Metabolism and Excretion of Canagliflozin in Mice, Rats, Dogs, and Humans

Mamidi, Rao N. V. S.; Cuyckens, Filip; Chen, Jie; Scheers, Ellen; Kalamaridis, Dennis; Lin, Ronghui; Silva, Fernando; Sha, Sue; Evans, David C.; Kelley, Michael F.; Devineni, Damayanthi; Johnson, Mark D.; Lim, Heng Keang

doi:10.1124/dmd.113.056440

Cited by 57 publications

(87 citation statements)

References 16 publications

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“…A species difference was observed for canagliflozin regarding the abundance of metabolite formation. Metabolite A, the alcohol oxidation product, was the predominant metabolite in rat and also has been reported as a rodent-specific product (Mamidi et al, 2014), whereas the glucuronidation metabolite B was the most abundant in human ( Fig. 3A; Table 2).…”

Section: Resultsmentioning

confidence: 99%

“…Species difference in metabolite formation from canagliflozin was reported in the in vivo metabolite identification experiments. UGTmediated O-glucuronidation was the major clearance pathway in human, whereas in rats, oxidation and oxidation-plus-glucuronidation products were the predominant pathways, with the alcohol oxidation of metabolite A being most abundant (Mamidi et al, 2014). In humans, UGT1A9 and UGT2B4 are responsible for the formation of the two O-glucuronidation metabolites, respectively (Francke et al, 2015), and CYP3A4 contributes to the formation of a minor hydroxylation metabolite (Mamidi et al, 2014), which was not detected as one of the major metabolites in human or rat hepatocytes in the present study.…”

Section: Discussionmentioning

confidence: 99%

“…UGTmediated O-glucuronidation was the major clearance pathway in human, whereas in rats, oxidation and oxidation-plus-glucuronidation products were the predominant pathways, with the alcohol oxidation of metabolite A being most abundant (Mamidi et al, 2014). In humans, UGT1A9 and UGT2B4 are responsible for the formation of the two O-glucuronidation metabolites, respectively (Francke et al, 2015), and CYP3A4 contributes to the formation of a minor hydroxylation metabolite (Mamidi et al, 2014), which was not detected as one of the major metabolites in human or rat hepatocytes in the present study. In the substrate depletion assay, no difference in UGT-mediated glucuronidation between the two strains was observed despite significantly lower UGT activity in ZDF compared with SD rats when the UGT probe substrate 4-MU was used.…”

Section: Discussionmentioning

confidence: 99%

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Difference in the Pharmacokinetics and Hepatic Metabolism of Antidiabetic Drugs in Zucker Diabetic Fatty and Sprague-Dawley Rats

Zhou¹,

Rougée²,

Bedwell³

et al. 2016

Drug Metabolism and Disposition

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The Zucker diabetic fatty (ZDF) rat, an inbred strain of obese Zucker fatty rat, develops early onset of insulin resistance and displays hyperglycemia and hyperlipidemia. The phenotypic changes resemble human type 2 diabetes associated with obesity and therefore the strain is used as a pharmacological model for type 2 diabetes. The aim of the current study was to compare the pharmacokinetics and hepatic metabolism in male ZDF and Sprague-Dawley (SD) rats of five antidiabetic drugs that are known to be cleared via various mechanisms. Among the drugs examined, metformin, cleared through renal excretion, and rosiglitazone, metabolized by hepatic cytochrome P450 2C, did not exhibit differences in the plasma clearance in ZDF and SD rats. In contrast, glibenclamide, metabolized by hepatic CYP3A, canagliflozin, metabolized mainly by UDP-glucuronosyltransferases (UGT), and troglitazone, metabolized by sulfotransferase and UGT, exhibited significantly lower plasma clearance in ZDF than in SD rats after a single intravenous administration. To elucidate the mechanisms for the difference in the drug clearance, studies were performed to characterize the activity of hepatic drug-metabolizing enzymes using liver S9 fractions from the two strains. The results revealed that the activity for CYP3A and UGT was decreased in ZDF rats using the probe substrates, and decreased unbound intrinsic clearance in vitro for glibenclamide, canagliflozin, and troglitazone was consistent with lower plasma clearance in vivo. The difference in pharmacokinetics of these two strains may complicate pharmacokinetic/ pharmacodynamic correlations, given that ZDF is used as a pharmacological model, and SD rat as the pharmacokinetics and toxicology strain.

