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Topical 2% ketoconazole cream monotherapy significantly improves adult female acne: A double-blind, randomized placebo-controlled trial.
Chottawornsak, N, Chongpison, Y, Asawanonda, P, Kumtornrut, C
The Journal of dermatology. 2019;(12):1184-1189
Abstract
The emergence of bacterial resistance is a global crisis. Prolonged use of antibiotics especially in acne is one issue of concern among dermatologists. Ketoconazole (KTZ) cream, a topical antifungal with anti-inflammatory and antiandrogenic actions, can decrease lipase activity of Cutibacterium acnes in vitro. We evaluated the efficacy and safety of KTZ cream in mild adult female acne (AFA) by conducting a randomized, double-blind, placebo-controlled trial using KTZ 2% and placebo cream twice daily for 10 weeks. We assessed the improvement of clinical severity, measured by AFA score graded by investigators and participants, and the change of acne count. Forty-one participants enrolled in our study. The proportion of participants with acne improvement from baseline (42.9% vs 9.5%, P = 0.015) and the success rate (45.0% vs 14.3%, P = 0.043) in the KTZ group were significantly higher than that of the placebo group. The most common adverse events were dryness and itching. The percentage change of acne count decreased significantly compared with baseline but did not differ statistically between the two groups (P = 0.268). We concluded that the KTZ monotherapy showed a plausible effect in improving AFA with excellent safety profile. It should be considered as a viable option for mild AFA treatment.
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Physiological based pharmacokinetic modeling to estimate in vivo Ki of ketoconazole on renal P-gp using human drug-drug interaction study result of fesoterodine and ketoconazole.
Oishi, M, Takano, Y, Torita, Y, Malhotra, B, Chiba, K
Drug metabolism and pharmacokinetics. 2018;(1):90-95
Abstract
This study was conducted to estimate in vivo inhibition constant (Ki) of ketoconazole on renal P-glycoprotein (P-gp) using human drug-drug interaction (DDI) study result of fesoterodine and ketoconazole. Fesoterodine is a prodrug which is extensively hydrolyzed by non-specific esterases to the active metabolite 5-hydroxymethyl tolterodine (5-HMT). 5-HMT is then further metabolized via Cytochrome P450 (CYP) 2D6 and CYP3A4. It is reported that 5-HMT is a substrate of P-gp whereas fesoterodine is not. Renal clearance of 5-HMT is approximately two-times greater than renal glomerular filtration rate. This suggests the possibility that renal clearance of 5-HMT involves secretion by P-gp. Utilizing the available pharmacokinetic characteristics of fesoterodine and 5-HMT, we estimated in vivo Ki of ketoconazole on P-gp at kidney based on DDI study data using physiologically-based pharmacokinetic approach. The estimated in vivo Ki of ketoconazole for hepatic CYP3A4 (6.64 ng/mL) was consistent with the reported values. The in vivo Ki of ketoconazole for renal P-gp was successfully estimated as 2.27 ng/mL, which was notably lower than reported in vitro 50% inhibitory concentration (IC50) values ranged 223-2440 ng/mL due to different condition between in vitro and in vivo.
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Exploratory effects of a strong CYP3A inhibitor (ketoconazole), a strong CYP3A inducer (rifampicin), and concomitant ethanol on piragliatin pharmacokinetics and pharmacodynamics in type 2 diabetic patients.
