Upregulation of EphA3 receptor after spinal cord injury

Spinal cord injury (SCI) releases a cascade of events that leads to the onset of an inhibitory milieu for axonal regeneration. Some of these changes result from the presence of repulsive factors that may restrict axonal outgrowth after trauma. The Eph receptor tyrosine kinase (RTK) family has emerged as a key repellent cue known to be involved in neurite outgrowth, synapse formation, and axonal pathfinding during development. Given the nonpermissive environment for axonal regeneration after SCI, we questioned whether re-expression of one of these molecules occurs during regenerative failure. We examined the expression profile of EphA3 at the mRNA and protein levels after SCI, using the NYU contusion model. There is a differential distribution of this molecule in the adult spinal cord and EphA3 showed an increase in expression after several injury models like optic nerve and brain injury. Standardized semi-quantitative RT-PCR analysis demonstrated a time-dependent change in EphA3 mRNA levels, without alterations in beta-actin levels. The basal level of EphA3 mRNA in the adult spinal cord is low and its expression was induced 2 days after trauma (the earliest time point analyzed) and this upregulation persisted for 28 days post-injury (the latest time point examined). These results were corroborated at the protein level by immunohistochemical analysis and the cell phenotype identified by double labeling studies. In control animals, EphA3 immunoreactivity was observed in motor neurons of the ventral horn but not in lesioned animals. In addition, GFAP-positive cells were visualized in the ventral region of injured white matter. These results suggest that upregulation of EphA3 in reactive astrocytes may contribute to the repulsive environment for neurite outgrowth and may be involved in the pathophysiology generated after SCI.     

Reevaluation of gray and white matter injury after spinal cord ischemia in rabbits

BACKGROUND: Although gray matter injury has been well characterized, the available data on white matter injury after spinal cord ischemia (SCI) in rabbits are limited. The current study was conducted to investigate the evolution of ischemia induced injury to gray and white matter and to correlate this damage to hind-limb motor function in rabbits subjected to SCI. METHODS: Thirty-eight rabbits were randomly assigned to 24-h, 4-day, or 14-day reperfusion groups or a sham group (n = 9 or 10 per group). SCI was induced by occlusion of the infrarenal aorta for 16 min. Hind-limb motor function was assessed using the Tarlov scale (0 = paraplegia, 4 = normal). The gray matter damage was assessed on the basis of the number of normal neurons in the anterior spinal cord. White matter damage was assessed on the basis of the extent of vacuolation and accumulation of amyloid precursor protein immunoreactivity. RESULTS: Tarlov scores gradually decreased and reached a nadir 14 days after reperfusion. There were no significant differences in the number of normal neurons among the 24-h, 4-day, and 14-day groups. The extent of vacuolation, expressed as a percent of total white matter area, was significantly greater in the 4-day and 14-day groups in comparison with the sham group. By contrast, there was no difference in vacuolation between the sham and 24-h groups. Amyloid precursor protein immunoreactivity was greater in the 4-day and 14-day groups. CONCLUSION: The results in the current study show that SCI induced white matter injury as well as gray matter injury in a rabbit model of SCI. The time course for 14 days after reperfusion may differ among the gray and white matter damages and hind-limb motor function in rabbits subjected to SCI.     

An evaluation of white matter injury after spinal cord ischemia in rats: a comparison with gray matter injury

