Literature DB >> 33247828

Valproic Acid Labeled Chitosan Nanoparticles Promote the Proliferation and Differentiation of Neural Stem Cells After Spinal Cord Injury.

Dimin Wang1,2, Kai Wang3, Zhenlei Liu3, Zonglin Wang2, Hao Wu4.   

Abstract

Chitosan nanoparticles and valproic acid are demonstrated as the protective agents in the treatment of spinal cord injury (SCI). However, the effects of valproic acid-labeled chitosan nanoparticles (VA-CN) on endogenous spinal cord neural stem cells (NSCs) following SCI and the underlying mechanisms involved remain to be elucidated. In this study, the VA-CN was constructed and the effects of VA-CN on NSCs were assessed in a rat model of SCI. We found VA-CN treatment promoted recovery of the tissue and locomotive function following SCI. Moreover, administration of VA-CN significantly enhanced neural stem cell proliferation and the expression levels of neurotrophic factors following SCI. Furthermore, administration of VA-CN led to a decrease in the number of microglia following SCI. In addition, VA-CN treatment significantly increased the Tuj 1- positive cells in the spinal cord of the SCI rats, suggesting that VA-CN could enhance the differentiation of NSCs following SCI. In conclusion, these results demonstrated that VA-CN could improve the functional and histological recovery through promoting the proliferation and differentiation of NSCs following SCI, which would provide a newly potential therapeutic manner for the treatment of SCI.

Entities:  

Keywords:  Differentiation; Neural stem cells; Neurotrophic factors; Proliferation; Spinal cord injury; Valproic acid labeled chitosan nanoparticles

Mesh:

Substances:

Year:  2020        PMID: 33247828     DOI: 10.1007/s12640-020-00304-y

Source DB:  PubMed          Journal:  Neurotox Res        ISSN: 1029-8428            Impact factor:   3.911


  47 in total

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Authors:  Hossein Baniasadi; Ahmad Ramazani S A; Shohreh Mashayekhan
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Review 2.  Cell transplantation therapy for spinal cord injury.

Authors:  Peggy Assinck; Greg J Duncan; Brett J Hilton; Jason R Plemel; Wolfram Tetzlaff
Journal:  Nat Neurosci       Date:  2017-04-25       Impact factor: 24.884

3.  Comparison of 2D and 3D neural induction methods for the generation of neural progenitor cells from human induced pluripotent stem cells.

Authors:  Abinaya Chandrasekaran; Hasan X Avci; Anna Ochalek; Lone N Rösingh; Kinga Molnár; Lajos László; Tamás Bellák; Annamária Téglási; Krisztina Pesti; Arpad Mike; Phetcharat Phanthong; Orsolya Bíró; Vanessa Hall; Narisorn Kitiyanant; Karl-Heinz Krause; Julianna Kobolák; András Dinnyés
Journal:  Stem Cell Res       Date:  2017-10-14       Impact factor: 2.020

4.  The standing and sitting sagittal spinopelvic alignment of Chinese young and elderly population: does age influence the differences between the two positions?

Authors:  Siyu Zhou; Zhuoran Sun; Wei Li; Wei Wang; Tong Su; Chengbo Du; Weishi Li
Journal:  Eur Spine J       Date:  2019-10-19       Impact factor: 3.134

5.  In vitro characteristics of valproic acid and all-trans-retinoic acid and their combined use in promoting neuronal differentiation while suppressing astrocytic differentiation in neural stem cells.

Authors:  Tianci Chu; Hengxing Zhou; Tianyi Wang; Lu Lu; Fuyuan Li; Bin Liu; Xiaohong Kong; Shiqing Feng
Journal:  Brain Res       Date:  2014-11-20       Impact factor: 3.252

6.  Insulin-like growth factor 1 is required for survival of transit-amplifying neuroblasts and differentiation of otic neurons.

Authors:  G Camarero; Y Leon; I Gorospe; F De Pablo; B Alsina; F Giraldez; I Varela-Nieto
Journal:  Dev Biol       Date:  2003-10-15       Impact factor: 3.582

7.  Selective killing of spinal cord neural stem cells impairs locomotor recovery in a mouse model of spinal cord injury.

Authors:  Melania Cusimano; Elena Brambilla; Alessia Capotondo; Donatella De Feo; Antonio Tomasso; Giancarlo Comi; Patrizia D'Adamo; Luca Muzio; Gianvito Martino
Journal:  J Neuroinflammation       Date:  2018-02-23       Impact factor: 8.322

8.  Transplanted neural stem/precursor cells instruct phagocytes and reduce secondary tissue damage in the injured spinal cord.

Authors:  Melania Cusimano; Daniela Biziato; Elena Brambilla; Matteo Donegà; Clara Alfaro-Cervello; Silvia Snider; Giuliana Salani; Ferdinando Pucci; Giancarlo Comi; Jose Manuel Garcia-Verdugo; Michele De Palma; Gianvito Martino; Stefano Pluchino
Journal:  Brain       Date:  2012-01-23       Impact factor: 13.501

9.  Pushing the science forward: chitosan nanoparticles and functional repair of CNS tissue after spinal cord injury.

Authors:  Bojun Chen; Debra Bohnert; Richard Ben Borgens; Youngnam Cho
Journal:  J Biol Eng       Date:  2013-06-03       Impact factor: 4.355

10.  Valproic acid attenuates traumatic spinal cord injury-induced inflammation via STAT1 and NF-κB pathway dependent of HDAC3.

Authors:  Shoubo Chen; Jingfang Ye; Xiangrong Chen; Jinnan Shi; Wenhua Wu; Wenping Lin; Weibin Lin; Yasong Li; Huangde Fu; Shun Li
Journal:  J Neuroinflammation       Date:  2018-05-18       Impact factor: 8.322
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  1 in total

1.  Rosiglitazone Ameliorates Spinal Cord Injury via Inhibiting Mitophagy and Inflammation of Neural Stem Cells.

Authors:  Qingqi Meng; Zhiteng Chen; Qingyuan Gao; Liqiong Hu; Qilong Li; Shutai Li; Lili Cui; Zhencheng Feng; Xingliang Zhang; Shiyun Cui; Haifeng Zhang
Journal:  Oxid Med Cell Longev       Date:  2022-01-04       Impact factor: 6.543
  1 in total

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