|Year : 2018 | Volume
| Issue : 4 | Page : 220-226
Therapeutic effect of cell transplantation and chondroitinase in rat spinal cord injury
Durai Murugan Muniswami, George Tharion
Department of Physical Medicine and Rehabilitation, Christian Medical College, Vellore, Tamil Nadu, India
|Date of Submission||31-Dec-2017|
|Date of Acceptance||05-Jul-2018|
|Date of Web Publication||20-Nov-2018|
Dr. Durai Murugan Muniswami
Department of Physical Medicine and Rehabilitation, Christian Medical College, Vellore - 632 004, Tamil Nadu
Source of Support: None, Conflict of Interest: None
| Abstract|| |
Background: Spinal cord injury (SCI) leads to permanent functional deficits because the central nervous system lacks the ability for spontaneous repair. Cell therapy strategies offered a hope in neurological repair. The clinical use of human embryonic stem cell transplantation is hampered by scientific and ethical controversies. Olfactory ensheathing cells (OECs)/bone marrow mesenchymal stem cell (MSC) is a promising cell source for autologous neurotransplantation devoid of ethical concerns. Aim: This study aimed to evaluate the combined therapeutic effect of OEC, MSC, and chondroitinase in SCI rat models. Materials and Methods: Adult female albino Wistar rats were divided into ten groups, n = 6 rats in each group and control (n = 11). T10 level laminectomy was done in anesthetized rats to create drop-weight SCI. Both OEC and MSC were transplanted on the 9th day following SCI as a combined therapy with different dosage of 2 × 105, 5 × 105, 10 × 105, and >10 × 105 at a ratio of 1:1 with/without chondroitinase (0.2 U). One group of SCI rats was treated with chondroitinase alone 0.2 U. Dulbecco's Modified Eagle medium was injected in control rats. The outcome of transplantation was assessed using Basso, Beattie, Bresnahan (BBB) scale and motor-evoked potential studies. Results: All the treated groups showed hindlimb motor recovery in BBB score except control group (P < 0.05). All the three combinations showed better results than OEC + MSC groups in hindlimb motor recovery. In dose–response relationship, 5- and 10-lakh combinations elicited increased functional recovery than 2- and more than 10-lakh combinations. However, chondroitinase alone demonstrated a highest BBB score than any other groups. Conclusions: Chondroitinase/cell combinations have a therapeutic beneficial effect in SCI.
Keywords: Basso, Beattie, Bresnahan, chondroitinase, electromyography, mesenchymal stem cells, olfactory ensheathing cells, spinal cord injury, transplantation
|How to cite this article:|
Muniswami DM, Tharion G. Therapeutic effect of cell transplantation and chondroitinase in rat spinal cord injury. Int J App Basic Med Res 2018;8:220-6
|How to cite this URL:|
Muniswami DM, Tharion G. Therapeutic effect of cell transplantation and chondroitinase in rat spinal cord injury. Int J App Basic Med Res [serial online] 2018 [cited 2021 May 16];8:220-6. Available from: https://www.ijabmr.org/text.asp?2018/8/4/220/245821
| Introduction|| |
Spinal cord injury (SCI) comprises complex orchestrated pathophysiological events characterized by neuronal death, demyelination, and glial scar formation. Following injury, central nervous system (CNS) axons fail to regenerate because of axonal growth inhibitors such as chondroitin sulfate proteoglycans (CSPGs), Nogo-A, myelin-associated glycoprotein, oligodendrocyte-myelin glycoprotein, reduced intrinsic growth-promoting gene expression,, lack of trophic support, and inflammatory response.
Bone marrow-mesenchymal stem cells (BM-MSCs) demonstrate neuroprotection by reducing cell death,, promoting endogenous cell proliferation, inducing angiogenesis, enhancing axonal remodeling, and promoting functional recovery after CNS injury. MSCs secrete various cytokines, neurotrophins, and growth factors such as brain-derived neurotrophic factor (BDNF), nerve growth factor (NGF), glial cell-derived neurotrophic factor (GDNF), vascular endothelial growth factor (VEGF), and basic fibroblast growth factor (FGF), which might create a favorable environment for regeneration.
