Experimental Solubility, Thermodynamic/Computational Validations, and GastroPlus-Based In Silico Prediction for Subcutaneous Delivery of Rifampicin.

We focused to explore a suitable solvent for rifampicin (RIF) recommended for subcutaneous (sub-Q) delivery [ethylene glycol (EG), propylene glycol (PG), tween 20, polyethylene glycol-400 (PEG400), oleic acid (OA), N-methyl-2-pyrrolidone (NMP), cremophor-EL (CEL), ethyl oleate (EO), methanol, and glycerol] followed by computational validations and in-silico prediction using GastroPlus. The experimental solubility was conducted over temperature ranges T = 298.2-318.2 K) and fixed pressure (p = 0.1 MPa) followed by validation employing computational models (Apelblat, and van't Hoff). Moreover, the HSPiP solubility software provided the Hansen solubility parameters. At T = 318.2K, the estimated maximum solubility (in term of mole fraction) values of the drug were in order of NMP (11.9 × 10-2) ˃ methanol (6.8 × 10-2) ˃ PEG400 (4.8 × 10-2) ˃ tween 20 (3.4 × 10-2). The drug dissolution was endothermic process and entropy driven as evident from "apparent thermodynamic analysis". The activity coefficients confirmed facilitated RIF-NMP interactions for increased solubility among them. Eventually, GastroPlus predicted the impact of critical input parameters on major pharmacokinetics responses after sub-Q delivery as compared to oral delivery. Thus, NMP may be the best solvent for sub-Q delivery of RIF to treat skin tuberculosis (local and systemic) and cutaneous related disease at explored concentration.

Development and evaluation of topical formulations for a novel skin whitening agent (AP736) using Hansen solubility parameters and PEG-PCL polymers.

AP736 itself is a novel skin whitening agent reported to exhibit anti-melanogenic and tyrosinase inhibitory activity. However, formulating a topical product has been difficult because AP736 is insoluble in water as well as in many oils. In this study, we aimed to develop a new topical delivery system in which AP736 is not only physically stable, but also suitably delivered to the skin. By calculating each HSP (Hansen Solubility Parameters), ethylenedioxy moiety-containing compounds could be easily selected for the formulation ingredients of AP736. Although diethylene glycol monoethyl ether with the highest solubility of AP736 enalbes to make AP736-incorporated water-in-oil emulsions well, the recrystallization of AP736 was observed in oil-in-water emulsions. Therefore, we fabricated polymeric nanoparticles (PNPs) in order to encapsulate AP736 to prevent its recrystallization. We used three different PEG-PCL polymers with various chain lengths and ethylenedioxy moiety-containing surfactants (i.e. Choleth) for fabricating PNPs. The prepared PNPs had a mean particle size from 50 nm to 200 nm. Most of PNPs showed the good encapsulation efficiency up to 90%. In particular, Choleth-24 had a significant role in encapsulating AP736 in PNPs. After encapsulation of AP736, no significant changes were observed in the sizes of tested PNPs within 4 weeks. Further, the recrystallization of AP736 was not observed in oil-in-water emulsions after 24 weeks of storage at 40 °C. In vitro permeation study using Strat-M showed that PNPs containing Choleth-24 has the faster release pattern compared to PNPs using Tween 80 and saturated in D.I. water. These results are demonstrating that PNPs might be an effective vehicle for stabilization in oil-in-water emulsions and topical application of AP736.