Sensorimotor Cortex Of Adult Rats Research Articles

Chronological Changes in Astrocytes Induced by Chronic Electrical Sensorimotor Cortex Stimulation in Rats

Motor cortex stimulation (MCS) is a treatment option for various disorders such as medically refractory pain, poststroke hemiplegia, and movement disorders. However, the exact mechanisms underlying its effects remain unknown. In this study, the effects of long-term chronic MCS were investigated by observing changes in astrocytes. A quadripolar stimulation electrode was implanted on the dura over the sensorimotor cortex of adult rats, and the cortex was continuously stimulated for 3 hours, 1 week, 4 weeks, and 8 weeks. Immunohistochemical staining of microglia (ionized calcium-binding adaptor molecule 1 [Iba1] staining) and astrocytes (glial fibrillary acidic protein [GFAP] staining), and neuronal degeneration histochemistry (Fluoro-Jade B staining) were carried out to investigate the morphological changes following long-term chronic MCS. Iba1 staining and Fluoro-Jade B staining showed no evidence of Iba1-positive microglial changes or neurodegeneration. Following continuous MCS, GFAP-positive astrocytes were enlarged and their number increased in the cortex and the thalamus of the stimulated hemisphere. These findings indicate that chronic electrical stimulation can continuously activate astrocytes and result in morphological and quantitative changes. These changes may be involved in the mechanisms underlying the neuroplasticity effect induced by MCS.

Effects of incisor extraction on jaw and tongue motor representations within face sensorimotor cortex of adult rats

Loss of teeth is associated with changes in somatosensory inputs and altered patterns of mastication, but it is unclear whether tooth loss is associated with changes in motor representations within face sensorimotor cortex of rats. We used intracortical microstimulation (ICMS) and recordings of cortically evoked muscle electromyographic (EMG) activities to test whether changes occur in the ICMS-defined motor representations of the left and right jaw muscles [masseter, anterior digastric (LAD, RAD)] and tongue muscle [genioglossus (GG)] within the cytoarchitectonically defined face primary motor cortex (face-M1) and adjacent face primary somatosensory cortex (face-S1) 1 week following extraction of the right mandibular incisor in anesthetized (ketamine-HCl) adult male Sprague-Dawley rats. Under local and general anesthesia, an "extraction" group (n = 8) received mucoalveolar bone surgery and extraction of the mandibular right incisor. A "sham-extraction" group (n = 6) received surgery with no extraction. A "naive" group (n = 6) had neither surgery nor extraction. Data were compared by using mixed-model repeated-measures ANOVA. Dental extraction was associated with a significantly increased number of sites within face-M1 and face-S1 from which ICMS evoked RAD EMG activities, a lateral shift of the RAD and LAD centers of gravity within face-M1, shorter onset latencies of ICMS-evoked GG activities within face-M1 and face-S1, and an increased number of sites within face-M1 from which ICMS simultaneously evoked RAD and GG activities. Our novel findings suggest that dental extraction may be associated with significant neuroplastic changes within the rat's face-M1 and adjacent face-S1 that may be related to the animal's ability to adapt to the altered oral state.

Sensorimotor cortex aspiration: A model for studying Wallerian degeneration-induced glial reactivity along the entire length of a single CNS axonal pathway

Although there are some similarities in the molecular and cellular pattern of Wallerian degeneration in the PNS and CNS, in the CNS the removal of axonal and myelin debris by microglia and astrocytes is not very efficient and occurs over a much longer time frame than seen in a peripheral nerve. Several animal models have been used to study Wallerian degeneration-induced glial reactivity in the CNS and PNS. Although these models have clarified some aspects of the mechanisms underlying the differential glial cell responses in the PNS and CNS, they do not lend themselves easily to deciphering the mechanisms governing the location and extent of Wallerian degeneration-induced CNS glial reactivity. The present study develops a new animal model that entails destruction of the left sensorimotor cortex of adult rats to induce Wallerian degeneration within the total length of a fiber tract (i.e. the dorsal corticospinal tract) that extends all the way from the cerebral cortex to the sacral level of the spinal cord. Since the axonal degeneration in the ventral medulla and dorsal funiculus of the spinal cord would be confined to the corticospinal tract, it was predicted the glial reactivity would also be restricted to this fiber tract. Three distinct proximal–distal levels of this pathway were examined to determine the morphology, distribution and immunophenotype of microglia and astrocytes between 1 day and 16 weeks after sensorimotor cortex aspiration. As expected, there was a proximal to distal gradient in the appearance of glial reactivity along the length of the pathway, with the microglial reactivity being seen as early as 3 weeks in the left pyramid, and by 4 weeks (i.e. at C6) and 6 weeks (i.e. at T11) in the right dorsal corticospinal tract. Astrocytic reactivity lagged behind that of the microglial response at each level of the pathway. The microglial and astrocytic reactivity persisted up to 16 weeks after cortical injury, which was the longest survival time studied. The sensorimotor cortex aspiration model should prove extremely useful in deciphering the molecular mechanisms controlling Wallerian degeneration-induced CNS glial reactivity and in determining the relative role of astrocytes vs microglia in clearance of axonal and myelin debris.

