Transplantation of embryonic spinal cord-derived neurospheres support growth of supraspinal projections and functional recovery after spinal cord injury in the neonatal rat

Great interest exists in using cell replacement strategies to repair the damaged central nervous system. Previous studies have shown that grafting rat fetal spinal cord into neonate or adult animals after spinal cord injury leads to improved anatomic growth/plasticity and functional recovery. It is clear that fetal tissue transplants serve as a scaffold for host axon growth. In addition, embryonic Day 14 (E14) spinal cord tissue transplants are also a rich source of neural-restricted and glial-restricted progenitors. To evaluate the potential of E14 spinal cord progenitor cells, we used in vitro-expanded neurospheres derived from embryonic rat spinal cord and showed that these cells grafted into lesioned neonatal rat spinal cord can survive, migrate, and differentiate into neurons and oligodendrocytes, but rarely into astrocytes. Synapses and partially myelinated axons were detected within the transplant lesion area. Transplanted progenitor cells resulted in increased plasticity or regeneration of corticospinal and brainstem-spinal fibers as determined by anterograde and retrograde labeling. Furthermore, transplantation of these cells promoted functional recovery of locomotion and reflex responses. These data demonstrate that progenitor cells when transplanted into neonates can function in a similar capacity as transplants of solid fetal spinal cord tissue.     

Olfactory ensheathing cells from the nose: Clinical application in human spinal cord injuries

Olfactory mucosa, the sense organ of smell, is an adult tissue that is regenerated and repaired throughout life to maintain the integrity of the sense of smell. When the sensory neurons of the olfactory epithelium die they are replaced by proliferation of stem cells and their axons grow from the nose to brain assisted by olfactory ensheathing cells located in the lamina propria beneath the sensory epithelium. When transplanted into the site of traumatic spinal cord injury in rat, olfactory lamina propria or purified olfactory ensheathing cells promote behavioural recovery and assist regrowth of some nerves in the spinal cord. A Phase I clinical trial demonstrated that autologous olfactory ensheathing cell transplantation is safe, with no adverse outcomes recorded for three years following transplantation. Autologous olfactory mucosa transplantation is also being investigated in traumatic spinal cord injury although this whole tissue contains many cells in addition to olfactory ensheathing cells, including stem cells. If olfactory ensheathing cells are proven therapeutic for human spinal cord injury there are several important practical issues that will need to be solved before they reach general clinical application. This article is part of a Special Issue entitled: Understanding olfactory ensheathing glia and their prospect for nervous system repair.     

Human umbilical cord blood (HUCB) cells for central nervous system repair

Cellular therapy is a compelling and potential treatment for certain neurological and neurodegenerative diseases as well as a viable treatment for acute injury to the spinal cord and brain. The hematopoietic system offers alternative sources for stem cells compared to those of fetal or embryonic origin. Bone marrow stromal and umbilical cord cells have been used in pre-clinical models of brain injury, directed to differentiate into neural phenotypes, and have been related to functional recovery after engraftment in central nervous system (CNS) injury models. This paper reviews the advantages, utilization and progress of human umbilical cord blood (HUCB) cells in the neural cell transplantation and repair field.     

Dental pulp stem cells and their potential roles in central nervous system regeneration and repair

Functional recovery from injuries to the brain or spinal cord represents a major clinical challenge. The transplantation of stem cells, traditionally isolated from embryonic tissue, may help to reduce damage following such events and promote regeneration and repair through both direct cell replacement and neurotrophic mechanisms. However, the therapeutic potential of using embryonic stem/progenitor cells is significantly restricted by the availability of embryonic tissues and associated ethical issues. Populations of stem cells reside within the dental pulp, representing an alternative source of cells that can be isolated with minimal invasiveness, and thus should illicit fewer moral objections, as a replacement for embryonic/fetal‐derived stem cells. Here we discuss the similarities between dental pulp stem cells (DPSCs) and the endogenous stem cells of the central nervous system (CNS) and their ability to differentiate into neuronal cell types. We also consider in vitro and in vivo studies demonstrating the ability of DPSCs to help protect against and repair neuronal damage, suggesting that dental pulp may provide a viable alternative source of stem cells for replacement therapy following CNS damage. © 2013 Wiley Periodicals, Inc.     

