Effect of Acetylation on the Nanofibril Formation of Chitosan from All-Atom De Novo Self-Assembly Simulations

Effect of Acetylation on the Nanofibril Formation of Chitosan from All-Atom De Novo Self-Assembly Simulations

Chitosan-based materials have broad applications, from biotechnology to pharmaceutics. Recent experiments showed that the degree and pattern of acetylation along the chitosan chain modulate its biological and physicochemical properties; however, the molecular mechanism remains unknown. Here, we repo...

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Bibliographic Details
Published in:Molecules (Basel, Switzerland) Vol. 29; no. 3; p. 561
Main Authors: Romany, Aarion, Payne, Gregory F, Shen, Jana
Format: Journal Article
Language:English
Published: Switzerland MDPI AG 23-01-2024
Subjects:
degree of acetylation
Hydrogen
Hydrogen bonding
Hydrogen bonds
Mechanics
Molecular dynamics
molecular dynamics simulations
Nanoparticles
pattern of acetylation
polysaccharide
self-assembly
Simulation
Simulation methods
Solvents
molecular dynamics simulations
self-assembly
pattern of acetylation
polysaccharide
degree of acetylation
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Summary:Chitosan-based materials have broad applications, from biotechnology to pharmaceutics. Recent experiments showed that the degree and pattern of acetylation along the chitosan chain modulate its biological and physicochemical properties; however, the molecular mechanism remains unknown. Here, we report, to the best of our knowledge, the first de novo all-atom molecular dynamics (MD) simulations to investigate chitosan's self-assembly process at different degrees and patterns of acetylation. Simulations revealed that 10 mer chitosan chains with 50% acetylation in either block or alternating patterns associate to form ordered nanofibrils comprised of mainly antiparallel chains in agreement with the fiber diffraction data of deacetylated chitosan. Surprisingly, regardless of the acetylation pattern, the same intermolecular hydrogen bonds mediate fibril sheet formation while water-mediated interactions stabilize sheet-sheet stacking. Moreover, acetylated units are involved in forming strong intermolecular hydrogen bonds (NH-O6 and O6H-O7), which offers an explanation for the experimental observation that increased acetylation lowers chitosan's solubility. Taken together, the present study provides atomic-level understanding the role of acetylation plays in modulating chitosan's physiochemical properties, contributing to the rational design of chitosan-based materials with the ability to tune by its degree and pattern of acetylation. Additionally, we disseminate the improved molecular mechanics parameters that can be applied in MD studies to further understand chitosan-based materials.
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ISSN:1420-3049
1420-3049
DOI:10.3390/molecules29030561