Literature DB >> 29844162

NT3-chitosan enables de novo regeneration and functional recovery in monkeys after spinal cord injury.

Jia-Sheng Rao1,2,3, Can Zhao2,1,3, Aifeng Zhang4, Hongmei Duan5, Peng Hao5, Rui-Han Wei1, Junkui Shang5, Wen Zhao5, Zuxiang Liu6,7,8, Juehua Yu9, Kevin S Fan10, Zhaolong Tian11, Qihua He12, Wei Song13, Zhaoyang Yang14,2, Yi Eve Sun15,16, Xiaoguang Li14,2,1.   

Abstract

Spinal cord injury (SCI) often leads to permanent loss of motor, sensory, and autonomic functions. We have previously shown that neurotrophin3 (NT3)-loaded chitosan biodegradable material allowed for prolonged slow release of NT3 for 14 weeks under physiological conditions. Here we report that NT3-loaded chitosan, when inserted into a 1-cm gap of hemisectioned and excised adult rhesus monkey thoracic spinal cord, elicited robust axonal regeneration. Labeling of cortical motor neurons indicated motor axons in the corticospinal tract not only entered the injury site within the biomaterial but also grew across the 1-cm-long lesion area and into the distal spinal cord. Through a combination of magnetic resonance diffusion tensor imaging, functional MRI, electrophysiology, and kinematics-based quantitative walking behavioral analyses, we demonstrated that NT3-chitosan enabled robust neural regeneration accompanied by motor and sensory functional recovery. Given that monkeys and humans share similar genetics and physiology, our method is likely translatable to human SCI repair.

Entities:  

Keywords:  CST regeneration; NT3; chitosan; nonhuman primate; spinal cord injury repair

Mesh:

Substances:

Year:  2018        PMID: 29844162      PMCID: PMC6004491          DOI: 10.1073/pnas.1804735115

Source DB:  PubMed          Journal:  Proc Natl Acad Sci U S A        ISSN: 0027-8424            Impact factor:   11.205


  46 in total

1.  Can experiments in nonhuman primates expedite the translation of treatments for spinal cord injury in humans?

Authors:  Grégoire Courtine; Mary Bartlett Bunge; James W Fawcett; Robert G Grossman; Jon H Kaas; Roger Lemon; Irin Maier; John Martin; Randolph J Nudo; Almudena Ramon-Cueto; Eric M Rouiller; Lisa Schnell; Thierry Wannier; Martin E Schwab; V Reggie Edgerton
Journal:  Nat Med       Date:  2007-05       Impact factor: 53.440

2.  Peripheral nerve grafts in a spinal cord prosthesis result in regeneration and motor evoked potentials following spinal cord resection.

Authors:  Jonathan Nordblom; Jonas K E Persson; Mikael Svensson; Per Mattsson
Journal:  Restor Neurol Neurosci       Date:  2009       Impact factor: 2.406

3.  Neutralization of ciliary neurotrophic factor reduces astrocyte production from transplanted neural stem cells and promotes regeneration of corticospinal tract fibers in spinal cord injury.

Authors:  Ken Ishii; Masaya Nakamura; Haining Dai; Tom P Finn; Hideyuki Okano; Yoshiaki Toyama; Barbara S Bregman
Journal:  J Neurosci Res       Date:  2006-12       Impact factor: 4.164

4.  Study of functional recovery produced by delayed localized cooling after spinal cord injury in primates.

Authors:  M S Albin; R J White; G Acosta-Rua; D Yashon
Journal:  J Neurosurg       Date:  1968-08       Impact factor: 5.115

5.  Peripheral nerve grafts and aFGF restore partial hindlimb function in adult paraplegic rats.

Authors:  Yu-Shang Lee; Ian Hsiao; Vernon W Lin
Journal:  J Neurotrauma       Date:  2002-10       Impact factor: 5.269

6.  The ability of human Schwann cell grafts to promote regeneration in the transected nude rat spinal cord.

Authors:  J D Guest; A Rao; L Olson; M B Bunge; R P Bunge
Journal:  Exp Neurol       Date:  1997-12       Impact factor: 5.330

7.  Effect of BDNF-plasma-collagen matrix controlled delivery system on the behavior of adult rats neural stem cells.

Authors:  Zhaoyang Yang; Hui Qiao; Zhiwei Sun; Xiaoguang Li
Journal:  J Biomed Mater Res A       Date:  2012-10-23       Impact factor: 4.396

Review 8.  Of mice and not men: differences between mouse and human immunology.

