Evaluating neuronal and glial growth on electrospun polarized matrices: bridging the gap in percussive spinal cord injuries

Woon N. Chow; David G. Simpson; John W. Bigbee; Raymond J. Colello

doi:10.1017/S1740925X07000580

Abstract

One of the many obstacles to spinal cord repair following trauma is the formation of a cyst that impedes axonal regeneration. Accordingly, we examined the potential use of electrospinning to engineer an implantable polarized matrix for axonal guidance. Polydioxanone, a resorbable material, was electrospun to fabricate matrices possessing either aligned or randomly oriented fibers. To assess the extent to which fiber alignment influences directional neuritic outgrowth, rat dorsal root ganglia (DRGs) were cultured on these matrices for 10 days. Using confocal microscopy, neurites displayed a directional growth that mimicked the fiber alignment of the underlying matrix. Because these matrices are generated from a material that degrades with time, we next determined whether a glial substrate might provide a more stable interface between the resorbable matrix and the outgrowing axons. Astrocytes seeded onto either aligned or random matrices displayed a directional growth pattern similar to that of the underlying matrix. Moreover, these glia-seeded matrices, once co-cultured with DRGs, conferred the matrix alignment to and enhanced outgrowth exuberance of the extending neurites. These experiments demonstrate the potential for electrospinning to generate an aligned matrix that influences both the directionality and growth dynamics of DRG neurites.

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Xie, Jingwei Li, Xiaoran and Xia, Younan 2008. Putting Electrospun Nanofibers to Work for Biomedical Research. Macromolecular Rapid Communications, Vol. 29, Issue. 22, p. 1775.

Xie, Jingwei MacEwan, Matthew R. Li, Xiaoran Sakiyama-Elbert, Shelly E. and Xia, Younan 2009. Neurite Outgrowth on Nanofiber Scaffolds with Different Orders, Structures, and Surface Properties. ACS Nano, Vol. 3, Issue. 5, p. 1151.

Xie, Jingwei MacEwan, Matthew R. Willerth, Stephanie M. Li, Xiaoran Moran, Daniel W. Sakiyama‐Elbert, Shelly E. and Xia, Younan 2009. Conductive Core–Sheath Nanofibers and Their Potential Application in Neural Tissue Engineering. Advanced Functional Materials, Vol. 19, Issue. 14, p. 2312.

Cao, Haoqing Liu, Ting and Chew, Sing Yian 2009. The application of nanofibrous scaffolds in neural tissue engineering. Advanced Drug Delivery Reviews, Vol. 61, Issue. 12, p. 1055.

Xie, Jingwei MacEwan, Matthew R. Schwartz, Andrea G. and Xia, Younan 2010. Electrospun nanofibers for neural tissue engineering. Nanoscale, Vol. 2, Issue. 1, p. 35.

East, Emma de Oliveira, Daniela Blum Golding, Jon P. and Phillips, James B. 2010. Alignment of Astrocytes Increases Neuronal Growth in Three-Dimensional Collagen Gels and Is Maintained Following Plastic Compression to Form a Spinal Cord Repair Conduit. Tissue Engineering Part A, Vol. 16, Issue. 10, p. 3173.

Ayres, Chantal E. Jha, B. Shekhar Sell, Scott A. Bowlin, Gary L. and Simpson, David G. 2010. Nanotechnology in the design of soft tissue scaffolds: innovations in structure and function. WIREs Nanomedicine and Nanobiotechnology, Vol. 2, Issue. 1, p. 20.

Beachley, Vince Katsanevakis, Eleni Zhang, Ning and Wen, Xuejun 2011. Biomedical Applications of Polymeric Nanofibers. Vol. 246, Issue. , p. 171.

Schaub, Nicholas J and Gilbert, Ryan J 2011. Controlled release of 6-aminonicotinamide from aligned, electrospun fibers alters astrocyte metabolism and dorsal root ganglia neurite outgrowth. Journal of Neural Engineering, Vol. 8, Issue. 4, p. 046026.

Jha, Balendu S. Colello, Raymond J. Bowman, James R. Sell, Scott A. Lee, Kangmin D. Bigbee, John W. Bowlin, Gary L. Chow, Woon N. Mathern, Bruce E. and Simpson, David G. 2011. Two pole air gap electrospinning: Fabrication of highly aligned, three-dimensional scaffolds for nerve reconstruction. Acta Biomaterialia, Vol. 7, Issue. 1, p. 203.

Phillips, James B. and Brown, Robert 2011. 3D Cell Culture. Vol. 695, Issue. , p. 183.

Lee, Yee-Shuan Collins, George and Livingston Arinzeh, Treena 2011. Neurite extension of primary neurons on electrospun piezoelectric scaffolds. Acta Biomaterialia, Vol. 7, Issue. 11, p. 3877.

You, Qingjun Duan, Liang Wang, Feng Du, Xiaodong and Xiao, Mingdi 2011. Characterization of the Inhibition of Vein Graft Intimal Hyperplasia by a Biodegradable Vascular Stent. Cell Biochemistry and Biophysics, Vol. 59, Issue. 2, p. 99.

Han, Dong and Cheung, Karen C. 2011. Biodegradable Cell-Seeded Nanofiber Scaffolds for Neural Repair. Polymers, Vol. 3, Issue. 4, p. 1684.

Alekseeva, Tijna Abou Neel, Ensanya A Knowles, Jonathan C. and Brown, Robert A. 2012. Development of Conical Soluble Phosphate Glass Fibers for Directional Tissue Growth. Journal of Biomaterials Applications, Vol. 26, Issue. 6, p. 733.

Wang, TY Forsythe, JS Parish, CL and Nisbet, DR 2012. Biofunctionalisation of polymeric scaffolds for neural tissue engineering. Journal of Biomaterials Applications, Vol. 27, Issue. 4, p. 369.

Lee, Sang and Yoo, James 2012. Handbook of Intelligent Scaffold for Tissue Engineering and Regenerative Medicine. p. 201.

Tan, Aaron Rajadas, Jayakumar and Seifalian, Alexander M. 2012. Biochemical engineering nerve conduits using peptide amphiphiles. Journal of Controlled Release, Vol. 163, Issue. 3, p. 342.

Madurantakam, Parthasarathy A. Rodriguez, Isaac A. Garg, Koyal McCool, Jennifer M. Moon, Peter C. and Bowlin, Gary L. 2013. Compression of Multilayered Composite Electrospun Scaffolds: A Novel Strategy to Rapidly Enhance Mechanical Properties and Three Dimensionality of Bone Scaffolds. Advances in Materials Science and Engineering, Vol. 2013, Issue. , p. 1.

Schaub, Nicholas J. Britton, Tara Rajachar, Rupak and Gilbert, Ryan J. 2013. Engineered Nanotopography on Electrospun PLLA Microfibers Modifies RAW 264.7 Cell Response. ACS Applied Materials & Interfaces, Vol. 5, Issue. 20, p. 10173.

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Evaluating neuronal and glial growth on electrospun polarized matrices: bridging the gap in percussive spinal cord injuries

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Evaluating neuronal and glial growth on electrospun polarized matrices: bridging the gap in percussive spinal cord injuries

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