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A morphological study of naturally occuring and induced neuronal death in the developing spinal cord of the ratLawson, Simon John January 1997 (has links)
No description available.
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The contribution of population activity in motor cortex to the control of skilled hand movement in the primatePinches, Elizabeth Margery January 2000 (has links)
No description available.
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Plasticity of Brainstem Motor Systems in Response to Developmental Nicotine ExposureWollman, Lila Buls, Wollman, Lila Buls January 2017 (has links)
Developmental nicotine exposure (DNE) is known to cause abnormal development of multiple brain regions and results in impaired control of breathing and altered behaviors that rely on proper coordination of the muscles of the tongue. The adverse effects of nicotine are presumably caused by its actions on nicotinic acetylcholine receptors (nAChRs), which modulate fast-synaptic transmission and play a prominent role during brain development. Previous work has shown that DNE alters nAChR function in multiple brainstem regions (Pilarski et al., 2012, Wollman et al, 2016). Moreover, DNE causes multiple changes to XIIMNs, which innervate the muscles of the tongue (Powell et al., 2016, Powell et al., 2015, Pilarski et al., 2011). These changes likely reflect both altered development as a primary outcome of the chronic presence of nicotine, as well as, homeostatic adjustments made in an attempt to maintain normal motoneuron output. With the experiments described here, we tested the hypothesis that DNE alters the development of fast-synaptic transmission to XIIMNs, which, along with intrinsic properties of these neurons, is a main determinant of motor output to the muscles of the tongue. Additionally, we tested the hypothesis that DNE alters the function of nAChRs located on multiple brainstem neurons, including those that modulate fast-synaptic transmission to XIIMNs. For these experiments, we used whole cell patch clamp recordings from XIIMNs in a transverse slice of the medulla, and extracellular recordings from the 4th cervical ventral root in the brainstem spinal cord, split bath preparation. All preparations were obtained from control or DNE neonatal rats in the first week of life. Overall, the results of these experiments show that DNE alters fast-synaptic transmission to XIIMNs, which likely reflects appropriate homeostatic adjustments aimed at maintaining normal motor output at rest. However, these results also show that nAChR function is significantly altered by DNE, indicating fast-synaptic transmission may not be appropriately modulated in response to increased release of acetylcholine (ACh), the endogenous neurotransmitter for nAChRs.
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An HRP Study of the Spatial and Electrotonic Distribution of Group IA Synapses on Type-Identified Ankle Extensor Motoneurons in the CatBurke, R. E., Glenn, L. Lee 26 August 1996 (has links)
Eight functionally identified group Ia muscle afferents from triceps surae or plantaris muscles were labeled intraaxonally with horseradish peroxidase (HRP) in seven adult cats. Subsequently, HRP was injected into two to six homonymous or heteronymous alpha-motoneurons per animal (total = 22), each identified by motor unit type and located near the site of afferent injection. The complete trajectories of labeled afferents were reconstructed, and putative synaptic contacts on HRP-labeled motoneurons were identified at high magnification. Dendritic paths from each contact were also mapped and measured. A total of 24 contact systems (the combination of a group Ia afferent and a postsynaptic motoneuron) were reconstructed, of which 17 were homonymous, and seven were heteronymous. Overall, homonymous contact systems had an average of 9.6 boutons, whereas heteronymous contact systems had an average of 5.9 boutons. The average number of boutons found on type S motoneurons in homonymous contact systems was smaller (6.4, range 3-17) than in systems involving types FF or FR motoneurons (FF: 10.4, range 4-18; FR: 11.3, range 4-32). Neither of these differences were statistically significant. In contrast to earlier reports, a majority (15/24) of contact systems included more than one collateral from the same Ia afferent. The complexity (number of branch points) in the arborization pathway leading to each contact (overall mean 8.4 +/- 3.3) was virtually identical in all contact systems, irrespective of the type of postsynaptic motoneuron. The three-dimensional distribution of group Ia contacts was not coextensive with the radially organized dendrites of motoneurons: Dendrites oriented in the ventromedial to dorsolateral axis had the fewest (8%) contacts, whereas rostrocaudal dendrites had the most (63%) contacts. Nevertheless, contacts were widely distributed on the motoneuron surface, with few on and near the soma (< or = 200 microns radial distance from the soma) or on the most distal parts of the tree (> or = 1,000 microns). The boutons in individual contact systems also showed wide spatial and estimated electrotonic distributions; only 3/24 systems had all contact located within a restricted spatial/electrotonic region. The relations between these anatomical results and existing electrophysiological data on group Ia synaptic potentials are discussed.