嗅鞘细胞移植治疗脊髓损伤的临床验证

背景: 一系列基础研究证实在动物脊髓损伤的模型中,嗅鞘细胞移植能够促进脊髓损伤的再生和恢复脊髓的部分神经功能。部分临床实验证明嗅鞘细胞的移植的确能改善脊髓损伤患者的神经功能,从而改善其生活质量。 目的：验证嗅鞘细胞移植对脊髓损伤患者神经功能修复的作用及安全性。 方法：取流产胚胎嗅球并消化成为单个嗅鞘细胞,培养纯化2周左右,制成嗅鞘细胞悬液。选择脊髓损伤患者213例,全麻下将制备好的嗅鞘细胞悬液采用区域性多靶点注射方法移植于损伤脊髓的周围。采用ASIA量表对患者移植前1d及移植后3周~2个月进行评分,评价患者脊髓恢复状况。 结果与结论：所有患者的脊髓神经功能于术后3周均有不同程度的改变,脊髓功能评分及感觉与运动功能均较移植前明显提高(P < 0.001),且随时间延长呈不断改善趋势;最长患者随访5年,未见已恢复的神经功能 减退及移植不良反应。证实嗅鞘细胞移植对脊髓损伤患者的神经功能恢复有促进作用,可以部分恢复及改善其部分脊髓神经功能,且治疗方法安全。     

Multimodal treatment for spinal cord injury: a sword of neuroregeneration upon neuromodulation

Spinal cord injury is linked to the interruption of neural pathways,which results in irreversible neural dysfunction.Neural repair and neuroregeneration are critical goals and issues for rehabilitation in spinal cord injury,which require neural stem cell repair and multimodal neuromodulation techniques involving personalized rehabilitation strategies.Besides the involvement of endogenous stem cells in neurogenesis and neural repair,exogenous neural stem cell transplantation is an emerging effective method for repairing and replacing damaged tissues in central nervous system diseases.However,to ensure that endogenous or exogenous neural stem cells truly participate in neural repair following spinal cord injury,appropriate interventional measures(e.g.,neuromodulation)should be adopted.Neuromodulation techniques,such as noninvasive magnetic stimulation and electrical stimulation,have been safely applied in many neuropsychiatric diseases.There is increasing evidence to suggest that neuromagnetic/electrical modulation promotes neuroregeneration and neural repair by affecting signaling in the nervous system;namely,by exciting,inhibiting,or regulating neuronal and neural network activities to improve motor function and motor learning following spinal cord injury.Several studies have indicated that fine motor skill rehabilitation training makes use of residual nerve fibers for collateral growth,encourages the formation of new synaptic connections to promote neural plasticity,and improves motor function recovery in patients with spinal cord injury.With the development of biomaterial technology and biomechanical engineering,several emerging treatments have been developed,such as robots,brain-computer interfaces,and nanomaterials.These treatments have the potential to help millions of patients suffering from motor dysfunction caused by spinal cord injury.However,large-scale clinical trials need to be conducted to validate their efficacy.This review evaluated the efficacy of neural stem cells and magnetic or electrical stimulation combined with rehabilitation training and intelligent therapies for spinal cord injury according to existing evidence,to build up a multimodal treatment strategy of spinal cord injury to enhance nerve repair and regeneration.     

Review: Manipulating the extracellular matrix and its role in brain and spinal cord plasticity and repair

