In silico modeling of functionalized poly(methylvinyl ether/maleic acid) for controlled drug release in the ocular milieu.

Controlling structurally defined properties of drug-bound macromolecules such as surface adhesion and interaction with endogenous proteins in the surrounding environment using prior data from computer-assisted simulation can be of great use in designing controlled release macromolecular therapeutic systems. In this paper, we describe experimental correlation of real-time properties of a polymer with pendant drug molecules, with predicted values obtained from studying in silico molecular interactions of this polymer with ocular surface proteins (mucin) for formulating an ophthalmic in situ gel. Mucoretention of the drug (norfloxacin) within the eye sac is closely associated with binding interactions occurring on the ocular surface, and covalent association of the drug with the mucoadhesive polymer, poly(methylvinyl ether/maleic acid), can largely reduce dosing frequency eliciting prolonged antibacterial action much required in treating conjunctival infections.

Network topology of LMWG cross-linked xyloglucan hydrogels for embedding hydrophobic nanodroplets: mechanistic insight and molecular dynamics.

Indigenous polymers have functional implications in biomedicine due to the presence of an inherent favorable structural architecture that supports hydrogel formation. In this study, we present the molecular level characterization of xyloglucan hydrogels using experimental and molecular simulation methods. We studied supramolecular self-assembly of tamarind seed-derived xyloglucan induced by low molecular weight gelators to form dense networks and rationalized its capabilities as a multifunctional and multiresponsive matrix for holding hydrophobic nanometric oleic acid globules intact for extended periods, preventing coalescence triggered instability using computational methods and imaging.