We quantitatively assessed both gray and white matter injury after spinal cord ischemia in rats, and the relationship between the magnitude of gray and white matter injury was determined. Twenty-five male rats were anesthetized with isoflurane, and spinal cord ischemia (SCI) was induced by balloon intraaortic occlusion combined with hypotension. The animals were randomly allocated to one of the following three groups: animals with SCI for 12 min (SCI-12; n = 8), 15 min (SCI-15; n = 9), or those with sham operation (n = 8). Twenty-four hours after reperfusion, hindlimb motor function was assessed using the Basso-Beattie-Bresnahan scale scoring. Gray matter damage was assessed on the basis of the number of normal neurons in the ventral horn. White matter damage was assessed on the basis of the extent of vacuolation and amyloid precursor protein immunoreactivity in the ventral and ventrolateral white matter. There were significantly less normal neurons in the SCI-15 group compared with those in the SCI-12 and sham groups (P < 0.05). There was a significant positive correlation between the Basso-Beattie-Bresnahan scores and the number of normal neurons. The percentages of vacuolation areas in the SCI-15 group were significantly larger compared with those in the SCI-12 and sham groups (30% +/- 10% versus 9% +/- 7%, 0% +/- 0%, P < 0.05). Immunohistochemical analysis revealed increased amyloid precursor protein immunoreactivity in the swollen axons, especially in the SCI-15 group. There was a significant negative correlation between the number of normal neurons and percentages of vacuolation areas. These results indicate that both gray and white matter were injured after SCI in rats and the degree of white mater injury was correlated with the severity of gray matter injury after a relatively short recovery period.     

大鼠脊髓损伤后巢蛋白在脊髓组织中的表达

目的探讨大鼠脊髓损伤后巢蛋白(nestin)的表达规律及其意义。方法30只Wister成年大鼠,随机分为正常对照组(A组)、损伤组(B组)。采用Allen打击模型(25g·cm),在T10段造成急性脊髓损伤,于损伤后1d、3d、1周、4周、8周进行取材,对距离损伤中心5mm处脊髓进行nestin免疫组化检测。应用图像分析软件进行nestin阳性区域面积侧算。结果A组脊髓室管膜细胞只可见极少数细胞胞浆内nestin表达,白质中几乎无表达。B组中nestin于损伤后24h表达于室管膜以及软膜,灰质和白质亦有少量表达,1周达到高峰(P<0.05),4周明显下降,8周时很少或几乎无表达。结论脊髓组织的许多部位可能存在具有分化和更新潜能的祖细胞,脊髓损伤后这些细胞被激活,在功能恢复中可能发挥着重要的作用。     

Reevaluation of Gray and White Matter Injury after Spinal Cord Ischemia in Rabbits

Background: Although gray matter injury has been well characterized, the available data on white matter injury after spinal cord ischemia (SCI) in rabbits are limited. The current study was conducted to investigate the evolution of ischemia induced injury to gray and white matter and to correlate this damage to hind-limb motor function in rabbits subjected to SCI.

Methods: Thirty-eight rabbits were randomly assigned to 24-h, 4-day, or 14-day reperfusion groups or a sham group (n = 9 or 10 per group). SCI was induced by occlusion of the infrarenal aorta for 16 min. Hind-limb motor function was assessed using the Tarlov scale (0 = paraplegia, 4 = normal). The gray matter damage was assessed on the basis of the number of normal neurons in the anterior spinal cord. White matter damage was assessed on the basis of the extent of vacuolation and accumulation of amyloid precursor protein immunoreactivity.

Results: Tarlov scores gradually decreased and reached a nadir 14 days after reperfusion. There were no significant differences in the number of normal neurons among the 24-h, 4-day, and 14-day groups. The extent of vacuolation, expressed as a percent of total white matter area, was significantly greater in the 4-day and 14-day groups in comparison with the sham group. By contrast, there was no difference in vacuolation between the sham and 24-h groups. Amyloid precursor protein immunoreactivity was greater in the 4-day and 14-day groups.     

