Literature DB >> 27701152

Tissue Engineering Approaches to Modulate the Inflammatory Milieu following Spinal Cord Injury.

Courtney M Dumont1, Daniel J Margul1,2, Lonnie D Shea1,3.   

Abstract

Tissue engineering strategies have shown promise in promoting healing and regeneration after spinal cord injury (SCI); however, these strategies are limited by inflammation and the immune response. Infiltration of cells of the innate and adaptive immune responses and the inflammation that follows cause secondary damage adjacent to the injury, increased scarring, and a potently inhibitory environment for the regeneration of damaged neurons. While the inflammation that ensues is typically associated with limited regeneration, the immune response is a crucial element in the closing of the blood-brain barrier, minimizing the spread of injury, and initiating healing. This review summarizes the strategies that have been developed to modulate the immune response towards an anti-inflammatory environment that is permissive to the regeneration of neurons, glia, and parenchyma. We focus on the use of biomaterials, biologically active molecules, gene therapy, nanoparticles, and stem cells to modulate the immune response, and illustrate concepts for future therapies. Current clinical treatments for SCI are limited to systemic hypothermia or methylprednisolone, which both act by systemically mitigating the effects of immune response but have marginal efficacy. Herein, we discuss emerging research strategies to further enhance these clinical treatments by directly targeting specific aspects of the immune response.
© 2016 S. Karger AG, Basel.

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Year:  2016        PMID: 27701152      PMCID: PMC5067186          DOI: 10.1159/000446646

Source DB:  PubMed          Journal:  Cells Tissues Organs        ISSN: 1422-6405            Impact factor:   2.481


  130 in total

Review 1.  Direct gene therapy for repair of the spinal cord.

Authors:  Bas Blits; Mary Bartlett Bunge
Journal:  J Neurotrauma       Date:  2006 Mar-Apr       Impact factor: 5.269

2.  Delivery of neurotrophin-3 from fibrin enhances neuronal fiber sprouting after spinal cord injury.

Authors:  Sara J Taylor; Ephron S Rosenzweig; John W McDonald; Shelly E Sakiyama-Elbert
Journal:  J Control Release       Date:  2006-06-22       Impact factor: 9.776

3.  A murine scavenger receptor MARCO recognizes polystyrene nanoparticles.

Authors:  Sanae Kanno; Akiko Furuyama; Seishiro Hirano
Journal:  Toxicol Sci       Date:  2007-03-14       Impact factor: 4.849

4.  Multiple channel bridges for spinal cord injury: cellular characterization of host response.

Authors:  Yang Yang; Laura De Laporte; Marina L Zelivyanskaya; Kevin J Whittlesey; Aileen J Anderson; Brian J Cummings; Lonnie D Shea
Journal:  Tissue Eng Part A       Date:  2009-11       Impact factor: 3.845

5.  Quantitative analysis of cellular inflammation after traumatic spinal cord injury: evidence for a multiphasic inflammatory response in the acute to chronic environment.

Authors:  Kevin D Beck; Hal X Nguyen; Manuel D Galvan; Desirée L Salazar; Trent M Woodruff; Aileen J Anderson
Journal:  Brain       Date:  2010-01-19       Impact factor: 13.501

6.  Coordinated antiinflammatory effects of interleukin 4: interleukin 4 suppresses interleukin 1 production but up-regulates gene expression and synthesis of interleukin 1 receptor antagonist.

Authors:  E Vannier; L C Miller; C A Dinarello
Journal:  Proc Natl Acad Sci U S A       Date:  1992-05-01       Impact factor: 11.205

7.  Conversion of Th17 into IL-17A(neg) regulatory T cells: a novel mechanism in prolonged allograft survival promoted by mesenchymal stem cell-supported minimized immunosuppressive therapy.

Authors:  Nataša Obermajer; Felix C Popp; Yorick Soeder; Jan Haarer; Edward K Geissler; Hans J Schlitt; Marc H Dahlke
Journal:  J Immunol       Date:  2014-10-10       Impact factor: 5.422

8.  Selective nanovector mediated treatment of activated proinflammatory microglia/macrophages in spinal cord injury.

Authors:  Simonetta Papa; Filippo Rossi; Raffaele Ferrari; Alessandro Mariani; Massimiliano De Paola; Ilaria Caron; Fabio Fiordaliso; Cinzia Bisighini; Eliana Sammali; Claudio Colombo; Marco Gobbi; Mara Canovi; Jacopo Lucchetti; Marco Peviani; Massimo Morbidelli; Gianluigi Forloni; Giuseppe Perale; Davide Moscatelli; Pietro Veglianese
Journal:  ACS Nano       Date:  2013-10-18       Impact factor: 15.881

9.  Enhanced GLT-1 mediated glutamate uptake and migration of primary astrocytes directed by fibronectin-coated electrospun poly-L-lactic acid fibers.

