Literature DB >> 25591483

Repair of spinal cord injury with neuronal relays: From fetal grafts to neural stem cells.

Joseph F Bonner1, Oswald Steward2.   

Abstract

Spinal cord injury (SCI) disrupts the long axonal tracts of the spinal cord leading to devastating loss of function. Cell transplantation in the injured spinal cord has the potential to lead to recovery after SCI via a variety of mechanisms. One such strategy is the formation of neuronal relays between injured long tract axons and denervated neurons. The idea of creating a neuronal relay was first proposed over 25 years ago when fetal tissue was first successfully transplanted into the injured rodent spinal cord. Advances in labeling of grafted cells and the development of neural stem cell culturing techniques have improved the ability to create and refine such relays. Several recent studies have examined the ability to create a novel neuronal circuit between injured axons and denervated targets. This approach is an alternative to long-distance regeneration of damaged axons that may provide a meaningful degree of recovery without direct recreation of lost pathways. This brief review will examine the contribution of fetal grafting to current advances in neuronal grafting. Of particular interest will be the ability of transplanted neurons derived from fetal grafts, neural precursor cells and neural stem cells to reconnect long distance motor and sensory pathways of the injured spinal cord. This article is part of a Special Issue entitled SI: Spinal cord injury.
Copyright © 2015 Elsevier B.V. All rights reserved.

Entities:  

Keywords:  Fetal graft; Neural progenitor cells; Neural stem cells; Neuronal relay; Spinal cord Injury; Transplantation

Mesh:

Year:  2015        PMID: 25591483      PMCID: PMC4499497          DOI: 10.1016/j.brainres.2015.01.006

Source DB:  PubMed          Journal:  Brain Res        ISSN: 0006-8993            Impact factor:   3.252


  74 in total

1.  Differential fate of multipotent and lineage-restricted neural precursors following transplantation into the adult CNS.

Authors:  Angelo C Lepore; Steven S W Han; Carla J Tyler-Polsz; Jingli Cai; Mahendra S Rao; Itzhak Fischer
Journal:  Neuron Glia Biol       Date:  2004-05

2.  Axonal projections between fetal spinal cord transplants and the adult rat spinal cord: a neuroanatomical tracing study of local interactions.

Authors:  L B Jakeman; P J Reier
Journal:  J Comp Neurol       Date:  1991-05-08       Impact factor: 3.215

3.  Forebrain GABAergic neuron precursors integrate into adult spinal cord and reduce injury-induced neuropathic pain.

Authors:  João M Bráz; Reza Sharif-Naeini; Daniel Vogt; Arnold Kriegstein; Arturo Alvarez-Buylla; John L Rubenstein; Allan I Basbaum
Journal:  Neuron       Date:  2012-05-24       Impact factor: 17.173

4.  Leukocyte common antigen-related phosphatase is a functional receptor for chondroitin sulfate proteoglycan axon growth inhibitors.

Authors:  Daniel Fisher; Bin Xing; John Dill; Hui Li; Hai Hiep Hoang; Zhenze Zhao; Xiao-Li Yang; Robert Bachoo; Stephen Cannon; Frank M Longo; Morgan Sheng; Jerry Silver; Shuxin Li
Journal:  J Neurosci       Date:  2011-10-05       Impact factor: 6.167

5.  Pseudorabies virus-based gene delivery to rat embryonic spinal cord grafts.

Authors:  Zsolt Boldogköi; András Szabó; Gerta Vrbová; Antal Nógrádi
Journal:  Hum Gene Ther       Date:  2002-04-10       Impact factor: 5.695

Review 6.  A systematic review of directly applied biologic therapies for acute spinal cord injury.

Authors:  Brian K Kwon; Elena B Okon; Ward Plunet; Darryl Baptiste; Karim Fouad; Jessica Hillyer; Lynne C Weaver; Michael G Fehlings; Wolfram Tetzlaff
Journal:  J Neurotrauma       Date:  2010-06-16       Impact factor: 5.269

7.  PTPsigma is a receptor for chondroitin sulfate proteoglycan, an inhibitor of neural regeneration.

Authors:  Yingjie Shen; Alan P Tenney; Sarah A Busch; Kevin P Horn; Fernando X Cuascut; Kai Liu; Zhigang He; Jerry Silver; John G Flanagan
Journal:  Science       Date:  2009-10-15       Impact factor: 47.728

