移植人脐带间充质干细胞修复大鼠脊髓损伤

背景：已知人脐带间充质干细胞对脊髓损伤存在着潜在的治疗价值,然而,当前对移植人脐带间充质干细胞治疗脊髓损伤及机制方面研究很少。 目的：观察人脐带间充质干细胞对脊髓损伤大鼠的治疗效果。 方法：40只Wistar大鼠建立脊髓损伤模型,38只造模成功后随机摸球法分为3组：空白对照组：只接受单纯损伤,不做任何移植;DMEM移植组：损伤后1周予以5 μL DMEM局部移植;细胞移植组：损伤后1周予以5 μL准备好的人脐带间充质干细胞局部移植(细胞数1×106)。移植后对实验动物通过BBB评分、体感诱发电位与运动诱发电位观察后肢功能恢复情况。分别于损伤后2,4,6,8,10周随机于细胞移植组抽取大鼠2只,免疫组织化学染色观察人脐带间充质干细胞存活、迁移、分化,通过胶质纤维酸性蛋白阳性细胞染色比较各组损伤局部胶质瘢痕形成面积。 结果与结论：BBB评分损伤后4周细胞移植组高于其他两组(P < 0.05),损伤后12周细胞移植组与其他两组相比SEP、MEP潜伏期缩短、波幅值增高(P < 0.05)。免疫组织化学染色示人脐带间充质干细胞可向神经元、星形胶质细胞和少突胶质细胞分化,分化的少突胶质细胞并包绕轴突形成髓鞘。细胞移植组损伤局部胶质瘢痕面积均小于其他两组(P < 0.05),空白对照组、DMEM移植组间差异无显著性(P > 0.05)。提示未经体外诱导的人脐带间充质干细胞可于损伤大鼠脊髓体内向神经元、星形胶质细胞、少突胶质细胞分化,减小胶质瘢痕,并促进脊髓损伤大鼠神经功能的恢复。     

Locally transplanted enteric glia improve functional and structural recovery in a rat model of spinal cord injury

BACKGROUND： We have previously reported that adult enteric glia （EG） facilitate the growth of transected dorsal root axons into the uninjured spinal cord to form functional connections with their targets. OBJECTIVE： The present study investigated the effects of EG on spinal cord function, tissue injury, and axonal regeneration following transplantation into injured rat spinal cords, according to histological and functional outcomes. DESIGN, TIME AND SETTING： A randomized controlled animal experiment was performed at McMaster University, Canada from January 2006 to March 2008. MATERIALS： EG were isolated from rat intestine, METHODS： One week following spinal cord crush, female Wistar rats were injected with an EG suspension （2 μL, 1 × 10^5/μL, n = 10） or with the same volume of fresh culture medium alone （control animals, n = 11）. The third group did not receive any injection following laminectomy and served as the sham-operated controls （n = 5）. MAIN OUTCOME MEASURES： Behavior was tested prior to transplantation and weekly following transplantation, with nine behavioral examinations in total. Open field, hind limb placement response foot orientation response, and inclined plane test were utilized. Immediately following the final behavioral examination, spinal cord T9 to L1 segments were harvested for immunohistochemical and hematoxylin-eosin staining to determine astroglial scarring, axonal regeneration and spinal cord lesion size. RESULTS： Rats with EG transplantation exhibited significantly better locomotor function with reduced tissue damage, compared with the control rats. Cystic cavities were present 2 months after injury in spinal cords from both control groups. In contrast, rats injected with EG did not present with cystic lesions. In addition, the injury site consisted of cellular material and nerve fibers, and axonal regeneration was apparent, with dense labeling of neurofilament-positive axons within the injury site. Moreover, regenerating axons were intimately associated with transplanted EG. CONCLUSION： These data indicated that EG enhanced functional improvement, which was associated with reduced tissue damage and axonal regeneration following transplantation into injured spinal cords.     