Brain and spinal cord injury can result in permanent cognitive, motor, sensory and autonomic deficits. The central nervous system (CNS) has a poor intrinsic capacity for regeneration, although some functional recovery does occur. This is mainly in the form of sprouting, dendritic remodelling and changes in neuronal coding, firing and synaptic properties; elements collectively known as plasticity. An important approach to repair the injured CNS is therefore to harness, promote and refine plasticity. In the adult, this is partly limited by the extracellular matrix (ECM). While the ECM typically provides a supportive framework to CNS neurones, its role is not only structural; the ECM is homeostatic, actively regulatory and of great signalling importance, both directly via receptor or coreceptor‐mediated action and via spatially and temporally relevant localization of other signalling molecules. In an injury or disease state, the ECM represents a key environment to support a healing and/or regenerative response. However, there are aspects of its composition which prove suboptimal for recovery: some molecules present in the ECM restrict plasticity and limit repair. An important therapeutic concept is therefore to render the ECM environment more permissive by manipulating key components, such as inhibitory chondroitin sulphate proteoglycans. In this review we discuss the major components of the ECM and the role they play during development and following brain or spinal cord injury and we consider a number of experimental strategies which involve manipulations of the ECM, with the aim of promoting functional recovery to the injured brain and spinal cord.     

不同来源成体神经干细胞促进大鼠脊髓损伤功能修复的比较研究

目的 评价大脑、骨髓和脂肪组织3种不同来源的神经干细胞对大鼠脊髓挫伤的治疗效果.方法 选取来源于同一大鼠成体中大脑、骨髓和脂肪的3个部位的组织,分离、诱导分化为不同来源的神经干细胞;应用自由落体损伤模型装置造成大鼠脊髓挫伤.将不同来源的神经干细胞分别移植入大鼠脊髓损伤部位,通过BBB评分比较修复脊髓损伤功能的效果,应用免疫荧光染色检测不同移植细胞在损伤脊髓中的存活、分布、迁移的情况.另设假手术对照组和生理盐水对照组.结果 与假手术对照组和生理盐水对照组比较,3个细胞处理组BBB评分在2～8周开始增加,9周以后更加明显,差异开始有统计学意义(P<0.05).在移植后1周和4周,细胞移植组中脑源性神经干细胞(SVZ-NSs)组Brdu/nestin+>神经元存活的数目明显高于其他2组.但差异没有统计学意义(P>0.05);到了第8周,3组均仅有少量Brdu/nestin+>细胞存活,相互之间比较差异无统计学意义(P>0.05).结论 植入来源于大脑、骨髓和脂肪组织的神经干细胞都可以在一定程度上提高脊髓损伤后运动功能恢复,但SVZ-NSs组的脊髓损伤大鼠运动功能恢复要比脂肪来源的神经干细胞(AD-NSs)组及骨髓来源的神经干细胞(BM-NSs)组更好.AD-NSs由于来源广泛和强有力的增殖能力,相比其他来源的神经干细胞,可能是更好的选择.     

Co-transplantation of fetal or adult dorsal root ganglia and of autologous peripheral nerve segments to the adult rat spinal cord: extensive reinnervation of the grafted nerves by the transplanted DRG cells.

Intraspinal transplantation of embryonic neurons and of autologous peripheral nerve segments is an essential tool for studying plasticity and repair in the adult mammalian spinal cord. Unlike adult central nervous system neurons, adult dorsal root ganglion (DRG) cells can be cultured in vitro and are assumed to survive transplantation. In the present work, we have co-transplanted adult (and also fetal, for comparison) DRG and peripheral nerve autografts to the cervical spinal cord of the adult rat. Similar results were obtained from both series: fetal as well as adult DRG cells did survive transplantation and nearly half of them grew lengthy axons into the grafted nerves. A few of them were seen to express a calcitonin gene-related peptide. Possibilities of central afferentation as well as of peripheral connectivity of these transplanted neurons is under study.     

Spinal cord regeneration: moving tentatively towards new perspectives

The failure of the adult human spinal cord to regenerate following injury is not absolute, but appears to be amenable to therapeutic manipulation. Recent work has shown that the provision of a growth permissive environment by the neutralization of inhibitory influences, or the grafting of fetal tissue, peripheral nerve, Schwann cells, or olfactory ensheathing cells can enhance regeneration in animal models of spinal cord injury. Stem cells are gaining ever-increasing favour as a treatment option for spinal cord injury. The potential of neural stem cells, embryonic stem cells, and bone marrow stromal cells is discussed. Additional treatment options such as pharmacological interventions, functional electrical stimulation and physiotherapy approaches are also explored. Basic science insights are used as a foundation for a discussion of a variety of clinical perspectives including repair of the chronically injured spinal cord, animal models of human spinal cord injuries and clinical trials. A more holistic approach towards spinal cord injury is suggested, one where a hierarchy of needs is recognised and quality of life is paramount. Finally, this review cautions against overly grandiose claims of an imminent miracle cure for human spinal cord injury.     