8.  Recovery of supraspinal control of stepping via indirect propriospinal relay connections after spinal cord injury.

Authors:  Gregoire Courtine; Bingbing Song; Roland R Roy; Hui Zhong; Julia E Herrmann; Yan Ao; Jingwei Qi; V Reggie Edgerton; Michael V Sofroniew
Journal:  Nat Med       Date:  2008-01-06       Impact factor: 53.440

9.  Targeting axon growth from neuronal transplants along preformed guidance pathways in the adult CNS.

Authors:  Kristine S Ziemba; Nagarathnamma Chaudhry; Alexander G Rabchevsky; Ying Jin; George M Smith
Journal:  J Neurosci       Date:  2008-01-09       Impact factor: 6.167

10.  Treatment of a mouse model of spinal cord injury by transplantation of human induced pluripotent stem cell-derived long-term self-renewing neuroepithelial-like stem cells.

Authors:  Yusuke Fujimoto; Masahiko Abematsu; Anna Falk; Keita Tsujimura; Tsukasa Sanosaka; Berry Juliandi; Katsunori Semi; Masakazu Namihira; Setsuro Komiya; Austin Smith; Kinichi Nakashima
Journal:  Stem Cells       Date:  2012-06       Impact factor: 6.277
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  26 in total

Review 1.  Cell biology of spinal cord injury and repair.

Authors:  Timothy M O'Shea; Joshua E Burda; Michael V Sofroniew
Journal:  J Clin Invest       Date:  2017-07-24       Impact factor: 14.808

Review 2.  Improving the therapeutic efficacy of neural progenitor cell transplantation following spinal cord injury.

Authors:  Michael A Lane; Angelo C Lepore; Itzhak Fischer
Journal:  Expert Rev Neurother       Date:  2016-12-21       Impact factor: 4.618

3.  The Therapeutic Effectiveness of Delayed Fetal Spinal Cord Tissue Transplantation on Respiratory Function Following Mid-Cervical Spinal Cord Injury.

Authors:  Chia-Ching Lin; Sih-Rong Lai; Yu-Han Shao; Chun-Lin Chen; Kun-Ze Lee
Journal:  Neurotherapeutics       Date:  2017-07       Impact factor: 7.620

Review 4.  Rewiring the spinal cord: Direct and indirect strategies.

Authors:  Maria Teresa Dell'Anno; Stephen M Strittmatter
Journal:  Neurosci Lett       Date:  2016-12-19       Impact factor: 3.046

5.  Integration of Transplanted Neural Precursors with the Injured Cervical Spinal Cord.

Authors:  Victoria M Spruance; Lyandysha V Zholudeva; Kristiina M Hormigo; Margo L Randelman; Tatiana Bezdudnaya; Vitaliy Marchenko; Michael A Lane
Journal:  J Neurotrauma       Date:  2018-04-24       Impact factor: 5.269

6.  Descending propriospinal neurons mediate restoration of locomotor function following spinal cord injury.

Authors:  Katelyn N Benthall; Ryan A Hough; Andrew D McClellan
Journal:  J Neurophysiol       Date:  2016-10-19       Impact factor: 2.714

Review 7.  The Neuroplastic and Therapeutic Potential of Spinal Interneurons in the Injured Spinal Cord.

Authors:  Lyandysha V Zholudeva; Liang Qiang; Vitaliy Marchenko; Kimberly J Dougherty; Shelly E Sakiyama-Elbert; Michael A Lane
Journal:  Trends Neurosci       Date:  2018-07-17       Impact factor: 13.837

8.  Grafting Embryonic Raphe Neurons Reestablishes Serotonergic Regulation of Sympathetic Activity to Improve Cardiovascular Function after Spinal Cord Injury.

Authors:  Shaoping Hou; Tatiana M Saltos; Eugene Mironets; Cameron T Trueblood; Theresa M Connors; Veronica J Tom
Journal:  J Neurosci       Date:  2020-01-02       Impact factor: 6.167

9.  Choosing the right cell for spinal cord repair.

Authors:  Lyandysha V Zholudeva; Michael A Lane
Journal:  J Neurosci Res       Date:  2018-11-01       Impact factor: 4.164

10.  Autophagy Inhibition Favors Survival of Rubrospinal Neurons After Spinal Cord Hemisection.

Authors:  Elisa Bisicchia; Laura Latini; Virve Cavallucci; Valeria Sasso; Vanessa Nicolin; Marco Molinari; Marcello D'Amelio; Maria Teresa Viscomi
Journal:  Mol Neurobiol       Date:  2016-08-11       Impact factor: 5.590
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