MicroRNA miR-133b is essential for functional recovery after spinal cord injury in adult zebrafish

MicroRNAs (miRNAs) play important roles during development and also in adult organisms by regulating the expression of multiple target genes. Here, we studied the function of miR-133b during zebrafish spinal cord regeneration and show upregulation of miR-133b expression in regenerating neurons of the brainstem after transection of the spinal cord. miR-133b has been shown to promote tissue regeneration in other tissue, but its ability to do so in the nervous system has yet to be tested. Inhibition of miR-133b expression by antisense morpholino (MO) application resulted in impaired locomotor recovery and reduced regeneration of axons from neurons in the nucleus of the medial longitudinal fascicle, superior reticular formation and intermediate reticular formation. miR-133b targets the small GTPase RhoA, which is an inhibitor of axonal growth, as well as other neurite outgrowth-related molecules. Our results indicate that miR-133b is an important determinant in spinal cord regeneration of adult zebrafish through reduction in RhoA protein levels by direct interaction with its mRNA. While RhoA has been studied as a therapeutic target in spinal cord injury, this is the first demonstration of endogenous regulation of RhoA by a microRNA that is required for spinal cord regeneration in zebrafish. The ability of miR-133b to suppress molecules that inhibit axon regrowth may underlie the capacity for adult zebrafish to recover locomotor function after spinal cord injury.     

Hepatocyte growth factor promotes endogenous repair and functional recovery after spinal cord injury

Many therapeutic interventions using neurotrophic factors or pharmacological agents have focused on secondary degeneration after spinal cord injury (SCI) to reduce damaged areas and promote axonal regeneration and functional recovery. Hepatocyte growth factor (HGF), which was identified as a potent mitogen for mature hepatocytes and a mediator of inflammatory responses to tissue injury, has recently been highlighted as a potent neurotrophic and angiogenic factor in the central nervous system (CNS). In the present study, we revealed that the extent of endogenous HGF up-regulation was less than that of c-Met, an HGF receptor, during the acute phase of SCI and administered exogenous HGF into injured spinal cord using a replication-incompetent herpes simplex virous-1 (HSV-1) vector to determine whether HGF exerts beneficial effects and promotes functional recovery after SCI. This treatment resulted in the significant promotion of neuron and oligodendrocyte survival, angiogenesis, axonal regrowth, and functional recovery after SCI. These results suggest that HGF gene delivery to the injured spinal cord exerts multiple beneficial effects and enhances endogenous repair after SCI. This is the first study to demonstrate the efficacy of HGF for SCI.     

Degradation of chondroitin sulfate proteoglycans potentiates transplant-mediated axonal remodeling and functional recovery after spinal cord injury in adult rats

Transplantation of growth-permissive cells or tissues was used to bridge a lesion cavity and induce axonal growth in experimental spinal cord injury (SCI). Axonal interactions between host and transplant may be affected by upregulation of inhibitory chondroitin sulfate proteoglycans (CSPGs) following various transplantation strategies. The extent of axonal growth and functional recovery after transplantation of embryonic spinal cord tissue decreases in adult compared to neonatal host. We hypothesized that CSPGs contribute to the decrease in the extent to which transplant supports axonal remodeling and functional recovery. Expression of CSPGs increased after overhemisection SCI in adult rats but not in neonates. Embryonic spinal cord transplant was surrounded by CSPGs deposited in host cord, and the interface between host and transplant seemed to contain a large amount of CSPGs. Intrathecally delivered chondroitinase ABC (C'ase) improved recovery of distal forelimb usage and skilled motor behavior after C4 overhemisection injury and transplantation in adults. This behavioral recovery was accompanied by an increased amount of raphespinal axons growing into the transplant, and raphespinal innervation to the cervical motor region was promoted by C'ase plus transplant. Moreover, C'ase increased the number of transplanted neurons that grew axons to the host cervical enlargement, suggesting that degradation of CSPGs supports remodeling not only of host axons but also axons from transplanted neurons. Our results suggest that CSPGs constitute an inhibitory barrier to prevent axonal interactions between host and transplant in adults, and degradation of the inhibitory barrier can potentiate transplant-mediated axonal remodeling and functional recovery after SCI.     

