Literature DB >> 23891888

Caudalized human iPSC-derived neural progenitor cells produce neurons and glia but fail to restore function in an early chronic spinal cord injury model.

Samuel E Nutt1, Eun-Ah Chang, Steven T Suhr, Laura O Schlosser, Sarah E Mondello, Chet T Moritz, Jose B Cibelli, Philip J Horner.   

Abstract

Neural progenitor cells (NPCs) have shown modest potential and some side effects (e.g. allodynia) for treatment of spinal cord injury (SCI). In only a few cases, however, have NPCs shown promise at the chronic stage. Given the 1.275 million people living with chronic paralysis, there is a significant need to rigorously evaluate the cell types and methods for safe and efficacious treatment of this devastating condition. For the first time, we examined the pre-clinical potential of NPCs derived from human induced pluripotent stem cells (hiPSCs) to repair chronic SCI. hiPSCs were differentiated into region-specific (i.e. caudal) NPCs, then transplanted into a new, clinically relevant model of early chronic cervical SCI. We established the conditions for successful transplantation of caudalized hiPSC-NPCs and demonstrate their remarkable ability to integrate and produce multiple neural lineages in the early chronic injury environment. In contrast to prior reports in acute and sub-acute injury models, survival and integration of hiPSC-derived neural cells in the early chronic cervical model did not lead to significant improvement in forelimb function or induce allodynia. These data indicate that while hiPSCs show promise, future work needs to focus on the specific hiPSC-derivatives or co-therapies that will restore function in the early chronic injury setting.
© 2013.

Entities:  

Keywords:  Induced pluripotent stem cells; Neural progenitor cells; Spinal cord injury

Mesh:

Year:  2013        PMID: 23891888      PMCID: PMC4109283          DOI: 10.1016/j.expneurol.2013.07.010

Source DB:  PubMed          Journal:  Exp Neurol        ISSN: 0014-4886            Impact factor:   5.330


  65 in total

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2.  Hindlimb locomotor and postural training modulates glycinergic inhibition in the spinal cord of the adult spinal cat.

Authors:  R D de Leon; H Tamaki; J A Hodgson; R R Roy; V R Edgerton
Journal:  J Neurophysiol       Date:  1999-07       Impact factor: 2.714

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Authors:  T Schallert; S M Fleming; J L Leasure; J L Tillerson; S T Bland
Journal:  Neuropharmacology       Date:  2000-03-03       Impact factor: 5.250

Review 4.  The Ki-67 protein: from the known and the unknown.

Authors:  T Scholzen; J Gerdes
Journal:  J Cell Physiol       Date:  2000-03       Impact factor: 6.384

5.  Allodynia limits the usefulness of intraspinal neural stem cell grafts; directed differentiation improves outcome.

Authors:  Christoph P Hofstetter; Niklas A V Holmström; Johan A Lilja; Petra Schweinhardt; Jinxia Hao; Christian Spenger; Zsuzsanna Wiesenfeld-Hallin; Shekar N Kurpad; Jonas Frisén; Lars Olson
Journal:  Nat Neurosci       Date:  2005-02-13       Impact factor: 24.884

6.  SOX2, a persistent marker for multipotential neural stem cells derived from embryonic stem cells, the embryo or the adult.

Authors:  Pam Ellis; B Matthew Fagan; Scott T Magness; Scott Hutton; Olena Taranova; Shigemi Hayashi; Andrew McMahon; Mahendra Rao; Larysa Pevny
Journal:  Dev Neurosci       Date:  2004 Mar-Aug       Impact factor: 2.984

7.  Increased expression of glutamate decarboxylase (GAD(67)) in feline lumbar spinal cord after complete thoracic spinal cord transection.

