Homotopic transplantation of embryonic neocortical tissue into the brain of adult rats after its damage

Structural characteristics (survival, growth, connections) have been studied in the transplant of the cerebral cortex tissue in Wistar rat embryos (18-day-old), implanted into the brain of mature rats of the same line at various time after a partial lesion of the sensomotor cortex. In 3-5 months after transplantation the light microscopy methods demonstrate that spatial interconnections of the transplant and the injured brain of the recipient depend on time interval between the cerebral lesion and transplantation of the embryonal nervous tissue. Horseradish peroxidase (HP) is ionophoretically injected into the recipient's cerebral tissue away from the place of transplantation. In the transplant retrogradely labelled HP neurons are revealed. This demonstrates efferent connections of the implanted tissue with the host's brain. Presence of the anterogradely labelled nervous terminals in the transplant tissue demonstrates existence of afferent connections of the transplant with the recipient's tissue. Possible mechanisms of survival, growth and formation of connections of the transplant in the injured brain of the mature animal are discussed.     

在大鼠创伤性脑损伤模型中神经干细胞移植对突触素表达的影响

目的探讨神经干细胞（NSCs）移植对创伤性脑损伤（TBI）模型大鼠感觉运动功能的恢复作用及其对损伤脑组织中突触素（SYP）表达的影响。方法体外培养大鼠胚胎皮质NSCs;采用Feeney法制备TBI模型,于造模后72h,移植组采用PKH26荧光示踪剂标记的NSCs直接移植于脑损伤区,对照组以等量生理盐水代替NSCs;分别于移植后不同时间点,采用Gridwalk和Latency试验检测TBI大鼠的感觉运动功能;荧光显微镜下计数移植细胞的存活数量;采用免疫印迹和RT-PCR技术检测脑损伤区及周围组织中SYP的表达。结果 NSCs移植大鼠前、后肢功能分别在移植后第2w和4w恢复至手术前水平,而直到第8w,对照组大鼠后肢功能和通过平板移动时间与NSCs移植组和基线比较仍有显著性差异（P〈0.05）。移植的NSCs随移植时间延长存活数量减少,移植后第4w和8w的存活数分别为6.3%±1.0%和4.1%±0.9%。在移植后的8w期间,移植组脑损伤区及周围组织中SYP的表达均明显高于对照组（P〈0.05）。结论移植的NSCs在TBI脑内能够存活,并明显改善了TBI大鼠对侧肢体的感觉运动功能;NSCs移植促进了脑损伤区及周围组织中SYP的表达,这可能是NSCs移植促进功能恢复的机理之一。     

Homotopic transplant of fetal cortex to lesioned motor cortex of adult rats. A comportamental and anatomical study.

Previous investigations have shown that the transplant of fetal nervous tissue in adult, formerly injured, brain induces an improvement of the neurological deficits. The process underlying this finding is not yet known. It has been proposed that this process is favourably supported by the reconstruction of the damaged circuitry, replacing the injured neurons with the transplanted fetal cells. In the present study we have investigated the relation between the improvement of the neurological deficits and the anatomical integration of the transplanted neurons within the host brain. The plan of the investigation included two steps: the first step consisted of inducing neurological deficits by kainic acid lesion of the motor cortex and then studying the changes in the motor learning following a homotopic transplant of fetal cortex in the side of the lesion. The second step consisted of studying the anatomical integration of the transplanted cortex with the thalamus of the host. The results showed that the rats with injury of the motor cortex followed by solid transplant of fetal cortex (E 17) had a significantly greater recovery of the motor learning with respect to non-transplanted rats with a lesioned motor cortex. In the same rats, the connections between the transplanted cerebral cortex and the thalamus of the host has been investigated. WGA-HRP solution was injected in the thalamus and both labeled fiber terminals and labeled cells were searched for in the transplants. The results showed that: 1) the host thalamus projects to the transplanted cortex with a lower density than to the host cortex surrounding the transplant; 2) the thalamic projection to the host cortex is topographically organized, whereas the projection to the transplant is arranged in patches without any topographical organization; 3) the transplant does not send a significant projection to the thalamus of the host. In conclusion, the experimental findings demonstrate that the reconstruction of an injured thalamo-cortical circuitry of adult rats transplanting fetal neurons is not possible. The improvement of the functional deficits by the transplant of fetal tissue may be referred to aspecific factors enhancing the functional activity of the host cortex undamaged by the initial injury. The identification of the nature of the hypothesized factors requires further investigation.     

