Luliconazole-Loaded Nanoliposomes as a Repurposing Strategy to Combat Memory Dysfunction in LPS-Induced Alzheimer's Rats.

Alzheimer's disease (AD) is a major neurodegenerative disorder with no definitive cure. Out of several proposed pathophysiology, microbial infection has recently been identified as one of the key pathogenic contributors for the development and progression of AD. In this context, the present study aims at a repurposing strategy through luliconazole (a potent imidazole derivative)-loaded optimized nanoliposomal carriers to treat AD. Optimized luliconazole-loaded nanoliposomes (LuNLs) were developed by the conventional thin-film hydration method followed by characterization in terms of FESEM, AFM, zeta potential, average size, loading %, and drug release (in vitro). The in vivo effectiveness of the LuNLs was investigated in LPS-induced AD rats. Molecular docking and simulation analysis demonstrated a favorable docking score between luliconazole and selected AD proteins. Spherical, nanosized (52.42 nm), negatively charged (-29.9 mV) LuNLs were reported showing a sustained drug release up to 24 h. An in vivo behavioral study depicted improved cognitive behavior in the LuNLs-treated group as compared to control groups. In vivo antioxidant activity in terms of SOD, MDA, and GSH inhibition by LuNLs was found comparable to that of standard formulation-treated groups, depicting the neuroprotective behavior of LuNLs. The histopathological observation of brain tissue in the LuNLs/control group further substantiated the in vivo behavioral study data. Based on the reports, luliconazole may be used as a viable, efficacious alternative for the treatment of AD, though further preclinical studies are highly warranted.