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Mechanisms of Adaptive and Maladaptive Plasticity After Spinal Cord InjuryGoltash, Sara 08 January 2024 (has links)
Spinal cord injury (SCI) is a debilitating condition that disrupts the communication between the brain and the spinal cord. Several studies have sought to determine how to revive dormant spinal circuits caudal to the lesion to restore movements in paralyzed patients. So far, recovery levels in human patients have been modest at best. In contrast, animal models of SCI exhibit more recovery of lost function. Recovery of lost function could arise from structural changes in spinal circuits following spinal cord injury. Previous work from our lab has identified dI3 interneurons as a spinal neuron population central to the recovery of locomotor function in spinalized mice. We seek to determine the changes in the circuitry of dI3 interneurons and motoneurons following SCI in adult mice. After a complete transection of the spinal cord at T9-T11 level in transgenic Isl1:YFP mice and subsequent treadmill training at various time points of recovery following surgery, we examined changes in three key circuits involving dI3 interneurons and motoneurons: 1) Sensory inputs from proprioceptive and cutaneous afferents, 2) GABAergic inputs onto sensory afferents (GABApre), 3) Central excitatory glutamatergic synapses from spinal neurons onto dI3 INs and motoneurons. Furthermore, we examined the possible role of treadmill training on changes in synaptic connectivity to dI3 interneurons and motoneurons.
Our data suggests that sensory inputs from the periphery labelled by VGLUT1⁺ to dI3 interneurons decrease transiently or only at later stages after injury, whereas levels of VGLUT1⁺ remain the same for motoneurons after injury. Levels of central excitatory inputs labelled by VGLUT2⁺ to dI3 INs and MNs may show transient increases but fall below levels seen in sham-operated mice after a period of time. Levels of GABApre boutons onto the VGLUT1⁺ sensory afferents that project onto to dI3 INs and MNs can rise shortly after SCI, but those increases do not persist. However, levels of these GABApre boutons onto VGLUT1⁺ inputs never fell below levels observed in sham-operated mice. For some synaptic inputs studied, levels were higher in spinal cord-injured animals that received treadmill training, but these increases were observed only at some time points.
Changes in spinal circuitry could be maladaptive. For example, spasticity is a common consequence of SCI, disrupting motor function and resulting in significant discomfort. Spasticity may arise from maladaptive changes in spinal circuits. Current models of hindlimb spasticity are lacking, hindering the study of mechanisms or treatments of spasticity. Therefore, we have generated a novel mouse model of SCI-related spasticity that utilizes optogenetics to activate a subset of cutaneous VGLUT2⁺ sensory afferents to produce reliable incidences of hindlimb spasticity. To examine the efficacy of this optogenetic spasticity model, a T9-T10 complete transection injury was performed in Isl1-Vglut2ᒼᵃᵗᒼʰ mice, followed by the implantation of EMG electrodes into the left and right gastrocnemius and tibialis anterior muscles. Beginning at 9 days post-injury, EMG recordings were performed during episodic optogenetic stimulation. During each recording session, an optic fiber coupled to a 470nm wavelength LED was used to deliver light pulses to the palmar surface of each hindpaw. The results of these recordings demonstrated significant increases in the amplitude of EMG responses to the light stimulus from 2 weeks post-injury to 5 weeks post-injury, indicating hyperreflexia. Interestingly, this hyperreflexia was significantly greater in the female cohort in comparison to the males. Incidences of prolonged involuntary muscle contraction and clonus were also detected through EMG and visual observation during the testing period, supporting the presence of spasticity.
Overall, the results in my thesis suggest remodelling of spinal circuits involving spinal interneurons that have previously been implicated in the recovery of locomotor function after spinal cord injury in mice. In addition, we have developed an optogenetic mouse model that appears to reliably elicit spasticity in SCI mice and may be valuable for the study of SCI-related limb spasticity mechanisms due to the maladaptive changes within the spinal cord.
