Transplantation of neural progenitor cells in chronic spinal cord injury

Previous studies demonstrated that neural progenitor cells (NPCs) transplanted into a subacute contusion injury improve motor, sensory, and bladder function. In this study we tested whether transplanted NPCs can also improve functional recovery after chronic spinal cord injury (SCI) alone or in combination with the reduction of glial scar and neurotrophic support. Adult rats received a T10 moderate contusion. Thirteen weeks after the injury they were divided into four groups and received either: 1. Medium (control), 2. NPC transplants, 3. NPC+lentivirus vector expressing chondroitinase, or 4. NPC+lentivirus vectors expressing chondroitinase and neurotrophic factors. During the 8 weeks post-transplantation the animals were tested for functional recovery and eventually analyzed by anatomical and immunohistochemical assays. The behavioral tests for motor and sensory function were performed before and after injury, and weekly after transplantation, with some animals also tested for bladder function at the end of the experiment. Transplant survival in the chronic injury model was variable and showed NPCs at the injury site in 60% of the animals in all transplantation groups. The NPC transplants comprised less than 40% of the injury site, without significant anatomical or histological differences among the groups. All groups also showed similar patterns of functional deficits and recovery in the 12 weeks after injury and in the 8 weeks after transplantation using the Basso, Beattie, and Bresnahan rating score, the grid test, and the Von Frey test for mechanical allodynia. A notable exception was group 4 (NPC together with chondroitinase and neurotrophins), which showed a significant improvement in bladder function. This study underscores the therapeutic challenges facing transplantation strategies in a chronic SCI in which even the inclusion of treatments designed to reduce scarring and increase neurotrophic support produce only modest functional improvements. Further studies will have to identify the combination of acute and chronic interventions that will augment the survival and efficacy of neural cell transplants.

[1]  T. Yaksh,et al.  Quantitative assessment of tactile allodynia in the rat paw , 1994, Journal of Neuroscience Methods.

[2]  I. Fischer,et al.  Transplantation of glial‐restricted precursor cells into the adult spinal cord: Survival, glial‐specific differentiation, and preferential migration in white matter , 2004, Glia.

[3]  W. Young,et al.  Managing Inflammation after Spinal Cord Injury through Manipulation of Macrophage Function , 2013, Neural plasticity.

[4]  Y. Ohkawa,et al.  Therapeutic Activities of Engrafted Neural Stem/Precursor Cells Are Not Dormant in the Chronically Injured Spinal Cord , 2013, Stem cells.

[5]  L. Marson,et al.  Identification of central nervous system neurons that innervate the bladder body, bladder base, or external urethral sphincter of female rats: A transneuronal tracing study using pseudorabies virus , 1997, The Journal of comparative neurology.

[6]  Linghui Yang,et al.  OECs transplantation results in neuropathic pain associated with BDNF regulating ERK activity in rats following cord hemisection , 2013, BMC Neuroscience.

[7]  I. Fischer,et al.  Phenotypic analysis of astrocytes derived from glial restricted precursors and their impact on axon regeneration , 2012, Experimental Neurology.

[8]  J. Wrathall,et al.  Coordination of the Bladder Detrusor and the External Urethral Sphincter in a Rat Model of Spinal Cord Injury: Effect of Injury Severity , 2001, The Journal of Neuroscience.

[9]  A. Basbaum,et al.  Use of serotonin immunocytochemistry as a marker of injury severity after experimental spinal trauma in rats , 1988, Brain Research.

[10]  X. Wen,et al.  A Novel Growth-Promoting Pathway Formed by GDNF-Overexpressing Schwann Cells Promotes Propriospinal Axonal Regeneration, Synapse Formation, and Partial Recovery of Function after Spinal Cord Injury , 2013, The Journal of Neuroscience.

[11]  M. Lemay,et al.  Grafted Neural Progenitors Integrate and Restore Synaptic Connectivity across the Injured Spinal Cord , 2011, The Journal of Neuroscience.

[12]  W. C. Groat,et al.  Changes in micturition after spinal cord injury in conscious rats. , 1999, Urology.

[13]  M. Tuszynski,et al.  Long-Distance Growth and Connectivity of Neural Stem Cells after Severe Spinal Cord Injury , 2012, Cell.

[14]  K. Fouad,et al.  Motor Axonal Regeneration after Partial and Complete Spinal Cord Transection , 2012, The Journal of Neuroscience.

[15]  S. Whittemore,et al.  Functional Recovery in Traumatic Spinal Cord Injury after Transplantation of Multineurotrophin-Expressing Glial-Restricted Precursor Cells , 2005, The Journal of Neuroscience.