TGF-beta1 and TGF-beta2 expression after traumatic human spinal cord injury

STUDY DESIGN: Immunohistochemical investigation in control and lesioned human spinal cords. OBJECTIVES: To assess the spatial and temporal expression patterns of transforming growth factor-beta1 and -beta2 (TGF-beta1 and TGF-beta2) in the human spinal cord after traumatic injury. SETTING: Germany, Aachen, Aachen University Hospital. METHODS: Sections from human spinal cords from 4 control patients and from 14 patients who died at different time points after traumatic spinal cord injury (SCI) were investigated immunohistochemically. RESULTS: In control cases, TGF-beta1 was confined to occasional blood vessels, intravascular monocytes and some motoneurons, whereas TGF-beta2 was only found in intravascular monocytes. After traumatic SCI, TGF-beta1 immunoreactivity was dramatically upregulated by 2 days after injury (the earliest survival time investigated) and was detected within neurons, astrocytes and invading macrophages. The staining was most intense over the first weeks after injury but gradually declined by 1 year. TGF-beta2 immunoreactivity was first detected 24 days after injury. It was located in macrophages and astrocytes and remained elevated for up to 1 year. In white matter tracts undergoing Wallerian degeneration, there was no induction of either isoform. CONCLUSION: The early induction of TGF-beta1 at the point of SCI suggests a role in the acute inflammatory response and formation of the glial scar, while the later induction of TGF-beta2 may indicate a role in the maintenance of the scar. Neither of these TGF-beta isoforms appears to contribute to the astrocytic scar formation in nerve fibre tracts undergoing Wallerian degeneration.     

The role of excitotoxicity in secondary mechanisms of spinal cord injury: a review with an emphasis on the implications for white matter degeneration

Following an initial impact after spinal cord injury (SCI), there is a cascade of downstream events termed 'secondary injury', which culminate in progressive degenerative events in the spinal cord. These secondary injury mechanisms include, but are not limited to, ischemia, inflammation, free radical-induced cell death, glutamate excitotoxicity, cytoskeletal degradation and induction of extrinsic and intrinsic apoptotic pathways. There is emerging evidence that glutamate excitotoxicity plays a key role not only in neuronal cell death but also in delayed posttraumatic spinal cord white matter degeneration. Importantly however, the differences in cellular composition and expression of specific types of glutamate receptors in grey versus white matter require a compartmentalized approach to understand the mechanisms of secondary injury after SCI. This review examines mechanisms of secondary white matter injury with particular emphasis on glutamate excitotoxicity and the potential link of this mechanism to apoptosis. Recent studies have provided new insights into the mechanisms of glutamate release and its potential targets, as well as the downstream pathways associated with glutamate receptor activation in specific types of cells. Evidence from molecular and functional expression of glutamatergic AMPA receptors in white matter glia (and possibly axons), the protective effects of AMPA/kainate antagonists in posttraumatic white matter axonal function, and the vulnerability of oligodendrocytes to excitotoxic cell death suggest that glutamate excitotoxicity is associated with oligodendrocyte apoptosis. The latter mechanism appears key to glutamatergic white matter degeneration after SCI and may represent an attractive therapeutic target.     

Creatine diet supplement for spinal cord injury: influences on functional recovery and tissue sparing in rats

Creatine-supplemented diet significantly attenuates cortical damage after traumatic brain injury in rodents. The protective mechanism likely involves maintenance of mitochondrial homeostasis. In the present study, we used two separate contusion spinal cord injury (SCI) instruments--the NYU device and the PSI Infinite Horizon (IH) impactor--to assess the efficacy of creatine-supplemented diets on hind limb functional recovery and tissue sparing in adult rats. Rats were fed control versus 2% creatine-supplemented chow for 4-5 weeks prior to SCI (pre-fed), after which most resumed a control diet while some remained on a 2% creatine diet (pre & post-fed). Following long-term behavioral analysis (BBB), the amount of spared spinal cord tissue among the dietary regimen groups was assessed using stereology. Comparatively, both instruments caused similar amounts of gray matter damage while the NYU device rendered a greater loss of white matter, reflected in more severe hind limb functional deficits than with the IH impactor. Relative to the control fed groups injured with either instrument, none of the creatine fed animals showed improvements in hind limb function or white matter tissue sparing. Although creatine did not attenuate gray matter loss in the NYU cohort, it significantly spared gray matter in the IH cohort with pre-fed and pre & post-fed regimens. Such selective sparing of injured spinal cord gray matter with a dietary supplement yields a promising strategy to promote neuroprotection after SCI. The relationship between the efficacy of creatine and the magnitude of the insults is discussed.     