Molecular interactions of neural chondroitin sulfate proteoglycans in the brain development

Aggrecan family proteoglycans, phosphacan/RPTPzeta/beta, and neuroglycan C (NGC) are the major classes of chondroitin sulfate proteoglycan in the developing mammalian brain. A multidomain is a common structural feature of these proteoglycans which can interact with various molecules including growth factors, cell adhesion molecules, and extracellular matrix molecules. Individual proteoglycans are distributed in the developing brain in a distinct temporal and spatial pattern, suggesting that they are involved in distinct phases of the brain development through multiple molecular interactions. This review mainly summarizes recent studies on the involvement of these three classes of proteoglycan in cell-cell and cell-substratum interactions during the brain development. Their expressions and proposed functional roles in injured brains are also mentioned. In addition, this review briefly covers potential functions of other neural chondroitin sulfate proteoglycans such as decorin, testican, NG2 proteoglycan, and amyloid precursor protein (APP) in developing and injured brains.     

Changing interactions between astrocytes and neurons during CNS maturation

The environments of the developing brain and injured adult brain differ in their abilities to support axonal growth. To determine if astrocytes contribute to this difference, neurons were plated onto astrocytes cultured from the neonatal rat cortex and from the injured adult brain. Two patterns of neurite growth were observed in these two astrocyte culture systems. Neurons contacting the neonatal astrocytes had neurites that were twice as long as those contacting the injured adult astrocytes. Furthermore, in cultures with neonatal astrocytes, neurites faithfully followed the astrocytic processes, maximizing their contact, while in cultures of injured adult astrocytes, the neurites had a tendency to cross the processes orthogonally, minimizing their interaction with the astrocytes. When neurons were grown suspended over either neonatal or injured adult astrocytes, no difference in neurite length or the pattern of neurite growth was observed, indicating that neurite growth was not differentially affected by soluble factors released from the two populations of astrocytes. The addition of fetal calf serum, which is known to contain protease inhibitors, did not alter neurite growth when compared to serum-free medium, suggesting that a substantial difference in protease activity does not account for the variations in neurite length observed. Based on these results, it appears that the molecular components of the external surface of injured adult astrocytes do not support neurite growth to the same extent as those found on neonatal astrocytes. The differing abilities of these two populations of cultured astrocytes to support neurite growth in culture may reflect a change in the functional role of these cells that occurs during the development of the central nervous system.     

Brain switching: studying evolutionary behavioral changes in the context of individual brain development

Working together at Nogent, Marie-Aimee Teillet, Nicole Le Douarin and the author successfully developed an extension of the quail-chick transplant technique for relating species brain cell differences to behavioral differences. This article reviews the application of the technique to species differences in motor behavior (crowing) and auditory perceptual preferences. Interspecies brain transplants provide a unique means for elucidating general cellular mechanisms which integrate evolutionary and individual experience during the development of complex brain circuitry.     

Anatomic connections between homotopic transplant of fetal cortical tissue and optic thalamus in adult rats

The present research was planned to study the possibility to reconstruct a damaged neural circuitry by replacing the injured neurons with homotopic fetal cells. In adult rats the motor cortex was injured with intracortical injection of kainic acid solution. After a delay of 10-14 days, a block of cerebral cortex of fetal rats (E17) was transplanted in the cavity produced by the kainic acid in the motor cortex. After 2-3 months, WGA-HRP solution was injected in the thalamus of the host and both anterogradely labeled fiber terminals and retrogradely labeled somata cells were researched in the transplanted cortex. The results showed that: 1) the host thalamus projects to the transplanted cortex with less density compared to the host cortex surrounding the transplant; 2) the thalamic projection to the transplant is not topographically organized whereas the projection to the host cortex is; 3) the transplant was virtually void of a significant projection to the thalamus of the host. In conclusion, the results offer direct evidence that the reconstruction of an injured thalamocortical circuitry of adult rat is not possible by transplanting homotopic fetal neurons.     

神经干细胞移植的临床研究进展

神经系统损伤会导致脑内神经干细胞（neural stem cells,NSCs）的扩增以实现自我修复功能,而通过外源细胞移植的方式来加速这一进程,可能是一种更有效的治疗手段。当前,神经干细胞临床研究所面临的主要问题是如何评价细胞在移植后的行为和功能。该文综述了近几年使用神经干细胞移植治疗几种主要神经系统疾病的临床研究成果,并着重关注了干细胞移植后的示踪研究。     

