Literature DB >> 23182350

Templated agarose scaffolds for the support of motor axon regeneration into sites of complete spinal cord transection.

Mingyong Gao1, Paul Lu, Bridget Bednark, Dan Lynam, James M Conner, Jeff Sakamoto, Mark H Tuszynski.   

Abstract

Bioengineered scaffolds have the potential to support and guide injured axons after spinal cord injury, contributing to neural repair. In previous studies we have reported that templated agarose scaffolds can be fabricated into precise linear arrays and implanted into the partially injured spinal cord, organizing growth and enhancing the distance over which local spinal cord axons and ascending sensory axons extend into a lesion site. However, most human injuries are severe, sparing only thin rims of spinal cord tissue in the margins of a lesion site. Accordingly, in the present study we examined whether template agarose scaffolds seeded with bone marrow stromal cells secreting Brain-Derived Neurotrophic Factor (BDNF) would support regeneration into severe, complete spinal cord transection sites. Moreover, we tested responses of motor axon populations originating from the brainstem. We find that templated agarose scaffolds support motor axon regeneration into a severe spinal cord injury model and organize axons into fascicles of highly linear configuration. BDNF significantly enhances axonal growth. Collectively, these findings support the feasibility of scaffold implantation for enhancing central regeneration after even severe central nervous system injury. Published by Elsevier Ltd.

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Year:  2012        PMID: 23182350      PMCID: PMC3518618          DOI: 10.1016/j.biomaterials.2012.10.070

Source DB:  PubMed          Journal:  Biomaterials        ISSN: 0142-9612            Impact factor:   12.479


  35 in total

1.  Regeneration of sensory axons within the injured spinal cord induced by intraganglionic cAMP elevation.

Authors:  Simona Neumann; Frank Bradke; Marc Tessier-Lavigne; Allan I Basbaum
Journal:  Neuron       Date:  2002-06-13       Impact factor: 17.173

2.  Endogenous radial glial cells support regenerating axons after spinal cord transection.

Authors:  Hiroshi Nomura; Howard Kim; Andrea Mothe; Tasneem Zahir; Iris Kulbatski; Cindi M Morshead; Molly S Shoichet; Charles H Tator
Journal:  Neuroreport       Date:  2010-09-15       Impact factor: 1.837

Review 3.  Guidelines for the conduct of clinical trials for spinal cord injury (SCI) as developed by the ICCP panel: clinical trial outcome measures.

Authors:  J D Steeves; D Lammertse; A Curt; J W Fawcett; M H Tuszynski; J F Ditunno; P H Ellaway; M G Fehlings; J D Guest; N Kleitman; P F Bartlett; A R Blight; V Dietz; B H Dobkin; R Grossman; D Short; M Nakamura; W P Coleman; M Gaviria; A Privat
Journal:  Spinal Cord       Date:  2006-12-19       Impact factor: 2.772

4.  Skin-derived precursors generate myelinating Schwann cells that promote remyelination and functional recovery after contusion spinal cord injury.

Authors:  Jeff Biernaskie; Joseph S Sparling; Jie Liu; Casey P Shannon; Jason R Plemel; Yuanyun Xie; Freda D Miller; Wolfram Tetzlaff
Journal:  J Neurosci       Date:  2007-09-05       Impact factor: 6.167

5.  Rationally designed peptides for controlled release of nerve growth factor from fibrin matrices.

Authors:  Stephanie M Willerth; Philip J Johnson; Dustin J Maxwell; Sarah R Parsons; Maria E Doukas; Shelly E Sakiyama-Elbert
Journal:  J Biomed Mater Res A       Date:  2007-01       Impact factor: 4.396

6.  Combinatorial therapy with neurotrophins and cAMP promotes axonal regeneration beyond sites of spinal cord injury.

Authors:  Paul Lu; Hong Yang; Leonard L Jones; Marie T Filbin; Mark H Tuszynski
Journal:  J Neurosci       Date:  2004-07-14       Impact factor: 6.167

Review 7.  Spinal cord contusion models.

Authors:  Wise Young
Journal:  Prog Brain Res       Date:  2002       Impact factor: 2.453

8.  Fibroblasts genetically modified to produce nerve growth factor induce robust neuritic ingrowth after grafting to the spinal cord.