神经生长导向因子Slit2在成年大鼠急性脊髓损伤后的表达

目的观察Slit2在大鼠急性脊髓损伤后不同时点表达量的变化和分布，探讨轴突再生导向机制。方法成年SD大鼠采用Allen’s法制作脊髓损伤（SCI）模型，分别于损伤后第2、4、7、14天取材，半定量逆转录-聚合酶链反应（RT-PCR）分析Sht2 mRNA表达水平变化，免疫组织化学法观察Slit蛋白在损伤脊髓区的分布情况。结果RT—PCR提示脊髓损伤后Slit2即开始出现转录上调，表达量持续增高并于第7天达到顶峰，之后逐步下降；免疫组织化学提示Slit2阳性信号先后出现在急性SCI区灰质胶质细胞及神经元胞质中，以前、后角及中央管周围较为聚集。结论大鼠SCI后有Slit2表达上调出现并在损伤脊髓灰质广泛分布，可能是轴索再生过程中生长锥导向性生长的关键调节者。     

Diffusion tensor imaging predicts hyperacute spinal cord injury severity

Experimental strategies that focus on ventral white matter (VWM) preservation during the hyperacute phase hold great potential for our improved understanding of functional recovery following traumatic spinal cord injury (SCI). Critical comparisons of human SCI to rapidly accumulating data derived from rodent models are limited by a basic lack of in vivo measures of subclinical pathophysiologic changes and white matter damage in the spinal cord. Spinal cord edema and intraparenchymal hemorrhage demonstrated with routine MR sequences have limited value for predicting functional outcomes in SCI animal models and in human patients. We recently demonstrated that in vivo derived diffusion tensor imaging (DTI) parameters are sensitive and specific biomarkers for spinal cord white matter damage. In this study, non-invasive in vivo DTI was utilized to evaluate the white matter of C57BL/6 mice 3 h after mild (0.3 mm), moderate (0.6 mm), or severe (0.9 mm) contusive SCI. In the hyperacute phase, relative anisotropy maps provided excellent gray-white matter contrast in all degrees of injury. In vivo DTI-derived measurements of axial diffusion differentiated between mild, moderate, and severe contusive SCI with good histological correlation. Cross-sectional regional measurements of white matter injury severity between dorsal columns and VWM varied with increasing cord displacement in a pattern consistent with spinal cord viscoelastic properties.     

Simultaneous application of two neurotrophic factors after spinal cord injury

We have studied the application of voltage gradients to injured spinal cord which enhanced regeneration of axons and reduced their retrograde degeneration after injury. This led to an implanted electronic device producing electrical fields sufficient to induce regeneration in both ascending and descending tracts of white matter (called oscillating field stimulation [OFS]), which has been associated with behavioral recovery in animal models of spinal cord injury (SCI). OFS has also proven to benefit neurologically complete spinal cord injured dogs and humans in clinical trials. These studies, however, have failed to confirm benefit if applied after the sub-acute period of SCI. Here we report on combining OFS with the application of a non-toxic neurotrophic factor, inosine, using a behavioral model for "chronic" SCI, the cutaneous trunci muscle (CTM) reflex in adult guinea pigs. Inosine was delivered subcutaneously in guinea pigs for 28 days using implantable "osmotic pumps"--alone or in combination with OFS. In all animals, experimental and control treatments were withheld for three months after a right lateral hemisection of the thoracic spinal cord. Both inosine and the combination therapy produced a statistically significant recovery of CTM receptive fields silenced permanently by spinal cord hemisection in controls--though the combination therapy enhanced the time of the appearance of recovered regions of skin. Retransection of the cord in three recovered animals eliminated the CTM recovery confirming changes in neural connections were restricted to the cord and not due to changes in cutaneous peripheral innervation. Morphometry of anterogradely labeled white matter revealed a statistically enhanced regeneration of ascending and descending projections in animals treated with the combination "therapy" compared to inosine alone. These data suggest that combining neurotrophic factors of differing modes of action likely enhance the outcome from "chronic" SCI.     

