PKPD modeling and dosing considerations in advanced ovarian cancer patients treated with cisplatin-based intraoperative intraperitoneal chemotherapy

Intraperitoneal chemoperfusion (IPEC) of cisplatin is a popular treatment for advanced ovarian cancer, typically under hyperthermia (HIPEC). The use of cisplatin under (H)IPEC is off-label, and the role of hyperthermia is unknown. The aim of this study was to characterize the pharmacokinetic/pharmacodynamic (PKPD) properties of cisplatin under (H)IPEC and to predict the optimal treatment regimen. Using a randomized design, data on intact cisplatin perfusate and plasma concentrations, leukocyte counts-a hematotoxicity marker-and serum creatinine-a nephrotoxicity marker-were collected from 50 patients treated with a combination of cytoreductive surgery (CRS) and either normothermic or hyperthermic IPEC of cisplatin dosed at 75, 100, and 120 mg/m(2). The non-linear mixed effects modeling technique was used to construct the PKPD models. The PK of intact cisplatin was characterized by a two-compartment model. A semi-physiological myelosuppression model for the leukopenia was modified to account for the CRS-induced leukocytosis and the residual myelosuppression effect of neoadjuvant chemotherapy. The incidence and severity of nephrotoxicity were described by a discrete-time Markov model. Hyperthermia increased the absorption rate of cisplatin by 16.3% but did not show a clinically relevant impact on the investigated toxicities compared with normothermia. Leukopenia was not severe, but nephrotoxicity can become severe or life-threatening and was affected by the dose and IPEC duration. The model predicted that nephrotoxicity is minimal at a cisplatin dose of 75 mg/m(2)with an IPEC duration of 1-2 h and an 1-h duration is favored for doses between 100 and 120 mg/m(2).

Publication year:2020

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