Nanostructured lipid carrier to overcome stratum corneum barrier for the delivery of agomelatine in rat brain; formula optimization, characterization and brain distribution study.

The current work attempted to achieve bypassed hepatic metabolism, controlled release, and boosted brain distribution of agomelatine by loading in NLC and administering via transdermal route. Agomelatine-loaded NLC (AG-NLC) was fabricated employing melt-emulsification technique and optimized using central composite design. The optimized AG-NLC had 183.16 ± 6.82 nm particle size, 0.241 ± 0.0236 polydispersity index, and 83.29 ± 2.76% entrapment efficiency. TEM and FESEM visually confirmed the size and surface morphology of AG-NLC, respectively. DSC thermogram confirmed the conversion of AG from crystalline to amorphous form, which indicates improved solubility of AG when loaded in NLC. For further stability and improved applicability, AG-NLC was converted into a hydrogel. The texture analysis of AG-NLC-Gel showed appropriate gelling property in terms of hardness (142.292 g), cohesiveness (0.955), and adhesiveness (216.55 g.sec). In comparison to AG-suspension-Gel (38.036 ± 6.058%), AG-NLC-Gel (89.440 ± 2.586%) exhibited significantly higher (P < 0.005) skin permeation profile during the 24 h study. In the CLSM study, Rhodamine-B loaded AG-NLC-Gel established skin penetration up to the depth of 45 µm, whereas AG-Suspension-Gel was restricted only to a depth of 25 µm. γ-scintigraphy in wistar rats revealed ~ 55.38% brain distribution potential of 99mTc-AG-NLC-Gel at 12 h, which was 6.31-fold higher than 99mTc-AG-Suspension-Gel. Overall, the gamma scintigraphy assisted brain distribution study suggests that NLC-Gel system may improve the brain delivery of agomelatine, when applied transdermally.

Poloxamer-407 thickened lipid colloidal system of agomelatine for brain targeting: Characterization, brain pharmacokinetic study and behavioral study on Wistar rats.

The current study was designed to enhance the brain bioavailability and to extract maximum therapeutic benefit from a novel antidepressant drug, agomelatine. For this purpose, a thermoresponsive in situ gel was prepared by dissolving 20% w/v of Poloxamer-407 in agomelatine containing nanoemulsion. To impart mucoadhesive property, 0.5% w/v concentration of chitosan was ensured in the final formulation, named as Ago-NE-gel+0.5%chitosan. The gelling point and mucoadhesive strength of Ago-NE-gel+0.5%chitosan were found to be 28 ± 1 °C, and 6246.27 dynes/cm2 respectively. The size of free micelles of Poloxamer-407 was recorded graphically at 18.43 ± 0.95 nm whereas the size of sterically stabilized Ago-NE was observed at 142.58 ± 4.21 nm. The viscosity and pH of Ago-NE-gel+0.5%chitosan were found to be 2439 ± 23 cP (at 35 ± 1 °C temperature) and 5.8 ± 0.2 respectively. The developed formulation was found safe on nasal mucosa during the toxicity study. CLSM based brain distribution study suggested that Ago-NE-gel+0.5%chitosan is more competent to deliver the drug into the brain as compared to agomelatine-suspension. After intranasal administration of Ago-NE-gel+0.5%chitosan in Wistar rats, the AUC0-8h in brain and plasma were found to be 1418.591 ± 71.87 and 473.901 ± 32.42 ng.h/ml respectively. The hypothesis conceived at the beginning of this research work was delivered as 2.82 folds enhanced bioavailability of agomelatine in the brain. The behavioral studies confirmed that the antidepressant activity of agomelatine can be improved by loading the drug into a mucoadhesive-nanoemulsion-gel system followed by its intranasal administration.