Zhi, J, Zhai, S, Georgy, A, Liang, Z, Boldrin, M
Journal of clinical pharmacology. 2016;(5):548-54
Abstract
Piragliatin is a CYP3A substrate; its inactive metabolite M4, formed through cytosolic reductase, is reversibly metabolized back to piragliatin through CYP3A. The impact of concomitant CYP3A modifiers thus cannot be predicted. Drinking alcohol under fasting conditions is associated with a recognized glucose-lowering effect, which might be synergistic with piragliatin's hypoglycemic effect. Two exploratory studies were conducted to examine these potential interactions in type 2 diabetes (T2D) patients: 16 completed an open-label, sequential 2-way crossover, 2-arm (randomized to ketoconazole and rifampicin) CYP3A study; another 18 participated in a double-blind, placebo-controlled, randomized 3-way crossover ethanol study. Administration of piragliatin (100-mg single dose) resulted in a 32% Cmax and 44% area under the curve (AUC∞ ) increase in piragliatin exposure without affecting glucose AUC0-6h following ketoconazole (400 mg QD × 5 days); 30% Cmax and 72% AUC∞ decrease in piragliatin exposure with a 13% increase in glucose AUC0-6h following rifampicin (600 mg QD × 5 days); and, unexpectedly, a 32% Cmax and 23% AUC0-6h decrease (no change in AUC∞ ) in piragliatin exposure with a 13% increase in glucose AUC0-6h following alcohol (40-g single dose). In conclusion, a strong CYP3A modifier or concomitant alcohol could lead to a change in exposure to piragliatin with a potential alteration in glucose-lowering effect.
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Effects of CYP3A4 Inhibitors Ketoconazole and Verapamil and the CYP3A4 Inducer Rifampicin on the Pharmacokinetic Parameters of Fostamatinib: Results from In Vitro and Phase I Clinical Studies.
Martin, P, Gillen, M, Millson, D, Oliver, S, Brealey, C, Grossbard, EB, Baluom, M, Lau, D, Sweeny, D, Mant, T, et al
Drugs in R&D. 2016;(1):81-92
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Abstract
BACKGROUND Fostamatinib (R788) is a spleen tyrosine kinase (SYK) inhibitor. The active metabolite of fostamatinib, R406, is primarily metabolized by CYP3A4. OBJECTIVES The aim of this study was to characterize hepatic microsomal metabolism of R406 and confirm the role of CYP3A4 in R406 metabolism, determining whether co-administration of CYP3A4 inhibitors (ketoconazole, verapamil) or inducers (rifampicin) affects R406 pharmacokinetics. METHODS R406 stability was determined using human hepatic microsomes. The CYP450 isoforms responsible for R406 metabolism in humans were identified using expressed CYP450 isoforms and specific chemical inhibitors. The ketoconazole interaction study (double-blind, randomized, placebo-controlled, two-period crossover) involved fostamatinib administration (single 80-mg dose), alone and with ketoconazole (200 mg twice daily). The verapamil and rifampicin interaction studies (open-label, two-period, fixed-sequence) involved fostamatinib administration (single 150-mg dose), alone and with immediate-release verapamil (80 mg three times daily) or rifampicin (600 mg once daily). Standard pharmacokinetic parameters were calculated in all studies. RESULTS/DISCUSSION Hepatic microsomes showed time-dependent loss of R406 and formation of para-O-demethylated R406. Microsomal metabolism of R406 was markedly inhibited by CYP3A4 inhibitors and, in the expressed CYP450 studies, the rate of R406 disappearance was greatest with CYP3A4. In the clinical studies, co-administration of ketoconazole caused a 2-fold (CI 1.77-2.30) increase in R406 exposure. Verapamil increased R406 exposure (39% increase, CI 8-80), whereas rifampicin co-administration decreased exposure by 75% (CI 68-81). Fostamatinib was well tolerated. CONCLUSION The oxidative metabolism of R406 is predominantly catalyzed by CYP3A4. In clinical studies, exposure to R406 is affected by concomitant administration of CYP3A4 inducers/inhibitors. These findings should be taken into account when considering co-prescription of fostamatinib with such agents.
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Pharmacokinetic interaction between the CYP3A4 inhibitor ketoconazole and the hormone drospirenone in combination with ethinylestradiol or estradiol.
