Global ETD Search

251	Effets de la noradrénaline sur les transmissions synaptiques dans la corne dorsale de la moelle épinière de rat / Effects of noradrenaline on synaptic transmissions in the dorsal horn of the rat spinal cord Seibt, Frederik 07 July 2015 (has links) La corne dorsale de la moelle épinière (CDME) est un site d’intégration et de modulation de l’information somatosensorielle. Les laminae profondes de la CDME jouent un rôle important dans la modulation des informations nociceptives. Notre objectif a été de caractériser les effets de la NA sur la transmission synaptique des laminae profondes de la CDME. Nous montrons que la NA facilite la transmission synaptique inhibitrice dans les laminae III-V de la CDME. Ce phénomène met en jeu l’activation d’adrénocepteurs alpha1, alpha2, et bêta et nécessite une communication interlaminaire intacte entre les laminae III-IV et V. L’inhibition du métabolisme glial produit les mêmes effets qu’une section mécanique entre les laminae IV et V. Une interaction entre les cellules gliales et les neurones des laminae profondes la CDME semble donc indispensable à l’effet facilitateur de la NA. / The dorsal horn of the spinal cord (DH) is an important site of integration and modulation of somatosensory information and deep laminae of the DH play an important role in the modulation of nociceptive information in the neuronal network of the spinal cord.Our aim was to characterize the effects of NA on synaptic transmission in deep laminae of the DH.We show that NA facilitates inhibitory synaptic transmission in laminae III-IV of the DH. This phenomenon involves the activation of alpha1, alpha2, and beta adrenoceptors and requires intact interlaminar communications between laminae III-IV and V. Glial cell metabolism inhibition has the same consequences as a mechanical section between laminae IV and V. These results indicate that an interaction between glial cell and deep laminae neurons of the DH seems essential for the facilitatory effect of NA on inhibitory synaptic communications in laminae III-IV of the DH. Moelle épinière Corne dorsale Noradrénaline Transmission synaptique Glie Spinal cord Dorsal horn Noradrenaline Synaptic transmission Glia 572.4 573.8
252	Úloha míšních TRPV1 receptorů v nociceptivním přenosu a modulační účinky chemokinu CCL2 a agonistů µ-opioidního receptoru / The role of spinal TRPV1 receptors in nociceptive signalling and the modulatory effect of chemokine CCL2 and µ-opioid receptor agonists Šulcová, Dominika January 2017 (has links) The first nociceptive synapse in the spinal cord dorsal horn represents an important site, where nociceptive synaptic transmission can be modulated under pathological conditions. One of the modulatory mechanism involves activation of the transient receptor potential vanilloid 1 (TRPV1) that is expressed on central terminals of primary nociceptive neurons, where it regulates release of neurotransmitters and neuromodulators. Previous studies suggested that changes in TRPV1 activity may be related to effects of chemokine CCL2 (C-C motif ligand 2) and may be also involved in synaptic transmission modulation after µ-opioid receptors (MOP-R) activation. Because CCL2 receptors CCR2 often co-localize with TRPV1 and MOP-R, the goal of this work was to studypossible interactions of these receptors on the pre-synaptic endings of primaryafferents in the spinal cord dorsal horn and their role in nociceptive signalling under pathological conditions. The presented thesis focused on the effect of CCL2 during peripheral neuropathy and its interference with µ-opioid receptor activation. To studysynaptic transmission at the spinal cord level, patch-clamp recordings of excitatory post-synaptic currents (EPSC) in superficial spinal cord dorsal horn neurons in acute lumbar spinal cord slices from rats was used....