Olfactory ensheathing cells (OECs) facilitate and guide the regeneration of olfactory axons from the peripheral nasal mucosa to the olfactory bulb in the brain. OEC has a dual characteristic of astroglial (reside in CNS) and Schwann cells (axonal ensheathment and neurotrophic support). Thus, OEC has shown to promote regeneration after SCI.,,, The inhibitory cues of the glial scar are rich in CSPG, which is the major obstacle. To overcome this obstacle, chondroitinase ABC was employed in SCI.,,,,,, Targeting a single factor can increase regeneration and axonal sprouting into or around the lesion site to a limited extent. Instead, an approach combining multiple targets can act synergistically to stimulate robust regeneration.,,,,
Individual treatments of OEC, MSC, and chondroitinase prove moderate efficacy in functional recovery after SCI. Hence, there is a need for combination strategies to overcome multiple factors that limit axonal growth. The current study aimed to evaluate the combined effect of OEC and MSC with/without inhibitory cues of the glial scar dissolving enzyme chondroitinase ABC in SCI rat models.
| Materials and Methods|| |
Adult albino Wistar rats were used for the study. The animals were obtained from the animal house of the institution (Christian Medical College, Vellore, Tamil Nadu, India). The study was approved by an Institutional Review Board and Institutions' Animal Ethical Committee.
Adult rat OECs from olfactory mucosa and rat BM-MSC from femur were cultured as described. Chondroitinase ABC protease free from Proteus vulgaris, catalog: 100332, Seikagaku BioBusiness Corporation, Japan, was purchased and used for the experiments.
Sixty-five adult female albino Wistar rats were divided into ten groups (n = 6 rats in each treatment group and n = 11 rats in control). Both OECs and BM-MSCs were transplanted on the 9th day following SCI as a combined therapy with different dosage of 2 lakhs (2 × 105), 5 lakhs (5 × 105), 10 lakhs (10 × 105), and more than 10 lakhs (>10 × 105) at a ratio of 1:1. Chondroitinase alone 0.2 U was treated in one group of SCI rats. Combination treatment of OECs, MSCs, and chondroitinase was done with different dosages of 2-, 5-, 10-, and more than 10-lakh cells at a ratio 1:1 with a constant dose of chondroitinase (0.2 U). In the control group (n = 11) after SCI, only DMEM was injected without cells on the 9th day.
Laminectomy and spinal cord injury
Female albino Wistar rats, 100–250 g in body weight, were anesthetized with ketamine and xylazine (90:10 mg/kg) administered intraperitoneally. Ophthalmic ointment was applied to the eyes to prevent drying during the operation. The fur was shaved on the mid-dorsal region and cleaned with povidone-iodine solution (7.5% w/v), finally with surgical spirit. Tegaderm™ was applied over it to prevent fur contamination during surgery. 2.0-cm incision was made over the lower thoracic area, muscle and connective tissues were bluntly dissected to expose the T6-T9 vertebrae. A T10 level laminectomy was completed using a microsurgery bone rongeur, taking care not to damage the spinal cord. The drop-weight injury was performed by using 10-g weight rod fall from 25-cm height on the exposed spinal cord. Absorbable suture (Vicryl, Johnson-Johnson Pvt Ltd, India) was used to ligate the incised muscle and skin. Meloxicam 1 mg/kg as analgesic, enrofloxacin 2.5 mg/kg as antibiotic, and ringer lactate 5 ml/100 g were administered subcutaneously as postoperative care. Animals had free access to food and water throughout the study.
Following the surgery, rats were placed in cages and monitored until they recovered from anesthesia. Rats were monitored twice a day throughout the postinjury survival period for general health and mobility within the cage. Bladder was manually expressed twice daily. Ringer lactate 5 ml/100 g was administered subcutaneously twice daily after each bladder expression for the first 7 postoperative days. Meloxicam 1 mg/kg as analgesic and enrofloxacin 2.5 mg/kg as antibiotic were administered for the first 7 postoperative days. Inspection for skin ulcers or evidence of autophagia was carried out daily. Bedding (paddy husk) was changed every alternate day.
