Sage Journals: Discover world-class research

Abstract

Using a complete spinal cord transection model, the present study employed a combinatorial strategy comprising rat bone marrow stem cells (rBMSCs) and polymer scaffolds to regenerate neurological function after spinal cord injury (SCI) of different lengths. SCI models with completely transected lesions were prepared by surgical removal of 1 mm (SC1) or 3 mm (SC3) lengths of spinal cord in the eighth-to-ninth spinal vertebrae, a procedure that resulted in bilateral hindlimb paralysis. A cylindrical poly(D,L-lactide-co-glycolide)/small intestinal submucosa scaffold 1 or 3 mm in length with or without rBMSCs was fitted into the completely transected lesion. Rats in SC1 and SC3 groups implanted with rBMSC-containing scaffolds received Basso–Beattie–Bresnahan scores for hindlimb locomotion of 15 and 8, respectively, compared with ∼3 for control rats in SC1-C and SC3-C groups implanted with scaffolds lacking rBMSCs. The amplitude of motor-evoked potentials recorded in the hindlimb area of the sensorimotor cortex after stimulation of the injured spinal cord averaged ∼100 μV in SC1-C and 10–50 μV in SC3-C groups at 4 weeks, and then declined to nearly zero at 8 weeks. In contrast, the amplitude of motor-evoked potentials increased from ∼300 to 350 μV between 4 and 8 weeks in SC1 rats and from ∼200 to ∼250 μV in SC3 rats. These results demonstrate functional recovery in rBMSC-transplanted rats, especially those with smaller defects. Immunohistochemically stained sections of the injury site showed clear evidence for axonal regeneration only in rBMSC-transplanted SC1 and SC3 models. In addition, rBMSCs were detected at the implanted site 4 and 8 weeks after transplantation, indicating cell survival in SCI. Collectively, our results indicate that therapeutic rBMSCs in a poly(D,L-lactide-co-glycolide)/small intestinal submucosa scaffold induced nerve regeneration in a complete spinal cord transection model and showed that functional recovery further depended on defect length.

Get full access to this article

View all access options for this article.

References

Hambly

P.R.

, Martin

Anaesthesia for chronic spinal cord lesions. Anaesthesia, 53:273. 1998.

Gross

R.E.

, Mei

, Gutekunst

C.A.

, Torre

The pivotal role of RhoA GTPase in the molecular signaling of axon growth inhibition after CNS injury and targeted therapeutic strategies. Cell Transplant, 16:245. 2007.

Hermanns

, Klapka

, Gasis

, Müller

H.W.

The collagenous wound healing scar in the injured central nervous system inhibits axonal regeneration. Adv Exp Med Biol, 557:177. 2006.

Han

, Jin

, Xiao

, Ni

, Wang

, Kong

, Wu

, Liang

, Chen

, Zhao

, Chen

, Dai

The promotion of neural regeneration in an extreme rat spinal cord injury model using a collagen scaffold containing a collagen binding neuroprotective protein and an EGFR neutralizing antibody. Biomaterials, 31:9212. 2010.

Teng

Y.D.

, Liao

W.L.

, Choi

, Konya

, Sabharwal

, Langer

, Sidman

R.L.

, Snyder

E.Y.

, Frontera

W.R.

Physical activity-mediated functional recovery after spinal cord injury: potential roles of neural stem cells. Regen Med, 1:763. 2006.

Sahni

, Kessler

J.A.

Stem cell therapies for spinal cord injury. Nat Rev Neurol, 6:363. 2010.

Zietlow

, Lane

E.L.

, Dunnett

S.B.

, Rosser

A.E.

Human stem cells for CNS repair. Cell Tissue Res, 3311:301. 2008.

Vacanti

M.P.

, Leonard

J.L.

, Dore

, Bonassar

L.J.

, Cao

, Stachelek

S.J.

, Vacanti

J.P.

, O'Connell

, Yu

C.S.

, Farwell

A.P.

, Vacanti

C.A.

Tissue-engineered spinal cord. Transplant Proceed, 33:592. 2001.

Baumann

M.D.

, Kang

C.E.

, Tator

C.H.

, Shoichet

M.S.