Paraplegic mice are leading to new advances in spinal cord injury research

STUDY DESIGN: Experimental laboratory investigations with paraplegic mouse models. OBJECTIVES: To review the most recent advances in the field of spinal cord injury research; immune system response, regeneration, and functional recovery.Settings:Laval University and Laval University Medical Center, Quebec, Canada. METHODS: Assessment of regenerative processes and locomotor function recovery induced by a variety of treatments and approaches in wild-type and genetically engineered mice with complete or incomplete lesions of the spinal cord. RESULTS: Recent studies have reported a number of significant observations providing additional insight into the role and mechanism of regeneration, immune system response, and functional recovery after spinal cord injury (SCI) using incomplete paraplegic mice with Nogo-A, NgR, EphA4, GFAP/vimentime, LIF, or Fas gene knock-out. A novel antibody called CXCL10 was also recently found to increase tissue sparing and angiogenesis after SCI. In an attempt to explore the possibilities of reactivating spared neurons below the injury level, researchers have found that pharmacological activation of specific subtypes of serotonin receptors (eg, 5-HT1A/2A/7) can sustain the production of basic locomotor-like movements in complete paraplegic mice. CONCLUSION: The growing availability of genetically engineered and mutant mouse strains along with molecular biology tools has led scientists to increasingly use murine models in SCI research. These new tools and models may assist scientists in understanding further the complex pathological consequences of SCI.     

Cellular localization of tumor necrosis factor-alpha following acute spinal cord injury in adult rats

Posttraumatic inflammatory reaction may contribute to secondary injury after traumatic spinal cord injury (SCI). Expression of tumor necrosis factor-alpha (TNF-alpha), a key inflammatory mediator, has been demonstrated in the injured cord. However, the specific cell types that are responsible for TNF-alpha expression after SCI remain to be identified. In the present study, cellular sources of TNF-alpha were examined in rats that received a spinal cord impact injury at the 9th thoracic (T9) level. Here we demonstrate that, within hours after SCI, increased TNF-alpha immunoreactivity was localized in neurons, glial cells (including astrocytes, oligodendrocytes, and microglia), and endothelial cells in areas of the spinal cord adjacent to the lesion site. Myelin breakdown was noted in oligodendrocytes that are immunopositive for TNF-alpha. In sham-operated controls, a low level of TNF-alpha immunoreactivity was detected. In antigen-absorption experiments, no TNF-alpha immunoreactivity was detected, indicating the specificity of TNF-alpha immunocytochemistry in the present study. Results suggest that various cell types, including neurons, glial cells, and vascular endothelial cells, contribute to TNF-alpha production in the injured cord.     

大鼠胚胎脊髓移植对损伤脊髓GAP-43 mRNA表达的影响

目的观察大鼠胚胎脊髓移植对损伤脊髓 GAP－ 43 mRNA表达和大鼠后肢功能恢复的影响。方法成年 Wistar大鼠 66只,随机被分为脊髓半切洞损伤应用胚胎脊髓移植组 (脊髓移植组, 30只 )、单纯脊髓半切洞损伤明胶海绵填充组 (单纯损伤组, 30只 )、正常对照组 (6只 )。术后第 1、 3、 7、 14、 28 d,对大鼠进行 Tarlov评分和斜板试验检查后肢功能。应用原位杂交的方法观察 GAP－ 43 mRNA的表达,记录阳性细胞数,采用计算机图像分析技术,进行定量分析。结果脊髓损伤后第 1 d,在脊髓移植组和单纯损伤组的损伤脊髓灰质中都可见到 GAP－ 43 mRNA的表达。于损伤后迅速增加,第 7 d时达到高峰。脊髓移植组 GAP－ 43 mRNA蛋白表达为 39.24± 6.83,约是单纯损伤组 (21.48± 7.83)的 2倍 (P< 0.05)。胚胎脊髓移植后可使损伤的脊髓中 GAP－ 43 mRNA持续高表达至术后第 28 d,而单纯损伤组仅持续到术后第 14 d。增加的 GAP－ 43 mRNA阳性细胞数与神经功能的改善平行。结论胚胎脊髓移植后可使损伤大鼠脊髓高表达 GAP－ 43 mRNA,并促进大鼠功能的恢复。     

