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Literature DB >> 16075258

Molecular targets in spinal cord injury.

Abstract

The spinal cord can be compared to a highway connecting the brain with the different body levels lying underneath, with the axons being the ultimate carriers of the electrical impulse. After spinal cord injury (SCI), many cells are lost because of the injury. To reconstitute function, damaged axons from surviving neurons have to grow through the lesion site to their initial targets. However, the territory they have to traverse has changed: the highway is full of inhibitory signals (myelin and scar components); the pavement itself has become bumpy (demyelination); and specialized cells are recruited to clear the way (inflammatory cells). Thus, actual strategies to treat spinal injuries aim at providing a permissive environment for regenerating axons and boosting the endogenous potential of axons to regenerate while limiting progression of secondary damage. Here we review some of the strategies currently under consideration to treat spinal injuries.

Entities: Disease

Mesh：

Year: 2005 PMID： 16075258 DOI： 10.1007/s00109-005-0663-3

Source DB: PubMed Journal: J Mol Med (Berl) ISSN： 0946-2716 Impact factor: 4.599

176 in total

1. Pretreatment with calpain inhibitor CEP-4143 inhibits calpain I activation and cytoskeletal degradation, improves neurological function, and enhances axonal survival after traumatic spinal cord injury.

Authors: P A Schumacher; R G Siman; M G Fehlings
Journal: J Neurochem Date: 2000-04 Impact factor: 5.372

Review 2. Neurotrophic factors, gene therapy, and neural stem cells for spinal cord repair.

Authors: Armin Blesch; Paul Lu; Mark H Tuszynski
Journal: Brain Res Bull Date: 2002-04 Impact factor: 4.077

3. Effects of neutralizing antibodies to TNF-alpha on pain-related behavior and nerve regeneration in mice with chronic constriction injury.

Authors: T Lindenlaub; P Teuteberg; T Hartung; C Sommer
Journal: Brain Res Date: 2000-06-02 Impact factor: 3.252

4. Oligodendroglial apoptosis occurs along degenerating axons and is associated with FAS and p75 expression following spinal cord injury in the rat.

Authors: S Casha; W R Yu; M G Fehlings
Journal: Neuroscience Date: 2001 Impact factor: 3.590

5. Neuroprotective autoimmunity: naturally occurring CD4+CD25+ regulatory T cells suppress the ability to withstand injury to the central nervous system.

Authors: Jonathan Kipnis; Tal Mizrahi; Ehud Hauben; Iftach Shaked; Ethan Shevach; Michal Schwartz
Journal: Proc Natl Acad Sci U S A Date: 2002-11-12 Impact factor: 11.205

6. Agmatine improves locomotor function and reduces tissue damage following spinal cord injury.

Authors: C G Yu; A E Marcillo; C A Fairbanks; G L Wilcox; R P Yezierski
Journal: Neuroreport Date: 2000-09-28 Impact factor: 1.837

7. Analysis of the effects of cyclooxygenase (COX)-1 and COX-2 in spinal nociceptive transmission using indomethacin, a non-selective COX inhibitor, and NS-398, a COX-2 selective inhibitor.

Authors: T Yamamoto; N Nozaki-Taguchi
Journal: Brain Res Date: 1996-11-11 Impact factor: 3.252

8. Combinatorial therapy with neurotrophins and cAMP promotes axonal regeneration beyond sites of spinal cord injury.

Authors: Paul Lu; Hong Yang; Leonard L Jones; Marie T Filbin; Mark H Tuszynski
Journal: J Neurosci Date: 2004-07-14 Impact factor: 6.167

9. Role of the bcl-2 gene after contusive spinal cord injury in mice.

Authors: Toshitaka Seki; Kazutoshi Hida; Mitsuhiro Tada; Izumi Koyanagi; Yoshinobu Iwasaki
Journal: Neurosurgery Date: 2003-07 Impact factor: 4.654

10. Minocycline reduces cell death and improves functional recovery after traumatic spinal cord injury in the rat.

Authors: Sang M Lee; Tae Y Yune; Sun J Kim; Do W Park; Young K Lee; Young C Kim; Young J Oh; George J Markelonis; Tae H Oh
Journal: J Neurotrauma Date: 2003-10 Impact factor: 5.269

10 in total

1. Neuroprotective ferulic acid (FA)-glycol chitosan (GC) nanoparticles for functional restoration of traumatically injured spinal cord.

Authors: Wei Wu; Seung-Young Lee; Xiangbing Wu; Jacqueline Y Tyler; He Wang; Zheng Ouyang; Kinam Park; Xiao-Ming Xu; Ji-Xin Cheng
Journal: Biomaterials Date: 2013-12-12 Impact factor: 12.479

2. Overexpression of neuritin in gastric cancer.

Authors: Ming Yuan; Yongjun Li; Chen Zhong; Yongkang Li; Jianhua Niu; Jianping Gong
Journal: Oncol Lett Date: 2015-10-12 Impact factor: 2.967

Review 3. Low molecular weight phospholipases A2 in mammalian brain and neural cells: roles in functions and dysfunctions.

Authors: Gianfrancesco Goracci; Monica Ferrini; Vincenza Nardicchi
Journal: Mol Neurobiol Date: 2010-03-19 Impact factor: 5.590

4. Mapping lipid alterations in traumatically injured rat spinal cord by desorption electrospray ionization imaging mass spectrometry.

Authors: Marion Girod; Yunzhou Shi; Ji-Xin Cheng; R Graham Cooks
Journal: Anal Chem Date: 2010-12-13 Impact factor: 6.986

5. Human embryonic stem cell-derived oligodendrocyte progenitor cell transplants improve recovery after cervical spinal cord injury.

Authors: Jason Sharp; Jennifer Frame; Monica Siegenthaler; Gabriel Nistor; Hans S Keirstead
Journal: Stem Cells Date: 2010-01 Impact factor: 6.277

6. Involvement of ERK2 in traumatic spinal cord injury.

Authors: Chen-Guang Yu; Robert P Yezierski; Aashish Joshi; Kashif Raza; Yanzhang Li; James W Geddes
Journal: J Neurochem Date: 2010-01-12 Impact factor: 5.372

7. Structural and functional regeneration after spinal cord injury in the weakly electric teleost fish, Apteronotus leptorhynchus.

Authors: Ruxandra F Sîrbulescu; Iulian Ilieş; Günther K H Zupanc
Journal: J Comp Physiol A Neuroethol Sens Neural Behav Physiol Date: 2009-05-10 Impact factor: 1.836