Literature DB >> 25866284

Exercise after spinal cord injury as an agent for neuroprotection, regeneration and rehabilitation.

Harra R Sandrow-Feinberg1, John D Houlé2.   

Abstract

Spinal cord injury (SCI) is a traumatic event from which there is limited recovery of function, despite the best efforts of many investigators to devise realistic therapeutic treatments. Partly this is due to the multifaceted nature of SCI, where there is considerable disarray and dysfunction secondary to the initial injury. Contributing to this secondary degeneration is neurotoxicity, vascular dysfunction, glial scarring, neuroinflammation, apoptosis and demyelination. It seems logical that addressing the need for neuroprotection, regeneration and rehabilitation will require different treatment strategies that may be applied at varied stages of the post-injury response. Here we focus on a single strategy, exercise/physical training, which appears to have multiple applications and benefits for an acute or chronic SCI. Exercise has been demonstrated to be advantageous at cellular and biochemical levels, as well as being of benefit for the whole animal or human subject. Data from our lab and others will be discussed to further elucidate the many positive aspects of implementing exercise following injury and to suggest that rehabilitation is not the sole target of a training regimen following SCI. This article is part of a Special Issue entitled SI: Spinal cord injury.
Copyright © 2015 Elsevier B.V. All rights reserved.

Entities:  

Keywords:  Exercise; Neurorehabilitation; Neurotrauma; Spinal cord injury

Mesh:

Substances:

Year:  2015        PMID: 25866284      PMCID: PMC4540698          DOI: 10.1016/j.brainres.2015.03.052

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


  56 in total

1.  Autoradiographic study of alpha1- and alpha2-noradrenergic and serotonin1A receptors in the spinal cord of normal and chronically transected cats.

Authors:  N Giroux; S Rossignol; T A Reader
Journal:  J Comp Neurol       Date:  1999-04-12       Impact factor: 3.215

Review 2.  Do apoptotic mechanisms regulate synaptic plasticity and growth-cone motility?

Authors:  Charles P Gilman; Mark P Mattson
Journal:  Neuromolecular Med       Date:  2002       Impact factor: 3.843

Review 3.  Upstream and downstream of mTOR.

Authors:  Nissim Hay; Nahum Sonenberg
Journal:  Genes Dev       Date:  2004-08-15       Impact factor: 11.361

Review 4.  Reducing cardiometabolic disease in spinal cord injury.

Authors:  Jochen Kressler; Rachel E Cowan; Gregory E Bigford; Mark S Nash
Journal:  Phys Med Rehabil Clin N Am       Date:  2014-08       Impact factor: 1.784

5.  Spontaneous corticospinal axonal plasticity and functional recovery after adult central nervous system injury.

Authors:  N Weidner; A Ner; N Salimi; M H Tuszynski
Journal:  Proc Natl Acad Sci U S A       Date:  2001-03-13       Impact factor: 11.205

6.  Acute and prolonged hindlimb exercise elicits different gene expression in motoneurons than sensory neurons after spinal cord injury.

Authors:  Benjamin E Keeler; Gang Liu; Rachel N Siegfried; Victoria Zhukareva; Marion Murray; John D Houlé
Journal:  Brain Res       Date:  2011-12-16       Impact factor: 3.252

7.  Exercise modulates microRNAs that affect the PTEN/mTOR pathway in rats after spinal cord injury.

Authors:  Gang Liu; Megan Ryan Detloff; Kassi N Miller; Lauren Santi; John D Houlé
Journal:  Exp Neurol       Date:  2011-11-19       Impact factor: 5.330

8.  Voluntary exercise induces a BDNF-mediated mechanism that promotes neuroplasticity.

Authors:  Fernando Gómez-Pinilla; Zhe Ying; Roland R Roy; Raffaella Molteni; V Reggie Edgerton
Journal:  J Neurophysiol       Date:  2002-11       Impact factor: 2.714

Review 9.  The growing role of mTOR in neuronal development and plasticity.

Authors:  Jacek Jaworski; Morgan Sheng
Journal:  Mol Neurobiol       Date:  2006-12       Impact factor: 5.590

10.  Altered patterns of reflex excitability, balance, and locomotion following spinal cord injury and locomotor training.

