Combining lipid based drug delivery and amorphous solid dispersions for improved oral drug absorption of a poorly water-soluble drug.

Two widely applied enabling drug delivery approaches, self-nanoemulsifying drug delivery systems (SNEDDS) and amorphous solid dispersions (ASD), were combined, with the aim of enhancing physical stability, solubilization and absorption of the model drug ritonavir. Ritonavir was loaded at a concentration above its saturation solubility (Seq) in the SNEDDS (superSNEDDS, 250% of Seq). An ASD of ritonavir with polyvinylpyrrolidone-vinyl acetate copolymers (Kollidon® VA64) was prepared by ball milling. Relevant control formulations, which include conventional SNEDDS (90% of Seq), superSNEDDS with a physical mix of Kollidon® VA64 and ritonavir (superSNEDDS+PM) and an aqueous suspension of ritonavir were used. A pharmacokinetic (PK) study in rats was performed to assess the relative bioavailability of ritonavir after oral administration. This was followed by evaluating the formulations in a novel two-step in vitro lipolysis model simulating rat gastric and intestinal conditions. The addition of a ritonavir containing ASD to superSNEDDS increased the degree of supersaturation from 250% to 275% Seq in the superSNEDDS and the physical stability (absence of drug recrystallization) of the system from 48 h to 1 month under ambient conditions. The PK study in rats displayed significantly higher Cmax and AUC0-7h (3-fold increase) and faster Tmax for superSNEDDS+ASD compared to the conventional SNEDDS whilst containing 3 times less lipid than the latter. Furthermore, superSNEDDS+ASD were able to keep the drug solubilised during in vitro lipolysis to the same degree as the conventional SNEDDS. These findings suggest that dissolving an ASD in a superSNEDDS can contribute to the development of novel oral delivery systems with increased bioavailability for poorly water-soluble drugs.

The ability of two in vitro lipolysis models reflecting the human and rat gastro-intestinal conditions to predict the in vivo performance of SNEDDS dosing regimens.

In this work, the influence of drug load and physical state of R3040 in self-nanoemulsifying drug delivery systems (SNEDDS) on R3040 absorption in rats was assessed. Furthermore, an in vitro lipolysis model simulating rat conditions (rat lipolysis model) was compared to a human lipolysis model in regard to the prediction of the in vivo data. The formulations were SNEDDS 80%, containing R3040 at 80% of its equilibrium solubility in SNEDDS (Seq); super-SNEDDS solution with R3040 supersaturated at 200% Seq; super-SNEDDS suspension containing R3040 at 200% Seq; Chasing principle (drug-free SNEDDS followed by R3040 aqueous suspension) and R3040 aqueous suspension. The pharmacokinetic profiles of R3040 in SNEDDS 80% and super-SNEDDS solution 200% were superimposed and higher than for super-SNEDDS suspension 200%, Chasing principle and aqueous suspension. Therefore, dosing R3040 dissolved in SNEDDS increased R3040 absorption irrespective of the drug load. While the human lipolysis model could not predict the rank order of absorption of the formulations, the rat lipolysis model predicted the similar absorption of R3040 in SNEDDS 80% and super-SNEDDS solution 200%. Thus, the rat lipolysis model showed to be an important step towards predictive in vitro models for rat studies.