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Literature DB >> 9914245

Regeneration in the spinal cord.

Abstract

Important advances have been made in our understanding of conditions that influence the intrinsic capacity of mature CNS neurons to initiate and maintain a regrowth response. The combination of exogenous neurotrophic support with strategies to alter the terrain at the injury site itself suggests that there are important interactions between them that lead to increased axonal regeneration. The ability of chronically injured neurons to initiate a regeneration response is unexpected. Our view of the role that inhibitors play in restricting axonal growth has also expanded. The findings indicate that the windows of opportunity for enhancing growth after spinal cord injury may be more numerous than previously thought.

Entities: Disease

Mesh：

Substances：
Nerve Growth Factors

Year: 1998 PMID： 9914245 DOI： 10.1016/s0959-4388(98)80124-4

Source DB: PubMed Journal: Curr Opin Neurobiol ISSN： 0959-4388 Impact factor: 6.627

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Cited

12 in total

Review 1. Could enhanced reflex function contribute to improving locomotion after spinal cord repair?

Authors: K G Pearson
Journal: J Physiol Date: 2001-05-15 Impact factor: 5.182

Review 2. Plasticity of connections underlying locomotor recovery after central and/or peripheral lesions in the adult mammals.

Authors: Serge Rossignol
Journal: Philos Trans R Soc Lond B Biol Sci Date: 2006-09-29 Impact factor: 6.237

Review 3. Cellular transplantation strategies for spinal cord injury and translational neurobiology.

Authors: Paul J Reier
Journal: NeuroRx Date: 2004-10

4. Remarkable recovery in an infant presenting with extensive perinatal cervical cord injury.

Authors: Israr Ul Haq; A K Gururaj
Journal: BMJ Case Rep Date: 2012-12-10

5. Re-establishing the regenerative potential of central nervous system axons in postnatal mice.

Authors: Kin-Sang Cho; Liu Yang; Bin Lu; Hong Feng Ma; Xizhong Huang; Milos Pekny; Dong Feng Chen
Journal: J Cell Sci Date: 2005-03-01 Impact factor: 5.285

6. Treatment of spinal cord injury with co-grafts of genetically modified Schwann cells and fetal spinal cord cell suspension in the rat.

Authors: Shi-Qing Feng; Xiao-Hong Kong; Shi-Fu Guo; Pei Wang; Li Li; Jin-Hua Zhong; Xin-Fu Zhou
Journal: Neurotox Res Date: 2005 Impact factor: 3.911

7. Degradation of chondroitin sulfate proteoglycans potentiates transplant-mediated axonal remodeling and functional recovery after spinal cord injury in adult rats.

Authors: Byung G Kim; Hai-Ning Dai; James V Lynskey; Marietta McAtee; Barbara S Bregman
Journal: J Comp Neurol Date: 2006-07-10 Impact factor: 3.215

8. A chemical genetic approach identifies piperazine antipsychotics as promoters of CNS neurite growth on inhibitory substrates.

Authors: Andrea L Johnstone; Gillian W Reierson; Robin P Smith; Jeffrey L Goldberg; Vance P Lemmon; John L Bixby
Journal: Mol Cell Neurosci Date: 2012-05-03 Impact factor: 4.314

Review 9. Nanomedicine for treating spinal cord injury.

Authors: Jacqueline Y Tyler; Xiao-Ming Xu; Ji-Xin Cheng
Journal: Nanoscale Date: 2013-08-14 Impact factor: 7.790

10. Immune responses following mouse peripheral nerve xenotransplantation in rats.

Authors: Lai-Jin Lu; Jia-Bing Sun; Zhi-Gang Liu; Xu Gong; Jian-Li Cui; Xi-Guang Sun
Journal: J Biomed Biotechnol Date: 2009-10-12