Hostname: page-component-cd9895bd7-mkpzs Total loading time: 0 Render date: 2024-12-27T02:41:29.010Z Has data issue: false hasContentIssue false
  • English
  • Français

Functional Recovery Following Spinal Cord Hemisection Mediated by a Unique Polymer Scaffold Seeded with Neural Stem Cells

Published online by Cambridge University Press:  15 March 2011

Erin Lavik ,
Yang D. Teng ,
David Zurakowski ,
Xianlu Qu ,
Evan Snyder  and
Robert Langer
Erin Lavik
Affiliation:
Department of Materials Science and Engineering, MIT
Yang D. Teng
Affiliation:
Department of Neurology, Children's Hospital, Boston
David Zurakowski
Affiliation:
Department of Orthopedics, Children's Hospital, Boston;
Xianlu Qu
Affiliation:
Department of Neurology, Children's Hospital, Boston
Evan Snyder
Affiliation:
Department of Neurology, Children's Hospital, Boston
Robert Langer
Affiliation:
Department of Chemical Engineering, MIT
Get access

Abstract

A dual scaffold structure made of biodegradable polymers and seeded with neural stem cells has been developed to address the issues of spinal cord injury including axonal severance and the loss of neurons and glia. The general design of the scaffold is derived the structure of the spinal cord with an outer section which mimics the white matter with long axial pores to provide axonal guidance and an inner section seeded with neural stem cells to address the issues of cell replacement and mimic the general character of the gray matter. The seeded scaffold leads to improved functional recovery as compared with the lesion control or cells alone following spinal cord injury.

Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 662: Symposia LL/MM/NN/OO – Biomaterials for Drug Delivery & Tissue Engineering , 2000 , OO1.2
Copyright
Copyright © Materials Research Society 2001

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

[1] Center, N. S. C. I. S., “Facts and Figures at a Glance,” University of Alabama, Brimingham, Alabama 2000.Google Scholar
[2] McDonald, J. W., Liu, X.-Z., Qu, Y., Liu, S., Mickey, S. K., Turetsky, D., Gottleib, D. I., and Choi, D. W., “Transplanted Embryonic Stem Cells Survive, Differentiate and Promote Recovery in Injured Rat Spinal Cord,” Nature Medicine, vol. 5, pp. 14101412, 1999.Google Scholar
[3] Xu, X., Zhang, S.-X., Li, H., Aebischer, P., and Bunge, M., “Regrowth of Axons into the Distal Spinal Cord Through a Schwann-Cell-Seeded Mini-Chanel Implanted into Hemisected Adult Rat Spinal Cord,” European Journal of Neuroscience, vol. 11, pp. 17231740, 1999.Google Scholar
[4] Khan, T., Dauzvardis, M., and Sayers, S., “Carbon Filament Implants Promote Axonal Growth Across the Transected Rat Spinal Cord,” Brain Research, vol. 541, pp. 139145, 1991.Google Scholar
[5] Marchand, R., and Woerley, S., “Transected Spinal Cords Grafted With In Situ Self-Assembled Collagen Matrices,” Neurosocientist, vol. 36, pp. 4560, 1990.Google Scholar
[6] Bellamkonda, R., Ranieri, J. P., and Aebischer, P., “Laminin Oligopeptide Derivatized Agarose Gels Allow Three-Dimensional Neurite Extension in Vitro,” Journal of Neuroscience Research, vol. 41, pp. 501509, 1995.Google Scholar
[7] Vacanti, M., Leonard, J., Dore, B., Bonassar, L., Cao, Y., Stachelek, S., Yu, C., O'Connell, F., Vacanti, J., and Vacanti, C., “Tissue Engineered Spinal Cord,” FASEB Journal, vol. 14, pp. A446–A446, 2000.Google Scholar
[8] Yandava, B., Billinghurst, L., and Snyder, E., ““Global” Cell Replacement is Feasible Via Neural Stem Cell Transplantation: Evidence from the Dysmyelinated Shiverer Mouse Brain,” Proceedings of the National Academy of Sciences, vol. 96, pp. 70297034, 1999.Google Scholar
[9] Mikos, A. G., Thorsen, A. J., Czerwonka, L. A., Bao, Y., Winslow, D. N., and Langer, R., “Preparation and Characterization of Poly(L-lactic acid) Foams,” Polymer, vol. 35, pp. 10681077, 1994.Google Scholar
[10] Schurgens, C., Maquet, V., Grandfils, C., Jerome, R., and Teyssie, P., “Biodegradable and Macroporous Polylactide Implants for Cell Transplanation: 1. Preparation of Macroporous Polylactide Supports by Solid-Liquid Phase Separation,” Polymer, vol. 37, pp. 10271038, 1996.Google Scholar
[11] Fitch, M. T., Doller, C., Combs, C. K., Landreth, G. E., and Silver, J., “Cellular and Molecular Mechanisms of Glial Scarring and Progressive Cavitation: In Vivo and In Vitro Analysis of InflMMtion-Induced Secondary Injury after CNS Trauma,” Journal of Neuoscience, vol. 19, pp. 81828198, 1999.Google Scholar
[12] Teng, Yang D., Lavik, Erin B., Qu, Xianlu, Ourednik, Jitka, Zurakowski, David, Langer, Robert, Snyder, Evan Y., “Functional Recovery Following Traumatic Spinal Cord Injury Mediated by a Unique Polymer Scaffold Seeded with Neural Stem Cells”, submitted 2000.Google Scholar
[13] Basso, D. M., Beattie, M. S., and Bresnahan, J. C., “A Sensitive and Reliable Locomotor Rating Scale for Open Field Testing in Rats,” Journal of Neurotrauma, vol. 12, pp. 121, 1995.Google Scholar
[14] Lu, P. et al. Neuroscience Abstract vol. 26, p. 332, 2000.Google Scholar