From cortex to cord: motor circuit plasticity after spinal cord injury

Spinal cord injury is associated with chronic sensorimotor deficits due to the interruption of ascending and descending tracts between the brain and spinal cord. Functional recovery after anatomically complete spinal cord injury is limited due to the lack of long-distance axonal regeneration of severed fibers in the adult central nervous system. Most spinal cord injuries in humans, however, are anatomically incomplete.Although restorative treatment options for spinal cord injury remain currently limited, research from experimental models of spinal cord injury have revealed a tremendous capability for both spontaneous and treatment-induced plasticity of the corticospinal system that supports functional recovery. We review recent advances in the understanding of corticospinal circuit plasticity after spinal cord injury and concentrate mainly on the hindlimb motor cortex, its corticospinal projections, and the role of spinal mechanisms that support locomotor recovery. First, we discuss plasticity that occurs at the level of motor cortex and the reorganization of cortical movement representations. Next, we explore downstream plasticity in corticospinal projections. We then review the role of spinal mechanisms in locomotor recovery. We conclude with a perspective on harnessing neuroplasticity with therapeutic interventions to promote functional recovery.     

New strategies for repairing the injured spinal cord: the role of stem cells

Thanks to advances in the stem cell biology of the central nervous system, the previously unconceivable regeneration of the damaged spinal cord is approaching reality. A number of potential strategies aim to optimize functional recovery after spinal cord injury. They include minimizing the progression of secondary injury, manipulating the inhibitory environment of the spinal cord, replacing lost tissue with transplanted cells or peripheral nerve grafts, remyelinating denuded axons and maximizing the intrinsic regenerative potential of endogenous progenitor cells. We review the application of stem cell transplantation to the spinal cord, emphasizing the use of embryonic stem cells for remyelinating damaged axons. Recent advancements in neural injury and repair, and the progress towards development of neuroprotective and regenerative interventions are discussed.     

Induced pluripotent stem cell-derived neural stem cell therapies for spinal cord injury

The greatest challenge to successful treatment of spinal cord injury is the limited regenerative capacity of the central nervous system and its inability to replace lost neurons and severed axons following injury. Neural stem cell grafts derived from fetal central nervous system tissue or embryonic stem cells have shown therapeutic promise by differentiation into neurons and glia that have the potential to form functional neuronal relays across injured spinal cord segments. However, implementation of fetal-derived or embryonic stem cell-derived neural stem cell therapies for patients with spinal cord injury raises ethical concerns. Induced pluripotent stem cells can be generated from adult somatic cells and differentiated into neural stem cells suitable for therapeutic use, thereby providing an ethical source of implantable cells that can be made in an autologous fashion to avoid problems of immune rejection. This review discusses the therapeutic potential of human induced pluripotent stem cell-derived neural stem cell transplantation for treatment of spinal cord injury, as well as addressing potential mechanisms, future perspectives and challenges.     