Following the drop-weight SCI, injection of chondroitinase/cell transplantation was done on the 9th day in spinal cord-injured rats. Behavioral assessment (Basso, Beattie, Bresnahan [BBB]) was conducted prior to the cell transplantation/chondroitinase treatment as described below. Rats were re-anesthetized (intraperitoneal ketamine/xylazine: 90:10 mg/kg), and the original incision was re-opened to expose the injured cord. Under a surgical microscope, the wound was explored and the injured spinal cord segment as well as a few millimeters above and below normal spinal cord was exposed. On the day of transplantation, second-passage OECs and MSCs were harvested from cultures and transferred into the 25-μl Hamilton syringe (approximately 100,000 cells/μl). All injections were made with the aid of a sterile Hamilton syringe. Both OEC and BM-MSCs were transplanted as an allogeneic combined therapy with different dosages of 2 lakhs, 5 lakhs, 10 lakhs, and more than 10 lakhs at a ratio of 1:1. Chondroitinase alone 0.2 U was treated in one group of SCI rats. Combined treatment of OEC, MSC, and chondroitinase was done with different dosages of 2 lakhs (2 × 105), 5 lakhs (5 × 105), 10 lakhs (10 × 105), and more than 10 lakhs of cells at a ratio of 1:1 with the constant dose of chondroitinase (0.2 U). 2-–50 μl of cell suspensions was injected at multiple sites, in and around at the site of injury into the spinal cord. The injured site was re-opened in the control rats and DMEM alone was injected on the 9th day. Following enzyme/cell transplantation, the surgical wound was closed and routine postoperative care was given.
Behavioral assessment – Basso, Beattie, Bresnahan score
The BBB scale is an operationally defined 21-point scale, designed to assess hindlimb locomotor recovery after impact injury to the spinal cord in rats. This locomotor scale includes categorical combinations of rat hindlimb joint movements, trunk position and stability, stepping, coordination, paw placement, toe clearance, and tail position, representing sequential recovery stages that rats attain after SCI. The motor assessment will be done up to 8–10 weeks after injury/transplant. Open-field observations were made on rats. All rats received bladder expression before open-field testing to eliminate behaviors due to bladder fullness. Rats were allowed to walk in the open field (45 cm × 60 cm rectangular tray) and video-recorded for assessment. All rats were assessed for BBB before transplant, i.e., on the 9th day after SCI and every week posttransplant onward up to 8 weeks.
Motor-evoked potential studies
Transcranial stimulation of motor cortex was done in the anesthetized rats and the electromyography (EMG) signals were recorded from the lower-limb muscles to indicate the functional integrity of the spinal cord. Bipolar superficial electrode was used to stimulate the motor cortex and the responses were recorded from the gastrocnemius muscles. Recording was done from control as well as cell/enzyme-transplanted rats at 8–10 weeks postspinal injury/transplantation. Recorded EMG signals were analyzed for amplitude.
At the end of the study, control and treated rats were anesthetized by intraperitoneal injection of ketamine/xylazine 90:10 mg/kg and transcardially perfused with 4% paraformaldehyde solution. A few centimeter length of spinal cord centered on the injury epicenter was removed and postfixed in 30% sucrose/phosphate-buffered saline at 4°C overnight. Longitudinal and cross-sections of spinal cord were cut and stained with hematoxylin and eosin. Representative tissue section was visualized in the light microscope.
Hindlimb motor recovery-BBB scores and amplitude of motor-evoked potential were statistically analyzed using SPSS version 16 (Apple computer Inc, Chicago, USA) one-way ANOVA post hoc Tukey's test to compare significances with different groups. The paired t-test was also done to compare within groups. Data for each group were represented as mean ± standard deviation P < 0.05 was considered statistically significant in this study.
| Results|| |
Basso, Beattie, Bresnahan
Olfactory ensheathing cell + mesenchymal stem cell (1:1)
Sequential hindlimb motor recovery was elicited in all the treated groups except control [Figure 1]a. Before transplantation, all the groups showed BBB (0.00 ± 0.00), but after transplantation BBB of 2 lakhs (4.0 ± 2.82), 5 lakhs (6.1 ± 4.62), 10 lakhs (5.1 ± 2.56), more than 10 lakhs (5.3 ± 2.50), which showed statistical significances (P < 0.05) in hindlimb motor functional recovery [Figure 2].
