Harnessing pharmacokinetic modeling to develop a long-acting subcutaneous HIV treatment platform for young children

Abstract

Background: Long-acting drug delivery strategies could augment pediatric human immunodeficiency virus (HIV) treatment effectiveness by bypassing population-specific challenges such as adherence. We harnessed pharmacokinetic (PK) modeling to develop a biodegradable, subcutaneous (SQ), reservoir-style implant for HIV treatment in 2-5-year-old children. Methods: Plasma was collected from New Zealand White rabbits over 30 h after a single intravenous (IV) bolus of bictegravir (BIC, 0.75 mg/kg), islatravir (ISL, 5 mg/kg) and/or emtricitabine (FTC, 30 mg/kg) then over a year after subcutaneous insertion of two to three implants eluting these antiretrovirals. Plasma antiretrovirals were quantified by HPLC-MS/MS and population PK models were fit to the IV PK profile to derive a mean unit impulse response (UIR). UIR was used to numerically deconvolve SQ absorption rate from the implant PK profile. SQ dosing rates were translated to pediatric plasma concentrations using published clinical PK parameters. Results: BIC, FTC, and ISL PK profiles were best described by two-compartment models. Each implant achieved quantifiable plasma concentrations for >360 days. Median SQ absorption rates (μg/day) at 3, 6 and 12 months of implantation were 116, 98 and 71 for BIC; 116, 37 and 5 for ISL; and 236, 116 and 24 for FTC. These 6-month dosing rates translated to pediatric plasma concentrations of 24 ng/mL BIC, 0.14 ng/mL ISL, and 0.7 ng/mL FTC. Conclusions: Our novel long-acting delivery platform exhibited antiretroviral SQ dosing rates for ≥6 months that are anticipated to achieve plasma concentrations in children within an efficacious range warranting further development for pediatric HIV treatment.