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Abstract

Melt electrowriting (MEW) can print high-resolution scaffolds with the ultrafine fibers from 800 nm to 20 µm. However, the cell seeding efficiency relatively low due to the large pore size of the MEW scaffold. Here, we reported a method to solve this dilemma by electrospinning a gelatin methacrylate (GelMA) hydrogel fibers membrane (HFM) on the MEW scaffold. This composite scaffold can own the controlled structures and porosity and excellent cell seeding performance. We systematically investigate the fabrication, morphology, and biocompatibility of composite scaffolds. The implanting of human umbilical vein endothelial cells(HUVES) showed excellent adhesion and biocompatibility on the composite scaffold. Moreover, the cells migrated gradually into the MEW scaffold along the GelMA HFM to form the cell sheet. We hold the opinion that the composite scaffolds have potential applications in the field of tissue engineering repair.

Keywords

Melt electrowriting electrospinning gelatin methacrylate composite scaffold

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3D printed high-resolution scaffold with hydrogel microfibers for providing excellent biocompatibility

Abstract

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