A Physiologically-Based Pharmacokinetic Modeling Approach To Predict Drug–Drug Interactions of Sonidegib (LDE225) with Perpetrators of CYP3A in Cancer Patients

Einolf, Heidi J.; Zhou, Jocelyn; Won, Christina S.; Wang, Lai; Rebello, Sam

doi:10.1124/dmd.116.073585

Cited by 22 publications

(21 citation statements)

References 19 publications

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“…Thus, there is a marked discrepancy between the estimated and actual values for the AUC ratio. We suggest some possible reasons for this discrepancy: uncertainties in key input parameters, such as the K deg of CYP3A, K i , and K inact of TAS‐303, may be alienated from in vivo data; the differential equations for intestinal inhibition implemented in the DDI simulator provide a static rather than dynamic model, and not accounting for the intestinal tissue binding of TAS‐303 in this model (the unbound fraction was assumed to be unity) may lead to an overestimation of unbound TAS‐303 concentration in enterocytes and its inhibitory effect on intestinal CYP3A activity . To reasonably describe the observed DDI between TAS‐303 and simvastatin, the current PBPK model of TAS‐303 needs to be further refined based on emerging preclinical and clinical findings through the future development of TAS‐303.…”

Section: Discussionmentioning

confidence: 99%

A Drug‐Drug Interaction Study to Evaluate the Effect of TAS‐303 on CYP3A Activity in the Small Intestine and Liver

Kumagai

Fujita

Maeda

et al. 2020

The Journal of Clinical Pharma

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TAS-303 (4-piperidinyl 2,2-diphenyl-2-[propoxy-1,1,2,2,3,3,3-d 7 ] acetate hydrochloride) is a novel selective noradrenaline reuptake inhibitor being developed for the treatment of stress urinary incontinence. An in vitro study and a physiologically based pharmacokinetic model simulation showed that TAS-303 had inhibitory potential against cytochrome P450 (CYP) 3A. This open-label, single-group study investigated the effect of TAS-303 on CYP3A activity by evaluating the pharmacokinetics (PK) of single-dose oral simvastatin 5 mg or intravenous midazolam 1 mg after repeated oral administration of TAS-303 3 mg in 12 healthy participants. TAS-303 plus simvastatin resulted in a 1.326-fold and a 1.420-fold increase of simvastatin in peak plasma concentration and area under the plasma concentration-time curve from time zero to time t, where t is the final time of detection (AUC 0-t ), respectively. The addition of midazolam resulted in a 1.090-fold increase in the midazolam AUC 0-t . TAS-303 had a weak PK interaction with simvastatin but no apparent interaction with midazolam. TAS-303 at 3 mg/day is a weak inhibitor of intestinal but not hepatic CYP3A activity. No clinically important safety concerns related to TAS-303 were raised.

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Section: Discussionmentioning

confidence: 99%

A Drug‐Drug Interaction Study to Evaluate the Effect of TAS‐303 on CYP3A Activity in the Small Intestine and Liver

Kumagai

Fujita

Maeda

et al. 2020

The Journal of Clinical Pharma

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“…Sonidegib is metabolized predominantly by CYP3A4 and does not inhibit or induce any other CYP3A4 enzyme systems to any great extent. Clinical studies included in the package labeling demonstrate co-administration with moderate or strong CYP3A4 inhibitor increased sonidegib AUC by 1.8- and 2.2-fold, respectively 79,81. Therefore, concomitant use with PIs or cobicistat should be avoided.…”

Section: Kinase Inhibitorsmentioning

confidence: 99%

Oral oncolytic and antiretroviral therapy administration: dose adjustments, drug interactions, and other considerations for clinical use

Badowski

Burton

Shaeer

et al. 2019

DIC

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The rise in non-AIDS defining cancers (NADCs) is emerging as a leading cause of death for HIV and cancer patients. To address this, current literature and guidelines suggest the continuation of antiretroviral therapy (ART) with oral oncolytic agents to prevent adverse complications associated with HIV disease progression. However, such an approach has the potential for drug–drug interactions and adverse events for patients on such therapy. Further, recommendations on how to adjust these medications, when used concomitantly, are limited. As such, our purpose is to evaluate existing literature through such means as drug databases (e.g. Micromedex, Lexi-Comp, etc.) and package inserts along with PubMed/Medline, Embase, and Google Scholar databases to develop a reference tool for providers to utilize when there is a decision to treat a patient with ART and oral oncolytic agents concurrently. Our findings suggest that there are many drug interactions that should be taken into consideration with dual therapy. Metabolism is a key determinant of dose adjustment, and many oncolytic agents and ART agents must have their dose adjusted as such. Most notably, several tyrosine kinase inhibitors require dose increases when used with non-nucleoside reverse transcriptase inhibitors (NNRTIs) but must be decreased when used concomitantly with protease inhibitors (PIs) and cobicistat. Further findings suggest that certain agents should not be used together, which include, but are not limited to, such combinations as bosutinib with NNRTIs, cobicistat, or PIs; idelalisib with maraviroc or PIs; neratinib with NNRTIs, cobicistat, or PIs; and venetoclax with NNRTIs. Overall, the most prominent oncolytic drug interactions were discovered when such agents were used concomitantly with PIs, cobicistat-boosted elvitegravir, or NNRTIs. Future studies are necessary to further evaluate the use of these agents together in disease therapy to generate absolute evidence of such findings. However, from the studies evaluated, much evidence exists to suggest that concomitant therapy is not without drug interactions. As such, clinical decisions regarding concomitant therapy should be evaluated in which the risk and benefit of dual therapy are assessed. Dose adjustments must be made accordingly and in consultation with both HIV and oncology clinicians and pharmacists to reduce the risk for adverse outcomes and disease progression for those with cancer and HIV/AIDS.