Regional Levels of Lactate and Norepinephrine After Experimental Brain Injury

Abstract: The recently developed controlled cortical impact model of brain injury in rats may be an excellent tool by which to attempt to understand the neurochemical mechanisms mediating the pathophysiology of traumatic brain injury. In this study, rats were subjected to lateral controlled cortical impact brain injury of low grade severity; their brains were frozen in situ at various times after injury to measure regional levels of lactate, high energy phosphates, and norepinephrine. Tissue lactate concentration in the injury site left cortex was increased in injured animals by sixfold at 30 min and twofold at 2.5 h and 24 h after injury ( p < 0.05). At all postinjury times, lactate concentration was also increased in injured animals by about twofold in the cortex and hippocampus adjacent to the injury site ( p < 0.05). No significant changes occurred in the levels of ATP and phosphocreatine in most of the brain regions of injured animals. However, in the primary site of injury (left cortex), phosphocreatine concentration was decreased by 40% in injured animals at 30 min after injury ( p < 0.05). The norepinephrine concentration was decreased in the injury site left cortex of injured animals by 38% at 30 min, 29% at 2.5 h, and 30% at 24 h after injury ( p < 0.05). The level of norepinephrine was also reduced by ∼20% in the cortex adjacent to the injury site in injured animals. The present results suggest that controlled cortical impact brain injury produces disorder in the neuronal oxidative and norepinephrine metabolism.     

Brain Cellular Injury and Recovery—Horizons for Improving Medical Therapies in Stroke and Trauma

An edited summary of an Interdepartmental Conference arranged by the Department of Medicine of the UCLA School of Medicine, Los Angeles. The Director of Conferences is William M. Pardridge, MD, Professor of Medicine.After ischemic and traumatic brain injury, many cells may be rendered dysfunctional but are not irreversibly damaged or disrupted. The brain tissue may become metabolically deranged, and neurons, while still alive, are paralyzed and cannot create an action potential or conduct an electrical impulse. This injured brain tissue is in a precarious state of increased vulnerability. If the milieu of the favorable, they may recover; if it is slightly unfavorable, they may die. There is now evidence that reversibly injured brain tissue will die from an ischemic or hypoxic insult ordinarily tolerated by the normal brain. The major challenge of modern research in stroke and trauma is to define the chemical and metabolic milieu in which the injured brain exists and to define an ideal milieu for healing.     

Moving toward a generalizable application of central thalamic deep brain stimulation for support of forebrain arousal regulation in the severely injured brain

This review considers the challenges ahead for developing a generalizable strategy for the use of central thalamic deep brain stimulation (CT/DBS) to support arousal regulation mechanisms in the severely injured brain. Historical efforts to apply CT/DBS to patients with severe brain injuries and a proof-of-concept result from a single-subject study are discussed. Circuit and cellular mechanisms underlying the recovery of consciousness are considered for their relevance to the application of CT/DBS, to improve consciousness and cognition in nonprogressive brain injuries. Finally, directions for development, and testing of generalizable criteria for CT/DBS are suggested, which aim to identify neuronal substrates and behavioral profiles that may optimally benefit from support of arousal regulation mechanisms.     

叶酸联合成体神经干细胞治疗创伤性脑损伤大鼠的实验

目的观察叶酸联合成体神经干细胞对创伤性脑损伤大鼠的治疗作用,探讨其可能作用机制。方法 120只Wistar大鼠随机分为6组,正常组,模型组,假手术组,叶酸注射组,成体神经干细胞移植组,成体神经干细胞移植＋叶酸注射组。倒置显微镜下观察神经干细胞形态学变化;流式细胞仪检测神经干细胞表面标记物CD105、CD45、CD44、CD29的表达;免疫荧光法检测神经元特异性烯醇酶（NSE成熟神经元的特异性标志）、胶质纤维酸性蛋白（GFAP胶质细胞的标记物）的表达;平衡木实验检测大鼠运动协调与整和能力;Morris水迷宫实验测试各组大鼠的学习记忆能力;HE染色及Brdu免疫组化实验观察脑组织形态学变化;酶联免疫吸附试验检测大鼠脑组中脑源性神经生长因子（BDNF）、神经生长因子（NGF）的表达;蛋白质印迹法检测脑组织中凋亡相关蛋白BCL-2、Bax、Caspase-3的表达。结果分离所得细胞能在体外传代培养,流式细胞仪检测发现细胞阳性表达CD44、CD29,阴性表达CD105、CD45,细胞经胎牛血清诱导分化后能形成NSE或GFAP阳性细胞。实验表明,叶酸与成体神经干细胞干预创伤性脑损伤大鼠模型后能显著改善其行为学变化,减轻脑组织的炎症反应,恢复受损神经细胞,增加脑组织内BDNF、NGF的含量,上调BCL-2的表达,下调Bax、Caspase-3的表达。结论叶酸联合成体神经干细胞干预创伤性脑损伤大鼠能显著改善中枢神经功能,对维持神经元微环境稳态具有重要的作用。     

