Cationic Biopolymer Decorated Asiatic Acid and Extract Incorporated Liposomes for Treating Early-stage Alzheimer's Disease: An and Investigation

Overview

Journal F1000Res

Specialties Biomedical Engineering
Science

Date 2023 Feb 10

PMID 36761834

Authors

Akhilesh Dubey

Namdev Dhas

Anup Naha

Usha Rani

Ravi Gs

Amitha Shetty

Chaithra R Shetty

Srinivas Hebbar

Affiliations

Soon will be listed here.

Abstract

Asiatic acid (AA) is a naturally occurring triterpenoid derivative of (CA) with neuroprotective effect. The study aimed to design an ideal oral drug delivery system to treat Alzheimer's disease (AD) and develop chitosan-embedded liposomes comprising an extract of CA (CLCAE) and compare them with the chitosan-coated liposomes of asiatic acid (CLAA) for oral delivery to treat the initial phases of AD. The solvent evaporation technique was used to develop CLCAE and CLAA, optimised with the experiment's design, and was further evaluated. Nuclear magnetic resonance (NMR) studies confirmed coating with chitosan. (TEM) and atomic force microscopy (AFM) indicated the successful formation of CLCAE and CLAA. Differential scanning colorimetry (DSC) confirmed the drug-phospholipid complex. Furthermore, the rate of release of CLCAE and CLAA was found to be 69.43±0.3 % and 85.3±0.3 %, respectively, in 24 h. permeation of CLCAE and CLAA was found to be 48±0.3 % and 78±0.3 %, respectively. In the Alcl3-induced AD model in rats, disease progression was confirmed by Y-maze, the preliminary histopathology evaluation showed significantly higher efficacy of the prepared liposomes (CLCAE and CLAA) compared to the extract (CAE) and they were found to have equivalent efficacy to the standard drug (rivastigmine tartrate). The considerable increase in pharmacodynamic parameters in terms of neuronal count in the CLAA group indicated the protective role against Alcl3 toxicity and was also confirmed by assessing acetylcholine (Ach) levels. The pharmacokinetic study, such as C , T , and area under curve (AUC) parameters, proved an increase in AA bioavailability in the form of CLAA compared to the pure AA and CLCAE forms. The preclinical study suggested that CLAA was found to have better stability and an ideal oral drug delivery system to treat AD.

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