253	Perceptual Ability is Diminished at Peak Limb Velocity of a Goal-directed Movement But is Unaffected During Motor Preparation Hajj, Joëlle January 2017 (has links) Due to various shortcomings of the visual system, some visual stimuli can only be identified with 100% accuracy if they are shown for a certain amount of time. This time can be measured using the Inspection Time (IT) paradigm. In an IT task, a “pi” figure with differing leg lengths is typically presented briefly (e.g., 20-200 ms) and is then immediately masked to prevent retinal afterimages. Participants are subsequently required to choose which of the two legs was longer. The objective of this task is to determine the shortest amount of time the pi figure needs to be shown for it to be perceived with 80% accuracy. Given that visual processing has been shown to be altered during and /or prior to a movement, the present experiment sought to test how the requirement to perform a motor task affected IT. Twenty-eight participants took part in the experiment, which was comprised of three conditions: no-movement (NM), peak velocity (PV), and foreperiod (FP). In the NM condition, participants grasped a manipulandum and engaged in the IT paradigm. At the end of every trial, participants verbally stated which leg they believed was longest. In the PV condition participants made a rapid movement to a target, and the IT stimulus was presented when their limb reached peak velocity. Finally in the FP condition the IT stimulus was presented during foreperiod (FP). In all three conditions the IT stimulus was randomly presented from between 15-105 ms (in 15 ms increments) and masked for 400 ms. Results showed no significant differences on the IT task between the NM and FP conditions, suggesting no visual upregulation during foreperiod. However, IT performance was significantly poorer in the PV condition in comparison to both the NM and FP condition, suggesting a visual downregulation at that particular movement kinematic. Perceptual processing speed Ventral stream Dorsal stream Visual upregulation Visual downregulation Inspection time paradigm Peak limb velocity Foreperiod
254	Neuropeptides et Néprilysines : rôle dans la mémoire chez la Drosophile / Neuropeptides and Neprilysins : role in memory in Drosophila Turrel, Oriane 28 September 2017 (has links) Au cours de ma thèse j’ai étudié les néprilysines (Nep), des protéinases connues pour dégrader de petits neuropeptides, en particulier les peptides amyloïdes (Aβ). Lors de la maladie d’Alzheimer, les peptides Aβ s’agrègent pour former des plaques toxiques. Il a été montré que l’expression des Nep module l’effet toxique d’Aβ sur la mémoire chez les modèles murins. Néanmoins, le rôle des Nep dans la mémoire dans des conditions physiologiques reste à ce jour inconnu.La drosophile exprime 4 Nep dans le système nerveux central adulte. Nous avons analysé leur rôle dans la mémoire olfactive. Les 4 Nep sont requises pour 2 phases spécifiques de mémoire: à moyen terme (MTM) et à long terme (LTM). De plus, nous avons identifié les neurones dans lesquels elles sont requises : les Mushroom Bodies (MB) ainsi qu’une paire de neurones afférents, les Dorsal Paired Medial neurons (DPM). Nous avons ensuite cherché à savoir si Aβ était l’une des cibles des Nep. Nous avons montré que l’expression d’Aβ dans les DPM n’altère la MTM que lorsque l’expression de Nep1 est inhibée. De plus, le défaut de LTM de drosophiles exprimant Aβ dans les DPM est sauvé par la surexpression de Nep1. En conclusion, nos résultats suggèrent qu’Aβ est dégradé par Nep1 au cours des processus de mémorisation, et qu’Aβ est une cible de Nep1 en conditions non pathologiques.Enfin, nous nous sommes intéressés au neuropeptide amnesiac, décrit comme étant requis pour la mémoire dans les DPM. Nos travaux démontrent qu’amnesiac est en fait requis dans les DPM pour leur développement, et chez l’adulte dans les MB pour activer l’adénylate cyclase responsable de la détection de coïncidence permettant la formation de la MTM. / During my PhD, I studied neprilysins, proteinases known to degrade small neuropeptides, in particular mammalian amyloid-β peptides (Aβ). During Alzheimer’s disease, Aβ peptides aggregate to form toxic plaques. It has been shown that neprilysins expression modulates toxic effects of Aβ on memory in murine models of the disease. However, the role of neprilysins