Simple and robust fabrication and characterization of conductive carbonized nanofibers loaded with gold nanoparticles for bone tissue engineering applications

Bone tissue engineering is a new and applicable emerging approach to repair bone defects. Electrical conductive scaffolds through a physiologically relevant physical signaling, i.e., electrical stimulation, are highly promising candidates for tissue engineering applications. In this paper, we fabric...

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Bibliographic Details
Published in:Materials Science & Engineering C 2020-12, Vol.117, p.111226, Article 111226
Main Authors: Nekounam, Houra, Allahyari, Zahra, Gholizadeh, Shayan, Mirzaei, Esmaeil, Shokrgozar, Mohammad Ali, Faridi-Majidi, Reza
Format: Article
Language:English
Subjects:
Blending
Bone tissue engineering
Bones
Carbon fibers
Carbon nanofiber
Cell proliferation
Conductive scaffolds
Electric Conductivity
Electrical conductivity
Electrical resistivity
Electrical stimuli
Electrospinning
Electrospraying
Fabrication
Gold
Gold nanoparticles
Graphitization
Infrared spectroscopy
Materials science
Mats
Metal Nanoparticles
Morphology
Nanofibers
Nanoparticles
Raman spectroscopy
Scaffolds
Spectroscopy
Spectroscopy, Fourier Transform Infrared
Spectrum analysis
Tissue Engineering
Tissue Scaffolds
Toxicity
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Summary:Bone tissue engineering is a new and applicable emerging approach to repair bone defects. Electrical conductive scaffolds through a physiologically relevant physical signaling, i.e., electrical stimulation, are highly promising candidates for tissue engineering applications. In this paper, we fabricated carbon nanofiber/gold nanoparticle (CNF/AuNP) conductive scaffolds using two distinct methods. These methods are blending electrospinning in which AuNPs were blended with electrospinning solution, and electrospinning/electrospraying in which AuNPs were electrosprayed simultaneously with electrospinning. The obtained electrospun mats underwent a stabilization/carbonization process. The scaffolds were characterized by SEM, XRD, FT-IR, and Raman spectroscopy. SEM characterizations showed improved morphology and a slight decrease in the diameter of the electrospinned and electrosprayed nanofibers (from 178.66 ± 38.40 nm to 157.94 ± 24.14 nm and 120.81 ± 13.77 nm, respectively). Raman spectroscopy showed improvement in the graphitization. Electrical conductivity improved by up to 29.2% and 81% in electrospraying and blending electrospinning modes, respectively. Indirect MTT and LDH toxicity assays directly were performed to assess MG63 cell toxicity, but no significant toxicity was observed, and the scaffolds did not adversely affect cell proliferation. It can be concluded these scaffolds have the potential for bone tissue engineering applications. [Display omitted] •Two robust methods are presented for loading carbon nanofibers with gold nanoparticles•Consistency in nanofiber size distribution is observed in both methods•Homogenous gold nanoparticle distribution is achieved in these methods•the crystalline form of the gold nanoparticles remained intact upon furnace exposure•In vitro experiments demonstrate high suitability for bone tissue engineering
ISSN:0928-4931
1873-0191
DOI:10.1016/j.msec.2020.111226