Transplantation of human neural stem cells for spinal cord injury in primates

Recent studies have shown that delayed transplantation of neural stem/progenitor cells (NSPCs) into the injured spinal cord can promote functional recovery in adult rats. Preclinical studies using nonhuman primates, however, are necessary before NSPCs can be used in clinical trials to treat human patients with spinal cord injury (SCI). Cervical contusion SCIs were induced in 10 adult common marmosets using a stereotaxic device. Nine days after injury, in vitro-expanded human NSPCs were transplanted into the spinal cord of five randomly selected animals, and the other sham-operated control animals received culture medium alone. Motor functions were evaluated through measurements of bar grip power and spontaneous motor activity, and temporal changes in the intramedullary signals were monitored by magnetic resonance imaging. Eight weeks after transplantation, all animals were sacrificed. Histologic analysis revealed that the grafted human NSPCs survived and differentiated into neurons, astrocytes, and oligodendrocytes, and that the cavities were smaller than those in sham-operated control animals. The bar grip power and the spontaneous motor activity of the transplanted animals were significantly higher than those of sham-operated control animals. These findings show that NSPC transplantation was effective for SCI in primates and suggest that human NSPC transplantation could be a feasible treatment for human SCI.     

Transplantation of embryonic spinal cord neurons to the injured distal nerve promotes axonal regeneration after delayed nerve repair

Peripheral nerve injury (PNI) usually results in poor functional recovery. Nerve repair is the common clinical treatment for PNI but is always obstructed by the chronic degeneration of the distal stump and muscle. Cell transplantation can alleviate the muscle atrophy after PNI, but the subsequent recovery of the locomotive function is seldom described. In this study, we combined cell transplantation and nerve repair to investigate whether the transplantation of embryonic spinal cord cells could benefit the delayed nerve repair. The experiment consisted of 3 stages: transection of the tibial nerve to induce ‘pre‐degeneration’, a second surgery performed 2 weeks later for transplantation of E14 embryonic spinal cord cells or vehicle (culture medium) at the distal end of the injured nerve, and, 3 months later, the removal of the grafted cells and the cross‐suturing of the residual distal end to the proximal end of a freshly cut ipsilateral common peroneal (CP) nerve. Cell survival and fate after the transplantation were investigated, and the functional recovery after the cross‐suturing was compared between the groups. The grafted cells could survive and generate motor neurons, extending axons that were subsequently myelinated and forming synapses with the muscle. After the cross‐suturing, the axonal regeneration from the proximal stump of the injured CP nerve and the functional recovery of the denervated gastrocnemius muscle were significantly promoted in the group receiving the cells. Our study presents a new perspective indicating that the transplantation of embryonic spinal cord neurons may be a valuable therapeutic strategy for PNI.     

Transplantation of olfactory ensheathing cells promotes axonal regeneration in a rat model of spinal cord injury