Wiesinger, H, Berse, M, Klein, S, Gschwend, S, Höchel, J, Zollmann, FS, Schütt, B
British journal of clinical pharmacology. 2015;(6):1399-410
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Abstract
AIMS: The present study was conducted to investigate the influence of the strong CYP3A4 inhibitor ketoconazole (KTZ) on the pharmacokinetics of drospirenone (DRSP) administered in combination with ethinylestradiol (EE) or estradiol (E2). METHODS This was a randomized, multicentre, open label, one way crossover, fixed sequence study with two parallel treatment arms. A group sequential design allowed terminating the study for futility after first study cohort. About 50 healthy young women were randomized 1 : 1 to 'DRSP/EE' or 'DRSP/E2'. Subjects in the 'DRSP/EE' group received DRSP 3 mg/EE 0.02 mg (YAZ®, Bayer) once daily for 21 to 28 days followed by DRSP 3 mg/EE 0.02 mg once daily plus KTZ 200 mg twice daily for 10 days. Subjects in the 'DRSP/E2' group received DRSP 3 mg/E2 1.5 mg (research combination) once daily for 21 to 28 days followed by DRSP 3 mg/E2 1.5 mg once daily plus KTZ 200 mg twice daily for 10 days. RESULTS Oral co-administration of DRSP/EE or DRSP/E2 and KTZ resulted in an increase in DRSP exposure (AUC(0,24 h)) in both treatment groups: DRSP/EE group: 2.68-fold DRSP increase (90% CI 2.44, 2.95); DRSP/E2 group: 2.30-fold DRSP increase (90% CI 2.08, 2.54). EE and estrone (metabolite of E2) exposures were increased ~1.4-fold whereas E2 exposure was largely unaffected by KTZ co-administration. CONCLUSIONS A moderate pharmacokinetic drug-drug interaction between DRSP and KTZ was demonstrated in this study. No relevant changes of medical concern were detected in the safety data collected in this study.
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Effect of axitinib on the QT interval in healthy volunteers.
Ruiz-Garcia, A, Houk, BE, Pithavala, YK, Toh, M, Sarapa, N, Tortorici, MA
Cancer chemotherapy and pharmacology. 2015;(3):619-28
Abstract
PURPOSE Axitinib is a potent and selective inhibitor of vascular endothelial growth factor receptors 1-3, approved for second-line treatment of advanced renal cell carcinoma (RCC). Preclinical studies did not indicate potential for axitinib-induced delayed cardiac repolarization. METHODS The effect of axitinib on corrected QT (QTc) prolongation was evaluated with one-stage concentration-QTc response modeling using data from a definitive randomized crossover QT phase I study in healthy volunteers administered one single 5-mg axitinib dose alone or in the presence of steady-state ketoconazole (400 mg once daily). RESULTS Axitinib and ketoconazole had opposite effects on heart rate: Axitinib lowered it, ketoconazole raised it. The final analysis showed a flat relationship between QTc and axitinib concentration (slope -0.0314 ms·mL/ng) for axitinib alone. Mean highest placebo-matched change from baseline in QTc was -3.0 [90 % confidence interval (CI) -5.4, -0.6] ms. At supratherapeutic axitinib exposures achieved with potent cytochrome P450 3A4/5 inhibition by ketoconazole, the model predicted mean QTc change of 6.5 (90 % CI 4.4-8.5) ms. The slope population mean estimate was -0.331 (95 % CI -0.860, 0.198) ms·mL/µg for ketoconazole alone and 0.0725 (0.0445-0.1005) ms·mL/ng for axitinib in the presence of ketoconazole. The results were then compared with those obtained based on more widely used Fridericia's, Bazett's, and study-specific correction methods. CONCLUSIONS Since axitinib plasma concentrations observed in this study exceeded the range of concentrations observed in patients with RCC at the highest approved clinical dose (10 mg twice daily), axitinib was not associated with clinically significant QTc prolongation in target populations.
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Effect of ketoconazole on lobeglitazone pharmacokinetics in Korean volunteers.