in memory under physiological conditions is still unknown. Drosophila expresses 4 neprilysins in the adult central nervous system. First we have analyzed their role in olfactive memory. We have shown that all of them are required for 2 specific memory phases: Middle-Term Memory (MTM) and Long-Term Memory (LTM). We also have identified the neurons in which they are required: the Mushroom Bodies (MB) and a pair of afferent neurons, the Dorsal Paired Medial (DPM) neurons. Then we investigated whether Aβ peptides could be one of the neprilysins’ targets. We have shown that Aβ expression in DPM neurons alters MTM only when Nep1 expression is inhibited. Furthermore, the LTM deficit of flies expressing Aβ in DPM neurons is rescued by Nep1 overexpression. To conclude, our results suggest that Nep1 degrades endogenous Aβ peptides during memory processes, and that Aβ is a physiological target for Nep1 under non-pathological condition.Finally, we became interested in the amnesiac neuropeptide, described as being required for memory in DPM neurons. Our work shows that amnesiac is actually required in DPM neurons for their development, and in the MB of adult flies in order to activate the adenylate cyclase responsible for coincidence detection leading to MTM formation. Drosophila melanogaster Mémoire olfactive Neurones dorsal paired medial Corps pédonculés Néprilysines Amnesiac Drosphila melanogaster Olfactory memory Neprilysins 612.8
255	Modulation of neuronal excitability in the cognitive control network by electrical stimulation Lehr, Albert 14 May 2020 (has links) No description available. 570 dorsal anterior cingulate cortex dorsolateral prefrontal cortex Stroop task instrumental learning Biologie (PPN619462639)
256	Noradrenergic Fiber Sprouting in the Cerebellum Kostrzewa, Richard M., Harston, Craig T., Fukushima, Hideki, Brus, Ryszard 01 January 1982 (has links) In order to attain a better understanding of the sprouting response of noradrenergic fibers in the central nervous system (CNS), noradrenergic innervation to the cerebellum was observed by the glyoxylic acid method after a variety of manipulations and in a genetic variant of mouse classified as "Purkinje cell degeneration" (pcd/pcd). It has been found that a midbrain lesion in rats at birth will result in a collateral sprouting response of noradrenergic fibers in the cerebellum at 8 weeks, as indicated by the increased number of histofluorescent fibers observed in the molecular layer of the cerebellar cortex. Another procedure, treatment of neonatal rats with nerve growth factor alone appears to produce a temporary stimulation of noradrenergic fiber growth in the cerebellum, as observed by the histofluorescent method, although the innervation at 6 weeks or later is ultimately unchanged from the control group. In contrast, NGF (500 units) given to rats in combination with 6-hydroxydopa (6-OHDOPA) (60 μg/g IP) at 3 days postbirth produces a hyperinnervation of the cerebellum by noradrenergic fibers by 2 weeks of age and until at least 8 weeks of age. A third procedure, locus coeruleus implantation, was generally unsuccessful using the procedures described, since the implant was usually non-viable after several days. In a few instances where histofluorescent nuclei were found within the implant, there was an abundance of histofluorescent fibers within and adjacent to the implant, with fibers appearing to grow into host cerebellum. In the final procedure, it was noted that the density of noradrenergic input to the molecular layer of the cerebellar cortex was markedly increased in a genetic mutant mouse, classified as "Purkinje cell degeneration" (pcd/pcd), which is characterized by the absence of Purkinje cells of the cerebellum in adulthood. However, because of the tissue shrinkage that occurs after loss of Purkinje cells during postnatal development, it is unclear as to whether this observation represents hyperinnervation or a normal complement of fibers in a smaller brain space. The above procedures demonstrate the plasticity of noradrenergic fibers in neonatal cerebellum, a brain region that undergoes considerable postnatal development. The cerebellum is thought to be a good site for studying development/ regeneration/sprouting of noradrenergic fibers in particular, and central axonal processes in general. cerebellum development locus coeruleus implantation dorsal bundle lesion nerve growth factor noradrenergic neurons purkinje cell degeneration regeneration sprouting Biomedical Sciences