BACKGROUND:Transplantation of olfactory ensheathing cells (OECs) into the injured spinal cord has been shown to promote axonal regeneration and functional recovery.However,the mechanisms underlying the effects of OEC transplantation remain controversial.OBJECTIVE:To observe fibrotic scar formation and axonal regeneration in the damaged spinal cord following OEC transplantation,and to determine whether OEC transplantation promotes neural regeneration by attenuating fibrotic scar formation.DESIGN,TIME AND SETTING:A randomized,controlled animal experiment was performed at the Department of Developmental Morphology,Tokyo Metropolitan Institute for Neuroscience,Fuchu,Japan and at the Department of Human Anatomy,College of Basic Medical Sciences,China Medical University,China between April 2007 and May 2009.MATERIALS:OECs were obtained from olfactory nerves and olfactory bulbs of male,4-week-old,Sprague Dawley rats.Rabbit anti-serotonin polyclonal antibody,rabbit anti-calcitonin gene-related peptide polyclonal antibody,rabbit anti-glial fibrillary acidic protein polyclonal antibody,rabbit anti-type IV collagen polyclonal antibody,and mouse anti-rat endothelial cell antigen-1 monoclonal antibody were used.METHODS:Male,Sprague Dawley rats aged 8 weeks were randomly divided into three groups:sham-surgery (n = 3),surgery (n = 9),and OEC transplantation (n = 11).Spinal cord transection at the T9-10 level was performed and the rats were transplanted with a 2-μL (1 × 105 cells) cell suspension.MAIN OUTCOME MEASURES:Formation of glial and fibrotic scars was examined using immunohistochemistry for glial fibrillary acidic protein and type IV collagen.Serotonin-positive and calcitonin gene-related peptide-positive axons were visualized by immunohistochemistry,respectively.Double immunofluorescence for type IV collagen and rat endothelial cell antigen-1 was also performed to determine co-localization of type IV collagen deposition and blood vessels.RESULTS:At 1 week after spinal cord injury,numerous glial cells were observed around the lesion site.Formation of fibrotic scar was determined by a large amount of type IV collagen deposition in the lesion center,and descending serotonin- or ascending calcitonin gene-related peptideconiaining axons stopped at the fibrotic scar that was formed in the lesion site.At week after transplantation,the formation of fibrotic scar was significantly inhibited.In addition,the fibrotic structure was partly formed and centralized in the blood vessel,and serotonergic and calcitonin gene-related peptide-containing axons were regenerated across the lesion site.CONCLUSION:OEC transplantation into the injured spinal cord attenuated fibrotic scar formation and promoted axon regeneration.     

Elamipretide reduces pyroptosis and improves functional recovery after spinal cord injury

Aims

Elamipretide (EPT), a novel mitochondria-targeted peptide, has been shown to be protective in a range of diseases. However, the effect of EPT in spinal cord injury (SCI) has yet to be elucidated. We aimed to investigate whether EPT would inhibit pyroptosis and protect against SCI.

Methods

After establishing the SCI model, we determined the biochemical and morphological changes associated with pyroptosis, including neuronal cell death, proinflammatory cytokine expression, and signal pathway levels. Furthermore, mitochondrial function was assessed with flow cytometry, quantitative real-time polymerase chain reaction, and western blot.

Results

Here, we demonstrate that EPT improved locomotor functional recovery following SCI as well as reduced neuronal loss. Moreover, EPT inhibited nucleotide-binding oligomerization domain-like receptor 3 (NLRP3) inflammasome activation and pyroptosis occurrence and decreased pro-inflammatory cytokines levels following SCI. Furthermore, EPT alleviated mitochondrial dysfunction and reduced mitochondrial reactive oxygen species level.

Conclusion

EPT treatment may protect against SCI via inhibition of pyroptosis.     

Carbon filaments direct the growth of postlesional plastic axons after spinal cord injury

The effect of implantation of carbon filaments and fetal tissues on the axonal regeneration following contusion injury in a rat model was investigated by in situ immunofluorescence. Female Sprague-Dawley rats were subjected to severe contusion injury to the spinal cord at T9-T10. All animals were divided into 5 groups (N = 5/group): normal controls. surgical controls, with carbon filament implants, with fetal tissue implants and with implants consisting of fetal tissue cocultured with carbon filaments. After a 10-week survival period, the astroglial response was assessed by immunoreactive glial fibrillary acidic protein and the neuro-axonal profile by immunoreactive phosphorylated and nonphosphorylated neurofilament proteins. The contusion injury resulted in: (a) dramatically increased immunoreactivity of glial fibrillary acidic protein indicating injury-associated reactive astrogliosis, (b) increase in immunoreactive phosphorylated neurofilament protein indicating upregulated phosphorylation of neurofilament protein, (c) with no change in the highly differentiated nonphosphorylated neurofilament protein which normally occur in the nonregenerating mature neurons. Implantation of fetal tissues alone following contusion injury did not show any appreciable change with regard to the immunoreactivities for the glial and neuronal markers studied, compared to the injury controls. However, the implantation of carbon filaments alone or together with fetal tissues directed the growth of glial fibrillary acidic protein-positive astroglia and phosphoneurofilament-positive neurites along the carbon fibers, with no effect on nonphosphoneurofilament protein. In conclusion, implantation of carbon filaments appears to be critical for facilitating the attachment of astroglia forming a substrate and scaffolding that can further support and direct the growth of postlesional plastic axons across the lesion. In addition, carbon filament prostheses in combination with fetal tissue implants provides an improved combinational approach to promote regrowth of injured neurons following injury.     