大鼠脊髓腹侧左迫损伤后神经营养素及受体表达的变化规律

目的：探讨脊髓损伤后脊髓功能恢复的分子生物学基础。方法：在制作脊髓腹侧压迫损伤的基础上,应用免疫组织化学的方法观察几种神经营养素及其受体表达的变化规律。结果：脊髓腹侧压迫损伤后BDNF,GNDF,NT3,NGF以及TrkA,TrkB,TrkC在伤后3h表达开始增加,伤后72h达到高峰,在伤后2周内其表达维持在相对较高的水平,且以BDNF及TrkB表达最明显。结论：脊髓损伤后这些内源性神经营养素及其受体的大量表达对受损伤脊髓的功能恢复起重要作用。同时也反映了受试动物的脊髓功能受损较重的特点。     

Delayed intrathecal delivery of RhoA siRNA to the contused spinal cord inhibits allodynia, preserves white matter, and increases serotonergic fiber growth

RhoA is a key regulator of the actin cytoskeleton that is upregulated after spinal cord injury (SCI). We analyzed different methods for siRNA delivery and developed siRNAs targeting RhoA (siRhoA) for SCI treatment. Cy 3.5-labeled siRNA delivered at the time of SCI yielded fluorescence in several cell types in the injury site. Intraspinal injections of chemically stabilized siRhoA into the spinal cord of injured rats reduced RhoA protein levels after 1 week and improved hindlimb walking over 6 weeks. To explore a less invasive route, we tested intrathecal injection of Cy 3.5-labeled siRNA via lumbar puncture 1 day after SCI, which resulted in robust uptake in the T9-T10 injury site. Lumbar injection of siRhoA 1 day after SCI reduced RhoA mRNA and protein levels 3 days after injection. Although siRhoA treatment did not yield significant improvement in locomotion, it decreased tactile hypersensitivity significantly compared to controls. Histological analysis at 8 weeks showed significant improvement in white matter sparing with siRhoA compared to control siRNA. siRhoA treatment also resulted in less accumulation of ED1+macrophages, increased PKC-γ immunoreactivity in the corticospinal tract rostral to the injury site, and increased serotonergic fiber growth 12 mm caudal to the contusion site. The ability of siRhoA to preserve white matter and promote serotonergic axonal regrowth caudal to the injury site is likely to suppress allodynia. This provides justification for considering clinical development of RhoA inhibitors to treat SCI sub-acutely to reduce allodynia, which occurs frequently in SCI patients.     

Behavioral and histological characterization of unilateral cervical spinal cord contusion injury in rats

Most experimental studies of spinal cord injury (SCI) in rats damage the thoracic cord, with the consequent functional loss being due to interruption of long tracts connecting the caudal spinal cord to the rostral nervous system. Less work has been done evaluating injury to the cervical cord, even though it is the most common level of human SCI. In addition to the long tracts, the cervical spinal cord contains the sensory and motor neurons responsible for upper extremity function. The purpose of this study was to further develop a rat model of cervical spinal cord contusion injury using a modified NYU/MASCIS weight drop device. Mild (6.25 mm) and moderate (12.5 mm) C5 unilateral injuries were produced. Behavioral recovery was examined using a grooming test, a paw preference test, a walkway test (The Catwalk), and a horizontal ladder test. Histological outcome measures included sparing at the lesion epicenter, sparing throughout the extent of the lesion, quantification of myelin loss rostral and caudal to the lesion, and motor neuron counts. Compared to controls, animals receiving SCI exhibited injury severity-specific deficits in forelimb, locomotor, and hindlimb function persisting for 6-weeks post-SCI. Histological analysis revealed ipsilateral containment of the injury, and differentiation between groups on all measures except motor neuron counts. This model has many advantages: (1) minimal animal care requirements post-SCI, (2) within subject controls, (3) functional loss involves primarily the ipsilateral forelimb, and (4) it is a behavioral and histological model for both gray and white matter damage caused by contusive SCI.     