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SMALL CONDUCTANCE CALCIUM-ACTIVATED POTASSIUM (SK) CHANNELS IN MAMMALIAN SPINAL MOTONEURONSDeng, Zhihui 12 May 2009 (has links)
No description available.
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Cellular Function of the Ia-motoneuron Circuit Following Peripheral Nerve RegenerationBullinger, Katie Leigh 28 July 2009 (has links)
No description available.
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Estudio de la supervivencia de las motoneuronas del núcleo del VI par craneal de la rata tras la administración de toxina botulínica y doxorrubicina en el músculo recto lateralGómez Ramírez, Ana María 14 June 1996 (has links)
Objetivo:Investigar "in vivo" la supervivencia de las motoneuronas del núcleo del VI par craneal tras la inyección intramuscular de toxina botulínica tipo A (TxBA) y doxorrubicina (DXR).
Método: En el músculo recto lateral de las ratas se inyectó fluorogold(FG) y se determinó el número de motoneuronas del núcleo del VI par craneal. Tras el marcaje con FG de dichas motoneuronas se realizó la inyección intramuscular de diferentes dosis de TxBA y de DXR.
Resultados: El número de motoneuronas marcadas con FG en los animales que fueron inyectados con TxBA fue similar al encontrado en los animales control. Sin embargo, era menor el número de motoneuronas marcadas en los animales inyectados con DXR.
Conclusiones: La inyección intramuscular de TxBA no induce muerte de motoneuronas. La inyección intramuscular de DXR induce una muerte neuronal dosis dependiente en las motoneuronas del núcleo del VI par craneal. / Purpose: To investigate "in vivo" the survival of abducens motoneurons (AMNs) after a single intramuscular injection of the botulinum toxin A (BTxA) or doxorubicin (DXR).
Methods: In rats, the AMNs were labeled with fluorogold (FG), which was applied intramuscularly in the lateral rectus muscle. The number of labeled neurons were determined in control animals; in animals that had received intramuscular injections of BTxA; and in rats that had received DXR.
Result: The numbers of FG-labeled neurons in the animals that had been injected with BTxA were similar to those found in control animals. However, there were fewer FG-labeled neurons in the animals injected with DXR.
Conclusion: The intramuscular injection of BTxA does not induce significant motoneuron death. Doxorubicin injected intramuscularly causes variable amounts of motoneuron death that is related to the amount of DXR injected.
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An exploration of the mechanisms behind peripheral nerve injuryWiberg, Rebecca January 2016 (has links)
Despite surgical innovation, the sensory and motor outcome after peripheral nerve injury is incomplete. In this thesis, the biological pathways potentially responsible for the poor functional recoveries were investigated in both the distal nerve stump/target organ, spinal motoneurons and dorsal root ganglia (DRG). The effect of delayed nerve repair was determined in a rat sciatic nerve transection model. There was a dramatic decline in the number of regenerating motoneurons and myelinated axons found in the distal nerve stumps of animals undergoing nerve repair after a delay of 3 and 6 months. RT-PCR of the distal nerve stumps showed a decline in expression of Schwann cells (SC) markers, with a progressive increase in fibrotic and proteoglycan scar markers, with increased delayed repair time. Furthermore, the yield of SC which could be isolated from the distal nerve segments progressively fell with increased delay in repair time. Consistent with the impaired distal nerve stumps the target medial gastrocnemius (MG) muscles at 3- and 6-months delayed repair were atrophied with significant declines in wet weights (61% and 27% compared with contralateral sides). The role of myogenic transcription factors, muscle specific microRNAs and musclespecific E3 ubiquitin ligases in the muscle atrophy was investigated in both gastrocnemius and soleus muscles following either crush or nerve transection injury. In the crush injury model, the soleus muscle showed significantly increased recovery in wet weight at days 14 and 28 (compared with day 7) which was not the case for the gastrocnemius muscle which continued to atrophy. There was a significantly more pronounced up-regulation of MyoD expression in the denervated soleus muscle compared with the gastrocnemius muscle. Conversely, myogenin was more markedly elevated in the gastrocnemius versus soleus muscles. The muscles also showed significantly contrasting transcriptional regulation of the microRNAs miR-1 and miR-206. MuRF1 and Atrogin-1 showed the highest levels of expression in the denervated gastrocnemius muscle. Morphological and molecular changes in spinal motoneurons were compared after L4-L5 ventral root avulsion (VRA) and distal peripheral nerve axotomy (PNA). Neuronal degeneration was indicated by decreased immunostaining for microtubule-associated protein-2 in dendrites and synaptophysin in presynaptic boutons after both VRA and PNA. Immunostaining for ED1-reactive microglia and GFAPpositive astrocytes was significantly elevated in all experimental groups. qRT-PCR analysis and Western blotting of the ventral horn from L4-L5 spinal cord segments revealed a significant upregulation of apoptotic cell death mediators including caspases-3 and -8 and a range of related death receptors following VRA. In contrast, following PNA, only caspase-8 was moderately upregulated. The mechanisms of primary sensory neuron degeneration were also investigated in the DRG following peripheral nerve axotomy, where several apoptotic pathways including those involving the endoplasmic reticulum were shown to be upregulated. In summary, these results show that the critical time point after which the outcome of regeneration becomes too poor appears to be 3-months. Both proximal and distal injury affect spinal motoneurons morphologically, but VRA induces motoneuron degeneration mediated through both intrinsic and extrinsic apoptotic pathways. Primary sensory neuron degeneration involves several different apoptotic pathways, including the endoplasmic reticulum.
