Organic-inorganic biohybrid films from wool-keratin/jellyfish-collagen/silica/boron via sol-gel reactions for soft tissue engineering applications

Yildiz, Safiye Nur; Sezgin Arslan, Tugba; Arslan, Yavuz Emre

doi:10.1088/1748-605x/ad2557

Biomed. Mater.

2024

DOI: 10.1088/1748-605x/ad2557

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Organic-inorganic biohybrid films from wool-keratin/jellyfish-collagen/silica/boron via sol-gel reactions for soft tissue engineering applications

Safiye Nur Yildiz,

Tugba Sezgin Arslan,

Yavuz Emre Arslan

Abstract: Therapeutic angiogenesis is pivotal in creating effective tissue-engineered constructs that deliver nutrients and oxygen to surrounding cells. Hence, biomaterials that promote angiogenesis can enhance the efficacy of various medical treatments, encompassing tissue engineering, wound healing, and drug delivery systems. Considering these, we propose a rapid method for producing composite silicon-boron-wool keratin/jellyfish collagen (Si-B-WK/JFC) inorganic-organic biohybrid films using sol-gel reactions. In this… Show more

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A Facile Strategy for Preparing Flexible and Porous Hydrogel‐Based Scaffolds from Silk Sericin/Wool Keratin by In Situ Bubble‐Forming for Muscle Tissue Engineering Applications

Demiray,

Sezgin Arslan,

Derkus

et al. 2024

Macromolecular Bioscience

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In the present study, it is aimed to fabricate a novel silk sericin (SS)/wool keratin (WK) hydrogel‐based scaffolds using an in situ bubble‐forming strategy containing an N‐(3‐dimethylaminopropyl)‐N′‐ethylcarbodiimide hydrochloride (EDC) and N‐hydroxysuccinimide (NHS) coupling reaction. During the rapid gelation process, CO2 bubbles are released by activating the carboxyl groups in sericin with EDC and NHS, entrapped within the gel, creating a porous cross‐linked structure. With this approach, five different hydrogels (S2K1, S4K2, S2K4, S6K3, and S3K6) are constructed to investigate the impact of varying sericin and keratin ratios. Analyses reveal that more sericin in the proteinaceous mixture reinforced the hydrogel network. Additionally, the hydrogels’ pore size distribution, swelling ratio, wettability, and in vitro biodegradation rate, which are crucial for the applications of biomaterials, are evaluated. Moreover, biocompatibility and proangiogenic properties are analyzed using an in‐ovo chorioallantoic membrane assay. The findings suggest that the S4K2 hydrogel exhibited the most promising characteristics, featuring an adequately flexible and highly porous structure. The results obtained by in vitro assessments demonstrate the potential of S4K2 hydrogel in muscle tissue engineering. However, further work is necessary to improve hydrogels with an aligned structure to meet the features that can fully replace muscle tissue for volumetric muscle loss regeneration.

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A Facile Strategy for Preparing Flexible and Porous Hydrogel‐Based Scaffolds from Silk Sericin/Wool Keratin by In Situ Bubble‐Forming for Muscle Tissue Engineering Applications

Demiray,

Sezgin Arslan,

Derkus

et al. 2024

Macromolecular Bioscience

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show abstract

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Organic-inorganic biohybrid films from wool-keratin/jellyfish-collagen/silica/boron via sol-gel reactions for soft tissue engineering applications

Cited by 1 publication

References 48 publications

A Facile Strategy for Preparing Flexible and Porous Hydrogel‐Based Scaffolds from Silk Sericin/Wool Keratin by In Situ Bubble‐Forming for Muscle Tissue Engineering Applications

A Facile Strategy for Preparing Flexible and Porous Hydrogel‐Based Scaffolds from Silk Sericin/Wool Keratin by In Situ Bubble‐Forming for Muscle Tissue Engineering Applications

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