局部注射骨髓间充质干细胞治疗大鼠脊髓损伤：运动功能有改善吗？

背景：目前研究多为骨髓间充质干细胞的体外培养及细胞移植对颅内疾病的治疗,对植入细胞在损伤脊髓中的成活、分化、迁移、结构重建等了解有限。 目的：探讨局部骨髓间充质干细胞移植在脊髓损伤修复中的作用和骨髓间充质干细胞替代治疗的可行性。 方法：成年健康雌性SD大鼠随机分为细胞移植组和对照组,建立SD大鼠脊髓横断损伤模型,伤后即刻分别向损伤区局部移植大鼠骨髓间充质干细胞悬液或无钙镁磷酸缓冲液。在术前和术后1 d,1周,2周,3周,4周和8周进行BBB评分,观测大鼠的运动功能,并于移植后1周免疫组织化学染色法观察BrdU标记的骨髓间充质干细胞在脊髓损伤处的存活情况,移植后4周进行损伤脊髓的大体观察和组织学检测。 结果与结论：移植后第1~8周细胞移植组BBB评分均髙于对照组;术后1周免疫组织化学染色结果显示在细胞移植组大鼠脊髓远端检测到BrdU阳性细胞,术后4周脊髓损伤处发现有神经纤维。证实通过损伤后立即局部注射的方式将骨髓间充质干细胞移植进大鼠脊髓损伤区,细胞可在损伤区存活;存活的骨髓间充质干细胞可分化为神经元,在损伤局部形成神经元通路,从而促进脊髓神经纤维传导功能的恢复,并促进高位脊髓损伤后大鼠后肢运动功能恢复。     

Transplant mediated repair of the central nervous system: an imminent solution?

PURPOSE OF REVIEW: This article reviews recent advances in the use of cell transplantation to promote recovery from traumatic injury of the CNS, focusing on axonal regeneration in the spinal cord. RECENT FINDINGS: The significant recent findings reported are: (1) the increased expression of inhibitory chondroitin sulphate-proteoglycans in host tissue following Schwann cell transplantation, highlighting the effects the transplant may have on the ability of the host tissue to support regeneration; (2) the ability of embryonic and neural stem cells to promote recovery following transplantation into experimental models of spinal cord injury; (3) that delayed grafting for several weeks after transplantation does not diminish the graft effectiveness and may be advantageous; (4) the use of transplanted fibroblasts engineered to express neurotrophic genes in a conditionally regulated manner using tetracycline-inducible promoters; and (5) the initial reports on phase 1 clinical trials of foetal spinal cord grafts into patients with post-traumatic syringomyelia demonstrating their feasibility and safety. SUMMARY: Recent advances largely involve experimental refinements of existing approaches and the emergent application of stem cell biology to overcome spinal cord injury. While most experimental studies concentrate on single or restricted combinations of approaches, the most effective clinical strategies will be multi-component. Their formulation will require the development of intermediate models for bridging the differences between experimental models in laboratory animals and naturally occurring traumatic injury in humans.     

嗅鞘细胞移植治疗中枢神经系统损伤的理论研究及临床应用

进行中枢神经系统损伤修复的候选胶质细胞包括嗅鞘细胞、少突胶质前体细胞和许旺细胞。少突胶质前体细胞很难获得大量移植用供体细胞,许旺细胞很难穿透胶质瘢痕,从应用方面均不如嗅鞘细胞。离体培养中嗅鞘细胞极强的可塑性可能会使嗅鞘细胞适时改变自身形态,以适应体内复杂的微环境,有利于神经再生。嗅鞘细胞移植后对脊髓后根损伤后再生有一定作用,其作用大小可能与嗅鞘移植物的成分有关,细胞制备技术和混合细胞移植能影响嗅鞘细胞移植物的效果。虽然胎脑的免疫原性很低,但合理应用免疫抑制剂会使嗅鞘细胞的移植效果有所改观。嗅鞘细胞除了重建损伤通路外,还可能通过轴突发芽、在非突触部位释放单胺类物质、改善病变部位环境并帮助附近的残余神经纤维保存功能和活性等机制对中枢神经的功能发生作用。嗅鞘细胞的细胞生物学和移植后行为学的深入研究都会加快人们对脊髓损伤的理解,并对脊髓损伤的修复治疗产生重要的理论指导意义。     