Electromyographic activity associated with spontaneous functional recovery after spinal cord injury in rats

This investigation was designed to study the spontaneous functional recovery of adult rats with incomplete spinal cord injury (SCI) at thoracic level during a time course of 2 weeks. Daily testing sessions included open field locomotor examination and electromyographic (EMG) recordings from a knee extensor (vastus lateralis, VL) and an ankle flexor muscle (tibialis anterior, TA) in the hindlimbs of treadmill walking rats. The BBB score (a locomotor score named after Basso et al., 1995, J. Neurotrauma, 12, 1-21) and various measures from EMG recordings were analysed (i.e. step cycle duration, rhythmicity of limb movements, flexor and extensor burst duration, EMG amplitude, root-mean-square, activity overlap between flexor and extensor muscles and hindlimb coupling). Directly after SCI, a marked drop in locomotor ability occurred in all rats with subsequent partial recovery over 14 days. The recovery was most pronounced during the first week. Significant changes were noted in the recovery of almost all analysed EMG measures. Within the 14 days of recovery, many of these measures approached control levels. Persistent abnormalities included a prolonged flexor burst and increased activity overlap between flexor and extensor muscles. Activity overlap between flexor and extensor muscles might be directly caused by altered descending input or by maladaptation of central pattern generating networks and/or sensory feedback.     

Transplantation of human bone marrow stromal cell‐derived Schwann cells reduces cystic cavity and promotes functional recovery after contusion injury of adult rat spinal cord

The aim of this study was to evaluate whether transplantation of human bone marrow stromal cell‐derived Schwann cells (hBMSC‐SC) promotes functional recovery after contusive spinal cord injury of adult rats. Human bone marrow stromal cells (hBMSC) were cultured from bone marrow of adult human patients and induced into Schwann cells (hBMSC‐SC) in vitro. Schwann cell phenotype was confirmed by immunocytochemistry. Growth factors secreted from hBMSC‐SC were detected using cytokine antibody array. Immunosppressed rats were laminectomized and their spinal cords were contused using NYU impactor (10 g, 25 mm). Nine days after injury, a mixture of Matrigel and hBMSC‐SC (hBMSC‐SC group) was injected into the lesioned site. Five weeks after transplantation, cresyl‐violet staining revealed that the area of cystic cavity was smaller in the hBMSC‐SC group than that in the control group. Immunohistochemstry revealed that the number of anti‐growth‐associated protein‐43‐positive nerve fibers was significantly larger in the hBMSC‐SC group than that in the control group. At the same time, the number of tyrosine hydroxylase‐ or serotonin‐positive fibers was significantly larger at the lesion epicenter and caudal level in the hBMSC‐SC group than that in the control group. In electron microscopy, formation of peripheral‐type myelin was recognized near the lesion epicenter in the hBMSC‐SC group. Hind limb function recovered significantly in the hBMSC‐SC group compared with the control group. In conclusion, the functions of hBMSC‐SC are comparable to original Schwann cells in rat spinal cord injury models, and are thus potentially useful treatments for patients with spinal cord injury.     