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Diagnostic and therapeutic strategies following spinal cord and brachial plexus injuriesKaralija, Amar January 2016 (has links)
Traumatic injuries to the spinal cord and brachial plexus induce a significant inflammatory response in the nervous tissue with progressive degeneration of neurons and glial cells, and cause considerable physical and mental suffering in affected patients. This thesis investigates the effects of the antioxidants N-acetyl-cysteine (NAC) and acetyl-L- carnitine (ALC) on the survival of motoneurons in the brainstem and spinal cord, the expression of pro-apoptotic and pro-inflammatory cell markers, axonal sprouting and glial cell reactions after spinal hemisection in adult rats. In addition, a novel MRI protocol has been developed to analyse the extent of neuronal degeneration in the spinal cord. Rubrospinal neurons and tibial motoneurons were pre-labelled with the fluorescent tracer Fast Blue one week before cervical C3 or lumbar L5 spinal cord hemisection. The intrathecal treatment with the antioxidants NAC (2.4mg/day) or ALC (0.9 mg/day) was initiated immediately after injury using Alzet2002 osmotic mini pumps. Spinal cord injury increased the expression of apoptotic cell markers BAX and caspase 3, induced significant degeneration of rubrospinal neurons and spinal motoneurons with associated decrease in immunoreactivity for microtubule-associated protein-2 (MAP2) in dendritic branches, synaptophysin in presynaptic boutons and neurofilaments in nerve fibers. Immunostaining for the astroglial marker glial fibrillary acidic protein and microglial markers OX42 and ED1 was markedly increased. Treatment with NAC and ALC attenuated levels of BAX, caspase 3, OX42 and ED1 expression after 2 weeks postoperatively. After 4-8 weeks of continuous intratheca ltreatment, NAC and ALC rescued approximately half of the rubrospinal neurons and spinal motoneurons destined to die, promoted axonal sprouting, restored the density of MAP2 and synaptophysin immunoreactivity and reduced the microglial reaction. However, antioxidant therapy did not affect the reactive astrocytes in the trauma zone. The inflammation modulating properties of ALC were also studied using cultures of human microglial cells. ALC increased the microglial production of interleukin IL-6 and BDNF, thereby possibly mediating the anti-inflammatory and pro-regenerative effects shown in vivo. To study degeneration in the spinal cord following pre-ganglionic and post-ganglionic brachial plexus injuries, adult rat models of ventral root avulsion and peripheral nerve injury were used. A novel MRI protocol was employed and the images were compared to morphological changes found in histological preparations. Ventral root avulsion caused degeneration of dendritic branches and axonal terminals in the spinal cord, followed by significant shrinkage of the ventral horn. Extensive astroglial and microglial reactions were detected in the histological preparations. Peripheral nerve injury reduced the density of dendritic branches but did not cause shrinkage of the ventral horn. Quantitative analysis of MRI images demonstrated changes in the ventral horn following ventral root avulsion only, thus validating the developed MRI technique as a possible tool for the differentiation of pre-ganglionic and post-ganglionic nerve injuries.
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