|Figure 1: Hindlimb motor recovery mean Basso, Beattie, Bresnahan score of olfactory ensheathing cell + mesenchymal stem cell transplantation. Transplanted groups progressed in Basso, Beattie, Bresnahan score except control group (a). On comparison, there was no statistical significance between the treated groups (P > 0.05). But, treated groups showed significant (P < 0.05) functional recovery as compared to control group (b). Error bars indicate the standard deviations|
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|Figure 2: Hindlimb motor recovery mean Basso, Beattie, Bresnahan score. Error bars indicate the standard deviations|
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All the treated groups exhibited functional recovery with variation in BBB scores at the end of the 8th week as compared to the control group (0.09 ± 0.30), which shows statistical significance (P < 0.05) [Figure 1]b. Different dosage elicits different outcome in motor recovery, but on statistical analysis showed no significant difference (P > 0.05) among the transplanted groups [Figure 1]b. However, in a dose–response relationship, 5 lakhs of OEC + MSC show promising maximum mean BBB score of 6.1 as compared to other dosages.
Olfactory ensheathing cell + mesenchymal stem cell + chondroitinase (1:1 + 0.2 U)
From the 1st week posttransplantation onward, the hindlimb motor recovery progressed steadily in all the treated groups except control [Figure 3]a. Before transplantation, all the groups showed BBB (0.00 ± 0.00), but after transplantation BBB of 2 lakhs (4.8 ± 2.31), 5 lakhs (5.8 ± 3.81), 10 lakhs (5.8 ± 4.21), more than 10 lakhs (4.1 ± 5.23), and chondroitinase (7.1 ± 2.48), which showed statistical significances (P < 0.05) in hindlimb motor functional recovery in the treated groups [Figure 2].
|Figure 3: Hindlimb motor recovery mean Basso, Beattie, Bresnahan score of olfactory ensheathing cell + mesenchymal stem cell + chondroitinase transplantation. The treated groups showed an improvement in Basso, Beattie, Bresnahan scores over the period of time (a). Among the treated groups, there is no statistical significance (P > 0.05) in the Basso, Beattie, Bresnahan score (b)|
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Different cell dosages with chondroitinase-treated groups elicited differences in BBB score, but there was no statistically significant difference (P > 0.05) among the treated groups. When all the treated groups were compared with the control group, only chondroitinase group, 5 lakhs of OEC + MSC + chondroitinase group, and 10 lakhs of OEC + MSC + chondroitinase group showed statistical significance (P < 0.05) in functional recovery [Figure 3]b. A dose–response relationship study showed that 5- and 10-lakh combinations expressed similar and better motor recovery than 2-lakh and more than 10-lakh combinations. Chondroitinase alone-treated group showed better results in hindlimb motor recovery compared with the other combinations [Figure 3].
Olfactory ensheathing cell + mesenchymal stem cell (1:1)
Although transplanted cells are OEC + MSC (1:1), but differ in dosage, these doses have an impact on recovery analyzed by the motor-evoked potential in amplitude. All the transplanted groups' EMG amplitude of 2 lakhs (0.8 ± 0.54), 5 lakhs (1.6 ± 0.87), 10 lakhs (1.2 ± 0.54), and more than 10 lakhs (1.3 ± 0.19) was statistically analyzed with a control group (0.2 ± 0.18), which showed statistical significance (P < 0.05), except 2-lakh group (P = 0.17). The low dose of 2 lakhs exhibited decreased amplitude, which indicates less amount of regeneration after SCI. Five-lakh group demonstrated maximum amplitude similar to BBB score, but above 5 lakhs of dosages decline in amplitude. Among the treated groups, the amplitude of 2-lakh compared with 5-lakh groups elicited statistical significance (P < 0.05), but the remaining groups did not show statistical significance (P > 0.05) [Figure 4].
|Figure 4: Mean electromyography amplitude of olfactory ensheathing cells + mesenchymal stem cell-transplanted rats. There is a significant increase in electromyography amplitude in 5-lakh, 10-lakh, and more than 10-lakh-transplanted rats as compared to control rats (P < 0.05). Among the treated groups, only 5-lakh combination showed statistical significance (P = 0.05) in comparison with 2-lakh combination group. The results demonstrate the transplant-mediated repair in treated groups of SCI rats|
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Olfactory ensheathing cell + mesenchymal stem cell + chondroitinase (1:1 + 0.2 U)
Different dosages of cells with chondroitinase have an impact on hindlimb motor recovery as analyzed by the motor-evoked potential. All the transplanted groups' EMG amplitude of 2 lakhs (0.9 ± 0.30), 5 lakhs (1.0 ± 0.16), 10 lakhs (1.4 ± 1.1), more than 10 lakhs (0.9 ± 0.25), and chondroitinase (1.6 ± 0.59) was statistically analyzed with a control group (0.2 ± 0.18), which did not show statistical significance (P > 0.05), except 10-lakh and chondroitinase-alone group [Figure 5]. 10-lakh group demonstrated a maximum of amplitude similar to BBB score, but 2-lakh dosage group and more than 10-lakh dosage group declined in amplitude. Chondroitinase alone-treated group showed increased amplitude than with combinations, which indicates the amount of regeneration after SCI.
