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Showing 21 to 27 of 27 (0.071 seconds)Spelling suggestions: "subject:"trigeminal serve"" "subject:"trigeminale serve""
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Nasal solitary chemoreceptor cells : cell turnover, nerve dependence, and detection capabilities /Gulbransen, Brian D. January 2007 (has links)
Thesis (Ph.D. in Neuroscience) -- University of Colorado Denver, 2007. / Typescript. Includes bibliographical references (leaves 129-151). Free to UCD affiliates. Online version available via ProQuest Digital Dissertations;
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Rôle de l'inhibition segmentaire dans le traitement de l'information nociceptive cutanée et méningée dans le complexe trigéminal / Role of segmental inhibition in cutaneous and meningeous nociceptive information treatment in medullary dorsal hornMelin, Céline 13 December 2011 (has links)
Une réduction de l'inhibition segmentaire contribue vraisemblablement à l'hypersensibilité douloureuse persistante – qui se manifeste par l'hyperalgie, l'allodynie, et la douleur spontanée – au cours d'états douloureux chroniques. L'association fréquente d'une allodynie avec la migraine – une céphalée épisodique – suggère qu'une perte de l'inhibition synaptique contribue aussi à la manifestation de la douleur migraineuse. Cependant, la grande prévalence de la migraine – plus de 10% de la population générale – soulève la question de savoir si le traitement des informations méningées par le réseau neuronal – associant interneurones excitateurs et inhibiteurs – dans le complexe trigéminal, premier relais sur les voies nociceptives de la face et des méninges, est le même que celui des autres informations, par exemple cutanées. Nous avons caractérisé l'effet du blocage pharmacologique des récepteurs à la glycine (GlyR) et des récepteurs GABAA (GABAAR) sur la transmission synaptique entre fibres afférentes primaires, cutanées ou méningées, et neurones de second ordre en enregistrant des potentiels de champ dans le sous-noyau caudal superficiel (Sp5C). Une stimulation électrique transcutanée évoque trois potentiels de champ négatifs dus à l'activation, du plus précoce au plus tardif, de fibres afférentes primaires de type Aβ, Aδ et C. Bloquer les GlyRs et/ou GABAARs segmentaires facilite les potentiels de champ polysynaptiques excitateurs évoqués par l'activation des fibres afférentes primaires de type A et, au contraire, inhibe, ou même abolit, les potentiels de champ C. Bloquer les récepteurs GABAB (GABABR) segmentaires prévient cette suppression. Il est intéressant de noter que bloquer les GABABRs, potentialise aussi les potentiels de champ C en condition controle. Une stimulation électrique méningée évoque deux potentiels de champ négatifs dus à l'activation, du plus précoce au plus tardif, des fibres afférentes primaires de type Aδ et C. Au contraire du potentiel de champ C cutané, le potentiel de champ C méningé est potentialisé après blocage des GlyRs et/ou GABAARs segmentaires. Ces résultats démontrent que le traitement des informations cutanées et méningées par le Sp5C est différent. Seule l'activation des fibres afférentes primaires cutanées de type A inhibe les inputs cutanés de type C vers le Sp5C par l'intermédiaire d'un circuit polysynaptique excitateur, d'interneurones GABAergiques de dernier ordre et de GABABRs présynaptiques. La théorie du "gate control" postule que l'activité des afférences non-nociceptives ferme la porte à la transmission des inputs nociceptifs vers les centres supérieurs. Nos résultats suggèrent que l'état de la porte dépend de l'activité non seulement dans les fibres afférentes primaires de type A mais aussi dans les circuits polysynaptiques excitateurs de la corne dorsale. / Pathological disruption of segmental inhibition is thought to contribute to persistent pain hypersensitivity – including hyperalgesia, allodynia and spontaneous pain – that occurs during chronic pain states. That allodynia is also often associated with migraine – an episodic headache – suggests that a loss of synaptic inhibition is also involved in the manifestation of headache pain. However, the very high prevalence of migraine – more than 10% of the general population – raises the question as to whether processing of meningeous inputs by local neuronal network – consisting of excitatory and inhibitory interneurons – within the trigeminal nucleus, the