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Biocomposite Scaffolds Based on Chitosan Extraction from Shrimp Shell Waste for Cartilage Tissue Engineering Application

Chirapond Chonanant, Pongrung Chancharoen, Sirirat Kiatkulanusorn, Nongnuch Luangpon, Kultida Klarod, Pornprom Surakul, Niramon Thamwiriyasati, Sanita Singsanan, Nipaporn Ngernyuang

2024ACS Omega13 citationsDOIOpen Access PDF

Abstract

High Resolution Image Download MS PowerPoint Slide Chitosan-based scaffolding possesses unique properties that make it highly suitable for tissue engineering applications. Chitosan is derived from deacetylating chitin, which is particularly abundant in the shells of crustaceans. This study aimed to extract chitosan from shrimp shell waste ( Macrobrachium rosenbergii ) and produce biocomposite scaffolds using the extracted chitosan for cartilage tissue engineering applications. Chitinous material from shrimp shell waste was deproteinized and deacetylated. The extracted chitosan was characterized and compared to commercial chitosan through various physicochemical analyses. The findings revealed that the extracted chitosan shares similar trends in the Fourier transform infrared spectroscopy spectrum, energy dispersive X-ray mapping, and X-ray diffraction pattern to commercial chitosan. Despite differences in the degree of deacetylation, these results underscore its comparable quality. The extracted chitosan was mixed with agarose, collagen, and gelatin to produce the blending biocomposite AG-CH-COL-GEL scaffold by freeze-drying method. Results showed AG-CH-COL-GEL scaffolds have a 3D interconnected porous structure with pore size 88–278 μm, high water uptake capacity (>90%), and degradation percentages in 21 days between 5.08% and 30.29%. Mechanical compression testing revealed that the elastic modulus of AG-CH-COL-GEL scaffolds ranged from 44.91 to 201.77 KPa. Moreover, AG-CH-COL-GEL scaffolds have shown significant potential in effectively inducing human chondrocyte proliferation and enhancing aggrecan gene expression. In conclusion, AG-CH-COL-GEL scaffolds emerge as promising candidates for cartilage tissue engineering with their optimal physical properties and excellent biocompatibility. This study highlights the potential of using waste-derived chitosan and opens new avenues for sustainable and effective tissue engineering solutions .

Topics & Concepts

BiocompositeChitosanShell (structure)Extraction (chemistry)Tissue engineeringShrimpMaterials scienceBiomedical engineeringPulp and paper industryComposite materialChemical engineeringChemistryEngineeringChromatographyComposite numberBiologyFisherySilk-based biomaterials and applicationsCollagen: Extraction and CharacterizationBone Tissue Engineering Materials