G. Heiner Sell memorial lecture: neuronal plasticity after spinal cord injury: significance for present and future treatments

Recent progress in the understanding of movement control allows us to define more precisely the requirements for successful rehabilitation of patients with neurologic deficits after a spinal cord injury (SCI). Load- and hip joint position-related afferent input seems to be of crucial importance for the generation and success of locomotor training. In addition, there is accumulating evidence from animal experiments that axonal regeneration can be induced after a SCI. Consequently, in the near future, new therapeutic approaches will be developed for the treatment of subjects with SCI. Functional training and regeneration represent complimentary approaches. Regenerating spinal tract fibers needs functional training to make the appropriate connections, and training effects will be enhanced by regenerating fibers. A clinical basis for monitoring the effects of novel interventional therapies is needed. Refined and combined clinical and neurophysiologic measures are needed for a precise qualitative and quantitative assessment of spinal cord function in patients with SCI at an early stage. This is a basic requirement for predicting functional outcome, as well as for recognizing any improvement in the recovery of function caused by a new treatment. To this aim, 14 European spinal cord injury centers involved in the rehabilitation of patients with acute SCI have built a close clinical collaboration using a standardized protocol for the assessment of the outcome after SCI and the extent of recovery achieved by actually applied therapies in a larger population of patients with SCI.     

Changes in nitric oxide synthase expression in young and adult rats after spinal cord injury

OBJECTIVE: To examine the clinical meaning of the changes in nitric oxide synthase (NOS) expression and activity after spinal cord injury (SCI) according to the age of the experiment animal. MATERIAL AND METHOD: Ten 5- and 16-week-old Sprague-Dawley rats were laminectomized at T10 and SCI induced at this level using a New York impactor. Outcome measures to assess SCI utilized the Basso-Beatti-Bresnahan scale to quantitate hind limb motor dysfunction as a functional outcome measure. NOS isoforms (nNOS, neuronal NOS; iNOS, inducible NOS; and eNOS, endothelial NOS) were also immunolocalized in sections of control and spinal cord injury in the two sample groups using specific monoclonal antibodies. Student's t-test evaluated the difference between the young and adult rats, and P<0.05 was considered as significant value. RESULT: As the expression of nNOS on the spinal gray matter of the adult rat decreased, eNOS activity increased. Different from the adult rat, expression of the nNOS in the young rat was maintained until 1 day after SCI, and compared with the adult rat; eNOS activity was increased in the vessels from the damaged gray matter area after 7 days of SCI. iNOS expression was maintained until the 7th day of SCI on the adult rat, but iNOS expression after 7 days of SCI on young rat decreased. The young rat showed relatively less motor disability on the hind limb when compared with the adult rat, and had a rapid recovery. CONCLUSION: Neural protective eNOS activity increased after SCI in the young rat, and neural destructive iNOS expression was more remarkable in the adult rat.     

Nicotine attenuates morphological deficits in a contusion model of spinal cord injury

Protection against the progression of secondary injury appears to be an effective therapeutic strategy in spinal cord injury (SCI). Evidence indicates that nicotine can induce potent neuroprotective effects against injury to spinal cord neurons. Therefore, the present study was focused on the effects of nicotine on the behavioral and morphological recovery associated with SCI. Adult male Long-Evans rats were subjected to a moderate contusion model of SCI and received subcutaneous injections of nicotine for 14 days at the dose of 0.35 or 7 mg/kg/day. The rats were examined using the BBB locomotor rating scale for 6 weeks. At the end of the BBB recording, spinal cords were examined for the volumetric tissue sparing of gray and white matters. All SCI rats demonstrated a loss of hindlimb function followed by a recovery phase that peaked at 2-3 weeks after the trauma. Compared to untreated SCI rats, chronic nicotine administration appeared to improve the recovery of the locomotor functions. Indeed, nicotine-treated animals scored consistently higher on the BBB scale indicating that the treatment altered animal behavior. However, when taking under consideration correction factors for multiple comparisons, these data did not reach significance at overall experimental levels of significance 0.05. Nevertheless, nicotine administration was effective in sparing tissue at injury epicenter and a lower dose of nicotine also resulted in significant sparing of white matter of the injured spinal cord. These results suggest that agonists of neuronal nicotinic receptors can be attractive candidates for SCI therapy.