Improvement of mechanical properties of zein porous scaffold by quenching/electrospun fiber reinforcement
- 4 October 2021
- journal article
- research article
- Published by IOP Publishing in Biomedical Materials
- Vol. 16 (6), 065016
- https://doi.org/10.1088/1748-605x/ac265d
Abstract
As a novel bone substitute material, zein-based scaffolds (ZS) should have suitable mechanical properties and porosity. ZS has shown good compressive properties matching cancellous bone, but there is still a demand to improve its mechanical properties, especially tensile and bending properties without adding plasticizers. The present study explored two simple and environment-friendly factors for this purpose: fiber reinforcement and quenching. Addition of electrospun zein fibers enhanced all mechanical properties significantly including compressive, tensile, and bending moduli; compressive and bending strengths of ZS with both higher (70-80%) and lower (50-60%) porosities, no matter whether heating treated or not treated. Especially, all these parameters were further enhanced significantly by addition of heating treated fibers. AFM provided evidence that high temperature modification could significantly alter the micro-elastic properties of zein electrospun fibers, i.e., increased stiffness of fibers. Quenching treatment also enhanced compressive, tensile, and bending strengths significantly. Finally, quenching treated ZS were implanted into critical-sized bone defects (15 mm) of the rabbit model to compare the repair efficacy with a commercial beta-tricalcium phosphate product. The results demonstrated that there were no remarkable differences in bone reconstructions between these two materials.Keywords
Funding Information
- Science and Technology Commission Shanghai Municipality (13JC1403400)
- National Key Research and Development Project (2019YFE0101200)
- Shanghai Municipal Education Commission (ZXGF082101)
- Plan of Jiaxing Innovation and Elites Leading
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