微囊化兔许旺细胞移植脊髓损伤大鼠：碱性成纤维细胞生长因子表达和后肢运动功能的变化

背景：研究表明微囊化兔许旺细胞移植于大鼠损伤脊髓后,能减轻炎症反应,促进脊髓再生,但具体作用途径尚不完全清楚。 目的：观察微囊化兔许旺细胞移植于损伤大鼠脊髓后,碱性成纤维细胞生长因子的表达以及后肢运动功能的恢复。 方法：取家兔坐骨神经以双酶消化法制成许旺细胞悬液后,再用气体喷入法制成海藻酸钡-许旺细胞微囊。同法制备不包被许旺细胞的空囊。SD大鼠随机分为4组：细胞组、空囊组、微囊组建立脊髓半横断损伤模型,分别于损伤处植入明胶海绵吸附的10 μL许旺细胞悬液、10 μL空囊、10 μL海藻酸钡-许旺细胞微囊;正常组不做任何干预。采用BBB评分观察大鼠后肢运动功能恢复情况,制作脊髓标本切片通过苏木精-伊红染色和尼氏染色行病理学检查,免疫组织化学染色观察碱性成纤维细胞生长因子的表达变化。 结果与结论：造模后即刻大鼠右后肢出现瘫痪;材料移植后7,14,28 d,微囊组大鼠后肢运动功能明显恢复,BBB评分明显优于细胞组、空囊组(P < 0.05或P < 0.01)。碱性成纤维细胞生长因子阳性细胞主要见于神经元细胞的胞浆及胶质细胞的胞核内。材料移植后第1,3,7天,胶质细胞主要在脊髓损伤附近处表达,其中第3天表达量最大;第14天在神经元细胞的胞浆内可见碱性成纤维细胞生长因子表达,微囊组表达程度明显高于细胞组、空囊组;之后各组表达程度均明显下降。提示微囊化兔许旺细胞移植于损伤大鼠脊髓后,可以抑制异种移植后免疫排斥,减轻炎症反应,增加碱性成纤维细胞生长因子表达,促进后肢功能恢复和脊髓再生。 关键词：脊髓损伤;移植;碱性成纤维细胞生长因子;运动功能;微囊;许旺细胞;生物材料 doi:10.3969/j.issn.1673-8225.2010.08.011     

Combined NgR vaccination and neural stem cell transplantation promote functional recovery after spinal cord injury in adult rats

C‐J. Xu, L. Xu, L‐D. Huang, Y. Li, P‐P. Yu, Q. Hang, X‐M. Xu and P‐H. Lu (2011) Neuropathology and Applied Neurobiology 37, 135–155
Combined NgR vaccination and neural stem cell transplantation promote functional recovery after spinal cord injury in adult rats Aims: After spinal cord injury (SCI), there are many adverse factors at the lesion site such as glial scar, myelin‐derived inhibitors, cell loss and deficiency of neurotrophins that impair axonal regeneration. Therefore, combination therapeutic strategies might be more effective than a single strategy for promoting functional recovery after SCI. In the present study, we investigated whether a Nogo66 receptor (NgR) vaccine, combined with neural stem cell (NSC) transplantation, could promote better functional recovery than when NgR vaccine or NSCs were used alone. Methods: Adult rats were immunized with NgR vaccine at 1 week after a contusive SCI at the thoracic level, and the NSCs, obtained from green fluorescent protein transgenic rats, were transplanted into the injury site at 8 weeks post injury. The functional recovery of the animals under various treatments was evaluated by three independent behavioural tests, that is, Basso, Beattie and Bresnahan locomotor rating scale, footprint analysis and grid walking. Results: The combined therapy with NgR vaccination and NSC transplantation protected more ventral horn motor neurones in the injured spinal cord and greater functional recovery than when they were used alone. Furthermore, NgR vaccination promoted migration of engrafted NSCs along the rostral‐caudal axis of the injured spinal cords, and induced their differentiation into neurones and oligodendrocytes in vivo. Conclusions: The combination therapy of NgR vaccine and NSC transplantation exhibited significant advantages over any single therapy alone in this study. It may represent a potential new therapy for SCI.     

