Literature DB >> 29279015

Rodent Neural Progenitor Cells Support Functional Recovery after Cervical Spinal Cord Contusion.

John Hoffman Brock1,2, Lori Graham2, Eileen Staufenberg2, Sarah Im2, Mark Henry Tuszynski1,2.   

Abstract

Previously, we and others have shown that rodent neural progenitor cells (NPCs) can support functional recovery after cervical and thoracic transection injuries. To extend these observations to a more clinically relevant model of spinal cord injury, we performed unilateral midcervical contusion injuries in Fischer 344 rats. Two-weeks later, E14-derived syngeneic spinal cord-derived multi-potent NPCs were implanted into the lesion cavity. Control animals received either no grafts or fibroblast grafts. The NPCs differentiated into all three neural lineages (neurons, astrocytes, oligodendrocytes) and robustly extended axons into the host spinal cord caudal and rostral to the lesion. Graft-derived axons grew into host gray matter and expressed synaptic proteins in juxtaposition with host neurons. Animals that received NPC grafts exhibited significant recovery of forelimb motor function compared with the two control groups (analysis of variance p < 0.05). Thus, NPC grafts improve forelimb motor outcomes after clinically relevant cervical contusion injury. These benefits are observed when grafts are placed two weeks after injury, a time point that is more clinically practical than acute interventions, allowing time for patients to stabilize medically, simplifying enrollment in clinical trials, and enhancing predictability of spontaneous improvement in control groups.

Entities:  

Keywords:  functional recovery; neural progenitor cells; spinal cord cervical contusion

Mesh:

Year:  2018        PMID: 29279015      PMCID: PMC5908429          DOI: 10.1089/neu.2017.5244

Source DB:  PubMed          Journal:  J Neurotrauma        ISSN: 0897-7151            Impact factor:   5.269


  22 in total

1.  Experimental modeling of spinal cord injury: characterization of a force-defined injury device.

Authors:  Stephen W Scheff; Alexander G Rabchevsky; Isabella Fugaccia; John A Main; James E Lumpp
Journal:  J Neurotrauma       Date:  2003-02       Impact factor: 5.269

2.  Evolving the lock to fit the key to create a family of G protein-coupled receptors potently activated by an inert ligand.

Authors:  Blaine N Armbruster; Xiang Li; Mark H Pausch; Stefan Herlitze; Bryan L Roth
Journal:  Proc Natl Acad Sci U S A       Date:  2007-03-02       Impact factor: 11.205

3.  Promotion of survival and differentiation of neural stem cells with fibrin and growth factor cocktails after severe spinal cord injury.

Authors:  Paul Lu; Lori Graham; Yaozhi Wang; Di Wu; Mark Tuszynski
Journal:  J Vis Exp       Date:  2014-07-27       Impact factor: 1.355

4.  Human neural stem cells differentiate and promote locomotor recovery in spinal cord-injured mice.

Authors:  Brian J Cummings; Nobuko Uchida; Stanley J Tamaki; Desirée L Salazar; Mitra Hooshmand; Robert Summers; Fred H Gage; Aileen J Anderson
Journal:  Proc Natl Acad Sci U S A       Date:  2005-09-19       Impact factor: 11.205

5.  Axonal projections between fetal spinal cord transplants and the adult rat spinal cord: a neuroanatomical tracing study of local interactions.

Authors:  L B Jakeman; P J Reier
Journal:  J Comp Neurol       Date:  1991-05-08       Impact factor: 3.215

6.  Acceptable benefits and risks associated with surgically improving arm function in individuals living with cervical spinal cord injury.

Authors:  K D Anderson; J Fridén; R L Lieber
Journal:  Spinal Cord       Date:  2008-11-25       Impact factor: 2.772

7.  Demonstrating efficacy in preclinical studies of cellular therapies for spinal cord injury - how much is enough?

Authors:  Brian K Kwon; Lesley J J Soril; Mark Bacon; Michael S Beattie; Armin Blesch; Jacqueline C Bresnahan; Mary Bartlett Bunge; Sarah A Dunlop; Michael G Fehlings; Adam R Ferguson; Caitlin E Hill; Soheila Karimi-Abdolrezaee; Paul Lu; John W McDonald; Hans W Müller; Martin Oudega; Ephron S Rosenzweig; Paul J Reier; Jerry Silver; Eva Sykova; Xiao-Ming Xu; James D Guest; Wolfram Tetzlaff
Journal:  Exp Neurol       Date:  2013-05-29       Impact factor: 5.330