|Figure 5: Mean electromyography amplitude of olfactory ensheathing cells + mesenchymal stem cell + chondroitinase-transplanted rats. All the treated groups show variations in electromyography amplitude depending on the regeneration of injured spinal cord. There is a marked increase in the amplitude of chondroitinase alone-treated rats and 10-lakh combination groups, which showed significance (P < 0.05) when compared to control rats. However, no significance was observed among the treated groups (P > 0.05)|
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Spinal cord tissue shows contused injury epicenter [Figure 6]a. There is a marked increase in degenerative cavity size of 2100.9 μm in control group [Figure 6]b. However, the cavity size was reduced to 1679 μm in treated (OEC + MSC + chondroitinase) SCI groups [Figure 6]c as compared to that of control group. Longitudinal section of the spinal cord [Figure 6]d, [Figure 6]e, [Figure 6]f, [Figure 6]g showed degeneration of white matter fibers, which was increased in control group as compared to treated groups. Cross-section of the spinal cord showed dissolved and degenerated cells in gray matter [Figure 6]h,[Figure 6]i,[Figure 6]j,[Figure 6]k; there is an increased degenerative cavity in control group as compared to treated groups.
|Figure 6: Histology of rat spinal cord after injury. Gross tissue of cord with injury epicenter (a). Degenerative cavity size of 2100.9 μm in control (b), and reduced cavity size to 1679 μm in all the three (olfactory ensheathing cell + mesenchymal stem cell + chondroitinase) treated spinal cords (c). scale bar = 20 μm. Longitudinal section of spinal cord showing white matter (d-g) degenerative (black arrow) and intact fibers (red arrow). Cross-section of spinal cord showing gray matter (h-k), in which there is an increased degeneration in controls than treated spinal cords. scale bar = 3 μm|
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| Discussion|| |
OEC has unique properties of both CNS glial cell astrocyte and peripheral nervous system glial Schwann cells. OEC can reside in a CNS environment like astrocytes and facilitate axonal regrowth like Schwann cells.,,,, OECs were found to secrete BDNF, neuregulins, NGF GDNF, NT-3, and NT-4. Numerous studies have demonstrated that OECs have the ability to remyelinate axons in vivo models., Both trophic/tropic actions of OEC and changes to the permissive environment of the glial scar/lesion site ultimately resulted in decreased glial fibrillary acidic protein reactivity and cavity formation. These special qualities of OEC attract the researchers to consider these cells for nervous system repair.MSC contribution to tissue repair by paracrine effects (BDNF, NGF, FGF2, VEGF, transforming growth factor-β, and insulin-like growth factor 1), transdifferentiation, and neuroprotection create a favorable environment for endogenous cell proliferation and thus the functional recovery achieved after CNS injury. Chondroitinase reduces inhibitory cues of CSPG and enhances functional recovery.[26–29]
The current study evaluates the effect of OEC, MSC, and chondroitinase in SCI with various parameters in consideration such as route of administration, dosage of cells with enzymes, and therapeutic window period. Varieties of spinal injury models such as complete transection, hemisection, tract lesion, contusion, and demyelination were experimented in various centers. The drop-weight injury was created in the current study to mimic road traffic accident. MSC transplanted 1 week after impact SCI at T8 level in female Sprague-Dawley rats showed cell survival, differentiation, and remarkable improvement in locomotor recovery of SCI rats. The effect of transplanted MSC in injured cord shows reduced lesion cavitation and white matter loss. The therapeutic window period for transplantation is also a key issue, as evidence suggests that cell engraftment and improved functional outcome if transplanted after a week, but < 14 days after injury. In this study, we have chosen 9th day post-SCI for transplantation to avoid loss of cells due to the inflammatory response during acute trauma. We have transplanted cells/enzymes in and around at the site of injured spinal cord as a therapeutic strategy rather than as an infusion or injecting in the lumbar.