Exogenous platelet-derived growth factor improves neurovascular unit recovery after spinal cord injury

The blood-spinal cord barrier plays a vital role in recovery after spinal cord injury. The neurovascular unit concept emphasizes the relationship between nerves and vessels in the brain, while the effect of the blood-spinal cord barrier on the neurovascular unit is rarely reported in spinal cord injury studies. Mouse models of spinal cord injury were established by heavy object impact and then immediately injected with plateletderived growth factor(80 μg/kg) at the injury site. Our results showed that after platelet-derived growth factor administration, spinal cord injury, neuronal apoptosis, and blood-spinal cord barrier permeability were reduced, excessive astrocyte proliferation and the autophagyrelated apoptosis signaling pathway were inhibited, collagen synthesis was increased, and mouse locomotor function was improved. In vitro, human umbilical vein endothelial cells were established by exposure to 200 μM H_2O_2. At 2 hours prior to injury, in vitro cell models were treated with 5 ng/mL platelet-derived growth factor. Our results showed that expression of blood-spinal cord barrier-related proteins, including Occludin, Claudin 5, and β-catenin, was significantly decreased and autophagy was significantly reduced. Additionally, the protective effects of platelet-derived growth factor could be reversed by intraperitoneal injection of 80 mg/kg chloroquine, an autophagy inhibitor, for 3 successive days prior to spinal cord injury. Our findings suggest that platelet-derived growth factor can promote endothelial cell repair by regulating autophagy, improve the function of the blood-spinal cord barrier, and promote the recovery of locomotor function post-spinal cord injury. Approval for animal experiments was obtained from the Animal Ethics Committee, Wenzhou Medical University, China(approval No. wydw2018-0043) in July 2018.     

Transplantation of olfactory ensheathing cells for promoting regeneration following spinal cord injury

OBJECTIVE: To investigate the status of olfactory ensheathing cells (OECs) transplantation in facilitating the regeneration of spinal cord injury. DATA SOURCES: Articles about OECs transplantation in treating spinal cord injury were searched in Pubmed database published in English from January 1981 to December 2005 by using the keywords of "olfactory ensheathing cells, transplantation, spinal cord injury". STUDY SELECTION: The data were checked primarily, literatures related to OECs transplantation and the regeneration of spinal cord injury were selected, whereas the repetitive studies and reviews were excluded. DATA EXTRACTION: Totally 43 articles about OECs transplantation and the regeneration and repair of spinal cord injury were collected, and the repetitive ones were excluded. DATA SYNTHESIS: There were 35 articles accorded with the criteria. OECs are the olfactory ensheathing glias isolated from olfactory bulb and olfactory nerve tissue. OECs have the characters of both Schwann cells in central nervous system and peripheral astrocytes. The transplanted OECs can migrate in the damaged spinal cord of host, can induce and support the regeneration, growth and extension of damaged neuritis. Besides, transgenic technique can enable it to carry some exogenous genes that promote neuronal regeneration, and express some molecules that can facilitate neural regeneration, so as to ameliorate the internal environment of nerve injury, induce the regeneration of damaged spinal cord neurons, which can stimulate the regeneration potential of the damaged spinal cord to reach the purpose of spinal cord regeneration and functional recovery. CONCLUSION: OECs are the glial cells with the energy for growth at mature phase, they can myelinize axons, secrete various biological nutrition factors, and then protect and support neurons, also facilitate neural regeneration. OECs have been successfully isolated from nasal olfactory mucosa and olfactory nerve. Therefore, autologous transplantation of OECs and objective genes modified OECs carrying various neurotrophic factors may become an effective method to treat spinal cord injury in the future.     