257	Neurochemical Diversity of Afferent Neurons That Transduce Sensory Signals From Dog Ventricular Myocardium Hoover, Donald, Shepherd, Angela V., Southerland, Elizabeth M., Armour, J. Andrew, Ardell, Jeffrey L. 18 August 2008 (has links) While much is known about the influence of ventricular afferent neurons on cardiovascular function in the dog, identification of the neurochemicals transmitting cardiac afferent signals to central neurons is lacking. Accordingly, we identified ventricular afferent neurons in canine dorsal root ganglia (DRG) and nodose ganglia by retrograde labeling after injecting horseradish peroxidase (HRP) into the anterior right and left ventricles. Primary antibodies from three host species were used in immunohistochemical experiments to simultaneously evaluate afferent somata for the presence of HRP and markers for two neurotransmitters. Only a small percentage (2%) of afferent somata were labeled with HRP. About half of the HRP-identified ventricular afferent neurons in T3 DRG also stained for substance P (SP), calcitonin gene-related peptide (CGRP), or neuronal nitric oxide synthase (nNOS), either alone or with two markers colocalized. Ventricular afferent neurons and the general population of T3 DRG neurons showed the same labeling profiles; CGRP (alone or colocalized with SP) being the most common (30-40% of ventricular afferent somata in T3 DRG). About 30% of the ventricular afferent neurons in T2 DRG displayed CGRP immunoreactivity and binding of the putative nociceptive marker IB4. Ventricular afferent neurons of the nodose ganglia were distinct from those in the DRG by having smaller size and lacking immunoreactivity for SP, CGRP, and nNOS. These findings suggest that ventricular sensory information is transferred to the central nervous system by relatively small populations of vagal and spinal afferent neurons and that spinal afferents use a variety of neurotransmitters. calcitonin gene-related peptide dorsal root ganglion neuronal nitric oxide synthase nodose ganglion substance P ventricular afferent neuron Biomedical Sciences
258	Resurgent sodicum current modulation by auxiliary subunits in dorsal root ganglia neurons and potential implications in pain pathologies Barbosa Nuñez, Cindy Marie 11 April 2016 (has links) Indiana University-Purdue University Indianapolis (IUPUI) / Increased electrical activity in peripheral sensory neurons contributes to pain. A unique type of sodium current, fast resurgent current, is proposed to increase nerve activity and has been associated with pain pathologies. While sodium channel isoform Nav1.6 has been identified as the main carrier of fast resurgent currents, our understanding of how resurgent currents are modulated in sensory neurons is fairly limited. Thus the goal of this dissertation was to identify resurgent current modulators. In particular, we focused on sodium channel beta subunits (Navβs) and fibroblast growth factor homologous factors (FHFs) in dorsal root ganglion (DRG) neurons. We hypothesized that Navβ4 and FHF2B act as positive regulators by mediating resurgent currents and modulating Nav1.6 inactivation, respectively. In contrast, we hypothesized FHF2A negatively regulates resurgent current by increasing the probability of channels in inactivated states. Thus, the aims of this dissertation were to 1) determine if Navβ4 regulates fast resurgent currents in DRG neurons, 2) examine the effects of Navβ4 knockdown on resurgent currents, firing frequency and pain associated behavior in an inflammatory pain model and 3) determine if FHF2A and FHF2B functionally regulate Nav1.6 currents, including resurgent currents in DRG neurons. To examine the aims, we used biochemical, electrophysiological and behavioral assays. Our results suggest that Navβ4 is a positive regulator of resurgent currents: in particular, the C-terminus likely mediates these currents. Localized knockdown of Navβ4 decreased inflammation-induced enhancement of resurgent currents and neuronal excitability, and prevented the development of persistent pain associated behavior in an inflammatory pain model. FHF2B increased resurgent currents and delayed inactivation. In contrast, FHF2A limited resurgent currents; an effect that is mainly contributed by