Chronic Cortical Injury and Epileptogensis: A Possible Role for Intracellular Chloride Homeostasis

Impaired Cl– Extrusion in Layer V Pyramidal Neurons of Chronically Injured Epileptogenic Neocortex Jin X, Huguenard JR, Prince DA J Neurophysiol 2005;93:2117–2126 In the mature brain, the K+/Cl– cotransporter KCC2 is important in maintaining low [Cl–]i, resulting in hyperpolarizing GABA responses. Decreases in KCC2 after neuronal injuries result in increases in [Cl–]i and enhanced neuronal excitability due to depolarizing GABA responses. We used the gramicidin perforated-patch technique to measure ECl(∼ EGABA) in layer V pyramidal neurons in slices of partially isolated sensorimotor cortex of adult rats to explore the potential functional consequence of KCC2 downregulation in chronically injured cortex. EGABA was measured by recording currents evoked with brief GABA puffs at various membrane potentials. No significant difference was found in ECl between neurons in control and undercut animals (–71.2 ± 2.6 and −71.8 ± 2.8 mV, respectively). However, when loaded with Cl– by applying muscimol puffs at 0.2 Hz for 60 seconds, neurons in the undercut cortex had a significantly shorter time constant for the positive shift in ECl during the Cl– loading phase (4.3 ± 0.5 s for control and 2.2 ± 0.4 s for undercut; p < 0.01). The positive shift in ECl 3 seconds after the beginning of Cl– loading was also significantly larger in the undercut group than in the control, indicating that neurons in undercut cortex were less effective in maintaining low [Cl–]i during repetitive activation of GABAA receptors. Application of furosemide eliminated the difference between the control and undercut groups for both of these measures of [Cl–]i regulation. The results suggest an impairment in Cl– extrusion resulting from decreased KCC2 expression that may reduce the strength of GABAergic inhibition and contribute to epileptogenesis.

Impaired Cl−Extrusion in Layer V Pyramidal Neurons of Chronically Injured Epileptogenic Neocortex

In the mature brain, the K(+)/Cl- cotransporter KCC2 is important in maintaining low [Cl-]i, resulting in hyperpolarizing GABA responses. Decreases in KCC2 after neuronal injuries result in increases in [Cl-]i and enhanced neuronal excitability due to depolarizing GABA responses. We used the gramicidin perforated-patch technique to measure E(Cl) ( approximately E(GABA)) in layer V pyramidal neurons in slices of partially isolated sensorimotor cortex of adult rats to explore the potential functional consequence of KCC2 downregulation in chronically injured cortex. E(GABA) was measured by recording currents evoked with brief GABA puffs at various membrane potentials. There was no significant difference in E(Cl) between neurons in control and undercut animals (-71.2 +/- 2.6 and -71.8 +/- 2.8 mV, respectively). However, when loaded with Cl- by applying muscimol puffs at 0.2 Hz for 60 s, neurons in the undercut cortex had a significantly shorter time constant for the positive shift in E(Cl) during the Cl- loading phase (4.3 +/- 0.5 s for control and 2.2 +/- 0.4 s for undercut, P < 0.01). The positive shift in E(Cl) 3 s after the beginning of Cl- loading was also significantly larger in the undercut group than in the control, indicating that neurons in undercut cortex were less effective in maintaining low [Cl-]i during repetitive activation of GABA(A) receptors. Application of furosemide eliminated the difference between the control and undercut groups for both of these measures of [Cl-]i regulation. The results suggest an impairment in Cl- extrusion resulting from decreased KCC2 expression that may reduce the strength of GABAergic inhibition and contribute to epileptogenesis.

EM colocalization of AMPA and NMDA receptor subunits at synapses in rat cerebral cortex

Electrophysiology and light microscopy suggest that a single excitatory synapse may use both amino-3-hydroxy-5-methylisoxazole-4-propionate (AMPA) and N-methyl-d-aspartate (NMDA) receptors. Using immunogold electron microscopy, we here provide direct evidence for colocalization at individual synapses in sensorimotor cortex of adult rats. Colocalization was most commonly observed on dendritic spines; subunits of the two classes of receptors seemed to be independently distributed within the synaptic active zone.

