Silk fibroin micro-particle scaffolds with superior compression modulus and slow bioresorption for effective bone regeneration

Silk fibroin micro-particle scaffolds with superior compression modulus and slow bioresorption for effective bone regeneration

Abstract Silk fibroin (SF), a natural polymer produced by Bombyx mori silkworms, has been extensively explored to prepare porous scaffolds for tissue engineering applications. Here, we demonstrate, a scaffold made of SF, which exhibits compression modulus comparable to natural cancellous bone while...

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Auteurs principaux: Anuya Nisal, Raeesa Sayyad, Prachi Dhavale, Bhakti Khude, Rucha Deshpande, Vidhyashri Mapare, Swati Shukla, Premnath Venugopalan
Format: article
Langue:EN
Publié: Nature Portfolio 2018
Sujets:
Medicine
R
Science
Q
Accès en ligne:https://doaj.org/article/704930cc48c2457f8c58276fe8eea5c7
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Résumé:Abstract Silk fibroin (SF), a natural polymer produced by Bombyx mori silkworms, has been extensively explored to prepare porous scaffolds for tissue engineering applications. Here, we demonstrate, a scaffold made of SF, which exhibits compression modulus comparable to natural cancellous bone while retaining the appropriate porosities and interconnected pore architecture. The scaffolds also exhibit high resistance to in-vitro proteolytic degradation due to the dominant beta sheet conformation of the SF protein. Additionally, the scaffolds are prepared using a simple method of microparticle aggregation. We also demonstrate, for the first time, a method to prepare SF micro-particles using a Hexafluoroisopropanol-Methanol solvent-coagulant combination. SF microparticles obtained using this method are monodisperse, spherical, non-porous and extremely crystalline. These micro-particles have been further aggregated together to form a 3D scaffold. The aggregation is achieved by random packing of these microparticles and fusing them together using a dilute SF solution. Preliminary in-vitro cell culture and in-vivo implantation studies demonstrate that the scaffolds are biocompatible and they exhibit the appropriate early markers, making them promising candidates for bone regeneration.

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