[16]  M. Fehlings,et al.  Delayed Transplantation of Adult Neural Precursor Cells Promotes Remyelination and Functional Neurological Recovery after Spinal Cord Injury , 2006, The Journal of Neuroscience.

[17]  P. Wood,et al.  Labeled Schwann cell transplantation: Cell loss, host Schwann cell replacement, and strategies to enhance survival , 2006, Glia.

[18]  I. Fischer,et al.  Transplanting neural progenitors into a complete transection model of spinal cord injury , 2014, Journal of neuroscience research.

[19]  D. Pearse,et al.  Stem and progenitor cell therapies: recent progress for spinal cord injury repair , 2008, Neurological research.

[20]  O. Steward,et al.  A noninvasive ultrasonographic method to evaluate bladder function recovery in spinal cord injured rats , 2005, Experimental Neurology.

[21]  J. Wrathall,et al.  Comparison of the effects of complete and incomplete spinal cord injury on lower urinary tract function as evaluated in unanesthetized rats , 2007, Experimental Neurology.

[22]  A. Sharma,et al.  Functional Recovery in Chronic Stage of Spinal Cord Injury by Neurorestorative Approach: A Case Report , 2014, Case reports in surgery.

[23]  I. Fischer,et al.  Promoting directional axon growth from neural progenitors grafted into the injured spinal cord , 2009, Journal of neuroscience research.

[24]  J. Silver,et al.  Functional regeneration beyond the glial scar , 2014, Experimental Neurology.

[25]  D. Geschwind,et al.  Combined Intrinsic and Extrinsic Neuronal Mechanisms Facilitate Bridging Axonal Regeneration One Year after Spinal Cord Injury , 2009, Neuron.

[26]  X. Navarro,et al.  Chronic transplantation of olfactory ensheathing cells promotes partial recovery after complete spinal cord transection in the rat , 2007, Glia.

[27]  J. García-Verdugo,et al.  Transplanted neural stem/precursor cells instruct phagocytes and reduce secondary tissue damage in the injured spinal cord. , 2012, Brain : a journal of neurology.

[28]  M. Oudega,et al.  Schwann cell transplantation for repair of the adult spinal cord. , 2006, Journal of neurotrauma.

[29]  Andrés Hurtado,et al.  Early necrosis and apoptosis of Schwann cells transplanted into the injured rat spinal cord , 2007, The European journal of neuroscience.

[30]  S. Strittmatter,et al.  Functional Axonal Regeneration through Astrocytic Scar Genetically Modified to Digest Chondroitin Sulfate Proteoglycans , 2007, The Journal of Neuroscience.

[31]  H. Okano,et al.  Transplantation of neural stem cells into the spinal cord after injury. , 2003, Seminars in cell & developmental biology.

[32]  B. Kwon,et al.  Expression of inflammatory cytokines following acute spinal cord injury in a rodent model , 2012, Journal of neuroscience research.

[33]  Charles Tator,et al.  Transplantation of adult rat spinal cord stem/progenitor cells for spinal cord injury. , 2007, Journal of neurotrauma.

[34]  Edmund R Hollis,et al.  Neurotrophins: Potential Therapeutic Tools for the Treatment of Spinal Cord Injury , 2011, Neurotherapeutics.

[35]  J. Wrathall,et al.  Dose-dependent reduction of tissue loss and functional impairment after spinal cord trauma with the AMPA/kainate antagonist NBQX , 1994, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[36]  I. Fischer,et al.  Grafted Lineage-Restricted Precursors Differentiate Exclusively into Neurons in the Adult Spinal Cord , 2002, Experimental Neurology.

[37]  M. Tuszynski,et al.  NT-3 gene delivery elicits growth of chronically injured corticospinal axons and modestly improves functional deficits after chronic scar resection , 2003, Experimental Neurology.

[38]  M. Murray,et al.  Transplantation of Neuronal and Glial Restricted Precursors into Contused Spinal Cord Improves Bladder and Motor Functions, Decreases Thermal Hypersensitivity, and Modifies Intraspinal Circuitry , 2005, The Journal of Neuroscience.

[39]  M. Lemay,et al.  Combining Peripheral Nerve Grafts and Chondroitinase Promotes Functional Axonal Regeneration in the Chronically Injured Spinal Cord , 2009, The Journal of Neuroscience.

[40]  Time-dependent changes in the microenvironment of injured spinal cord affects the therapeutic potential of neural stem cell transplantation for spinal cord injury , 2013, Molecular Brain.

[41]  D. Basso,et al.  Acute and chronic tactile sensory testing after spinal cord injury in rats. , 2012, Journal of visualized experiments : JoVE.

[42]  O. Steward,et al.  Deficits in bladder function following spinal cord injury vary depending on the level of the injury , 2010, Experimental Neurology.

