Nanofibers support oligodendrocyte precursor cell growth and function as a neuron-free model for myelination study

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Authors
Li, Yongchao
Ceylan, Muhammet
Shrestha, Bikesh
Wang, Haibo
Lu, Q. Richard
Asmatulu, Ramazan
Yao, Li
Advisors
Issue Date
2014-01
Type
Article
Keywords
SPINAL-CORD-INJURY , ENGINEERED NANOFIBERS , NERVE REGENERATION , SCHWANN-CELLS , TRANSECTION , STEM , RAT , SCAFFOLDS , OUTGROWTH , CULTURE
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Li, Yongchao; Ceylan, Muhammet; Shrestha, Bikesh; Wang, Haibo; Lu, Q. Richard; Asmatulu, Ramazan; Yao, Li. 2014. Nanofibers support oligodendrocyte precursor cell growth and function as a neuron-free model for myelination study. Biomacromolecules, vol. 15:no. 1:ppg. 319–326
Abstract

Nanofiber-based scaffolds may simultaneously provide immediate contact guidance for neural regeneration and act as a vehicle for therapeutic cell delivery to enhance axonal myelination. Additionally, nanofibers can serve as a neuron-free model to study myelination of oligodendrocytes. In this study, we fabricated nanofibers using a polycaprolactone and gelatin copolymer. The ratio of the gelatin component in the fibers was confirmed by energy dispersive X-ray spectroscopy. The addition of gelatin to the polycaprolactone (PCL) for nanofiber fabrication decreased the contact angle of the electrospun fibers. We showed that both polycaprolactone nanofibers as well as polycaprolactone and gelatin copolymer nanofibers can support oligodendrocyte precursor cell (OPC) growth and differentiation. OPCs maintained their phenotype and viability on nanofibers and were induced to differentiate into oligodendrocytes. The differentiated oligodendrocytes extend their processes along the nanofibers and ensheathed the nanofibers. Oligodendrocytes formed significantly more myelinated segments on the PCL and gelatin copolymer nanofibers than those on PCL nanofibers alone.

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Publisher
American Chemical Society
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Series
Biomacromolecules;v.15:no.1
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DOI
ISSN
1525-7797
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