Literature DB >> 25982872

Artificial collagen-filament scaffold promotes axon regeneration and long tract reconstruction in a rat model of spinal cord transection.

Hidenori Suzuki1, Tsukasa Kanchiku2, Yasuaki Imajo2, Yuichiro Yoshida2, Norihiro Nishida2, Toshikazu Gondo3, Satoru Yoshii4, Toshihiko Taguchi2.   

Abstract

Traumatically injured spinal cord (SC) displays structural damage that includes discontinuity of long tracts and cavitations. Axonal regrowth beyond the lesion is necessary to achieve functional recovery following SC injury. We report here the development of an artificial collagen-filament (CF) scaffold to replace the SC in 8-week-old female Fisher rats. Axonal sprouting and regrowth was very rapid following grafting of the CF. One week after implantation, the scaffold was filled with cells of host origin and with regenerated axons. Histological examination of SC adjacent to the scaffold showed little cavity formation or fibrous scarring. Eight weeks after implantation, myelinated nerve fibers were found in the scaffold and 10-25 % of rubrospinal tracts were repaired. Four to six weeks after transplantation, motor evoked potentials were recorded in CF-grafted rats but were not detectable in non-grafted rats. Electrophysiological and histological examinations revealed the grafted CF was likely to function as a nerve tract. In addition, these results suggest that collagen fibers may provide a permissive microenvironment for the elongation of SC axons and to support the process of spinal cord regeneration.

Entities:  

Keywords:  Axonal regeneration; Collagen filament; Long tract; Motor evoked potential; Spinal cord injury

Mesh:

Substances:

Year:  2015        PMID: 25982872     DOI: 10.1007/s00795-015-0104-5

Source DB:  PubMed          Journal:  Med Mol Morphol        ISSN: 1860-1499            Impact factor:   2.309


  33 in total

Review 1.  Building a bridge: engineering spinal cord repair.

Authors:  Herbert M Geller; James W Fawcett
Journal:  Exp Neurol       Date:  2002-04       Impact factor: 5.330

Review 2.  Biopolymers and biodegradable smart implants for tissue regeneration after spinal cord injury.

Authors:  Liudmila N Novikova; Lev N Novikov; Jan-Olof Kellerth
Journal:  Curr Opin Neurol       Date:  2003-12       Impact factor: 5.710

3.  Neurospheres induced from bone marrow stromal cells are multipotent for differentiation into neuron, astrocyte, and oligodendrocyte phenotypes.

Authors:  Hidenori Suzuki; Toshihiko Taguchi; Hiroshi Tanaka; Hideo Kataoka; Zhenglin Li; Keiichi Muramatsu; Toshikazu Gondo; Shinya Kawai
Journal:  Biochem Biophys Res Commun       Date:  2004-09-24       Impact factor: 3.575

4.  Multiple-channel scaffolds to promote spinal cord axon regeneration.

Authors:  Michael J Moore; Jonathan A Friedman; Eric B Lewellyn; Sara M Mantila; Aaron J Krych; Syed Ameenuddin; Andrew M Knight; Lichun Lu; Bradford L Currier; Robert J Spinner; Richard W Marsh; Anthony J Windebank; Michael J Yaszemski
Journal:  Biomaterials       Date:  2005-08-31       Impact factor: 12.479

5.  Transplantation of neurospheres derived from bone marrow stromal cells promotes neurological recovery in rats with spinal cord injury.

Authors:  Hidenori Suzuki; Toshihiko Taguchi; Yoshihiko Kato; Tsukasa Kanchiku; Takashi Imagama; Takahiro Yara; Atsushi Moriya; Keiichi Muramatsu; Hiroshi Tanaka; Toshikazu Gondo
Journal:  Med Mol Morphol       Date:  2011-09-16       Impact factor: 2.309

6.  Bridging a spinal cord defect using collagen filament.

Authors:  Satoru Yoshii; Masanori Oka; Mitsuhiro Shima; Masao Akagi; Ataru Taniguchi
Journal:  Spine (Phila Pa 1976)       Date:  2003-10-15       Impact factor: 3.468

Review 7.  Spinal cord injury: time to move?

Authors:  Serge Rossignol; Martin Schwab; Michal Schwartz; Michael G Fehlings
Journal:  J Neurosci       Date:  2007-10-31       Impact factor: 6.167

8.  Nerve growth factor delivery by gene transfer induces differential outgrowth of sensory, motor, and noradrenergic neurites after adult spinal cord injury.

Authors:  M H Tuszynski; K Gabriel; F H Gage; S Suhr; S Meyer; A Rosetti
Journal:  Exp Neurol       Date:  1996-01       Impact factor: 5.330

9.  Restoration of function after spinal cord transection using a collagen bridge.

Authors:  Satoru Yoshii; Masanori Oka; Mitsuhiro Shima; Ataru Taniguchi; Yoshiro Taki; Masao Akagi
Journal:  J Biomed Mater Res A       Date:  2004-09-15       Impact factor: 4.396

Review 10.  Functional electrical stimulation after spinal cord injury: current use, therapeutic effects and future directions.

Authors:  K T Ragnarsson
Journal:  Spinal Cord       Date:  2007-09-11       Impact factor: 2.772
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  4 in total

1.  Anatomically Inspired Three-dimensional Micro-tissue Engineered Neural Networks for Nervous System Reconstruction, Modulation, and Modeling.

Authors:  Laura A Struzyna; Dayo O Adewole; Wisberty J Gordián-Vélez; Michael R Grovola; Justin C Burrell; Kritika S Katiyar; Dmitriy Petrov; James P Harris; D Kacy Cullen
Journal:  J Vis Exp       Date:  2017-05-31       Impact factor: 1.355

2.  Experimental Models of Spinal Cord Injury in Laboratory Rats.

Authors:  A N Minakov; A S Chernov; D S Asutin; N A Konovalov; G B Telegin
Journal:  Acta Naturae       Date:  2018 Jul-Sep       Impact factor: 1.845

Review 3.  Fibrotic Scar in CNS Injuries: From the Cellular Origins of Fibroblasts to the Molecular Processes of Fibrotic Scar Formation.

Authors:  Maryam Ayazi; Sandra Zivkovic; Grace Hammel; Branko Stefanovic; Yi Ren
Journal:  Cells       Date:  2022-08-02       Impact factor: 7.666

Review 4.  Biomaterial-Supported Cell Transplantation Treatments for Spinal Cord Injury: Challenges and Perspectives.

Authors:  Shengwen Liu; Thomas Schackel; Norbert Weidner; Radhika Puttagunta
Journal:  Front Cell Neurosci       Date:  2018-01-11       Impact factor: 5.505
  4 in total

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