中枢神经损伤后影响轴突再生的因素

与周围神经不同 ,成年哺乳动物中枢神经损伤后轴突不能再生 ,往往造成不可逆的功能丧失。影响再生的原因相当复杂 ,胶质瘢痕形成、神经营养因子缺乏及存在诸多的抑制性因子等。本文就一些影响中枢神经再生的因子从其结构、分布、功能及可能的作用机制诸方面作一综述     

CSPGs在大鼠脊髓损伤后的表达及其与GFAP的关系

目的:观察脊髓损伤后CSPGs的表达及其与GFAP的关系。方法:成年雄性SD大鼠25只,随机分为对照组和损伤组,损伤组分脊髓挤压损伤后0h、72h、1w、4w组,运用免疫荧光双重染色方法观察CSPGs与GFAP的表达。结果:挤压伤后损伤部位的CSPGs和GFAP的表达均增高,但二者的变化趋势并不一样。其中CSPGs从损伤后表达开始增高,此后一直增加,并在1w至4w时逐渐稳定,主要分布逐渐集中于损伤部位;星形胶质细胞的免疫反应也逐渐增加,其分布逐渐集中于损伤区域的边缘,逐渐形成胶质瘢痕界膜。损伤1w至4w,损伤区域内几乎没有了星形胶质细胞表达,但仍留有大量的CSPGs。结论:早期抑制星形胶质细胞分泌CSPGs,可以防止在损伤部位沉积大量的CSPGs,从而减小其对再生纤维的抑制作用。     

京尼平苷酸通过稳定微管促进脊髓损伤后轴突生长

脊髓损伤（spinal cord injury, SCI）是中枢神经系统最严重的创伤之一,其可造成患者感觉和运动功能障碍,并且引发一系列严重的并发症。促进轴突再生是修复脊髓损伤后功能恢复的关键因素。京尼平苷酸（geniposidic acid, GA）具有神经保护作用,但其在脊髓损伤后轴突生长的作用及机制方面尚未见报道。本研究通过提取原代神经元,并建立糖氧剥夺模型(oxygen glucose deprivation, OGD)。通过RT-PCR、Western印迹、免疫荧光等方法,探讨GA对神经元轴突的促进作用及其机制。结果发现,GA可以显著促进神经元轴突生长,并呈剂量依赖性。与OGD组神经元轴突长度（22±5.788 μm）相比,给予10 μmol/L的GA可使神经元轴突长度显著增加（68±17.73 μm）。同时,轴突生长相关蛋白（GAP43,MAP2）的基因和蛋白质水平都显著上升。不仅如此,我们发现,GA促进轴突生长与稳定神经元轴突微管相关,可使A/T的比值增加约1.5倍。同时,通过建立大鼠急性脊髓损伤模型评价GA在体内的效果,与对照组相比,每天腹腔注射GA（10 mg/kg）的大鼠在术后28 d的BBB评分（11.8分）和斜板试验（41.7°）均显著增高。上述结果表明,GA可能通过稳定微管从而促进轴突再生,最终促进脊髓损伤后运动功能的恢复。因此,GA 可能成为治疗脊髓损伤的有前景的候选药物。     

bFGF通过抑制Nogo-A信号减少脊髓损伤后胶质瘢痕形成

脊髓损伤后胶质瘢痕的形成是阻碍神经恢复的关键原因之一。碱性成纤维细胞生长因子（basic fibroblast growth factor,bFGF）具有良好的神经保护及促进脊髓损伤的修复作用,然而其对于胶质瘢痕的影响及其机制仍不清楚。本研究通过采用血管动脉夹（30 g）夹闭雌性SD大鼠脊髓2 min造成急性脊髓损伤模型并予以每天皮下注射bFGF（80 μg/kg）,探讨bFGF促进脊髓损伤的恢复作用是否涉及到胶质瘢痕调控和Nogo-A/NgR信号的相关机制。通过检测损伤后28 d,各组BBB评分和斜板试验,发现bFGF显著促进脊髓损伤后大鼠运动功能的恢复。HE及尼氏染色显示,bFGF处理组相对于生理盐水处理组,其神经元明显增多,空洞面积减少。同时,星形胶质细胞标记物GFAP免疫荧光结果表明,bFGF减少胶质瘢痕形成,抑制星形胶质细胞过度激活。同样,通过Western 印迹检测发现,bFGF处理后,胶质瘢痕相关蛋白（如GFAP, neurocan）以及神经突生长抑制蛋白（Nogo-A）信号通路相关蛋白质表达量下降。上述结果表明,bFGF可能通过抑制Nogo-A信号蛋白的表达,从而抑制胶质瘢痕的形成,促进脊髓损伤的恢复。此机制研究为脊髓损伤的治疗和恢复提供全新的思路和药物靶点。     