Authors:  N J Tillakaratne; M Mouria; N B Ziv; R R Roy; V R Edgerton; A J Tobin
Journal:  J Neurosci Res       Date:  2000-04-15       Impact factor: 4.164

8.  Transplantation of human neural stem cells for spinal cord injury in primates.

Authors:  A Iwanami; S Kaneko; M Nakamura; Y Kanemura; H Mori; S Kobayashi; M Yamasaki; S Momoshima; H Ishii; K Ando; Y Tanioka; N Tamaoki; T Nomura; Y Toyama; H Okano
Journal:  J Neurosci Res       Date:  2005-04-15       Impact factor: 4.164

9.  Specification of motoneurons from human embryonic stem cells.

Authors:  Xue-Jun Li; Zhong-Wei Du; Ewa D Zarnowska; Matthew Pankratz; Lauren O Hansen; Robert A Pearce; Su-Chun Zhang
Journal:  Nat Biotechnol       Date:  2005-01-30       Impact factor: 54.908

10.  Targeting recovery: priorities of the spinal cord-injured population.

Authors:  Kim D Anderson
Journal:  J Neurotrauma       Date:  2004-10       Impact factor: 5.269
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  42 in total

1.  Meta-analysis of stem cell transplantation for reflex hypersensitivity after spinal cord injury.

Authors:  Xuemei Chen; Bohan Xue; Yuping Li; Chunhua Song; Peijun Jia; Xiuhua Ren; Weidong Zang; Jian Wang
Journal:  Neuroscience       Date:  2017-06-27       Impact factor: 3.590

2.  MMP9-sensitive polymers mediate environmentally-responsive bivalirudin release and thrombin inhibition.

Authors:  D S Chu; D L Sellers; M J Bocek; A E Fischedick; P J Horner; S H Pun
Journal:  Biomater Sci       Date:  2015-01       Impact factor: 6.843

3.  Prolonged human neural stem cell maturation supports recovery in injured rodent CNS.

Authors:  Paul Lu; Steven Ceto; Yaozhi Wang; Lori Graham; Di Wu; Hiromi Kumamaru; Eileen Staufenberg; Mark H Tuszynski
Journal:  J Clin Invest       Date:  2017-08-21       Impact factor: 14.808

4.  A Cervical Hemi-Contusion Spinal Cord Injury Model for the Investigation of Novel Therapeutics Targeting Proximal and Distal Forelimb Functional Recovery.

Authors:  Sarah E Mondello; Michael D Sunshine; Amanda E Fischedick; Chet T Moritz; Philip J Horner
Journal:  J Neurotrauma       Date:  2015-09-29       Impact factor: 5.269

5.  Transplantation of M2-Deviated Microglia Promotes Recovery of Motor Function after Spinal Cord Injury in Mice.

Authors:  Shuhei Kobashi; Tomoya Terashima; Miwako Katagi; Yuki Nakae; Junko Okano; Yoshihisa Suzuki; Makoto Urushitani; Hideto Kojima
Journal:  Mol Ther       Date:  2019-09-10       Impact factor: 11.454

Review 6.  Stem cells for spinal cord injury: Strategies to inform differentiation and transplantation.

Authors:  Nisha R Iyer; Thomas S Wilems; Shelly E Sakiyama-Elbert
Journal:  Biotechnol Bioeng       Date:  2016-09-21       Impact factor: 4.530

7.  A Comparative Study of Three Different Types of Stem Cells for Treatment of Rat Spinal Cord Injury.

Authors:  Jiri Ruzicka; Lucia Machova-Urdzikova; John Gillick; Takashi Amemori; Nataliya Romanyuk; Kristyna Karova; Kristyna Zaviskova; Jana Dubisova; Sarka Kubinova; Raj Murali; Eva Sykova; Meena Jhanwar-Uniyal; Pavla Jendelova
Journal:  Cell Transplant       Date:  2016-11-02       Impact factor: 4.064

8.  Human iPS cell-derived astrocyte transplants preserve respiratory function after spinal cord injury.

Authors:  Ke Li; Elham Javed; Daniel Scura; Tamara J Hala; Suneil Seetharam; Aditi Falnikar; Jean-Philippe Richard; Ashley Chorath; Nicholas J Maragakis; Megan C Wright; Angelo C Lepore
Journal:  Exp Neurol       Date:  2015-07-26       Impact factor: 5.330

9.  Characterization of neural stem cells modified with hypoxia/neuron-specific VEGF expression system for spinal cord injury.

Authors:  Y Yun; J Oh; Y Kim; G Kim; M Lee; Y Ha
Journal:  Gene Ther       Date:  2017-11-20       Impact factor: 5.250

Review 10.  iPSC-derived neural precursor cells: potential for cell transplantation therapy in spinal cord injury.

Authors:  Narihito Nagoshi; Hideyuki Okano
Journal:  Cell Mol Life Sci       Date:  2017-10-09       Impact factor: 9.261
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