Distribution of Calretinin-Immunopositive Neurons in the Cat Lumbar Spinal Cord

Journal of Evolutionary Biochemistry and Physiology - A variety of neural networks in the central nervous system is determined by the heterogeneity of its constituent neuronal populations....     

Electrophysiology of the Fetal Spinal Cord : II. Interaction among peripheral inputs and recurrent inhibition

Interactions of peripheral inputs to the motoneuron of the kitten fetus as young as 3 weeks prenatal were studied by reflex discharge from the ventral root as well as by recording from single motoneurons. Facilitation was found between two synergists in fetuses 1 to 2 weeks before birth. Intracellular recording showed that the facilitation could be explained by summation of excitatory postsynaptic potentials. Inhibition was found between antagonists in the fetuses 2 to 3 weeks before birth and was accompanied by inhibitory postsynaptic potentials. Recurrent inhibition was very powerful in the fetal spinal cord as shown by large motoneuron hyperpolarization by antidromic stimulation. Cells presumed to be "Renshaw cells" and which responded to both ortho- and antidromic stimulation with repetitive firing were shown in the 2 weeks prenatal fetus. These results lead to the conclusion that there is considerable effective synaptic connection of afferent collaterals already established by the later stage of intrauterine life and that this may be achieved independently of external stimuli.     

猫腰髓白质年龄相关的形态学变化

以青年成年猫(1-3龄,2-2．5 kg)和老年猫(12龄,3-3．5kg)L6段脊髓白质为研究对象,用 神经丝蛋白(NF)免疫染色显示神经纤维,用改良的Holzer结晶紫染色显示所有胶质细胞并用成年动物Golgi 法显示其形态,用胶质纤维酸性蛋白(GFAP)免疫染色显示星形胶质细胞。光镜下对青年猫与老年猫腰髓白质 中神经纤维和胶质细胞进行形态学观察和定量研究。与青年猫相比,老年猫腰髓白质中的神经纤维密度显著下 降(P相似文献   

Effect of Electroacupuncture on Neurotrophin Expression in Cat Spinal Cord after Partial Dorsal Rhizotomy

Neuroplasticity of the spinal cord following electroacupuncture (EA) has been demonstrated although little is known about the possible underlying mechanism. This study evaluated the effect of EA on expression of neurotrophins in the lamina II of the spinal cord, in cats subjected to dorsal rhizotomy. Cats received bilateral removal of L1–L5 and L7–S2 dorsal root ganglia (DRG, L6 DRG spared) and unilateral EA. They were sacrificed 7 days after surgery, and the L6 spinal segment removed and processed by immunohistochemistry and in situ hybridization histochemistry, to demonstrate the expression of neurotrophins. Significantly greater numbers of nerve growth factor (NGF) and neurotrophin-3 (NT-3) positive neurons, brain-derived neurotrophic factor (BDNF) immunoreactive varicosities and NT-3 positive neurons and glial cells were observed in lamina II on the acupunctured (left) side, compared to the non-acupunctured, contralateral side. Greater number of neurons expressing NGF mRNA was also observed on the acupunctured side. No signal for mRNA to BDNF and NT-3 was detected. The above findings demonstrate that EA can increase the expression of endogenous NGF at both the mRNA and protein level, and BDNF and NT-3 at the protein level. It is postulated that EA may promote the plasticity of the spinal cord by inducing increased expression of neurotrophins.     

Effects of a Single Intravenous Glucocorticoid Dose on Biogenic Amine Levels in Cat Lumbar Spinal Cord

Abstract: The effects of a single large intravenous dose of methylprednisolone on the steady state levels of dopamine, norepinephrine, and 5-hydroxytryptamine in cat lumbar spinal cord, as a function of dose (15, 30, or 90 mg/kg) and time (1 or 24 h) after administration, were examined by high performance liquid chromatography with electrochemical detection. Methylprednisolone produced a dose-related increase in the levels of dopamine and 5-hydroxytryptamine, but not norepinephrine, measured at 1 h. The effect of the single glucocorticoid dose was biphasic, however, as measurement of the three amines at 24 h showed each to be depressed below the levels found in untreated animals. The possible mechanistic basis and the significance of these glucocorticoid effects are discussed.     

