Abstract

1.?The absorption, distribution, metabolism and excretion of a novel dipeptidyl peptidase IV inhibitor, gemigliptin, were examined following single oral administration of ¹⁴C-labeled gemigliptin to rats.

2.?The ¹⁴C-labeled gemigliptin was rapidly absorbed after oral administration, and its bioavailability was 95.2% (by total radioactivity). Distribution to specific tissues other than the digestive organs was not observed. Within 7 days after oral administration, 43.6% of the administered dose was excreted via urine and 41.2% was excreted via feces. Biliary excretion of the radioactivity was about 17.7% for the first 24?h. After oral administration of gemigliptin to rats, the in vivo metabolism of gemigliptin was investigated with bile, urine, feces, plasma and liver samples.

3.?The major metabolic pathway was hydroxylation, and the major circulating metabolites were a dehydrated metabolite (LC15-0516) and hydroxylated metabolites (LC15-0635 and LC15-0636).     

The biotransformation of [14C]lormetazepam in dogs,rabbits, rats and rhesus monkeys

1. After oral or intravenous doses (0.25?mg/kg) of [¹⁴C]lormetazepam to rats, most of the urinary radioactivity was associated with polar components and < 1% dose was excreted as unconjugated lormetazepam. About 30% of an oral dose was excreted in rat bile as a conjugate of lormetazepam and about 50% dose as polar metabolites. Plasma also contained mainly polar metabolites, and unchanged lormetazepam represented at most 10% of total plasma radioactivity after an oral dose.

2. Almost all the radioactivity in dog, rhesus monkey and rabbit urine, after oral or intravenous doses (0.5–0.7?mg/kg) of [¹⁴C]lormetazepam, was associated with conjugated material. In the dog there were only two major components, conjugates of lormetazepam and lorazepam (N-desmethyl-lormetazepam) which accounted for about 24% and 14% respectively of the oral dose in the 0–24?h urine. The same two conjugated components were also present in dog bile. Conjugated lormetazepam was the only major component in monkey and rabbit urine and accounted for about 60% dose in the 0–24?h urine of each species, while conjugated lorazepam accounted for only about 0.5% and 4% respectively.

3. Dog and monkey plasma contained mostly conjugated material after oral and intravenous doses (0.05–0.07?mg/kg of [¹⁴C]lormetazepam. Dog plasma after an oral dose contained conjugates of both lormetazepam and lorazepam with peak concn. at 1?h of 130 and 47 ng/ml respectively. Concn. of these conjugates in plasma declined with apparent terminal half-lives of about 17 and 27?h respectively after oral doses, and 13?h in both cases after intravenous doses. Conjugated lormetazepam was the only major component in monkey plasma representing a peak concn. of 180 ng/ml at 1?h after an oral dose, and declined with an apparent terminal half-life of about 11?h after oral or intravenous doses.

4. Lormetazepam crosses the placental ‘barrier’ of rabbits: its concn. in the foetus were similar to those in maternal plasma after intravenous doses.     

Metabolism,excretion and pharmacokinetics of [14C]glasdegib (PF-04449913) in healthy volunteers following oral administration

1.?The metabolism, excretion and pharmacokinetics of glasdegib (PF-04449913) were investigated following administration of a single oral dose of 100?mg/100 μCi [¹⁴C]glasdegib to six healthy male volunteers (NCT02110342).

2.?The peak concentrations of glasdegib (890.3?ng/mL) and total radioactivity (1043 ngEq/mL) occurred in plasma at 0.75?hours post-dose. The AUC_inf were 8469?ng.h/mL and 12,230 ngEq.h/mL respectively, for glasdegib and total radioactivity.

3.?Mean recovery of [¹⁴C]glasdegib-related radioactivity in excreta was 91% of the administered dose (49% in urine and 42% in feces). Glasdegib was the major circulating component accounting for 69% of the total radioactivity in plasma. An N-desmethyl metabolite and an N-glucuronide metabolite of glasdegib represented 8% and 7% of the circulating radioactivity, respectively. Glasdegib was the major excreted component in urine and feces, accounting for 17% and 20% of administered dose in the 0–120?hour pooled samples, respectively. Other metabolites with abundance <3% of the total circulating radioactivity or dose in plasma or excreta were hydroxyl metabolites, a desaturation metabolite, N-oxidation and O-glucuronide metabolites.

4.?Elimination of [¹⁴C]glasdegib-derived radioactivity was essentially complete, with similar contribution from urinary and fecal routes. Oxidative metabolism appears to play a significant role in the biotransformation of glasdegib.     