Sil Oh, E, Ok Kim, C, Kim, KH, Kim, YN, Kim, C, Lee, JI, Park, MS
Clinical therapeutics. 2014;(7):1064-71
Abstract
PURPOSE Lobeglitazone, a peroxisome proliferator-activated receptor-γ agonist, is metabolized primarily by the cytochrome P450 (CYP) 3A4 isoenzyme. Individuals concomitantly taking lobeglitazone and a CYP3A4 inhibitor may experience some adverse effects secondary to increased systemic exposure to lobeglitazone. To address such potential concern, we evaluated the effects of ketoconazole, a prototypic CYP3A4 inhibitor, on the pharmacokinetic (PK) properties and associated adverse effects of lobeglitazone. METHODS A PK drug-drug interaction study was conducted in healthy individuals between 20 and 45 years old in a randomized, open-label, 2-way crossover design. Even though the PK study was performed on a single dose of lobeglitazone, multiple ketoconazole doses were given to ensure that the full extent of inhibition of CYP3A4 was maintained during the PK sampling. All study participants received a single oral dose of lobeglitazone 0.5 mg with or without 9 oral 200-mg doses of ketoconazole pretreatment twice daily. The primary PK parameter end points (AUC and Cmax) were estimated using noncompartmental analysis, and the 90% CIs for the geometric mean ratios (ratio of lobeglitazone and ketoconazole to lobeglitazone alone) were investigated. Tolerability (adverse events, vital signs, ECG, and laboratory tests) was also assessed. FINDINGS A total of 24 Korean men (mean age, 26 years; age range, 20-32 years; mean weight, 68 kg; weight range, 59-81 kg) completed the study and were evaluable for lobeglitazone PK properties and tolerability. The mean (SD) Cmax values of lobeglitazone with and without ketoconazole were 49 (7) ng/mL and 48 (6) ng/mL at 1.5 and 1.0 hours after dosing, respectively. The mean (SD) AUC∞ values were 532 (117) ng·h/mL and 405 (110) ng·h/mL, respectively. Although the Cmax was not significantly affected, the geometric mean ratio for AUC∞ was increased by a point estimate of 1.33 (90% CI, 1.23-1.44). A single oral administration of lobeglitazone 0.5 mg with or without ketoconazole pretreatment did not produce any clinically significant adverse effects on vital signs, 12-lead ECG profiles, or laboratory tests. IMPLICATIONS The administration of lobeglitazone, 0.5 mg alone or in combination with multiple doses of ketoconazole, was generally well tolerated. The systemic exposure of lobeglitazone was increased to a modest extent by pretreatment with 9 twice-daily doses of ketoconazole. Clinicaltrials.gov identifier: NCT01330563.
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Pharmacokinetic interactions between the orexin receptor antagonist almorexant and the CYP3A4 inhibitors ketoconazole and diltiazem.
Dingemanse, J, Cruz, HG, Gehin, M, Hoever, P
Journal of pharmaceutical sciences. 2014;(5):1548-56
Abstract
Almorexant, a tetrahydroisoquinoline orexin receptor antagonist and first representative of a new class of compounds for the treatment of insomnia, is a substrate of the cytochrome P450 3A4 isoenzyme (CYP3A4). Two randomized two-way crossover studies were performed in healthy subjects investigating the pharmacokinetic interaction between almorexant and the CYP3A4 inhibitors ketoconazole and diltiazem. When administered as a single dose of 100 mg almorexant during steady state of ketoconazole (400 mg once daily for 14 days) or diltiazem treatment (300 mg once daily for 11 days), the exposure to almorexant was 10.5- and 3.5-fold, respectively, greater when compared with almorexant alone. Exposure to the phenol metabolites M3 and M8 increased in the presence of the CYP3A4 inhibitors, whereas that to M6 (dealkylated metabolite) decreased. Concomitant ketoconazole decreased formation of the dehydrogenated metabolite M5 and diltiazem increased concentrations of this metabolite. Higher almorexant exposure was associated with an increased incidence of typical almorexant-related adverse events such as fatigue (both studies) and somnolence (ketoconazole study only). The present results indicate that dose adaptation must be considered when almorexant would be coadministered with inhibitors of CYP3A4.
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Influence of CYP3A4 induction/inhibition on the pharmacokinetics of vilazodone in healthy subjects.
