Extramedullary Chitosan Channels Promote Survival of Transplanted Neural Stem and Progenitor Cells and Create a Tissue Bridge After Complete Spinal Cord Transection

Nomura, Hiroshi; Zahir, Tasneem; Kim, Howard; Katayama, Yusuke; Kulbatski, Iris; Morshead, Cindi M.; Shoichet, Molly S.; Tator, Charles H.

doi:10.1089/tea.2007.0180

Cited by 119 publications

(111 citation statements)

References 72 publications

(96 reference statements)

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“…The BBB scores and respective standard deviations were extrapolated to the nearest decimal point from the published graphs in some studies. 9,12,30 Studies with no published BBB scores 10,16,17,19,22,24,29 or with published graphs which did not allow for extraction of values 20,21,31 were excluded from cumulative meta-analysis. A 'metan' command was utilized for calculation of individual and poole-weighted mean difference between experimental and control groups using the DerSimonian-Laird method.…”

Section: Methodsmentioning

confidence: 99%

“…Spinal cord transection [9][10][11]14,21,[23][24][25][26]28,31,32 was the most common injury model followed by hemisection. 12,13,[15][16][17][18][19]22,27,29,30 Most studies contained information about the effects of acute intervention after induction of SCI but some studies also contained information about the effects in the sub-acute or chronic phase.…”

Section: Overall Characteristics Of Published Studiesmentioning

confidence: 99%

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Biomaterial-based interventions for neuronal regeneration and functional recovery in rodent model of spinal cord injury: A systematic review

Krishna

Konakondla

Nicholas

et al. 2013

The Journal of Spinal Cord Medicine

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Context: There is considerable interest in translating laboratory advances in neuronal regeneration following spinal cord injury (SCI). A multimodality approach has been advocated for successful functional neuronal regeneration. With this goal in mind several biomaterials have been employed as neuronal bridges either to support cellular transplants, to release neurotrophic factors, or to do both. A systematic review of this literature is lacking. Such a review may provide insight to strategies with a high potential for further investigation and potential clinical application. Objective: To systematically review the design strategies and outcomes after biomaterial-based multimodal interventions for neuronal regeneration in rodent SCI model. To analyse functional outcomes after implantation of biomaterial-based multimodal interventions and to identify predictors of functional outcomes. Methods: A broad PubMed, CINHAL, and a manual search of relevant literature databases yielded data from 24 publications; 14 of these articles included functional outcome information. Studies reporting behavioral data in rat model of SCI and employing biodegradable polymer-based multimodal intervention were included. For behavioral recovery, studies using severe injury models (transection or severe clip compression (>16.9 g) or contusion (50 g/cm)) were categorized separately from those investigating partial injury models (hemisection or moderate-to-severe clip compression or contusion). Results: The cumulative mean improvements in Basso, Beattie, and Bresnahan scores after biomaterial-based interventions are 5.93 (95% CI = 2.41 − 9.45) and 4.44 (95% CI = 2.65 -6.24) for transection and hemisection models, respectively. Factors associated with improved outcomes include the type of polymer used and a follow-up period greater than 6 weeks. Conclusion: The functional improvement after implantation of biopolymer-based multimodal implants is modest. The relationship with neuronal regeneration and functional outcome, the effects of inflammation at the site of injury, the prolonged survival of supporting cells, the differentiation of stem cells, the effective delivery of neurotrophic factors, and longer follow-up periods are all topics for future elucidation. Future investigations should strive to further define specific factors associated with improved functional outcomes in clinically relevant models.

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Section: Methodsmentioning

confidence: 99%

Section: Overall Characteristics Of Published Studiesmentioning

confidence: 99%

Biomaterial-based interventions for neuronal regeneration and functional recovery in rodent model of spinal cord injury: A systematic review

Krishna

Konakondla

Nicholas

et al. 2013

The Journal of Spinal Cord Medicine

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“…Biomaterials are becoming increasingly popular as a potential tool for the treatment of SCI as a mean to restore the ECM at the site of injury. Various materials, both of natural and synthetic origin, have been investigated for potential applications in the spinal cord (Nomura, Tator, & Shoichet, 2006;Novikova et al, 2003;Samadikuchaksaraei, 2007;Straley, Foo, & Heilshorn, 2010). These materials can support endogenous tissue regeneration (Tysseling-Mattiace et al, 2008;Woerly, Pinet, de Robertis, Van Diep, & Bousmina, 2001), promote directed axonal regrowth (Li and Hoffman-Kim, 2008;Yoshii, Ito, Shima, Taniguchi, & Akagi, 2009), enhance cell transplant survival and integration (Itosaka et al, 2009;Teng et al, 2002), deliver drugs ( Johnson, Parker, & Sakiyama-Elbert, 2009;Kang, Poon, Tator, & Shoichet, 2009;Willerth & Sakiyama-Elbert, 2007), and seal damaged dura mater (Gazzeri et al, 2009).…”