Intrathecal delivery of a polymeric nanocomposite hydrogel after spinal cord injury. Biomaterials, 31:7631. 2010.

10.

Silva

N.A.

, Salgado

A.J.

, Sousa

R.A.

, Oliveira

J.T.

, Pedro

A.J.

, Leite-Almeida

, Cerqueira

, Almeida

, Mastronardi

, Mano

J.F.

, Neves

N.M.

, Sousa

, Reis

R.L.

Development and characterization of a Novel Hybrid Tissue Engineering–based scaffold for spinal cord injury repair. Tissue Eng Part A, 16:45. 2010.

11.

Novikova

L.N.

, Novikov

L.N.

, Kellerth

J.O.

Biopolymers and biodegradable smart implants for tissue regeneration after spinal cord injury. Curr Opin Neurol, 16:711. 2003.

12.

Talac

, Friedman

J.A.

, Moore

M.J.

, Lu

, Jabbari

, Windebank

A.J.

, Currier

B.L.

, Yaszemski

M.J.

Animal models of spinal cord injury for evaluation of tissue engineering treatment strategies. Biomaterials, 25:1505. 2004.

13.

De Nicola

A.F.

, Labombarda

, Deniselle

M.C.

, Gonzalez

S.L.

, Garay

, Meyer

, Gargiulo

, Guennoun

, Schumacher

Progesterone neuroprotection in traumatic CNS injury and motoneuron degeneration. Front Neuroendocrinol, 30:173. 2009.

14.

Schmidt

C.E.

, Leach

J.B.

Neural tissue engineering: strategies for repair and regeneration. Annu RevBiomed Eng, 5:293. 2003.

15.

Hooshmand

M.J.

, Sontag

C.J.

, Uchida

, Tamaki

, Anderson

A.J.

, Cummings

B.J.

Analysis of host-mediated repair mechanisms after human CNS-stem cell transplantation for spinal cord injury: correlation of engraftment with recovery. PLoS One, 4:e5871. 2009.

16.

Gregory

C.M.

, Bowden

M.G.

, Jayaraman

, Shah

, Behrman

, Kautz

S.A.

, Vandenborne

Resistance training and locomotor recovery after incomplete spinal cord injury: a case series. Spinal Cord, 45:522. 2007.

17.

Fouad

, Metz

G.A.

, Merkler

, Dietz

, Schwab

M.E.

Treadmill training in incomplete spinal cord injured rats. Behav Brain Res, 115:107. 2000.

18.

Kiyotani

, Teramachi

, Takimoto

, Nakamura

, Shimizu

, Endo

Nerve regeneration across a 25-mm gap bridged by a polyglycolic acid-collagen tube: a histological and electrophysiological evaluation of regenerated nerves. Brain Res, 740:66. 1996.

19.

Kim

S.K.

, Hong

K.D.

, Jang

J.W.

, Lee

S.J.

, Kim

M.S.

, Khang

, Lee

H.B.

Tissue Engineered Spinal Cord using Bone Marrow Stromal Stem Cells Seeded PGA Scaffolds; Preliminary Study. Tissue Eng Regen Med, 1:149. 2004.

20.

Hong

K.D.

, Seo

K.S.

, Kim

S.H.

, Kim

S.K.

, Khang

, Shin

H.S.

, Kim

M.S.

, Lee

H.B.

Preparation and release behavior of albumin-loaded PLGA scaffold by ice particle leaching method. Polymer(Korea), 29:282. 2005.

21.

Kim

S.K.

, Kim

S.H.

, Lee

H.R.

, Cho

M.H.

, Kim

M.S.

, Khang

, Lee

H.B.

Preparation and characterization of BDNF-loaded PLGA scaffold. Tissue Eng Regen Med, 2:388. 2005.

22.

Kim

S.H.

, Yun

S.J.

, Jang

J.W.

, Kim

M.S.

, Khang

, Lee

H.B.

Effect of SIS/PLGA porous scaffolds and muscle-derived stem cell on the formation of tissue engineered bone. Polymer(Korea), 30:14. 2006.

23.

Kim

M.S.

, Ahn

H.H.

, Cho

M.H.