Authors:  Javier Mestas; Christopher C W Hughes
Journal:  J Immunol       Date:  2004-03-01       Impact factor: 5.422

9.  Repair of thoracic spinal cord injury by chitosan tube implantation in adult rats.

Authors:  Xiaoguang Li; Zhaoyang Yang; Aifeng Zhang; Tailing Wang; Weichang Chen
Journal:  Biomaterials       Date:  2008-11-29       Impact factor: 12.479

10.  Controlled release of neurotrophin-3 and platelet-derived growth factor from fibrin scaffolds containing neural progenitor cells enhances survival and differentiation into neurons in a subacute model of SCI.

Authors:  Philip J Johnson; Alexander Tatara; Alicia Shiu; Shelly E Sakiyama-Elbert
Journal:  Cell Transplant       Date:  2009-10-09       Impact factor: 4.064
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  36 in total

1.  Spatiotemporal Dynamics of the Molecular Expression Pattern and Intercellular Interactions in the Glial Scar Response to Spinal Cord Injury.

Authors:  Leilei Gong; Yun Gu; Xiaoxiao Han; Chengcheng Luan; Chang Liu; Xinghui Wang; Yufeng Sun; Mengru Zheng; Mengya Fang; Shuhai Yang; Lai Xu; Hualin Sun; Bin Yu; Xiaosong Gu; Songlin Zhou
Journal:  Neurosci Bull       Date:  2022-07-05       Impact factor: 5.203

2.  Restoration of complex movement in the paralyzed upper limb.

Authors:  Brady A Hasse; Drew E G Sheets; Nicole L Holly; Katalin M Gothard; Andrew J Fuglevand
Journal:  J Neural Eng       Date:  2022-07-01       Impact factor: 5.043

3.  Continual Deletion of Spinal Microglia Reforms Astrocyte Scar Favoring Axonal Regeneration.

Authors:  Longkuo Xia; Jianhuan Qi; Mingming Tang; Jing Liu; Da Zhang; Yanbing Zhu; Baoyang Hu
Journal:  Front Pharmacol       Date:  2022-06-27       Impact factor: 5.988

Review 4.  Enhancing Stem Cell-Based Therapeutic Potential by Combining Various Bioengineering Technologies.

Authors:  In-Sun Hong
Journal:  Front Cell Dev Biol       Date:  2022-07-05

5.  Neural regeneration therapy after spinal cord injury induces unique brain functional reorganizations in rhesus monkeys.

Authors:  Jia-Sheng Rao; Can Zhao; Rui-Han Wei; Ting Feng; Shu-Sheng Bao; Wen Zhao; Zhaolong Tian; Zuxiang Liu; Zhao-Yang Yang; Xiao-Guang Li
Journal:  Ann Med       Date:  2022-12       Impact factor: 5.348

6.  The Overexpression of Insulin-Like Growth Factor-1 and Neurotrophin-3 Promote Functional Recovery and Alleviate Spasticity After Spinal Cord Injury.

Authors:  Zuliyaer Talifu; Chuan Qin; Zhang Xin; Yixin Chen; Jiayi Liu; Subarna Dangol; Xiaodong Ma; Han Gong; Zhisheng Pei; Yan Yu; Jianjun Li; Liangjie Du
Journal:  Front Neurosci       Date:  2022-04-29       Impact factor: 5.152

7.  Reduction in pericyte coverage leads to blood-brain barrier dysfunction via endothelial transcytosis following chronic cerebral hypoperfusion.

Authors:  Zhengyu Sun; Chenhao Gao; Dandan Gao; Ruihua Sun; Wei Li; Fengyu Wang; Yanliang Wang; Huixia Cao; Guoyu Zhou; Jiewen Zhang; Junkui Shang
Journal:  Fluids Barriers CNS       Date:  2021-05-05

Review 8.  Drug delivery carriers with therapeutic functions.

Authors:  Shuting S Cai; Tianyu Li; Tolulope Akinade; Yuefei Zhu; Kam W Leong
Journal:  Adv Drug Deliv Rev       Date:  2021-07-21       Impact factor: 17.873

Review 9.  A roadmap for promoting endogenous in situ tissue restoration using inductive bioscaffolds after acute brain injury.

Authors:  Michel Modo; Stephen F Badylak
Journal:  Brain Res Bull       Date:  2019-05-22       Impact factor: 3.715

Review 10.  Corticospinal Motor Circuit Plasticity After Spinal Cord Injury: Harnessing Neuroplasticity to Improve Functional Outcomes.

Authors:  Syed Faraz Kazim; Christian A Bowers; Chad D Cole; Samantha Varela; Zafar Karimov; Erick Martinez; Jonathan V Ogulnick; Meic H Schmidt
Journal:  Mol Neurobiol       Date:  2021-08-03       Impact factor: 5.590
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