FHF2A's N-terminus activity that increased accumulation of channels in inactivated states. Interestingly, in an inflammatory pain model FHF2B was upregulated and FHFA isoforms were downregulated. Together these results suggest that FHF2A/B modulation might contribute to enhanced resurgent currents and increased neuronal excitability observed in the inflammatory pain model. Overall, our work has identified three resurgent current modulators FHF2A, FHF2B and Navβ4. Manipulation of these proteins or their activity might result in novel strategies for the study and treatment of pain. Auxiliary subunits Dorsal Root Ganglia Pain Resurgent sodium currents Sodium channel Sensory neurons Sodium channels Sensory neurons Pain Nociceptors
259	Origins of Cardiac Vagal Preganglionic Fibers: A Retrograde Transport Study Stuesse, Sherry L. 18 March 1982 (has links) The origin of cardiac preganglionic neurons in the rat was investigated using the retrograde transport of horseradish peroxidase (HRP). A single injection of HRP was made into the right myocardium in either a sinoatrial or mid-ventricular location. Labeled cells were found in the mid- and lower medulla primarily in and around the nucleus ambiguus (NA) 600-1800 μm above the obex. The dorsal motor nucleus of X (DMN) was sparsely labeled and a few cells were found in an intermediate zone near the level of the obex. Labeling was bilateral with slightly heavier labeling found ipsilateral to the injection site than contralateral to it. Following a unilateral vagotomy, labeled cells were only found ipsilateral to the intact vagus. Atrial and midventricular injections yielded similar results. Occasionally only 1- cells in the NA were labeled per section. Inspection of serial sections revealed that in these sparsely labeled rats, the HRP was often in the same location within the NA forming a column of cells within the nucleus. The columns sometimes extended at least 240 μm in the rostral-caudal direction. The columnar organization was most apparent in rats with few labeled cells presumably because it was obscured in nuclei that were heavily labeled. In a second group of rats, the right vagus was cut at the cervical level and dipped in HRP to determine the extent of the NA and DMN in rats. In these animals, heavier labeling was found in the DMN than in the NA. Cells in the DMN were filled from the upper spinal cord to its most rostral extent 1200 μm above the obex. Thus, although the DMN and NA send projections in the vagus nerve, those axons terminating in the myocardium primarily originate in the NA. autonomic nervous system brain stem cardiac innervation dorsal motor nucleus of X nucleus ambiguus parasympathetic rat medulla vagus
260	Modulation of Nicotinic ACh-, GABA(a)- and 5-HT<sub>3</sub>-Receptor Functions by External H-7, a Protein Kinase Inhibitor, in Rat Sensory Neurones Hu, Hong Zhen, Li, Zhi Wang 01 December 1997 (has links) 1. The effects of external H-7, a potent protein kinase inhibitor, on the responses mediated by γ-aminobutyric acid A type (GAGA(A))-, nicotinic acetylcholine (nicotinic ACh)-, ionotropic 5-hydroxytryptamine (5-HT3)-, adenosine 5'-triphosphate (ATP)-, N-methyl-D-aspartate (NMDA)- and kainate (KA)-receptors were studied in freshly dissociated rat dorsal root ganglion neurone by use of whole cell patch-clamp technique. 2. External H-7 (1-1000 μM) produced a reversible, dose-dependent inhibition of whole cell currents activated by GABA, ACh and 5-HT. 3. Whole-cell currents evoked by ATP, 2-methylthio-ATP, NMDA and KA were sensitive to external H-7. 4. External H-7 shifted the dose-response curve of GABA-activated currents downward without changing the EC50 significantly (from 15.0 ± 4.0 μM to 18.0 ± 5.0 μM). The maximum response to GABA was depressed by 34.0 ± 5.3%. This inhibitory action of H-7 was voltage-independent. 5. Intracellular application of H-7 (20 μM), cyclic AMP (1 mM) and BAPTA (10 mM) could not reverse the H-7 inhibition of GABA-activated currents. 6. The results suggest that external H-7 selectively and allosterically modulates the functions of GABA(A)-, nicotine ACh- and 5-HT3 receptors via a common conserved site in the external domain of these receptors. dorsal root ganglion glutamate receptors H-7 modulation nicotinic receptor superfamily P2X receptor whole cell patch clamp recording

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