少突胶质前体细胞治疗脊髓损伤的研究进展

脊髓损伤(spinal cord injury,SCI)是一种严重危害人类生命健康的疾病,其发病率呈现逐年上升的趋势,并且治疗较为困难。研究发现脊髓损伤后少突胶质细胞大量死亡,引发脱髓鞘病变,这可能是其难以治疗的原因之一。少突胶质前体细胞(OPCs)为少突胶质细胞的祖细胞,后者是中枢神经系统的成髓鞘细胞。OPCs来源于胚胎发育早期神经管腹侧神经上皮细胞,随着神经管的发育,OPCs逐渐增殖、迁移并分化为成熟OL,参与中枢神经系统轴突髓鞘的形成。随着对OPCs的不断深入研究,发现OPCs移植对SCI有较好的疗效,这可能为SCI患者开辟一条新的治疗途径。本文就OPCs治疗SCI的动物实验研究结果做一综述。     

MicroRNAs参与调控中枢神经系统的发育及脊髓损伤修复

microRNAs（miRNAs）不仅参与神经系统的生长发育、功能完善,还参与脊髓损伤病理及损伤后修复过程。miRNAs能使中枢神经系统按正确的时序性和空间性顺序进行发育和分化,在维持生物体记忆及生物钟方面起着重要作用。miRNAs异常表达同脊髓损伤病理过程相关。目前,体内及体外实验均已证实,miRNAs不仅能够维持神经干细胞增殖,而且可以促进神经元轴突伸长,从而为脊髓损伤的治疗带来新的治疗策略。     

脊髓损伤后神经环路重建的研究进展

成年哺乳类脊髓损伤后的修复与再生是一项复杂且尚未解决的挑战.随着全球经济的增长,脊髓损伤的发生率呈上升趋势.脊髓损伤可能导致永久性的运动功能障碍和感觉丧失,给患者及其家属带来极大的经济压力和心理负担.因此,迫切需要开发有效的治疗脊髓损伤的新策略.近年来,应用外源性或内源性神经元中继的治疗手段为脊髓损伤后环路重建提供了新的思路.将干细胞或生物材料等移植物作用于脊髓损伤区,可改善损伤区局部微环境,诱导神经干细胞定向分化为神经元,促进脊髓环路重建和功能恢复,因此成为较有临床应用前景的方法.本综述主要介绍细胞移植治疗、组织工程策略和基因调控等方法在修复受损脊髓的神经网络中的应用,并讨论了脊髓损伤后新生神经元是否具有潜在的功能整合,重建受损神经环路,并恢复其运动和感觉功能等问题.     

治疗脊髓损伤之建立星形胶质细胞模型的研究进展

脊髓损伤(spinal cord injury,SCI)是一种极为复杂的破坏性疾病,一旦脊髓损伤发生,治疗棘手,对患者家庭、国家带来巨大的经济、社会负担。近年来,通过建立大鼠脊髓损伤细胞相关模型,对于脊髓损伤的病因病机治疗等方面有了进一步的认识,而星形胶质细胞模型的建立对脊髓损伤治疗有深远意义。研究发现,星形胶质细胞作为靶细胞通过血-脑脊液屏障直接或间接对脊髓损伤有双向调控作用。本文通过对近年来星形胶质细胞模型培养制备方案等研究进行总结,以期为建立一个客观化、定量化、可模拟化的星形胶质细胞模型提供指导对脊髓损伤的治疗提供新的思路。     