Boinpally, R, Gad, N, Gupta, S, Periclou, A
Clinical therapeutics. 2014;(11):1638-49
Abstract
PURPOSE Vilazodone is a serotonin reuptake inhibitor and 5-HT1A partial agonist approved for the treatment of major depressive disorder in adults. Vilazodone seems to be metabolized primarily by the cytochrome P-450 (CYP) 3A4 isozyme and non-CYP-mediated pathways; concomitant use of drugs that affect CYP3A4 activity could potentially alter systemic exposure to vilazodone. The present studies evaluated whether CYP3A4 inhibition (study 1) or induction (study 2) affected the pharmacokinetics of vilazodone. METHODS Participants were healthy adult volunteers. Study 1 was conducted in 2 parts and evaluated the pharmacokinetics of single-dose vilazodone administered with multiple-dose (200 mg once daily) ketoconazole, a CYP3A4 inhibitor. Part 1 was an open-label pharmacokinetic assessment of a single 5-mg vilazodone dose with or without ketoconazole. Part 2 was a randomized, double-blind, placebo-controlled, crossover study comparing vilazodone pharmacokinetics after a single 10-mg dose alone or co-administered with ketoconazole or placebo. Study 2 was an open-label, multiple-dose, single-sequence study evaluating the effect of steady-state carbamazepine, a CYP3A4 substrate and inducer, on the pharmacokinetics of steady-state vilazodone (40 mg once daily). Primary pharmacokinetic parameters for both studies were AUC and Cmax for vilazodone. Lack of pharmacokinetic interaction was concluded if the 90% CIs of the ratio of vilazodone plus the CYP3A4 inhibitor/inducer relative to vilazodone alone (or plus placebo) for AUC and Cmax were within the 80% to 125% range. Subject-reported and investigator-identified adverse events (AEs), laboratory values, vital signs, and 12-lead ECG parameters were recorded. FINDINGS In study 1/parts 1 and 2 (n = 15 and 22 enrolled, respectively), mean vilazodone AUC increased 42% and 51%, respectively, in the presence of ketoconazole (expected to be at steady state) versus vilazodone alone (part 1) or with placebo (part 2). The upper limit of the 90% CIs for the vilazodone AUC and Cmax geometric mean ratios exceeded 125%. In study 2 (n = 30 enrolled), co-administration of vilazodone and the carbamazepine extended-release formulation decreased mean steady-state vilazodone exposure ~45%, and the 90% CIs for the vilazodone AUC and Cmax geometric mean ratios were not within the range of 80% to 125%. In both studies, most AEs were of mild intensity, and gastrointestinal AEs predominated. IMPLICATIONS These results suggest that up to a 50% decrease of vilazodone dosage should be considered when it is given in combination with strong CYP3A4 inhibitors; conversely, increasing the vilazodone dosage up to a maximum of 80 mg/d should be considered when it is given in combination with strong CYP3A4 inducers. (Study registration numbers: SB-659746/029; VLZ-PK-02.).
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Effects of ketoconazole on the pharmacokinetics of ponatinib in healthy subjects.
Narasimhan, NI, Dorer, DJ, Niland, K, Haluska, F, Sonnichsen, D
Journal of clinical pharmacology. 2013;(9):974-81
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Abstract
Ponatinib is a BCR-ABL tyrosine kinase inhibitor (TKI) approved for the treatment of chronic myeloid leukemia and Philadelphia chromosome-positive acute lymphoblastic leukemia in patients resistant or intolerant to prior TKIs. In vitro studies suggested that metabolism of ponatinib is partially mediated by CYP3A4. The effects of CYP3A4 inhibition on the pharmacokinetics of ponatinib and its CYP3A4-mediated metabolite, AP24567, were evaluated in a single-center, randomized, two-period, two-sequence crossover study in healthy volunteers. Subjects (N = 22) received two single doses (orally) of ponatinib 15 mg, once given alone and once coadministered with daily (5 days) ketoconazole 400 mg, a CYP3A4 inhibitor. Ponatinib plus ketoconazole increased ponatinib maximum plasma concentration (C(max)) and area under the concentration-time curve (AUC) compared with ponatinib alone. The estimated mean ratios for AUC0-∞, AUC0-t, and C(max) indicated increased exposures to ponatinib of 78%, 70%, and 47%, respectively; exposure to AP24567 decreased by 71%. Exposure to AP24567 was marginal after ponatinib alone (no more than 4% of the exposure to ponatinib). These results suggest that caution should be exercised with the concurrent use of ponatinib and strong CYP3A4 inhibitors and that a ponatinib dose decrease to 30 mg daily, from the 45 mg daily starting dose, could be considered.