Authors:  Jonathan M Zuidema; María C Hyzinski-García; Kristien Van Vlasselaer; Nicholas W Zaccor; George E Plopper; Alexander A Mongin; Ryan J Gilbert
Journal:  Biomaterials       Date:  2013-11-15       Impact factor: 12.479

10.  A biodegradable nanoparticle platform for the induction of antigen-specific immune tolerance for treatment of autoimmune disease.

Authors:  Zoe Hunter; Derrick P McCarthy; Woon Teck Yap; Christopher T Harp; Daniel R Getts; Lonnie D Shea; Stephen D Miller
Journal:  ACS Nano       Date:  2014-02-27       Impact factor: 15.881
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  15 in total

Review 1.  Biomaterial Approaches to Modulate Reactive Astroglial Response.

Authors:  Jonathan M Zuidema; Ryan J Gilbert; Manoj K Gottipati
Journal:  Cells Tissues Organs       Date:  2018-12-05       Impact factor: 2.481

2.  Combinatorial tissue engineering partially restores function after spinal cord injury.

Authors:  Jeffrey S Hakim; Brian R Rodysill; Bingkun K Chen; Ann M Schmeichel; Michael J Yaszemski; Anthony J Windebank; Nicolas N Madigan
Journal:  J Tissue Eng Regen Med       Date:  2019-03-20       Impact factor: 3.963

3.  Spinal Progenitor-Laden Bridges Support Earlier Axon Regeneration Following Spinal Cord Injury.

Authors:  Courtney M Dumont; Mary K Munsell; Mitchell A Carlson; Brian J Cummings; Aileen J Anderson; Lonnie D Shea
Journal:  Tissue Eng Part A       Date:  2018-10-19       Impact factor: 3.845

4.  Polycistronic Delivery of IL-10 and NT-3 Promotes Oligodendrocyte Myelination and Functional Recovery in a Mouse Spinal Cord Injury Model.

Authors:  Dominique R Smith; Courtney M Dumont; Jonghyuck Park; Andrew J Ciciriello; Amina Guo; Ravindra Tatineni; Brian J Cummings; Aileen J Anderson; Lonnie D Shea
Journal:  Tissue Eng Part A       Date:  2020-02-25       Impact factor: 3.845

5.  Injectable hydrogels of optimized acellular nerve for injection in the injured spinal cord.

Authors:  R Chase Cornelison; Elisa J Gonzalez-Rothi; Stacy L Porvasnik; Steven M Wellman; James H Park; David D Fuller; Christine E Schmidt
Journal:  Biomed Mater       Date:  2018-03-21       Impact factor: 3.715

Review 6.  Nanoparticle-Based Delivery to Treat Spinal Cord Injury-a Mini-review.

Authors:  Atanu Chakraborty; Andrew J Ciciriello; Courtney M Dumont; Ryan M Pearson
Journal:  AAPS PharmSciTech       Date:  2021-03-12       Impact factor: 3.246

7.  IL-10 lentivirus-laden hydrogel tubes increase spinal progenitor survival and neuronal differentiation after spinal cord injury.

Authors:  Andrew J Ciciriello; Dominique R Smith; Mary K Munsell; Sydney J Boyd; Lonnie D Shea; Courtney M Dumont
Journal:  Biotechnol Bioeng       Date:  2021-04-23       Impact factor: 4.395

8.  Acute Implantation of Aligned Hydrogel Tubes Supports Delayed Spinal Progenitor Implantation.

Authors:  Andrew J Ciciriello; Dominique R Smith; Mary K Munsell; Sydney J Boyd; Lonnie D Shea; Courtney M Dumont
Journal:  ACS Biomater Sci Eng       Date:  2020-09-14

9.  Immunomodulation as a neuroprotective strategy after spinal cord injury.

Authors:  Susana Monteiro; António J Salgado; Nuno A Silva
Journal:  Neural Regen Res       Date:  2018-03       Impact factor: 5.135

10.  Delayed Injection of a Physically Cross-Linked PNIPAAm-g-PEG Hydrogel in Rat Contused Spinal Cord Improves Functional Recovery.

Authors:  Maxime Bonnet; Olivier Alluin; Thomas Trimaille; Didier Gigmes; Tanguy Marqueste; Patrick Decherchi
Journal:  ACS Omega       Date:  2020-04-27
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