Disposition and pharmacokinetics of temozolomide in rat

1.?Temozolomide, an imidazotetrazine derivative, is a cytotoxic alkylating agent of broad-spectrum antitumour activity. The absorption, metabolism, distribution and excretion of temozolomide have been investigated in male and female Sprague–Dawley and Long–Evans rats following single oral or intravenous dose administration of 200?mg?m^?2 non-radiolabelled or ¹⁴C-radiolabelled temozolomide. The distribution of ¹⁴C-temozolomide was also evaluated by whole-body autoradiography in male Sprague–Dawley rats. Plasma concentrations of temozolomide and its active metabolite 3-methyl-(triazen-1-yl)imidazole-4-carboxamide (MTIC) were determined by high-performance liquid chromatography (HPLC) with ultraviolet detection. Plasma, urine and faeces were profiled by HPLC with radiochemical detection.

2.?Temozolomide was rapidly and extensively (>90%) absorbed and widely distributed in tissues. The distribution pattern of radioactivity was gender independent. Penetration into the brain following oral or intravenous administration was 35–39% based on the brain/plasma AUC ratio.

3.?Following intravenous or oral administration, temozolomide was primarily eliminated renally (75–85% of the dose) as either unchanged drug, a carboxylic acid analogue, AIC (a degradation product) and a highly polar unidentified peak. Biliary excretion was minimal (1.4–1.6%). The pharmacokinetics (oral versus intravenous) were similar and gender independent. The absolute oral availability was 96–100%. Temozolomide was rapidly eliminated (t_1/2 = 1.2?h) and converted to MTIC.

4.?Systemic exposure to MTIC was about 2% that of temozolomide. Overall, the disposition of temozolomide in rats was similar to that observed in humans.     

Disposition and urinary metabolic pattern of cabergoline,a potent dopaminergic agonist,in rat,monkey and man

1. The disposition and urinary metabolic pattern of ¹⁴C-cabergoline was studied in rat, monkey and man after oral administration of the labelled drug.

2. In all species radioactivity was mainly excreted in faeces, with urinary excretion accounting for 11, 13 and 22% of the dose in rat, monkey and man, respectively.

3. After oral treatment, biliary excretion of radioactivity in rat accounted for 19% of the dose within 24?h.

4. Unchanged drug in 0-24-h urine samples of rat, monkey and man amounted to 20, 9 and 10% of urinary radioactivity, respectively. In the 24-72-h urine samples of all species the relative percentage of unchanged drug increased compared with that measured in the 0-24-h urine.

5. The main metabolite was the acid derivative (FCE21589), which in 0-24-h urine samples of rat, monkey and man accounted for 30, 21 and 41% of urinary radioactivity, respectively.

6. Other metabolites identified in urine of all species resulted from hydrolysis of the urea moiety, the loss of the 3-dimethylaminopropyl group and the deallylation of the piperidine nitrogen.     

Disposition,metabolism and mass balance of delafloxacin in healthy human volunteers following intravenous administration

Abstract

1. The pharmacokinetics and disposition of delafloxacin was investigated following a single intravenous (300?mg, 100?µCi) dose to healthy male subjects.

2. Mean C_max, AUC_0–∞, T_max and t_1/2 values for delafloxacin were 8.98?µg/mL, 21.31?µg?h/mL, 1?h and 2.35?h, respectively, after intravenous dosing.

3. Radioactivity was predominantly excreted via the kidney with 66% of the radioactive dose recovered in the urine. Approximately 29% of the radioactivity was recovered in the faeces, giving an overall mean recovery of 94% administered radioactivity.

4. The predominant circulating components were identified as delafloxacin and a direct glucuronide conjugate of delafloxacin.     

Absorption,metabolism and excretion of cobimetinib,an oral MEK inhibitor,in rats and dogs

1.?The absorption, metabolism and excretion of cobimetinib, an allosteric inhibitor of MEK1/2, was characterized in mass balance studies following single oral administration of radiolabeled (¹⁴C) cobimetinib to Sprague–Dawley rats (30?mg/kg) and Beagle dogs (5?mg/kg).

2.?The oral dose of cobimetinib was well absorbed (81% and 71% in rats and dogs, respectively). The maximal plasma concentrations for cobimetinib and total radioactivity were reached at 2–3?h post-dose. Drug-derived radioactivity was fully recovered (～90% of the administered dose) with the majority eliminated in feces via biliary excretion (78% of the dose for rats and 65% for dogs). The recoveries were nearly complete after the first 48?h following dosing.

3.?The metabolic profiles indicated extensive metabolism of cobimetinib prior to its elimination. For rats, the predominant metabolic pathway was hydroxylation at the aromatic core. Lower exposures for cobimetinib and total radioactivity were observed in male rats compared with female rats, which was consistent to in vitro higher clearance of cobimetinib for male rats. For dogs, sequential oxidative reactions occurred at the aliphatic portion of the molecule. Though rat metabolism was well-predicted in vitro with liver microsomes, dog metabolism was not.

4.?Rats and dogs were exposed to the two major human circulating Phase II metabolites, which provided relevant metabolite safety assessment. In general, the extensive sequential oxidative metabolism in dogs, and not the aromatic hydroxylation in rats, was more indicative of the metabolism of cobimetinib in humans.