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Section: Resultsmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

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Difference in the Pharmacokinetics and Hepatic Metabolism of Antidiabetic Drugs in Zucker Diabetic Fatty and Sprague-Dawley Rats

Zhou¹,

Rougée²,

Bedwell³

et al. 2016

Drug Metabolism and Disposition

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“…2) [23]. The unchanged drug accounted for the major drug-related component in the plasma (canagliflozin: *57 %; metabolites: *43 %) in healthy participants [20].…”

Section: Metabolismmentioning

confidence: 99%

Clinical Pharmacokinetic, Pharmacodynamic, and Drug–Drug Interaction Profile of Canagliflozin, a Sodium-Glucose Co-transporter 2 Inhibitor

Devineni

Polidori

2015

Clin Pharmacokinet

Self Cite

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The sodium-glucose co-transporter 2 (SGLT2) inhibitors represent novel therapeutic approaches in the management of type 2 diabetes mellitus; they act on kidneys to decrease the renal threshold for glucose (RTG) and increase urinary glucose excretion (UGE). Canagliflozin is an orally active, reversible, selective SGLT2 inhibitor. Orally administered canagliflozin is rapidly absorbed achieving peak plasma concentrations in 1-2 h. Dose-proportional systemic exposure to canagliflozin has been observed over a wide dose range (50-1600 mg) with an oral bioavailability of 65 %. Canagliflozin is glucuronidated into two inactive metabolites, M7 and M5 by uridine diphosphate-glucuronosyltransferase (UGT) 1A9 and UGT2B4, respectively. Canagliflozin reaches steady state in 4 days, and there is minimal accumulation observed after multiple dosing. Approximately 60 % and 33 % of the administered dose is excreted in the feces and urine, respectively. The half-life of orally administered canagliflozin 100 or 300 mg in healthy participants is 10.6 and 13.1 h, respectively. No clinically relevant differences are observed in canagliflozin exposure with respect to age, race, sex, and body weight. The pharmacokinetics of canagliflozin remains unaffected by mild or moderate hepatic impairment. Systemic exposure to canagliflozin is increased in patients with renal impairment relative to those with normal renal function; however, the efficacy is reduced in patients with renal impairment owing to the reduced filtered glucose load. Canagliflozin did not show clinically relevant drug interactions with metformin, glyburide, simvastatin, warfarin, hydrochlorothiazide, oral contraceptives, probenecid, and cyclosporine, while co-administration with rifampin modestly reduced canagliflozin plasma concentrations and thus may necessitate an appropriate monitoring of glycemic control. Canagliflozin increases UGE and suppresses RTG in a dose-dependent manner, thereby lowering the plasma glucose levels and reducing the glycosylated hemoglobin levels through an insulin-independent mechanism of action. The 300-mg dose provides near-maximal effects on RTG throughout the full 24-h dosing interval, whereas the effect of the 100-mg dose on RTG is near-maximal for approximately 12 h and is modestly attenuated during the overnight period. The observed pharmacokinetic/pharmacodynamic profile of canagliflozin in patients with type 2 diabetes mellitus supports a once-daily dosing regimen.

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“…1), and available evidence indicates that glucuronidation of the glucoside moiety is the major metabolic pathway of both compounds in humans. CNF is glucuronidated at the 2-and 3-hydroxyl groups of the glucoside rings; the respective glucuronides are referred to as M5 and M7 (Mamidi et al, 2014). The urinary excretion of M5 and M7 in patients with type 2 diabetes ranges from 7 to 10% and 21 to 32% of the administered dose, respectively (Devineni et al, 2013).…”

Section: Introductionmentioning

confidence: 99%

Inhibition of Human UDP-Glucuronosyltransferase Enzymes by Canagliflozin and Dapagliflozin: Implications for Drug-Drug Interactions

et al. 2015

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Metabolism and Excretion of Canagliflozin in Mice, Rats, Dogs, and Humans

Cited by 57 publications

References 16 publications

Difference in the Pharmacokinetics and Hepatic Metabolism of Antidiabetic Drugs in Zucker Diabetic Fatty and Sprague-Dawley Rats

Difference in the Pharmacokinetics and Hepatic Metabolism of Antidiabetic Drugs in Zucker Diabetic Fatty and Sprague-Dawley Rats

Clinical Pharmacokinetic, Pharmacodynamic, and Drug–Drug Interaction Profile of Canagliflozin, a Sodium-Glucose Co-transporter 2 Inhibitor

Inhibition of Human UDP-Glucuronosyltransferase Enzymes by Canagliflozin and Dapagliflozin: Implications for Drug-Drug Interactions

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