Behavioral, morphologic and biochemical correlates of the early effect of a neural transplant into the damaged brain of adult rats

Complex study was carried out of the behavioural, morphological and neurobiochemical parameters of the effect of an embryonal neural transplant of the amygdala in the first weeks after its introduction into the area of the left amygdala of adult rats-recipients. The neural transplant promoted normalization of animals food search, disturbed by operative interference. The amygdalar embryonal tissue lowered the proliferative glia reaction, produced by the brain lesion, and intensified the nervous tissue regeneration. The neural transplant intensified generalized adaptive neurobiochemical processes in the lesioned brain.     

综述与专论：CKLF1作为缺血性脑卒中治疗的潜在靶点

缺血性脑卒中是一种血液循环障碍疾病,可导致严重的神经功能缺损。卒中病人中约有87%的病例为缺血性卒中。神经炎症是中风损伤的主要病理状态之一。CKLF1是2001年发现的非经典CC型趋化因子,对单核细胞、中性粒细胞和淋巴细胞表现出很强的趋化活性。CKLF1在胎儿大脑中含量最高,但在健康成人阶段不存在。越来越多的证据表明,CKLF1表达在成年卒中动物模型中,并被重新激活,参与神经炎症反应的多个过程。然而,其生物活性和药物发现的发展仍缺乏系统的文献报道。因此,我们收集已发表的资料并做此综述,简要阐明CKLF1在缺血性脑卒中中的作用,并解释其加重缺血性脑卒中的机制。此外,还发现了一些潜在的抗卒中药物,表明CKLF1是治疗缺血性卒中的潜在靶点。     

CKLF1作为缺血性脑卒中治疗的潜在靶点

缺血性脑卒中是一种血液循环障碍疾病,可导致严重的神经功能缺损.卒中病人中约有87％的病例为缺血性卒中.神经炎症是中风损伤的主要病理状态之一.CKLF1是2001年发现的非经典CC型趋化因子,对单核细胞、中性粒细胞和淋巴细胞表现出很强的趋化活性.CKLF1在胎儿大脑中含量最高,但在健康成人阶段不存在.越来越多的证据表明,...     

Macrophages are comprised of resident brain microglia not infiltrating peripheral monocytes acutely after neonatal stroke

Macrophages can be both beneficial and detrimental after CNS injury. We previously showed rapid accumulation of macrophages in injured immature brain acutely after ischemia-reperfusion. To determine whether these macrophages are microglia or invading monocytes, we subjected post-natal day 7 (P7) rats to transient 3 h middle cerebral artery (MCA) occlusion and used flow cytometry at 24 and 48 h post-reperfusion to distinguish invading monocytes (CD45high/CD11b+) from microglia (CD45low/medium/CD11b+). Inflammatory cytokines and chemokines were determined in plasma, injured and contralateral tissue 1-24 h post-reperfusion using ELISA-based cytokine multiplex assays. At 24 h, the number of CD45+/CD11b+ cells increased 3-fold in injured compared to uninjured brain tissue and CD45 expression shifted from low to medium with less than 10% of the population expressing CD45high. MCA occlusion induced rapid and transient asynchronous increases in the pro-inflammatory cytokine IL-beta and chemokines cytokine-induced neutrophil chemoattractant protein 1 (CINC-1) and monocyte-chemoattractant protein 1 (MCP-1), first in systemic circulation and then in injured brain. Double immunofluorescence with cell-type specific markers showed that multiple cell types in the injured brain produce MCP-1. Our findings show that despite profound increases in MCP-1 in injured regions, monocyte infiltration is low and the majority of macrophages in acutely injured regions are microglia.     