8.  Functional recovery in rats with ischemic paraplegia after spinal grafting of human spinal stem cells.

Authors:  D Cizkova; O Kakinohana; K Kucharova; S Marsala; K Johe; T Hazel; M P Hefferan; M Marsala
Journal:  Neuroscience       Date:  2007-05-23       Impact factor: 3.590

9.  Spinal cord reconstitution with homologous neural grafts enables robust corticospinal regeneration.

Authors:  Ken Kadoya; Paul Lu; Kenny Nguyen; Corinne Lee-Kubli; Hiromi Kumamaru; Lin Yao; Joshua Knackert; Gunnar Poplawski; Jennifer N Dulin; Hans Strobl; Yoshio Takashima; Jeremy Biane; James Conner; Su-Chun Zhang; Mark H Tuszynski
Journal:  Nat Med       Date:  2016-03-28       Impact factor: 53.440

10.  Long-distance axonal growth from human induced pluripotent stem cells after spinal cord injury.

Authors:  Paul Lu; Grace Woodruff; Yaozhi Wang; Lori Graham; Matt Hunt; Di Wu; Eileen Boehle; Ruhel Ahmad; Gunnar Poplawski; John Brock; Lawrence S B Goldstein; Mark H Tuszynski
Journal:  Neuron       Date:  2014-08-07       Impact factor: 17.173
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  10 in total

1.  Neural Stem Cell Grafts Form Extensive Synaptic Networks that Integrate with Host Circuits after Spinal Cord Injury.

Authors:  Steven Ceto; Kohei J Sekiguchi; Yoshio Takashima; Axel Nimmerjahn; Mark H Tuszynski
Journal:  Cell Stem Cell       Date:  2020-08-05       Impact factor: 24.633

2.  Choosing the right cell for spinal cord repair.

Authors:  Lyandysha V Zholudeva; Michael A Lane
Journal:  J Neurosci Res       Date:  2018-11-01       Impact factor: 4.164

Review 3.  The translational landscape in spinal cord injury: focus on neuroplasticity and regeneration.

Authors:  Thomas H Hutson; Simone Di Giovanni
Journal:  Nat Rev Neurol       Date:  2019-11-14       Impact factor: 42.937

Review 4.  Spinal Interneurons as Gatekeepers to Neuroplasticity after Injury or Disease.

Authors:  Lyandysha V Zholudeva; Victoria E Abraira; Kajana Satkunendrarajah; Todd C McDevitt; Martyn D Goulding; David S K Magnuson; Michael A Lane
Journal:  J Neurosci       Date:  2021-01-20       Impact factor: 6.709

5.  Adult Neural Progenitor Cells Transplanted into Spinal Cord Injury Differentiate into Oligodendrocytes, Enhance Myelination, and Contribute to Recovery.

Authors:  Sreenivasa Raghavan Sankavaram; Ramil Hakim; Ruxandra Covacu; Arvid Frostell; Susanne Neumann; Mikael Svensson; Lou Brundin
Journal:  Stem Cell Reports       Date:  2019-04-25       Impact factor: 7.765

6.  Transplanting Cells for Spinal Cord Repair: Who, What, When, Where and Why?

Authors:  Lyandysha V Zholudeva; Michael A Lane
Journal:  Cell Transplant       Date:  2019-01-18       Impact factor: 4.064

7.  Rehabilitation combined with neural progenitor cell grafts enables functional recovery in chronic spinal cord injury.

Authors:  Paul Lu; Camila M Freria; Lori Graham; Amanda N Tran; Ashley Villarta; Dena Yassin; J Russell Huie; Adam R Ferguson; Mark H Tuszynski
Journal:  JCI Insight       Date:  2022-08-22

8.  Effects of biological sex mismatch on neural progenitor cell transplantation for spinal cord injury in mice.

Authors:  Michael Pitonak; Miriam Aceves; Prakruthi Amar Kumar; Gabrielle Dampf; Peyton Green; Ashley Tucker; Valerie Dietz; Diego Miranda; Sunjay Letchuman; Michelle M Jonika; David Bautista; Heath Blackmon; Jennifer N Dulin
Journal:  Nat Commun       Date:  2022-09-14       Impact factor: 17.694

Review 9.  Neural Stem Cells: Promoting Axonal Regeneration and Spinal Cord Connectivity.

Authors:  Camila Marques de Freria; Erna Van Niekerk; Armin Blesch; Paul Lu
Journal:  Cells       Date:  2021-11-25       Impact factor: 6.600

Review 10.  Multi-target approaches to CNS repair: olfactory mucosa-derived cells and heparan sulfates.

Authors:  Susan L Lindsay; George A McCanney; Alice G Willison; Susan C Barnett
Journal:  Nat Rev Neurol       Date:  2020-02-25       Impact factor: 42.937
  10 in total

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