电针对脊髓损伤星形胶质细胞增生及其NGF表达的影响

目的研究脊髓损伤后电针治疗对星形胶质细胞增生及其内源性神经生长因子(nerve growth factor,NGF)表达的影响.方法选用成年雌性Wistar大鼠,随机分为3组.A组为正常对照组,B组、C组为下胸段脊髓不完全损伤.B组损伤后不治疗,C组损伤后给予督脉电针治疗.损伤后3 d、1 、2或4周应用免疫组化染色分别观察损伤脊髓胶质原纤维酸性蛋白(glial fibroblast acid protein,GFAP)和NGF表达的变化.结果 B组术后3 d,GFAP阳性细胞明显增多, 2周后开始减少,4周时仍有较多的阳性细胞;C组GFAP阳性细胞明显少于B组,1周时达高峰.脊髓损伤后NGF表达呈逐渐增加的趋势.C组NGF的表达明显高于B组,且一直保持在较高水平.NGF阳性细胞大部分与GFAP阳性细胞形态相似.结论电针治疗能减少星形胶质细胞增生,促进内源性NGF的合成,从而创造了有利于神经再生的微环境.     

多发伤患者院前急救应用简易脊髓损伤评估法的护理观察

目的探讨多发伤患者院前急救应用简易脊髓损伤评估法的护理及效果。方法选取我院2013年1月~2014年11月院前急救以脊柱损伤为主的多发伤患者40例为研究对象,应用简易脊髓损伤评估法对护理的实施进行有效评估及指导。结果 40例患者中,除1例患者在抢救时死亡,2例患者现场检查已瘫痪外,其余患者经院前急救处理后均顺利转运至医院进一步治疗,无继发性损伤的发生。结论简易脊髓损伤评估法应用于脊柱损伤为主的多发伤患者院前急救护理中,能有效预防或避免出现继发性损伤,效果显著。     

An Ex Vivo Laser-induced Spinal Cord Injury Model to Assess Mechanisms of Axonal Degeneration in Real-time

Injured CNS axons fail to regenerate and often retract away from the injury site. Axons spared from the initial injury may later undergo secondary axonal degeneration. Lack of growth cone formation, regeneration, and loss of additional myelinated axonal projections within the spinal cord greatly limits neurological recovery following injury. To assess how central myelinated axons of the spinal cord respond to injury, we developed an ex vivo living spinal cord model utilizing transgenic mice that express yellow fluorescent protein in axons and a focal and highly reproducible laser-induced spinal cord injury to document the fate of axons and myelin (lipophilic fluorescent dye Nile Red) over time using two-photon excitation time-lapse microscopy. Dynamic processes such as acute axonal injury, axonal retraction, and myelin degeneration are best studied in real-time. However, the non-focal nature of contusion-based injuries and movement artifacts encountered during in vivo spinal cord imaging make differentiating primary and secondary axonal injury responses using high resolution microscopy challenging. The ex vivo spinal cord model described here mimics several aspects of clinically relevant contusion/compression-induced axonal pathologies including axonal swelling, spheroid formation, axonal transection, and peri-axonal swelling providing a useful model to study these dynamic processes in real-time. Major advantages of this model are excellent spatiotemporal resolution that allows differentiation between the primary insult that directly injures axons and secondary injury mechanisms; controlled infusion of reagents directly to the perfusate bathing the cord; precise alterations of the environmental milieu (e.g., calcium, sodium ions, known contributors to axonal injury, but near impossible to manipulate in vivo); and murine models also offer an advantage as they provide an opportunity to visualize and manipulate genetically identified cell populations and subcellular structures. Here, we describe how to isolate and image the living spinal cord from mice to capture dynamics of acute axonal injury.     

The Expression of Nerve Growth Factor Receptor on Schwann Cells and the Effect of These Cells on Regeneration of Axons in Traumatically Injured Human Spinal Cord

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Cholinergic Receptor Alterations in the Brain Stem of Spinal Cord Injured Rats

Cholinergic receptors in upper motor neurons of brain stem control locomotion and coordination. Present study unravels cholinergic alterations in brain stem during spinal cord injury to understand signalling pathway changes which may be associated with spinal cord injury mediated motor deficits. We evaluated cholinergic function in brain stem by studying the expression of choline acetyl transferase and acetylcholine esterase. We quantified metabotropic muscarinic cholinergic receptors by receptor assays for total muscarinic, muscarinic M1 and M3 receptor subunits, gene expression studies using Real Time PCR and confocal imaging using FITC tagged secondary antibodies. The gene expression of ionotropic nicotinic cholinergic receptors and confocal imaging were also studied. The results from our study showed metabolic disturbance in cholinergic pathway as choline acetyl transferase is down regulated and acetylcholine esterase is up regulated in spinal cord injury group. The significant decrease in muscarinic receptors showed by decreased receptor number along with down regulated gene expression and confocal imaging accounts for dysfunction of metabotropic acetylcholine receptors in spinal cord injury group. Ionotropic acetylcholine receptor alterations were evident from the decreased gene expression of alpha 7 nicotinic acetylcholine receptors and confocal imaging. The motor coordination was analysed by Grid walk test which showed an increased foot slips in spinal cord injured rats. The significant reduction in brain stem cholinergic function might have intensified the motor dysfunction and locomotor disabilities.     

