Self-micellizing solid dispersion of tacrolimus: Physicochemical and pharmacokinetic characterization.

The present study was undertaken to develop a self-micellizing solid dispersion (SMSD) of tacrolimus (TAC) to improve the biopharmaceutical properties of TAC. An SMSD formulation of TAC (SMSD/TAC) and amorphous solid dispersion formulation of TAC (ASD/TAC) were prepared with Soluplus® , an amphiphilic copolymer, and hydroxypropyl cellulose, respectively. Physicochemical properties were characterized in terms of morphology, crystallinity, storage stability, interaction of TAC with Soluplus® , and micelle-forming potency; pharmacokinetic behavior was also evaluated in rats. Tacrolimus in both formulations was in an amorphous state. After storage at 40°C/75% relativity humidity for 4 weeks, there were no significant changes in the crystallinity of TAC between nonaged and aged SMSD/TAC, whereas slight recrystallization was observed in aged ASD/TAC. The results of circular dichroism (CD) and infrared spectroscopic analyses were indicative of the potent drug-polymer interaction in SMSD/TAC, possibly leading to the prevention of recrystallization. Compared with other TAC samples, SMSD/TAC exhibited significant improvement in the dissolution behavior of TAC through the immediate formation of fine micelles. After the oral administration of TAC samples (10 mg TAC/kg) to rats, there was marked enhancement in systemic exposure to TAC with both formulations; in particular, SMSD/TAC achieved an increase in bioavailability ca. 20-fold higher than crystalline TAC. The SMSD approach might provide an effective dosage form for TAC with enhanced physicochemical stability and oral absorption.

UniORV, a New Multi-Unit Dosage Form, Improved Biopharmaceutical Properties of Tacrolimus in Rats and Humans.

PURPOSE: The aim of the present study was to develop a new multi-unit dosage formulation, Universal ORbicular Vehicle (UniORV), to improve the biopharmaceutical properties of tacrolimus (TAC). METHODS: TAC-loaded UniORV (UO/TAC) was produced by the dripping and gelling of a solution comprising TAC, gelatin, starch syrup, and triethyl citrate at 0.5 w/w% drug loading. Its microstructure was elucidated by polarized light microscopy and the Raman mapping technique. The pharmacokinetic profiles of TAC after the oral administration of UO/TAC were evaluated in rats and healthy humans. RESULTS: The dissolution behavior of UO/TAC was similar to that of commercial capsules, and the formation of nanoparticles was detected by TEM in dissolved media. In a stability study on UO/TAC, only 2.6 and 4.7% decreases in TAC concentrations were observed at 40± 2°C/75 ± 5% relative humidity for 4 months and at 50± 2°C for 2 months, respectively. A pharmacokinetic study on rats revealed a 30-fold higher AUC than that with crystalline TAC. A randomized double-blind crossover study on 8 healthy males showed that UniORV achieved a 1.4-fold increase in AUC and 34% decrease in inter-individual variation from the reference formulation. CONCLUSION: The new dosage form UniORV is a promising approach to improve the dissolution, amorphous stability, and biopharmaceutical properties of TAC, which is a poorly water-soluble drug.

Protective effects of tranilast on experimental colitis in rats.

The present study aimed to verify the efficacy of tranilast (TL) for treating inflammatory bowel disease (IBD) with the use of an experimental colitis model. The experimental colitis model was prepared by intrarectal instillation of 2,4,6-trinitrobenzenesulfonic acid (TNBS; 40mg/kg) dissolved in water containing 25% ethanol. The pharmacological effects of TL after repeated oral administration were evaluated by biomarker and histological analyses, and the pharmacokinetic behavior of TL was also examined after single oral administration. The intrarectal instillation of TNBS solution caused colitis, as evidenced by ca. 2.2-, 5-, and 3-fold increases in myeloperoxidase (MPO) activity, infiltrated cell numbers, and the thickness of the submucosa in the colon, respectively. However, orally-taken TL (10mg/kg, twice a day for 9days) led to a 92% reduction in the increase of the MPO level by TNBS enema, and cellular infiltration and thickened submucosa in the experimental colitis model tended to also be suppressed by repeated oral administration of TL. The oral bioavailability of TL in TNBS-treated rats was calculated to be as low as ca. 6.5%, and the poor oral absorption of TL may be a limitation of the treatment for IBD. TL could attenuate TNBS-induced colitis on the basis of the obtained results, and the anti-inflammatory effects would have clinical relevance to the therapeutic outcomes of TL in IBD patients. Although further improvement in the oral bioavailability of TL might be required for better pharmacological outcomes, TL would be an efficacious agent for treating IBD.

Crystallization of Poly(3-hexylthiophene) Nanofiber in a Narrow Groove.

Whisker-type poly(3-hexylthiophene-2,5-diyl) (P3HT) nanofibers were aligned by restricting their growth direction using an approximately 100⁻1000 nm wide narrow groove fabricated by thermal nanoimprinting. In grooves made of an amorphous fluoropolymer (CYTOP™) with widths of less than 1500 nm, the nanofibers oriented uniaxially perpendicular to the groove and their length was limited to the width of the groove. This result indicates that the nucleation of nanofibers tends to be selectively promoted near the interface of CYTOP™ with fluoro-groups, and nanofiber growth perpendicular to the wall is promoted because P3HT molecules are supplied more frequently from the center of the groove. Furthermore, the orientation induced anisotropic conductivity, and the conductivity parallel to the oriented nanofibers was more than an order of magnitude higher than that perpendicular to the oriented nanofibers.