Section: Chitosan For Central Nervous System Repairmentioning

confidence: 99%

“…This property has been used to prepare a nonviral vector gene delivery system (Mumper, Wang, Claspell, & Rolland, 1995). Among the different tissue organs, many studies have investigated the use of chitosan for repair, not only because of its biocompatibility, biodegradability, low toxicity, and cost but also because of its excellent potential for supporting three-dimensional organization of regenerating tissues (Evans et al, 1999;Ho et al, 2005;Ma et al, 2003;Madihally & Matthew, 1999;Novikova, Novikov, & Kellerth, 2003;Vasconcelos & GayEscoda, 2000). Here, we review the main chitosan-based bioengineering strategies for peripheral nerve and spinal cord injury (SCI) repair.…”

Section: Introductionmentioning

confidence: 99%

The Use of Chitosan-Based Scaffolds to Enhance Regeneration in the Nervous System

Gnavi

Barwig²,

Freier³

et al. 2013

International Review of Neurobiology

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Various biomaterials have been proposed to build up scaffolds for promoting neural repair. Among them, chitosan, a derivative of chitin, has been raising more and more interestamongbasicandclinicalscientists.Anumberofstudieswithneuronalandglial cellcultures haveshownthat thisbiomaterial has biomimetic properties,which make it a good candidate for developing innovative devices for neural repair. Yet, in vivo experimental studies have shown that chitosan can be successfully used to create scaffolds that promote regeneration both in the central and in the peripheral nervous system. In this review, the relevant literature on the use of chitosan in the nervous tissue, either alone or in combination with other components, is overviewed. Altogether, the promising in vitro and in vivo experimental results make it possible to foresee that time for clinicaltrialswithchitosan-basednerveregenerationpromotingdevicesisapproaching quickly.

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“…CH biodegradability and cytocompatibility with neural cells [7] associated with its versatility to be processed into flexible tubular and porous structures make it interesting for the design of guidance matrices. CH-based nerve guidance matrices have been successfully explored for peripheral nerve regeneration [8] and, more recently, for application in the spinal cord, in combination with cell transplantation therapies [9][10][11]. CH degradation in vivo is thought to be mediated predominantly by lysozyme [12], an enzyme normally present in the cerebrospinal fluid at low concentrations, though upregulated after SCI [13,14].…”

Section: Introductionmentioning

confidence: 99%

Endothelialization of chitosan porous conduits via immobilization of a recombinant fibronectin fragment (rhFNIII7–10)

et al. 2013

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The present study aimed to develop a pre-endothelialized chitosan (CH) porous hollowed scaffold for application in spinal cord regenerative therapies. CH conduits with different degrees of acetylation (DA; 4% and 15%) were prepared, characterized (microstructure, porosity and water uptake) and functionalized with a recombinant fragment of human fibronectin (rhFNIII ). Immobilized rhFNIII 7-10 7-10 was characterized in terms of amount ( 125 I-radiolabelling), exposure of cell-binding domains (immunofluorescence) and ability to mediate endothelial cell (EC) adhesion and cytoskeletal rearrangement. Func-K e y w o r d s :Three-dimensional scaffolds tionalized conduits revealed a linear increase in immobilized rhFNIII 7-10 with rhFNIII 7-10 concentration, Surface grafting Protein radiolabelling Protein conformation Spinal cord injury and, for the same concentration, higher amounts of rhFNIII7-10 on DA 4% compared with DA 15%. Moreover, rhFNIII7-10 concentrations as low as 5 and 20 lg ml -1 in the coupling reaction were shown to provide DA 4% and 15% scaffolds, respectively, with levels of exposed cell-binding domains exceeding those observed on the control (DA 4% scaffolds incubated in a 20 lg ml -1 human fibronectin solution). These grafting conditions proved to be effective in mediating EC adhesion/cytoskeletal organization on CH with DA 4% and 15%, without affecting the endothelial angiogenic potential. rhFNIII7-10 grafting to CH could be a strategy of particular interest in tissue engineering applications requiring the use of endothelialized porous matrices with tunable degradation rates.

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Extramedullary Chitosan Channels Promote Survival of Transplanted Neural Stem and Progenitor Cells and Create a Tissue Bridge After Complete Spinal Cord Transection

Cited by 119 publications

References 72 publications

Biomaterial-based interventions for neuronal regeneration and functional recovery in rodent model of spinal cord injury: A systematic review

Biomaterial-based interventions for neuronal regeneration and functional recovery in rodent model of spinal cord injury: A systematic review

The Use of Chitosan-Based Scaffolds to Enhance Regeneration in the Nervous System

Endothelialization of chitosan porous conduits via immobilization of a recombinant fibronectin fragment (rhFNIII7–10)

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