Authors:  Prodip K Bose; Jiamei Hou; Ronald Parmer; Paul J Reier; Floyd J Thompson
Journal:  Front Physiol       Date:  2012-07-18       Impact factor: 4.566
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  30 in total

Review 1.  The role of exosomal microRNAs in central nervous system diseases.

Authors:  Yifei Yu; Kun Hou; Tong Ji; Xishu Wang; Yining Liu; Yangyang Zheng; Jinying Xu; Yi Hou; Guangfan Chi
Journal:  Mol Cell Biochem       Date:  2021-01-29       Impact factor: 3.396

2.  Cbp-dependent histone acetylation mediates axon regeneration induced by environmental enrichment in rodent spinal cord injury models.

Authors:  Thomas H Hutson; Claudia Kathe; Ilaria Palmisano; Kay Bartholdi; Arnau Hervera; Francesco De Virgiliis; Eilidh McLachlan; Luming Zhou; Guiping Kong; Quentin Barraud; Matt C Danzi; Alejandro Medrano-Fernandez; Jose P Lopez-Atalaya; Anne L Boutillier; Sarmistha H Sinha; Akash K Singh; Piyush Chaturbedy; Lawrence D F Moon; Tapas K Kundu; John L Bixby; Vance P Lemmon; Angel Barco; Gregoire Courtine; Simone Di Giovanni
Journal:  Sci Transl Med       Date:  2019-04-10       Impact factor: 17.956

3.  Neuroprotective Effects of Exercise on the Morphology of Somatic Motoneurons Following the Death of Neighboring Motoneurons.

Authors:  Cory Chew; Dale R Sengelaub
Journal:  Neurorehabil Neural Repair       Date:  2019-07-09       Impact factor: 3.919

4.  Exercise-Induced Changes to the Macrophage Response in the Dorsal Root Ganglia Prevent Neuropathic Pain after Spinal Cord Injury.

Authors:  Soha J Chhaya; Daniel Quiros-Molina; Alessandra D Tamashiro-Orrego; John D Houlé; Megan Ryan Detloff
Journal:  J Neurotrauma       Date:  2018-10-18       Impact factor: 5.269

5.  Critical Care Management of Acute Spinal Cord Injury-Part II: Intensive Care to Rehabilitation.

Authors:  Amanda Sacino; Kathryn Rosenblatt
Journal:  J Neuroanaesth Crit Care       Date:  2019-09-13

6.  Body System Effects of a Multi-Modal Training Program Targeting Chronic, Motor Complete Thoracic Spinal Cord Injury.

Authors:  Katie L Gant; Kathleen G Nagle; Rachel E Cowan; Edelle C Field-Fote; Mark S Nash; Jochen Kressler; Christine K Thomas; Mabelin Castellanos; Eva Widerström-Noga; Kimberly D Anderson
Journal:  J Neurotrauma       Date:  2017-10-16       Impact factor: 5.269

Review 7.  Development and Application of Three-Dimensional Bioprinting Scaffold in the Repair of Spinal Cord Injury.

Authors:  Dezhi Lu; Yang Yang; Pingping Zhang; Zhenjiang Ma; Wentao Li; Yan Song; Haiyang Feng; Wenqiang Yu; Fuchao Ren; Tao Li; Hong Zeng; Jinwu Wang
Journal:  Tissue Eng Regen Med       Date:  2022-06-29       Impact factor: 4.169

Review 8.  Behavioral testing in animal models of spinal cord injury.

Authors:  K Fouad; C Ng; D M Basso
Journal:  Exp Neurol       Date:  2020-07-28       Impact factor: 5.330

9.  Blocking of BDNF-TrkB signaling inhibits the promotion effect of neurological function recovery after treadmill training in rats with spinal cord injury.

Authors:  Xiangzhe Li; Qinfeng Wu; Caizhong Xie; Can Wang; Qinghua Wang; Chuanming Dong; Lu Fang; Jie Ding; Tong Wang
Journal:  Spinal Cord       Date:  2018-07-12       Impact factor: 2.772

Review 10.  Inflammogenesis of Secondary Spinal Cord Injury.

Authors:  M Akhtar Anwar; Tuqa S Al Shehabi; Ali H Eid
Journal:  Front Cell Neurosci       Date:  2016-04-13       Impact factor: 5.505
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