Over the years, the performance of the liposomal formulations of temoporfin, Foslip® and Fospeg®, was investigated in a broad array of cell-based assays and preclinical animal models. So far, little attention has been paid to the influence of drug release and liposomal stability on the plasma concentration-time profile. The drug release is a key attribute which impacts product quality and the in vivo efficacy of nanocarrier formulations. In the present approach, the in vitro drug release and the drug-protein transfer of Foslip® and Fospeg® was determined using the dispersion releaser technology. To analyze the stability of both formulations in physiological fluids, nanoparticle tracking analysis was applied. A comparable drug release behavior and a high physical stability with a vesicle size of approximately 92 ± 2 nm for Foslip® and at 111 ± 5 nm for Fospeg® were measured. The development of a novel hybrid in silico model resulted in an optimal representation of the in vivo data. Based on the information available for previous formulations, the model enabled a prediction of the performance of Foslip® in humans. To verify the simulations, plasma concentration-time profiles of a phase I clinical trial were used. An absolute average fold error of 1.4 was achieved. Moreover, a deconvolution of the pharmacokinetic profile into different fractions relevant for the in vivo efficacy and safety was achieved. While the total plasma concentration reached a cmax of 2298 ng/mL after 0.72 h, the monomolecular drug accounted for a small fraction of the photosensitizer with a cmax of 321 ng/mL only.
Keywords: Dissolution testing; In vitro drug release; In vitro-in vivo correlation (IVIVC); Liposomes; Nanomaterials; Nanomedicines; Pharmacokinetics; Photosensitizer; Physiologically-based pharmacokinetic (PBPK) modeling; Temoporfin; mTHPC.
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