The combination of OEC+MSC+chondroitinase of 2-lakh group showed better motor recovery than 2-lakh groups of OEC+MSC analyzed by BBB and EMG. Similarly, all three combinations of 10-lakh groups showed increased BBB and EMG amplitude than 10-lakhs of OEC+MSC group, whereas 5-lakhs of OEC+MSC and OEC+MSC+chondroitinase group exhibit approximately similar outcome. However, higher dosage of more than 10-lakhs of OEC+MSC and OEC+MSC+chondroitinase group did not increase in recovery than 5-lakhs or 10-lakhs, which may be due to saturation or unable to accommodate in the cord. In the dose-response relationship study, 5 to 10-lakh combinations have the maximum therapeutic effects of SCI of the rat models, weighing about 100-200 g. As expected, all the three combination strategies had the maximum therapeutic effects to address multiple obstacles after SCI. However, chondroitinase alone demonstrated higher BBB score than that of cell combinations. Although the sample size is small in the current study to confirm chondroitinase as the best candidate. Histological studies demonstrated lesser amount of degenerating cells in treated cord as compared to Control. Extensive evidence of regeneration by histological method was limited in the current study. Future studies may address the in-depth mechanism of regeneration after SCI.
| Conclusions|| |
The combination of OEC, MSC, and chondroitinase shows promising therapeutic effect in SCI for future clinical applications.
Financial support and sponsorship
This study was financially supported by the Department of Biotechnology, Ministry of Science and Technology, Government of India.
Conflicts of interest
There are no conflicts of interest.
| References|| |
Liu BP, Cafferty WB, Budel SO, Strittmatter SM. Extracellular regulators of axonal growth in the adult central nervous system. Philos Trans R Soc Lond B Biol Sci 2006;361:1593-610.
Park KK, Liu K, Hu Y, Smith PD, Wang C, Cai B, et al
. Promoting axon regeneration in the adult CNS by modulation of the PTEN/mTOR pathway. Science 2008;322:963-6.
Smith PD, Sun F, Park KK, Cai B, Wang C, Kuwako K, et al
. SOCS3 deletion promotes optic nerve regeneration in vivo. Neuron 2009;64:617-23.
Tuszynski MH, Gabriel K, Gage FH, Suhr S, Meyer S, Rosetti A, et al
. Nerve growth factor delivery by gene transfer induces differential outgrowth of sensory, motor, and noradrenergic neurites after adult spinal cord injury. Exp Neurol 1996;137:157-73.
Fitch MT, Doller C, Combs CK, Landreth GE, Silver J. Cellular and molecular mechanisms of glial scarring and progressive cavitation:In vivo
and in vitro
analysis of inflammation-induced secondary injury after CNS trauma. J Neurosci 1999;19:8182-98.
Huang W, Mo X, Qin C, Zheng J, Liang Z, Zhang C, et al
. Transplantation of differentiated bone marrow stromal cells promotes motor functional recovery in rats with stroke. Neurol Res 2013;35:320-8.
Tsai MJ, Tsai SK, Hu BR, Liou DY, Huang SL, Huang MC, et al
. Recovery of neurological function of ischemic stroke by application of conditioned medium of bone marrow mesenchymal stem cells derived from normal and cerebral ischemia rats. J Biomed Sci 2014;21:5.
Bao X, Wei J, Feng M, Lu S, Li G, Dou W, et al
. Transplantation of human bone marrow-derived mesenchymal stem cells promotes behavioral recovery and endogenous neurogenesis after cerebral ischemia in rats. Brain Res 2011;1367:103-13.
Guo F, Lv S, Lou Y, Tu W, Liao W, Wang Y, et al
. Bone marrow stromal cells enhance the angiogenesis in ischaemic cortex after stroke: Involvement of notch signalling. Cell Biol Int 2012;36:997-1004.
van Velthoven CT, Kavelaars A, Heijnen CJ. Mesenchymal stem cells as a treatment for neonatal ischemic brain damage. Pediatr Res 2012;71:474-81.