[43]  J. Houlé,et al.  Chronic at- and below-level pain after moderate unilateral cervical spinal cord contusion in rats. , 2013, Journal of neurotrauma.

[44]  D. Basso,et al.  A sensitive and reliable locomotor rating scale for open field testing in rats. , 1995, Journal of neurotrauma.

[45]  J. Wrathall,et al.  Local Blockade of Sodium Channels by Tetrodotoxin Ameliorates Tissue Loss and Long-Term Functional Deficits Resulting from Experimental Spinal Cord Injury , 1997, The Journal of Neuroscience.

[46]  M. Tuszynski,et al.  Axon regeneration through scars and into sites of chronic spinal cord injury , 2007, Experimental Neurology.

[47]  V. Rafuse,et al.  Sprouting of CGRP primary afferents in lumbosacral spinal cord precedes emergence of bladder activity after spinal injury , 2007, Experimental Neurology.

[48]  L. Weaver,et al.  Sprouting of primary afferent fibers after spinal cord transection in the rat , 1998, Neuroscience.

[49]  N. Theodore,et al.  Pharmacological therapy for acute spinal cord injury. , 2015, Neurosurgery.

[50]  A. Blesch,et al.  Neurotrophic factors in combinatorial approaches for spinal cord regeneration , 2012, Cell and Tissue Research.

[51]  M. Hassouna,et al.  Change of vanilloid receptor 1 following neuromodulation in rats with spinal cord injury. , 2002, The Journal of surgical research.

[52]  W. D. de Groat,et al.  Immunoneutralization of nerve growth factor in lumbosacral spinal cord reduces bladder hyperreflexia in spinal cord injured rats. , 2002, The Journal of urology.

[53]  I. Fischer,et al.  Transplantation of human glial restricted progenitors and derived astrocytes into a contusion model of spinal cord injury. , 2011, Journal of neurotrauma.

[54]  M. Murray,et al.  Nogo-66 Receptor Antagonist Peptide (NEP1-40) Administration Promotes Functional Recovery and Axonal Growth After Lateral Funiculus Injury in the Adult Rat , 2008, Neurorehabilitation and neural repair.

[55]  I. Fischer,et al.  Human astrocytes derived from glial restricted progenitors support regeneration of the injured spinal cord. , 2013, Journal of neurotrauma.

[56]  D. Pearse,et al.  Survival, Integration, and Axon Growth Support of Glia Transplanted into the Chronically Contused Spinal Cord , 2005, Cell transplantation.

[57]  A. Tessler,et al.  Transplants of Fibroblasts Genetically Modified to Express BDNF Promote Axonal Regeneration from Supraspinal Neurons Following Chronic Spinal Cord Injury , 2002, Experimental Neurology.

[58]  W. C. Groat,et al.  Localization of NADPH diaphorase in the thoracolumbar and sacrococcygeal spinal cord of the dog. , 1997, Journal of the autonomic nervous system.

[59]  M. Fehlings,et al.  Synergistic Effects of Transplanted Adult Neural Stem/Progenitor Cells, Chondroitinase, and Growth Factors Promote Functional Repair and Plasticity of the Chronically Injured Spinal Cord , 2010, The Journal of Neuroscience.

[60]  J. Riddell,et al.  Olfactory ensheathing cell transplantation as a strategy for spinal cord repair—what can it achieve? , 2007, Nature Clinical Practice Neurology.

[61]  I. Fischer,et al.  Chondroitinase activity can be transduced by a lentiviral vector in vitro and in vivo , 2011, Journal of Neuroscience Methods.

[62]  D. Basso,et al.  Validity of acute and chronic tactile sensory testing after spinal cord injury in rats , 2010, Experimental Neurology.

[63]  P. Popovich,et al.  Emerging Concepts in Myeloid Cell Biology after Spinal Cord Injury , 2011, Neurotherapeutics.

[64]  Marion Murray,et al.  Transplantation of genetically modified cells contributes to repair and recovery from spinal injury , 2002, Brain Research Reviews.

[65]  R. Ribeiro‐dos‐Santos,et al.  Use of Autologous Mesenchymal Stem Cells Derived from Bone Marrow for the Treatment of Naturally Injured Spinal Cord in Dogs , 2014, Stem cells international.

[66]  M. Fehlings,et al.  A systematic review of cellular transplantation therapies for spinal cord injury. , 2011, Journal of neurotrauma.

[67]  I. Fischer,et al.  Lineage-restricted neural precursors survive, migrate, and differentiate following transplantation into the injured adult spinal cord , 2005, Experimental Neurology.

[68]  H. Kakizaki,et al.  Immortalized neural stem cells transplanted into the injured spinal cord promote recovery of voiding function in the rat. , 2003, The Journal of urology.