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“…Ketoconazole, a potent CYP3A4 inhibitor, increased sonidegib AUC 0‐240h 2.25‐fold (90% CI: 1.78–2.86) and C max 1.49‐fold (90% CI: 1.11–1.99). In contrast, rifampicin, a CYP3A4 inducer, decreased 800 mg PO QD sonidegib AUC 0‐240h exposure by 72% (ratio 0.28, 90% CI: 0.22–0.35) and C max by 54% (ratio 0.46, 90% CI 0.35–0.61) 10 . Thus, the FDA‐approved product labelling indicates that concomitant administration of sonidegib with moderate–strong CYP3A inhibitors and moderate–strong CYP3A inducers should be avoided 8 .…”

Section: Discussionmentioning

confidence: 93%

“…Based on population pharmacokinetic (PK) modelling the elimination half‐life of sonidegib was 28 days. Little or no parent sonidegib was found in the urine as it is primarily cleared from the body in humans by hepatic metabolism, predominantly via CYP3A 8,10,11 . Sonidegib treatment of human liver microsomes showed inhibition of CYP2B6 (IC 50 ~ 0.5 μmol L −1 ; inhibitor constant [K i ] 0.045 μmol L −1 , substrate bupropion) and CYP2C9 (IC 50 ~ 5 μmol L −1 ; K i 1.7 μmol L −1 , substrate diclofenac).…”

Section: Introductionmentioning

confidence: 99%

The effect of sonidegib (LDE225) on the pharmacokinetics of bupropion and warfarin in patients with advanced solid tumours

Pooler

Ness

Sarantopoulos

et al. 2020

Brit J Clinical Pharma

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Aims We evaluated the potential effect of sonidegib at an oral dose of 800 mg once daily (QD) on the pharmacokinetics (PK) of the probe drugs warfarin (CYP2C9) and bupropion (CYP2B6). Methods This was a multicentre, open‐label study to evaluate the effect of sonidegib on the PK of the probe drugs warfarin and bupropion in patients with advanced solid tumours. Cohort 1 patients received a single warfarin 15‐mg dose on Day 1 of the run‐in period and on Cycle 2 Day 22 (C2D22) of sonidegib administration. Cohort 2 patients received a single bupropion 75‐mg dose on Day 1 of run‐in period and on C2D22 of sonidegib administration. Sonidegib 800 mg QD oral dosing began on Cycle 1 Day 1 of a 28‐day cycle after the run‐in period in both cohorts. Results The geometric means ratios [90% confidence interval] for (S)‐warfarin with and without sonidegib were: area under the concentration–time curve from time 0 to infinity (AUCinf) 1.15 [1.07, 1.24] and maximum plasma concentration (Cmax) 0.88 [0.81, 0.97]; and for (R)‐warfarin were: AUCinf 1.10 [0.98, 1.24] and Cmax 0.93 [0.87, 1.0]. The geometric means ratios [90% confidence interval] of bupropion with and without sonidegib were: AUCinf 1.10 [0.99, 1.23] and Cmax 1.16 [0.95, 1.42]. Sonidegib 800 mg had a safety profile that was similar to that of lower dose sonidegib 200 mg and was unaffected by single doses of the probe drugs. Conclusions Sonidegib dosed orally at 800 mg QD (higher than the Food and Drug Administration‐approved dose) did not impact the PK or pharmacodynamics of warfarin (CYP2C9 probe substrate) or the PK of bupropion (CYP2B6 probe substrate).

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A Physiologically-Based Pharmacokinetic Modeling Approach To Predict Drug–Drug Interactions of Sonidegib (LDE225) with Perpetrators of CYP3A in Cancer Patients

Cited by 22 publications

References 19 publications

A Drug‐Drug Interaction Study to Evaluate the Effect of TAS‐303 on CYP3A Activity in the Small Intestine and Liver

A Drug‐Drug Interaction Study to Evaluate the Effect of TAS‐303 on CYP3A Activity in the Small Intestine and Liver

Oral oncolytic and antiretroviral therapy administration: dose adjustments, drug interactions, and other considerations for clinical use

The effect of sonidegib (LDE225) on the pharmacokinetics of bupropion and warfarin in patients with advanced solid tumours

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