Ding X, Li Y, Liu Z, Zhang J, Cui Y, Chen X, et al
. The sonic hedgehog pathway mediates brain plasticity and subsequent functional recovery after bone marrow stromal cell treatment of stroke in mice. J Cereb Blood Flow Metab 2013;33:1015-24.
Chen X, Li Y, Wang L, Katakowski M, Zhang L, Chen J, et al
. Ischemic rat brain extracts induce human marrow stromal cell growth factor production. Neuropathology 2002;22:275-9.
Liu N, Zhang Y, Fan L, Yuan M, Du H, Cheng R, et al
. Effects of transplantation with bone marrow-derived mesenchymal stem cells modified by survivin on experimental stroke in rats. J Transl Med 2011;9:105.
Barnett SC. Olfactory ensheathing cells: Unique glial cell types? J Neurotrauma 2004;21:375-82.
Franklin RJ, Gilson JM, Franceschini IA, Barnett SC. Schwann cell-like myelination following transplantation of an olfactory bulb-ensheathing cell line into areas of demyelination in the adult CNS. Glia 1996;17:217-24.
Rao YJ, Zhu WX, Du ZQ, Jia CX, Du TX, Zhao QA, et al
. Effectiveness of olfactory ensheathing cell transplantation for treatment of spinal cord injury. Genet Mol Res 2014;13:4124-9.
Raisman G. Olfactory ensheathing cells – Another miracle cure for spinal cord injury? Nat Rev Neurosci 2001;2:369-75.
Raisman G. Olfactory ensheathing cells and repair of brain and spinal cord injuries. Cloning Stem Cells 2004;6:364-8.
Mackay-Sim A. Olfactory ensheathing cells and spinal cord repair. Keio J Med 2005;54:8-14.
Morgenstern DA, Asher RA, Fawcett JW. Chondroitin sulphate proteoglycans in the CNS injury response. Prog Brain Res 2002;137:313-32.
Asher RA, Morgenstern DA, Moon LD, Fawcett JW. Chondroitin sulphate proteoglycans: Inhibitory components of the glial scar. Prog Brain Res 2001;132:611-9.
Bradbury EJ, Moon LD, Popat RJ, King VR, Bennett GS, Patel PN, et al
. Chondroitinase ABC promotes functional recovery after spinal cord injury. Nature 2002;416:636-40.
Huang WC, Kuo WC, Cherng JH, Hsu SH, Chen PR, Huang SH, et al
. Chondroitinase ABC promotes axonal re-growth and behavior recovery in spinal cord injury. Biochem Biophys Res Commun 2006;349:963-8.
Yick LW, Wu W, So KF, Yip HK, Shum DK. Chondroitinase ABC promotes axonal regeneration of Clarke's neurons after spinal cord injury. Neuroreport 2000;11:1063-7.
Tester NJ, Howland DR. Chondroitinase ABC improves basic and skilled locomotion in spinal cord injured cats. Exp Neurol 2008;209:483-96.
Caggiano AO, Zimber MP, Ganguly A, Blight AR, Gruskin EA. Chondroitinase ABCI improves locomotion and bladder function following contusion injury of the rat spinal cord. J Neurotrauma 2005;22:226-39.
Lee YS, Lin CY, Jiang HH, Depaul M, Lin VW, Silver J, et al
. Nerve regeneration restores supraspinal control of bladder function after complete spinal cord injury. J Neurosci 2013;33:10591-606.
Lu P, Yang H, Jones LL, Filbin MT, Tuszynski MH. Combinatorial therapy with neurotrophins and cAMP promotes axonal regeneration beyond sites of spinal cord injury. J Neurosci 2004;24:6402-9.
Fouad K, Schnell L, Bunge MB, Schwab ME, Liebscher T, Pearse DD, et al
. Combining Schwann cell bridges and olfactory-ensheathing glia grafts with chondroitinase promotes locomotor recovery after complete transection of the spinal cord. J Neurosci 2005;25:1169-78.
Fu XM, Liu SJ, Dan QQ, Wang YP, Lin N, Lv LY, et al
. Combined bone mesenchymal stem cell and olfactory ensheathing cell transplantation promotes neural repair associated with CNTF expression in traumatic brain-injured rats. Cell Transplant 2015;24:1533-44.
DePaul MA, Lin CY, Silver J, Lee YS. Peripheral nerve transplantation combined with acidic fibroblast growth factor and chondroitinase induces regeneration and improves urinary function in complete spinal cord transected adult mice. PLoS One 2015;10:e0139335.
