Celecoxib-Loaded Self-micellizing Solid Dispersion Suppresses Its Delayed Absorption in Rats with Impaired Gastrointestinal Motility.

The aim of this study was to develop a self-micellizing solid dispersion of celecoxib (SMSD/CEL) with enhanced dissolution to suppress a delay in absorption under impairment of gastrointestinal (GI) secretion and motility induced by severe pain. Soluplus®-based SMSD/CEL was prepared by lyophilization and physiochemically characterized. A pharmacokinetic study of orally-dosed CEL samples was carried out in rats with propantheline (PPT)-induced the impairment of GI secretion and motility. SMSD/CEL was micellized in aqueous media with a mean diameter of 153 nm, and it showed improved dissolution behavior of CEL under acidic conditions with 2.1-fold higher dissolved CEL at 120 min than crystalline CEL. SMSD/CEL was found to be in an amorphous state, and there was no significant crystallization even after storage under accelerated conditions for 8 weeks, indicating relatively high storage stability of the amorphous form. Orally-dosed crystalline CEL in PPT-treated rats showed a delayed mean absorption time (MAT) and area under the curve of plasma concentration versus time from 0 to 4 h (AUC0-4) was reduced to 12% compared with that in normal rats, whereas SMSD/CEL suppressed the delay and decrease of absorption in PPT-treated rats. From these findings, SMSD/CEL might be efficacious to suppress poor and delayed absorption of CEL for better pain medication in the presence of impaired GI secretion and motility associated with severe pain.

Self-Emulsifying Drug Delivery System of Celecoxib for Avoiding Delayed Oral Absorption in Rats with Impaired Gastric Motility.

This study aimed to develop a self-emulsifying drug delivery system (SEDDS) of celecoxib (CEL) for suppressed delay in oral absorption under impaired gastric motility. A pseudo-ternary phase diagram was constructed for the determination of the optimal component ratio in SEDDS of CEL (SEDDS/CEL), and the SEDDS/CEL was physicochemically characterized. A pharmacokinetic study on orally dosed CEL samples (5-mg CEL/kg) was carried out in normal and propantheline (PPT)-treated rats to mimic impaired gastric motility. SEDDS/CEL rapidly formed a fine emulsion with a mean size of 147 nm in distilled water and significantly improved the dissolution behavior of CEL under pH 1.2 condition with a 20-fold higher dissolved amount than crystalline CEL. In normal rats, orally dosed SEDDS/CEL provided a 4.6-fold higher systemic exposure than that of crystalline CEL, due to the improved dissolution properties of CEL. Crystalline CEL showed delayed and decreased oral absorption of CEL in PPT-treated rats as evidenced by a 6.9-h-delayed mean absorption time and only 12% of the systemic exposure of CEL compared with those in normal rats. In contrast, SEDDS/CEL enhanced the oral absorption of CEL with a 14.6-fold higher systemic exposure with significant suppression of delay in absorption than crystalline CEL even in PPT-treated rats. SEDDS/CEL could be an efficacious option for suppressing delay in CEL absorption even under impairment of gastric motility, possibly leading to rapid and reproducible management of severe acute pain.

Improved biopharmaceutical properties of carvedilol employing α-tocopheryl polyethylene glycol 1000 succinate-based self-emulsifying drug delivery system.

The main objective of this study was to develop a self-emulsifying drug delivery system (SEDDS) of carvedilol (CAR) with improved oral absorption and hepatoprotective properties. SEDDS-CAR was prepared based on d-α-tocopheryl polyethylene glycol 1000 succinate (TPGS) and physicochemically characterized. Pharmacokinetic behaviors after the oral administration of CAR samples in rats were evaluated to clarify the possible enhancement of the oral absorption of CAR. The hepatoprotective effects of orally dosed CAR samples were assessed in a rat model of acute hepatic injury induced by carbon tetrachloride (CCl4). SEDDS-CAR showed the immediate formation of fine micelles with a mean droplet size of 84 nm when introduced in aqueous media. SEDDS-CAR improved the dissolution behavior of CAR in distilled water as evidenced by at least five-fold higher solubility than the equilibrium solubility of CAR. After the single oral administration of SEDDS-CAR (10 mg-CAR/kg) in rats, enhanced CAR exposure was observed with an increase of AUC0-∞ showing a 2.5-fold increase compared with crystalline CAR. In CCl4-treated rats, orally dosed SEDDS-CAR (10 mg-CAR/kg, p.o.) led to 91.8 and 91.2% reductions of ALT and AST, respectively; however, crystalline CAR was found to be less effective. From these findings, SEDDS-CAR might be an efficacious oral dosage option for enhancing the hepatoprotective potential of CAR.

Predictive Models Based on Molecular Images and Molecular Descriptors for Drug Screening.