Transplantation of olfactory ensheathing cells for promoting regeneration following spinal cord injury

OBJECTIVE： To investigate the status of olfactory ensheathing cells （OECs） transplantation in facilitating the regeneration of spinal cord injury. DATA SOURCES： Articles about OECs transplantation in treating spinal cord injury were searched in Pubmed database published in English from January 1981 to December 2005 by using the keywords of ＂olfactory ensheathing cells, transplantation, spinal cord injury＂. STUDY SELECTION： The data were checked primarily, literatures related to OECs transplantation and the regeneration of spinal cord injury were selected, whereas the repetitive studies and reviews were excluded. DATA EXTRACTION： Totally 43 articles about OECs transplantation and the regeneration and repair of spinal cord injury were collected, and the repetitive ones were excluded. DATA SYNTHESIS： There were 35 articles accorded with the criteria. OECs are the olfactory ensheathing glias isolated from olfactory bulb and olfactory nerve tissue. OECs have the characters of both Schwann cells in central nervous system and peripheral astrocytes. The transplanted OECs can migrate in the damaged spinal cord of host, can induce and support the regeneration, growth and extension of damaged neuritis. Besides, transgenic technique can enable it to carry some exogenous genes that promote neuronal regeneration, and express some molecules that can facilitate neural regeneration, so as to ameliorate the internal environment of nerve injury, induce the regeneration of damaged spinal cord neurons, which can stimulate the regeneration potential of the damaged spinal cord to reach the purpose of spinal cord regeneration and functional recovery. CONCLUSION： OECs are the glial cells with the energy for growth at mature phase, they can myelinize axons, secrete various biological nutrition factors, and then protect and support neurons, also facilitate neural regeneration. OECs have been successfully isolated from nasal olfactory mucosa and olfactory nerve. Therefore, autologous transplantation of OECs and objective genes modified OECs carrying various neurotrophic factors may become an effective method to treat spinal cord injury in the future.     

Regrowth of axons into the distal spinal cord through a Schwann-cell-seeded mini-channel implanted into hemisected adult rat spinal cord

Schwann cells (SCs) have been shown to be a key element in promoting axonal regeneration after being grafted into the central nervous system (CNS). In the present study, SC-supported axonal regrowth was tested in an adult rat spinal cord implantation model. This model is characterized by a right spinal cord hemisection at the eighth thoracic segment, implantation of a SC-containing mini-channel and restoration of cerebrospinal fluid circulation by suturing the dura. We demonstrate that a tissue cable containing grafted SCs formed an effective bridge between the two stumps of the hemicord 1 month after transplantation. Approximately 10 000 myelinated and unmyelinated axons (1 : 9) per cable were found at its midpoint. In addition to propriospinal axons and axons of peripheral nervous system (PNS) origin, axons from as many as 19 brainstem regions also grew into the graft without additional treatments. Most significantly, some regenerating axons in the SC grafts were able to penetrate through the distal graft-host interface to re-enter the host environment, as demonstrated by anterograde axonal labelling. These axons coursed toward, and then entered the grey matter where terminal bouton-like structures were observed. In channels containing no SCs, limited axonal growth was seen within the graft and no axons penetrated the distal interface. These findings further support the notion that SCs are strong promotors of axonal regeneration and that the mini-channel model may be appropriate for further investigation of axonal re-entry, synaptic reconnection and functional recovery following spinal cord injury.     

Valproic acid reduces autophagy and promotes functional recovery after spinal cord injury in rats

Secondary damage is a critical determinant of the functional outcome in patients with spinal cord injury (SCI), and involves multiple mechanisms of which the most important is the loss of nerve cells mediated by multiple factors. Autophagy can result in cell death, and plays a key role in the development of SCI. It has been recognized that valproic acid (VPA) is neuroprotective in certain experimental animal models, however, the levels of autophagic changes in the process of neuroprotection by VPA treatment following SCI are still unknown. In the present study, we determined the extent of autophagy after VPA treatment in a rat model of SCI. We found that both the mRNA and protein levels of Beclin-1 and LC3 were significantly increased at 1, 2, and 6 h after SCI and peaked at 2 h; however, Western blot showed that autophagy was markedly decreased by VPA treatment at 2 h post-injury. Besides, post-SCI treatment with VPA improved the Basso-Beattie-Bresnahan scale, increased the number of ventral horn motoneurons, and reduced myelin sheath damage compared with vehicle-treated animals at 42 days after SCI. Together, our results demonstrated the characteristics of autophagy expression following SCI, and found that VPA reduced autophagy and enhanced motor function.