Tharion G, Indirani K, Durai M, Meenakshi M, Devasahayam SR, Prabhav NR, et al
. Motor recovery following olfactory ensheathing cell transplantation in rats with spinal cord injury. Neurol India 2011;59:566-72.
] [Full text]
Basso DM, Beattie MS, Bresnahan JC. A sensitive and reliable locomotor rating scale for open field testing in rats. J Neurotrauma 1995;12:1-21.
Boruch AV, Conners JJ, Pipitone M, Deadwyler G, Storer PD, Devries GH, et al
. Neurotrophic and migratory properties of an olfactory ensheathing cell line. Glia 2001;33:225-9.
Gudiño-Cabrera G, Nieto-Sampedro M. Schwann-like macroglia in adult rat brain. Glia 2000;30:49-63.
Lakatos A, Franklin RJ, Barnett SC. Olfactory ensheathing cells and Schwann cells differ in their in vitro
interactions with astrocytes. Glia 2000;32:214-25.
Li Y, Carlstedt T, Berthold CH, Raisman G. Interaction of transplanted olfactory-ensheathing cells and host astrocytic processes provides a bridge for axons to regenerate across the dorsal root entry zone. Exp Neurol 2004;188:300-8.
Woodhall E, West AK, Chuah MI. Cultured olfactory ensheathing cells express nerve growth factor, brain-derived neurotrophic factor, glia cell line-derived neurotrophic factor and their receptors. Brain Res Mol Brain Res 2001;88:203-13.
Wang L, Yang P, Liang X, Ma L, Wei J. Comparison of therapeutic effects of olfactory ensheathing cells derived from olfactory mucosa or olfactory bulb on spinal cord injury mouse models. Xi Bao Yu Fen Zi Mian Yi Xue Za Zhi 2014;30:379-83.
Imaizumi T, Lankford KL, Waxman SG, Greer CA, Kocsis JD. Transplanted olfactory ensheathing cells remyelinate and enhance axonal conduction in the demyelinated dorsal columns of the rat spinal cord. J Neurosci 1998;18:6176-85.
Richter MW, Fletcher PA, Liu J, Tetzlaff W, Roskams AJ. Lamina propria and olfactory bulb ensheathing cells exhibit differential integration and migration and promote differential axon sprouting in the lesioned spinal cord. J Neurosci 2005;25:10700-11.
Parr AM, Tator CH, Keating A. Bone marrow-derived mesenchymal stromal cells for the repair of central nervous system injury. Bone Marrow Transplant 2007;40:609-19.
Tabakow P, Raisman G, Fortuna W, Czyz M, Huber J, Li D, et al
. Functional regeneration of supraspinal connections in a patient with transected spinal cord following transplantation of bulbar olfactory ensheathing cells with peripheral nerve bridging. Cell Transplant 2014;23:1631-55.
Ramón-Cueto A, Cordero MI, Santos-Benito FF, Avila J. Functional recovery of paraplegic rats and motor axon regeneration in their spinal cords by olfactory ensheathing glia. Neuron 2000;25:425-35.
Li Y, Decherchi P, Raisman G. Transplantation of olfactory ensheathing cells into spinal cord lesions restores breathing and climbing. J Neurosci 2003;23:727-31.
Keyvan-Fouladi N, Raisman G, Li Y. Functional repair of the corticospinal tract by delayed transplantation of olfactory ensheathing cells in adult rats. J Neurosci 2003;23:9428-34.
Li Y, Field PM, Raisman G. Repair of adult rat corticospinal tract by transplants of olfactory ensheathing cells. Science 1997;277:2000-2.
Plant GW, Christensen CL, Oudega M, Bunge MB. Delayed transplantation of olfactory ensheathing glia promotes sparing/regeneration of supraspinal axons in the contused adult rat spinal cord. J Neurotrauma 2003;20:1-6.
Takami T, Oudega M, Bates ML, Wood PM, Kleitman N, Bunge MB, et al
. Schwann cell but not olfactory ensheathing glia transplants improve hindlimb locomotor performance in the moderately contused adult rat thoracic spinal cord. J Neurosci 2002;22:6670-81.
[Figure 1], [Figure 2], [Figure 3], [Figure 4], [Figure 5], [Figure 6]