Electron Microscopic Study of Demyelination in an Experimentally Induced Lesion in Adult Cat Spinal Cord

Plaques of subpial demyelination were induced in adult cat spinal cords by repeated withdrawal and reinjection of cerebrospinal fluid. Peripheral cord was fixed by replacing cerebrospinal fluid available at cisternal puncture with 3 per cent buffered OsO₄. Following extirpation, surface tissue was further fixed in 2 per cent buffered OsO₄, dehydrated in ethanol, and embedded in araldite. Normal subpial cord consists mainly of myelinated axons and two types of macroglia, fibrous astrocytes and oligodendrocytes. Twenty-nine hours after lesion induction most myelin sheaths are deteriorating and typical macroglia are no longer visible. Phagocytosis of myelin debris has begun. In 3-day lesions, axons are intact and their mitochondria and neurofibrils appear normal despite continued myelin breakdown. All axons are completely demyelinated by 6 days. They lack investments only briefly, however, for at 10 and 14 days, macroglial processes appear and embrace them. These macroglia do not resemble either one of the normally occurring glia; their dense cytoplasm contains fibrils in addition to the usual organelles. It is proposed that these macroglia, which later accomplish remyelination, are the hypertrophic or swollen astrocytes of classical neuropathology. The suggestion that these astrocytes possess the potential to remyelinate axons in addition to their known ability to form cicatrix raises the possibility of pharmacological control of their expression.     

Plasticity of the Injured Human Spinal Cord: Insights Revealed by Spinal Cord Functional MRI

Introduction

While numerous studies have documented evidence for plasticity of the human brain there is little evidence that the human spinal cord can change after injury. Here, we employ a novel spinal fMRI design where we stimulate normal and abnormal sensory dermatomes in persons with traumatic spinal cord injury and perform a connectivity analysis to understand how spinal networks process information.

Methods

Spinal fMRI data was collected at 3 Tesla at two institutions from 38 individuals using the standard SEEP functional MR imaging techniques. Thermal stimulation was applied to four dermatomes in an interleaved timing pattern during each fMRI acquisition. SCI patients were stimulated in dermatomes both above (normal sensation) and below the level of their injury. Sub-group analysis was performed on healthy controls (n = 20), complete SCI (n = 3), incomplete SCI (n = 9) and SCI patients who recovered full function (n = 6).

Results

Patients with chronic incomplete SCI, when stimulated in a dermatome of normal sensation, showed an increased number of active voxels relative to controls (p = 0.025). There was an inverse relationship between the degree of sensory impairment and the number of active voxels in the region of the spinal cord corresponding to that dermatome of abnormal sensation (R² = 0.93, p<0.001). Lastly, a connectivity analysis demonstrated a significantly increased number of intraspinal connections in incomplete SCI patients relative to controls suggesting altered processing of afferent sensory signals.

Conclusions

In this work we demonstrate the use of spinal fMRI to investigate changes in spinal processing of somatosensory information in the human spinal cord. We provide evidence for plasticity of the human spinal cord after traumatic injury based on an increase in the average number of active voxels in dermatomes of normal sensation in chronic SCI patients and an increased number of intraspinal connections in incomplete SCI patients relative to healthy controls.     

Survey of Intermediate Filament Proteins in Optic Nerve and Spinal Cord: Evidence for Differential Expression

The distribution of intermediate filament proteins in optic nerve and spinal cord from rat, hamster, goldfish, frog, and newt were analyzed by two-dimensional gel electrophoresis. General as well as specific monoclonal and polyclonal antibodies were reacted against putative intermediate filament proteins. In vitro incubations of excised optic nerve in the presence of [35S]methionine distinguished between neuronal and nonneuronal intermediate filament proteins. The proteins of the intermediate filament complex in the two tissues for rat and hamster were similar. The typical neurofilament triplet and glial fibrillary acidic protein (GFAP) were observed. Vimentin was more concentrated in the optic nerve than in the spinal cord. The goldfish, newt, and frog contained neurofilament proteins in the 145-150K range and in the 70-85K range. In addition, predominant neurofilament proteins in the 58-62K molecular-weight range were found in all three species. In contrast to mammalian species, the goldfish, newt, and frog displayed extensive heterogeneity between optic nerve and spinal cord in the expression of both neuronal and nonneuronal intermediate filament proteins. The distinctive presence of low-molecular-weight intermediate filament proteins and their high concentration in the optic nerve and spinal cord of these nonmammalian vertebrates is discussed in terms of neuronal development and regeneration.     

Protective Effect of Mild Hypothermia on Spinal Cord Ischemia-Induced Delayed Paralysis and Spinal Cord Injury

Neurochemical Research - To explore the mechanism regarding the regulation of spinal cord ischemia (SCI) in rats by mild hypothermia. A SCI rat model was established through aorta occlusion, and in...     