Characterization of pharmacologically identified voltage-gated calcium channel currents in acutely isolated rat neocortical neurons. I. Adult neurons

1. Whole cell recordings were obtained from pyramidal neurons acutely dissociated from the sensorimotor cortex of adult rats. 2. Whole cell calcium channel currents were similar in appearance when elicited from holding potentials of -90 or -40 mV. With 5 mM Ba2+ as the charge carrier, currents began to activate at approximately -45 mV, peaked at approximately -10 mV, and had an apparent reversal potential of approximately +45 mV. Current amplitude and voltage dependence varied with the concentration and identity of the charge carrier (Ca2+ vs. Ba2+). Calcium channel currents were blocked completely by > 200 microM Cd2+ (IC50 approximately 3.5 microM). 3. We determined saturating doses for blockade of currents by nifedipine (Nif), omega-conotoxin GVIA (CgTx), and omega-agatoxin IVA (AgTx) in adult cells. We also tested the selectivity of these compounds by applying them in combination and in different orders. We found the three compounds to be highly, but not perfectly, specific. 4. L-type current was operationally defined as that blocked by 5 microM Nif, N-type current as that blocked by 1 microM CgTx, and P-type current as that blocked by 100 nM AgTx. In adult cells, each of these compounds blocked 30-35% of the current. When all three blockers were applied concurrently, approximately 80% of the current was blocked (20% of current was resistant to the 3 blockers). 5. Few biophysical differences were found between the pharmacologically defined current components in adult cells. The resistant current had a more rapid time-to-peak, inactivated more rapidly and completely, and activated at more negative potentials than the other three types.

Unilateral grafting of fetal neocortex into a cortical cavity improves healing of a symmetric lesion in the contralateral cortex of adult rats

Fetal neocortical tissue (ED 14) was grafted unilaterally into a cortical cavity made bilaterally in the sensorimotor cortex of adult rats. Transplantation was done immediately after the lesion (group TR 0, n = 8) or with 14-day delay (group TR 14, n = 8). Six rats served as lesion only controls (group LES). After long-term survival (up to 15 months) the brains were photographed and surface areas of transplant and contralateral cavities were measured by means of a graphic tablet. The results show that (a) the presence of a transplant in one lesion cavity in the cortex decrease the size of a similar cavity in the contralateral cortex and that (b) the better host transplant integration there is, the greater the effect on the contralateral lesion. No correlation between the size of the transplant and the size of the symmetric traumatic lesion was found. The ameliorating effect of the transplant on the contralateral cortical lesion size is most likely related to the long-term influence of growth or trophic factors released by transplanted cells which lead to the healing of the symmetric lesion.

Biochemical and anatomical analysis of cholinergic, noradrenergic and serotonergic innervation of fetal neocortical transplants placed in excitotoxin-induced neocortical lesions of adult rats

Fetal neocortical block transplants were implanted into the excitotoxically ablated sensorimotor cortex of adult rats in order to examine the density of innervation and distribution of presumptive host derived afferent fibers within these transplants. Cholinergic fiber innervation was examined at 3 months post grafting by measuring acetylcholinesterase (AChE) and choline acetyl-transferase (ChAT) enzyme activities within the grafts and within the corresponding host cortex by radiochemical enzyme assays as well as by AChE histochemistry for the visualization of AChE positive fibers. Noradrenergic and serotonergic inputs were examined by high performance liquid chromatography (HPLC) measurements of noradrenaline (NA) and serotonin (5-hydroxytryp-tamine, 5-HT) concentrations as well as by tyrosine hydroxylase (TH) and 5-HT immunocytochemistry for the visualization of monoaminergic fiber distribution. Our results demonstrated that the grafts contained significantly lower levels of neurotransmitter markers when compared to normal unablated cortex. The anatomical analysis showed an unequal fiber distribution within the transplants. Areas adjacent to the host tissue revealed a relatively dense fiber innervation when compared to the density observed within the more central parts of the transplants, and the anatomical data therefore supported the biochemical data in suggesting an overall lower cholinergic and monoaminergic innervation of fetal neocortical transplants placed into the lesioned adult cortex when compared to normal cortex.

Visualization of outgrowing axons of grafted neurons by anterograde labelling with Phaseolus vulgaris leucoagglutinin in the motor cortex of the rat

Fetal cerebral cortical tissue was transplanted into an aspirated lesion cavity made in the sensorimotor cortex of adult rats. Ten weeks after grafting, outgrowing fibers from the graft were visualized by an anterograde tracing technique using Phaseolus vulgaris leucoagglutinin (PHA-L). It was demonstrated that the efferent fibers grew into the neighboring host cortical tissue, the corpus callosum and in some cases approached caudate/putamen. Characteristic axon arborization with abundant boutons were found in the host cortical tissue, but only in close vicinity to the grafts. It is concluded that the PHA-L anterograde tracing technique can be a useful tool to assess the degree of anatomical integration of the transplants into the host tissue.