Authors:  M H Tuszynski; D A Peterson; J Ray; A Baird; Y Nakahara; F H Gage
Journal:  Exp Neurol       Date:  1994-03       Impact factor: 5.330

9.  Templated agarose scaffolds support linear axonal regeneration.

Authors:  Shula Stokols; Jeff Sakamoto; Chris Breckon; Todd Holt; James Weiss; Mark H Tuszynski
Journal:  Tissue Eng       Date:  2006-10

10.  cAMP and Schwann cells promote axonal growth and functional recovery after spinal cord injury.

Authors:  Damien D Pearse; Francisco C Pereira; Alexander E Marcillo; Margaret L Bates; Yerko A Berrocal; Marie T Filbin; Mary Bartlett Bunge
Journal:  Nat Med       Date:  2004-05-23       Impact factor: 53.440
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  44 in total

1.  3D Printed Stem-Cell Derived Neural Progenitors Generate Spinal Cord Scaffolds.

Authors:  Daeha Joung; Vincent Truong; Colin C Neitzke; Shuang-Zhuang Guo; Patrick J Walsh; Joseph R Monat; Fanben Meng; Sung Hyun Park; James R Dutton; Ann M Parr; Michael C McAlpine
Journal:  Adv Funct Mater       Date:  2018-08-09       Impact factor: 18.808

2.  The Impact of Prestretch Induced Surface Anisotropy on Axon Regeneration.

Authors:  Chun Liu; Ryan Pyne; Jungsil Kim; Neil Thomas Wright; Seungik Baek; Christina Chan
Journal:  Tissue Eng Part C Methods       Date:  2016-01-08       Impact factor: 3.056

3.  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

4.  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

5.  Oriented Nanofibrous Polymer Scaffolds Containing Protein-Loaded Porous Silicon Generated by Spray Nebulization.

Authors:  Jonathan M Zuidema; Tushar Kumeria; Dokyoung Kim; Jinyoung Kang; Joanna Wang; Geoffrey Hollett; Xuan Zhang; David S Roberts; Nicole Chan; Cari Dowling; Elena Blanco-Suarez; Nicola J Allen; Mark H Tuszynski; Michael J Sailor
Journal:  Adv Mater       Date:  2018-01-24       Impact factor: 30.849

Review 6.  Recent advances in nanotherapeutic strategies for spinal cord injury repair.

Authors:  Young Hye Song; Nikunj K Agrawal; Jonathan M Griffin; Christine E Schmidt
Journal:  Adv Drug Deliv Rev       Date:  2018-12-22       Impact factor: 15.470

7.  Promotion of neuronal regeneration by using self-polymerized dendritic polypeptide scaffold for spinal cord tissue engineering.

Authors:  Jun Ming Wan; Liang le Liu; Jian Fang Zhang; Jian Wei Lu; Qi Li
Journal:  J Mater Sci Mater Med       Date:  2017-12-14       Impact factor: 3.896

8.  3D Printed Neural Regeneration Devices.

Authors:  Daeha Joung; Nicolas S Lavoie; Shuang-Zhuang Guo; Sung Hyun Park; Ann M Parr; Michael C McAlpine
Journal:  Adv Funct Mater       Date:  2019-11-08       Impact factor: 18.808

9.  In Vivo Microcomputed Tomography of Nanocrystal-Doped Tissue Engineered Scaffolds.

Authors:  Stacey M Forton; Matthew T Latourette; Maciej Parys; Matti Kiupel; Dena Shahriari; Jeff S Sakamoto; Erik M Shapiro
Journal:  ACS Biomater Sci Eng       Date:  2016-02-29

Review 10.  Naturally-Derived Biomaterials for Tissue Engineering Applications.

Authors:  Matthew Brovold; Joana I Almeida; Iris Pla-Palacín; Pilar Sainz-Arnal; Natalia Sánchez-Romero; Jesus J Rivas; Helen Almeida; Pablo Royo Dachary; Trinidad Serrano-Aulló; Shay Soker; Pedro M Baptista
Journal:  Adv Exp Med Biol       Date:  2018       Impact factor: 2.622
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