Effects of Embryonic Neural Stem Cell Transplantation on DNA Damage in the Brain and Spinal Cord Following Spinal Cord Injury

Embryonic neural stem cell (ENSC) transplantation is used experimentally for the improvement of spinal cord repair following spinal cord injury (SCI). However, the effects of such intervention on oxidative stress and cell death remain unknown. We used in vivo Comet assay in the acute and chronic SCI groups compared with the SCI+ENSC transplantation groups of experimental rats in order to evaluate DNA damage in the spinal cord. Chronic SCI resulted in the generation of oxidative DNA damage in the spinal cord brain and kidneys, as indicated by high Comet assay parameters, including the percentage of DNA in the tail (T%, or TD), tail moment (TM), and tail length (TL). The DNA damage levels significantly decreased after ENSC transplantation in the spinal cords of acute and chronic SCI groups within the lesion site and rostrally and caudally to the injury, and in the brains and kidneys of the chronic SCI group. Thus, ENSC transplantation is found to be an effective tool for limitation of DNA damage following spinal cord injury.     

Time Course of Immediate Early Gene Protein Expression in the Spinal Cord following Conditioning Stimulation of the Sciatic Nerve in Rats

Long-term potentiation induced by conditioning electrical stimulation of afferent fibers is a widely studied form of synaptic plasticity in the brain and the spinal cord. In the spinal cord dorsal horn, long-term potentiation is induced by a series of high-frequency trains applied to primary afferent fibers. Conditioning stimulation (CS) of sciatic nerve primary afferent fibers also induces expression of immediate early gene proteins in the lumbar spinal cord. However, the time course of immediate early gene expression and the rostral-caudal distribution of expression in the spinal cord have not been systematically studied. Here, we examined the effects of sciatic nerve conditioning stimulation (10 stimulus trains, 0.5 ms stimuli, 7.2 mA, 100 Hz, train duration 2 s, 8 s intervals between trains) on cellular expression of immediate early genes, Arc, c-Fos and Zif268, in anesthetized rats. Immunohistochemical analysis was performed on sagittal sections obtained from Th13- L5 segments of the spinal cord at 1, 2, 3, 6 and 12 h post-CS. Strikingly, all immediate early genes exhibited a monophasic increase in expression with peak increases detected in dorsal horn neurons at 2 hours post-CS. Regional analysis showed peak increases at the location between the L3 and L4 spinal segments. Both Arc, c-Fos and Zif268 remained significantly elevated at 2 hours, followed by a sharp decrease in immediate early gene expression between 2 and 3 hours post-CS. Colocalization analysis performed at 2 hours post-CS showed that all c-Fos and Zif268 neurons were positive for Arc, while 30% and 43% of Arc positive neurons were positive for c-Fos and Zif268, respectively. The present study identifies the spinal cord level and time course of immediate early gene (IEGP) expression of relevance for analysis of IEGPs function in neuronal plasticity and nociception.     

Differential Expression of Micro-Heterogeneous LewisX-Type Glycans in the Stem Cell Compartment of the Developing Mouse Spinal Cord

Complex glycan structures and their respective carrier molecules are often expressed in a cell type specific manner. Thus, glycans can be used for the enrichment of specific cell types such as neural precursor cells (NPCs). We have recently shown that the monoclonal antibodies 487^LeX and 5750^LeX differentially detect the LewisX (LeX) glycan on NPCs in the developing mouse forebrain. Here, we analysed the staining pattern of both antibodies during late embryonic mouse spinal cord development. At E13.5 both antibodies strongly label the central canal region. Along these lines they detect the LeX glycan primarily on Nestin-positive NPCs at that age. Moreover, we show that spinal cord NPCs cultured as free floating neurospheres display a high immunoreactivity to both antibodies. In that context, we also demonstrate that the 487^LeX antibody can be used to deplete a subpopulation of neurosphere forming NPCs from a mixed E13.5 spinal cord cell suspension. Towards the end of embryogenesis the overall immunoreactivity to both antibodies increases and the staining appears very diffuse. However, the 5750^LeX antibody still labels the central canal region. The increase in immunoreactivity correlates with an expression increase of the extracellular matrix molecules Tenascin C and Receptor Protein Tyrosine Phosphatase β/ζ, two potential LeX carrier proteins. In line with this, immunoprecipitation analyses confirmed Tenascin C as a LeX carrier protein in the embryonic mouse spinal cord. However, the immunoreactivity to both antibodies appears only to be marginally affected in the absence of Tenascin C, arguing against Tenascin C being the major LeX carrier. In conclusion our study gives some novel insights into the complex expression of LeX glycans and potential carrier proteins during the development of the mouse spinal cord.