Electrospun poly(vinyl alcohol)/reduced graphene oxide nanofibrous scaffolds for skin tissue engineering

[Display omitted] •Glucose-reduced graphene oxide (GRGO) was synthesized using glucose as a reducing agent.•Nanofibrous composites of poly(vinyl alcohol)/GRGO (PG) were fabricated by electrospinning.•PG scaffolds were covalently crosslinked using acidic glutaraldehyde in acetone environment.•PG scaf...

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Published in:Colloids and surfaces, B, Biointerfaces B, Biointerfaces, 2020-07, Vol.191, p.110994, Article 110994
Main Authors: Narayanan, Kannan Badri, Park, Gyu Tae, Han, Sung Soo
Format: Article
Language:English
Subjects:
Animals
Biocompatible Materials - chemistry
Cell Proliferation
Cells, Cultured
Electrospinning
Erythrocytes - cytology
Fibroblast
Fibroblasts - cytology
Graphite - chemistry
Humans
Nanofibers - chemistry
Poly(vinyl alcohol)
Polyvinyl Alcohol - chemistry
Reduced graphene oxide
Scaffold
Skin - cytology
Swine
Tissue engineering
Tissue Engineering - methods
Tissue Scaffolds
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Summary:[Display omitted] •Glucose-reduced graphene oxide (GRGO) was synthesized using glucose as a reducing agent.•Nanofibrous composites of poly(vinyl alcohol)/GRGO (PG) were fabricated by electrospinning.•PG scaffolds were covalently crosslinked using acidic glutaraldehyde in acetone environment.•PG scaffolds did not induce perceptible red blood cell hemolysis even at a GRGO concentration of 1 wt%.•PG scaffolds exhibited excellent hemocompatibility and biocompatibility with skin fibroblasts. Graphene is composed of a two-dimensional (2D) layer of carbon atoms arranged in a honeycomb lattice configuration. In this paper, we adopted a green synthetic method of producing reduced graphene oxide using glucose as a reducing and stabilizing agent. We also investigated the fabrication of electrospun nanofibers of glucose-reduced graphene oxide (GRGO) (0–1.0 wt%) reinforced with polyvinyl alcohol (PVA) as (PG) scaffolds, and chemically crosslinked with acidic glutaraldehyde (GA) in acetone medium to mimic the extracellular matrix (ECM) for skin tissue engineering applications. These PG scaffolds were evaluated for morphology, mechanical strength, surface wettability, thermal properties, hemocompatibility, and biocompatibility. Field emission-scanning electron microscopy (FE-SEM) revealed an increase in the thickness of nanofibers in PG scaffolds with an increase in the concentration of GRGO. X-ray diffraction and attenuated total reflectance-infrared and Raman spectra showed the GRGO was incorporated in the PVA nanofibrous matrix. As the concentration of GRGO was increased in PG scaffolds, tensile strengths and elongations at break decreased, whereas thermal properties increased. The biological activities of PG scaffolds were evaluated using in vitro hemolysis, using CCD-986Sk (a human skin fibroblast cell line) viability and proliferation assays, and by live/dead cell imaging. Results showed GRGO inclusion in PVA nanofibers caused a slight hydrophilic to hydrophobic shift. PG scaffolds did not cause hemolysis of red blood cells even at a GRGO loading of 1.0 wt%, and PG-1.0 scaffold (with a GRGO loading of 1.0 wt%) exhibited excellent compatibility with fibroblasts and significantly increased metabolic activity after culture for 21 days as compared with PG-0 controls. DAPI staining and live/dead imaging assays showed that all PG scaffolds increased fibroblast proliferation and viability, indicating the potential for skin tissue engineering applications.
ISSN:0927-7765
1873-4367
DOI:10.1016/j.colsurfb.2020.110994