, Shin

Y.N.

, Khang

, Lee

H.B.

An in vivo study of the host tissue response to subcutaneous implantation of PLGA- and/or porcine small intestinal submucosa based scaffolds. Biomaterials, 28:5137. 2007.

24.

Willerth

S.M.

, Sakiyama-Elbert

S.E.

Cell therapy for spinal cord regeneration. Adv Drug Deliv Rev, 60:263. 2008.

25.

Cho

M.H.

, Lee

J.H.

, Ahn

H.H.

, Lee

J.Y.

, Kim

E.S.

, Kang

Y.M.

, Min

B.H.

, Kim

J.H.

, Lee

H.B.

, Kim

M.S.

Induction of neurogenesis in rat bone marrow mesenchymal stem cells using purine structure-based compounds. Mol BioSyst, 5:609. 2009.

26.

Furuya

, Hashimotoa

, Koda

, Okawa

, Murata

, Takahashi

, Yamashita

, Yamazaki

Treatment of rat spinal cord injury with a Rho-kinase inhibitor and bone marrow stromal cell transplantation. Brain Res, 1295:192. 2009.

27.

Himes

B.T.

, Neuhuber

, Coleman

, Kushner

, Swanger

S.A.

, Kopen

G.C.

, Wagner

, Shumsky

J.S.

, Fischer

Recovery of function following grafting of human bone marrow-derived stromal cells into the injured spinal cord. Neurorehabil Neural Repair, 20:278. 2006.

28.

Isele

N.B.

, Lee

H.S.

, Landshamer

, Straube

, Padovan

C.S.

, Plesnila

, Culmsee

Bone marrow stromal cells mediate protection through stimulation of PI3-K/Akt and MAPK signaling in neurons. Neurochem Int, 50:243. 2007.

29.

Teng

Y.D.

, Lavik

E.B.

, Qu

, Park

K.I.

, Ourednik

, Zurakowski

, Langer

, Snyder

E.Y.

Functional recovery following traumatic spinal cord injury mediated by a unique polymer scaffold seeded with neural stem cells. Proc Natl Acad of Sci U S A, 99:3024. 2002.

30.

Courtine

, Bunge

M.B.

, Fawcett

J.W.

, Grossman

R.G.

, Kaas

J.H.

, Lemon

, Maier

, Martin

, Nudo

R.J.

, Ramon-Cueto

, Rouiller

E.M.

, Schnell

, Wannier

, Schwab

M.E.

, Edgerton

V.R.

Can experiments in nonhuman primates expedite the translation of treatments for spinal cord injury in humans?

Nat Med, 13:561. 2007.

31.

Pritchard

C.D.

, Slotkin

J.R.

, Yu

, Dai

, Lawrence

, Bronson

R.T.

, Reynolds

F.M.

, Teng

Y.D.

, Woodard

E.J.

, Langer

R.S.

Establishing a model spinal cord injury in the African green monkey for the preclinical evaluation of biodegradable polymer scaffolds seeded with human neural stem cells. J Neurosci Methods, 188:258. 2010.

32.

Zhang

, Yan

, Wen

, Zhang

, Yan

, Wen

Tissue-engineering approaches for axonal guidance. Brain Res Rev, 49:48. 2005.

33.

Ditunno

J.F.

Jr. , Cohen

M.E.

, Hauck

W.W.

, Jackson

A.B.

, Sipski

M.L.

Recovery of upper-extremity strength in complete and incomplete tetraplegia: a multicenter study. Arch Phys Med Rehabil, 81:389. 2000.

34.

Lee

K.H.

, Yoon

D.H.

, Chung

, Sohn

, Lee

B.H.

Neuroprotective effects of mexiletine on motor evoked potentials in demyelinated rat spinal cords. Neurosci Res, 67:59. 2010.

Supplementary Material

Please find the following supplemental material available below.

For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.

For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.

0.18 MB

0.00 MB

Regeneration of Completely Transected Spinal Cord Using Scaffold of Poly(D,L-Lactide-co-Glycolide)/Small Intestinal Submucosa Seeded with Rat Bone Marrow Stem Cells

Abstract

Get full access to this article

References

Supplementary Material