Robot-Assisted Arm Assessments in Spinal Cord Injured Patients: A Consideration of Concept Study

Robotic assistance is increasingly used in neurological rehabilitation for enhanced training. Furthermore, therapy robots have the potential for accurate assessment of motor function in order to diagnose the patient status, to measure therapy progress or to feedback the movement performance to the patient and therapist in real time. We investigated whether a set of robot-based assessments that encompasses kinematic, kinetic and timing metrics is applicable, safe, reliable and comparable to clinical metrics for measurement of arm motor function. Twenty-four healthy subjects and five patients after spinal cord injury underwent robot-based assessments using the exoskeleton robot ARMin. Five different tasks were performed with aid of a visual display. Ten kinematic, kinetic and timing assessment parameters were extracted on joint- and end-effector level (active and passive range of motion, cubic reaching volume, movement time, distance-path ratio, precision, smoothness, reaction time, joint torques and joint stiffness). For cubic volume, joint torques and the range of motion for most joints, good inter- and intra-rater reliability were found whereas precision, movement time, distance-path ratio and smoothness showed weak to moderate reliability. A comparison with clinical scores revealed good correlations between robot-based joint torques and the Manual Muscle Test. Reaction time and distance-path ratio showed good correlation with the “Graded and Redefined Assessment of Strength, Sensibility and Prehension” (GRASSP) and the Van Lieshout Test (VLT) for movements towards a predefined position in the center of the frontal plane. In conclusion, the therapy robot ARMin provides a comprehensive set of assessments that are applicable and safe. The first results with spinal cord injured patients and healthy subjects suggest that the measurements are widely reliable and comparable to clinical scales for arm motor function. The methods applied and results can serve as a basis for the future development of end-effector and exoskeleton-based robotic assessments.     

Assessment of Glial Scar,Tissue Sparing,Behavioral Recovery and Axonal Regeneration following Acute Transplantation of Genetically Modified Human Umbilical Cord Blood Cells in a Rat Model of Spinal Cord Contusion

Objective and Methods

This study investigated the potential for protective effects of human umbilical cord blood mononuclear cells (UCB-MCs) genetically modified with the VEGF and GNDF genes on contusion spinal cord injury (SCI) in rats. An adenoviral vector was constructed for targeted delivery of VEGF and GDNF to UCB-MCs. Using a rat contusion SCI model we examined the efficacy of the construct on tissue sparing, glial scar severity, the extent of axonal regeneration, recovery of motor function, and analyzed the expression of the recombinant genes VEGF and GNDF in vitro and in vivo.

Results

Transplantation of UCB-MCs transduced with adenoviral vectors expressing VEGF and GDNF at the site of SCI induced tissue sparing, behavioral recovery and axonal regeneration comparing to the other constructs tested. The adenovirus encoding VEGF and GDNF for transduction of UCB-MCs was shown to be an effective and stable vehicle for these cells in vivo following the transplantation into the contused spinal cord.

Conclusion

Our results show that a gene delivery using UCB-MCs-expressing VEGF and GNDF genes improved both structural and functional parameters after SCI. Further histological and behavioral studies, especially at later time points, in animals with SCI after transplantation of genetically modified UCB-MCs (overexpressing VEGF and GDNF genes) will provide additional insight into therapeutic potential of such cells.     

A Contusion Model of Severe Spinal Cord Injury in Rats

The translational potential of novel treatments should be investigated in severe spinal cord injury (SCI) contusion models. A detailed methodology is described to obtain a consistent model of severe SCI. Use of a stereotactic frame and computer controlled impactor allows for creation of reproducible injury. Hypothermia and urinary tract infection pose significant challenges in the post-operative period. Careful monitoring of animals with daily weight recording and bladder expression allows for early detection of post-operative complications. The functional results of this contusion model are equivalent to transection models. The contusion model can be utilized to evaluate the efficacy of both neuroprotective and neuroregenerative approaches.