骨髓间充质干细胞立体定向移植治疗大鼠脊髓损伤*

摘要 背景：传统观念认为,神经组织损伤后几乎不能再生,以往对SCI的治疗缺乏有效手段,致使本病致残率高,疗效差。干细胞治疗关键在于移植具有再生能力的干细胞,通过多种作用机制,可以重建中枢神经系统的结构和功能,近年来引起了广泛的关注。 目的：探讨立体定向移植骨髓间充质干细胞（MSCs）对大鼠脊髓损伤修复的影响并探讨其机制 设计、时间及地点：随机对照动物实验,于2007-10/2008-6在天津市环湖医院完成。 材料：1月龄SD大鼠20只,用于制备骨髓间充质干细胞;健康成年Wistar大鼠45只,雌性、同系,体质量280±20 g。将动物随机分为对照组、假手术组与移植组,每组各15只。 方法：密度梯度离心法结合贴壁筛选法分离骨髓间充质干细胞,经流式细胞仪鉴定为MSCs。以动脉瘤夹夹闭法制备大鼠脊髓损伤（SCI）模型,在SCI大鼠致伤后第7天,通过立体定向途径移植MSCs到移植组大鼠脊髓损伤中心,移植等量生理盐水至假手术组大鼠脊髓损伤中心,对照组大鼠不做处理。 主要观察指标：SCI大鼠损伤前及损伤后第7天、14天、30天、60天、90天的BBB评分;损伤后第90天处死大鼠,观察其脊髓组织中有无BrdU阳性细胞、Brdu+NSE、Brdu+GFAP、Brdu+bFGF、Brdu+BDNF免疫组化双染阳性细胞并观察NSE、GFAP、bFGF、BDNF单染阳性细胞。 结果： ①BBB评分发现,MSCs移植组大鼠BBB后肢功能评分恢复优于对照组（p<0.05）;假手术组BBB评分在损伤后30天内恢复速度慢于对照组（p<0.05）,至第90天与对照组比较无显著差异（P>0.05）;②免疫组织化学染色发现,移植组大鼠脊髓内在损伤中心及头、尾端距离脊髓损伤中心1cm处均可见BrdU染色阳性细胞及Brdu+NSE、Brdu+GFAP、Brdu+bFGF、Brdu+BDNF免疫组化双染阳性细胞。移植组NSE、GFAP、bFGF、BDNF单染阳性细胞数明显高于对照组和假手术组（p<0.05）。 结论： MSCs移植可以促进SCI大鼠的神经功能的恢复,其机制可能与移植细胞分化为神经元样和神经胶质细胞样细胞,并分泌或促进宿主分泌神经营养因子有关。 关键词 脊髓损伤 骨髓间充质干细胞 立体定向 细胞移植     

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.     

CNS transplants promote anatomical plasticity and recovery of function after spinal cord injury

We are using neural tissue transplantation after spinal cord injury to identify the rules which determine the response of young neurons to injury, to identify the mechanisms underlying anatomical plasticity and recovery of function following spinal cord injury, and to determine the conditions which change during development, leading to the more restricted growth capacity of mature neurons following injury. Spinal cord lesions at birth interrupt different pathways at different relative stages in their development. Neural tissue transplants modify the response of the immature central nervous system neurons to injury. In the current studies, we have used neuroanatomical and behavioral methods to compare the response of the late-developing corticospinal pathway with that of brainstem-spinal pathways which are intermediate in their development and that of the relatively mature dorsal root pathway. We find that both late-developing and regenerating neuronal populations contribute to the transplant-induced anatomical plasticity, and suggest that this anatomical plasticity underlies the transplant-mediated sparing and recovery of function.     

Transplants of fetal neural tissue and autologous peripheral nerves in an attempt to repair spinal cord injuries in the adult rat. An overall view

Embryonic neurons and autologous peripheral nerve segments constitute selected materials for studying central nervous system plasticity and repair in adult mammals. Transplanted to the brain or the spinal cord, the former are possible substitutes designed to replace lost or deficient host neurons while the latter have useful stimulating and guiding effects upon axonal regrowth from surviving axotomized neurons. Consequently, these techniques give rise to interesting prospects for short and medium range fundamental research as well as for possible medium and long-term clinical applications. From a basic viewpoint, utilisation of such transplants is designed to study the survival, the morphological and biochemical differentiation, the reafferentation, the expression of potentialities for plasticity, axonal growth or regeneration, synaptogenesis, of host as well as of transplanted embryonic neurons. From a clinical viewpoint these studies should attempt at finding solutions to counteract the effects of severe traumatic or neurodegenerative lesions of the brain and of the spinal cord which until now appear quite refractory to therapeutic approaches.