小鼠胎肝间充质干细胞在缺血脑组织中迁移机制的研究

目的：探讨小鼠胎肝间充质干细胞（flMSCs）在缺血脑组织中迁移的机制。方法：分离和培养小鼠flMSCs,制备小鼠脑缺血再灌注模型,RT-PCR方法检测小鼠flMSCs表达的趋化因子受体及其唯一配体基质细胞来源因子1α（SDF-1α）在缺血损伤脑组织中的n1RNA表达;Westernblot检测SDF-1α蛋白在缺血损伤脑组织中的表达;免疫组织化学检测SDF-1α在缺血损伤脑组织中的表达和分布;Boydenchamber法进行SDF-1α诱导flMSCs迁移的体外实验。结果：flMSCs经RT-PCR检测表达趋化因子受体CR1,CR3,CXCR1,CXCR2,CXCR3,CXCR4。脑缺血损伤侧脑组织SDF-1αmRNA表达显著增高,与正常脑组织SDF-1αmRNA比,具有显著差异（P〈0．01）,Westernblot检测显示缺血侧脑组织SDF-1α蛋白表达量在12、24、48h分别为0．35±0．05,0．88±0．04,0．74±0．07,与正常脑组织SDF-1α蛋白（0．22±0．04）比,差异有显著性（P〈0．01）。免疫组织化学检测显示,缺血损伤后24h,缺血侧脑皮质,海马等缺血边缘区SDF-1α表达显著增高,缺血对侧及正常脑组织未见明显SDF-1α表达。体外迁移实验显示SDF—1α体外可以趋化flMSCs发生迁移,CXCR4阻断抗体可以阻断SDF—1α诱导flMSCs发生的迁移。结论：SDF-1α可以诱导flMSCs发生迁移,趋化因子受体CXCR4及其配体SDF-1α的相互作用是flMSCs在缺血损伤脑组织中迁移的机制之一.     

THE EFFECT OF INJURY ON MONOAMINE CONCENTRATIONS IN THE RAT HYPOTHALAMUS

Abstract— The monoamine concentrations have been measured in four regions of the brain (hypothalamus, cortex, cerebellum and brain stem) in rats injured by either hind-limb ischaemia or scald. Both injuries produced a rapid fall in the noradrenaline concentration of the hypothalamus which recovered slowly if the injury was not fatal. This effect of injury was seen after pretreatment with a-methyl-p-tyrosine to inhibit noradrenaline synthesis, indicating an increased rate of utilization of noradrenaline after injury. These injuries did not affect the 5-hydroxytryptamine concentration in the hypothalamus, but changes were found in the concentration of this monoamine and in that of its metabolite, 5-hydroxyindole acetic acid, in the brain stem. It is concluded that these forms of injury had specific effects on the brain monoamines. The hypothalamic changes were not secondary to changes in core temperature or to hypotension or hypovolaemia and they are discussed in relation to the impairment of temperature regulation seen in the injured rat.     

Development of Prolonged Focal Cerebral Edema and Regional Cation Changes Following Experimental Brain Injury in the Rat

The present study examined the formation of regional cerebral edema in adult rats subjected to lateral (parasagittal) experimental fluid-percussion brain injury. Animals receiving fluid-percussion brain injury of moderate severity over the left parietal cortex were assayed for brain water content at 6 h, 24 h, and 2, 3, 5, and 7 days post injury. Regional sodium and potassium concentrations were measured in a separate group of animals at 10 min, 1 h, 6 h, and 24 h following fluid-percussion injury. Injured parietal cortex demonstrated significant edema, beginning at 6 h post injury (p less than 0.05) and persisting up to 5 days post injury. In the hippocampus ipsilateral to the site of cortical injury, significant edema occurred as early as 1 h post injury (p less than 0.05), with resolution of water accumulation beginning at 3 days. Sodium concentrations significantly increased in both injured cortex (1 h post injury, p less than 0.05) and injured hippocampus (10 min post injury, p less than 0.05). Potassium concentrations fell significantly 1 h post injury within the injured cortex (p less than 0.05), whereas significant decreases were not observed until 24 h post injury within the injured hippocampus. Cation alterations persisted throughout the 24-h post injury period. These results demonstrate that regional brain edema and cation deregulation occur in rats subjected to lateral fluid-percussion brain injury and that these changes may persist for a prolonged period after brain injury.     

Changes in the activity of different classes of enzymes in the cerebral cortex of rats in ontogeny and after the transplantation of embryonic nerve tissue

The activity of lactate dehydrogenase (LDH), indophenol oxidase, aspartate aminotransferase (AsAT), alkaline phosphatase, acid phosphatase and aldolase at different stages of rat development was measured. We have also determined changes in the activity of these enzymes resulting from transplantation of embryonic nerve tissue (ENT) into the brain of adult animals. During development from the embryo to the adult animal, LDH and AsAT activities increased, while alkaline phosphatase activity diminished. After ENT transplantation, the most prominent changes were in the alkaline phosphatase activity whereas the activity of LDH, AsAT and acid phosphatase remained unchanged and similar to that in the brain cortex of intact adult animals. Changes in the enzyme activity resulting from ENT transplantation changed in a manner characteristic of the transplant. Local brain damage did not change the activity of the studied enzymes fifty days after surgery.