Various toxicity and pharmacokinetic evaluations as screening experiments are needed at the drug discovery stage. Currently, to reduce the use of animal experiments and developmental expenses, the development of high-performance predictive models based on quantitative structure-activity relationship analysis is desired. From these evaluation targets, we selected 50% lethal dose (LD50), blood-brain barrier penetration (BBBP), and the clearance (CL) pathway for this investigation and constructed predictive models for each target using 636-11,886 compounds. First, we constructed predictive models using the DeepSnap-deep learning (DL) method and images of compounds as features. The calculated area under the curve (AUC) and balanced accuracy (BAC) were, respectively, 0.887 and 0.818 for LD50, 0.893 and 0.824 for BBBP, and 0.883 and 0.763 for the CL pathway. Next, molecular descriptors (MDs) of compounds were calculated using Molecular Operating Environment, alvaDesc, and ADMET Predictor to construct predictive models using the MD-based method. Using these MDs, we constructed predictive models using DataRobot. The calculated AUC and BAC were, respectively, 0.931 and 0.805 for LD50, 0.919 and 0.849 for BBBP, and 0.900 and 0.807 for the CL pathway. In this investigation, we constructed predictive models combining the DeepSnap-DL and MD-based methods. In ensemble models using the mean predictive probability of the DeepSnap-DL and MD-based methods, the calculated AUC and BAC were, respectively, 0.942 and 0.842 for LD50, 0.936 and 0.853 for BBBP, and 0.908 and 0.832 for the CL pathway, with improved predictive performance observed for all variables compared with either single method alone. Moreover, in consensus models that adopted only compounds for which the results of the two methods agreed, the calculated BAC for LD50, BBBP, and the CL pathway were 0.916, 0.918, and 0.847, respectively, indicating higher predictive performance than the ensemble models for all three variables. The predictive models combining the DeepSnap-DL and MD-based methods displayed high predictive performance for LD50, BBBP, and the CL pathway. Therefore, the application of this approach to prediction targets in various drug discovery screenings is expected to accelerate drug discovery.

Physicochemical and biopharmaceutical characterization of celecoxib nanoparticle: Avoidance of delayed oral absorption caused by impaired gastric motility.

The present study aimed to develop a celecoxib (CEL) nanoparticle with improved dissolution/dispersion and consistent absorption even in the presence of impaired gastric motility. CEL was pulverized by a wet-milling with hydroxypropyl cellulose (HPC), and the prepared nanoparticles were physicochemically characterized after freeze-drying. CEL nanoparticle with HPC-SSL (NP/CEL) exhibited better dissolution/dispersion behavior in pH1.2 solution compared with CEL nanoparticles with other polymers, as evidenced by a 21.8-fold higher initial dissolution/dispersion rate than crystalline CEL. The mean particle diameter of water suspended-NP/CEL was 250 nm, and the CEL nanoparticle existed in an amorphous state. Even after storage at 40 °C for 4 weeks, there were no significant changes in the dissolution/dispersion behavior. Oral absorption of CEL samples (5 mg-CEL/kg) was evaluated in normal and propantheline (PPT)-treated rats with simulated gastric motility impairment. In PPT-treated rats, oral crystalline CEL led to a decrease in oral absorption by 12% of the AUC0-4 compared with that in normal rats, whereas NP/CEL suppressed the pharmacokinetic transition of CEL by 43% of the AUC0-4 due to the improved dissolution/dispersion behavior of CEL. The NP/CEL system might be promising to avoid decreased absorption of CEL caused by impaired gastric motility.

Ginger Extract-Loaded Solid Dispersion System with Enhanced Oral Absorption and Antihypothermic Action.

The aim of this study is to enhance the antihypothermic action of ginger extract (GE) employing a solid dispersion (SD) approach. The prepared SD of GE (GE/SD) was characterized in terms of physicochemical and pharmacokinetic properties. The antihypothermic action of GE samples was evaluated in a rat model of hypothermia. GE/SD exhibited improved dissolution behavior of the major active ingredients in GE, 6-gingerol (6G) and 8-gingerol (8G), with levels of dissolution 12- and 31-fold higher than that of GE, respectively. Even after storage under accelerated conditions, limited degradations of 6G and 8G were observed in GE/SD, although 6G and 8G were slightly degraded in GE. After oral administration of GE (300 mg/kg) and GE/SD (100 mg of GE/kg), the relative bioavailabilities of 6G and 8G in GE/SD were 5.0- and 5.8-fold higher than those in GE, respectively. Orally administered GE/SD (30 mg of GE/kg) inhibited ethanol-evoked hypothermia because of improved oral absorption of 6G and 8G. From these observations, the SD approach might be efficacious for enhancing the nutraceutical potentials of GE.