first relay station for incoming nociceptive signals of the face and meninges, is the same as that of others, for instance cutaneous. We sought to characterize how pharmacological blockade of glycine and GABAA receptors modifies synaptic transmission between either cutaneous or meningeous primary afferent fibers and second order neurons by recording field potentials in the rat superficial medullary dorsal horn (MDH). Transcutaneous electrical stimulation evokes three negative field potentials elicited by, from the earliest to the latest, Aβ-, Aδ- and C-fiber primary afferents. Blocking segmental glycine and/or GABAA receptors strongly facilitates A-fiber-activated polysynaptic excitatory field potentials but, conversely, inhibits, or even abolishes, C-fiber field potentials. Blocking segmental GABAB receptors reverses such suppression. Interestingly, it also potentiates C-fiber field potentials under control conditions. Meningeous electrical stimulation evokes two negative field potentials elicited by, from the earliest to the latest, Aδ- and C-fiber primary afferents. Unlike cutaneous C-fiber field potentials, meningeous ones are facilitated by blocking segmental glycine and/or GABAA receptors. These results demonstrate that MDH processing of cutaneous and meningeous inputs are different. Only activation of cutaneous A-fiber primary afferents inhibits cutaneous C-fiber inputs to the MDH by the way of polysynaptic excitatory pathways, last-order GABAergic interneurons and presynaptic GABAB receptors. In view of the gate control theory postulating that afferent volleys in non-nociceptive afferents close the gate to central transmission of nociceptive inputs, our results suggest that the state of the gate depends on firing activities of both A-fiber primary afferents and polysynaptic excitatory circuits, i.e. the inhibitory tone, within the dorsal horn.
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Organização Topográfica e Quantificação das Vias Trigêmino-Rubrais em Camundongos Distróficos e Normais / Topographic organization and quantification of trigemial-rubral pathways in control and dystrophic micePinto, Magali Luci [UNIFESP] 27 February 2008 (has links) (PDF)
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Publico-10874.pdf: 336312 bytes, checksum: bde3d9f65dc223d46e21349b3e3c3fee (MD5) / Pacientes com distrofia muscular de Duchenne apresentam alteracoes no sistema nervoso central (SNC). Mudancas no SNC tambem ocorrem nos camundongos distroficos (mdx), incluindo perda de fibras rubro-espinais. Para examinar se outras vias tambem sao reduzidas no mdx, propusemo-nos a estudar a organizacao topografica das vias trigemino-rubrais e quantificar os neuronios do Complexo Trigeminal que se projetam para o nucleo Rubro em camundongos C57BL10 (normais) e distroficos (mdx) de diferentes idades. Para tanto, os animais foram submetidos a cirurgia estereotaxica para as injecoes dos tracadores de transporte retrogrado Fluorogold, Rodamina e Fluoresceina, bilateralmente, no nucleo Rubro. Sete dias depois, os animais foram sacrificados sob anestesia atraves de perfusao transcardiaca e os encefalos foram congelados em meio de embebicao proprio no uso do aparelho criostato e, destes encefalos foram realizados cortes seriados na espessura de 35 ƒÊm. A analise foi realizada em microscopico de epifluorescencia. Foram contados os neuronios do subnucleo oral do nucleo espinal do nervo trigemeo em camundongos normais e distroficos de 3, 6 e 12 meses de idade. No Sistema Intersticial, foram contados todos os neuronios marcados ao longo de sua extensao. Nossos resultados mostraram que existe uma organizacao topografica na projecao dos neuronios do Complexo Trigeminal e do Sistema Intersticial para o nucleo Rubro, em camundongos. Todos os nucleos sensoriais do Complexo Trigeminal apresentaram intensa marcacao bilateral, com predominio contralateral quando o sitio de injecao foi na regiao magnocelular do nucleo Rubro; os neuronios apresentaram pouca ou nenhuma marcacao quando o sitio atingiu a região parvocelular e, quando o sítio de injeção atingiu a região intermediária do núcleo a qual abrange suas partes magnocelular e parvocelular, a marcação retrógrada foi mais intensa só quando o foco do sítio atingiu mais a região magnocelular. O núcleo motor do Complexo Trigeminal não foi marcado em nenhuma das situações. No Sistema Intersticial, foram marcados os neurônios apenas quando o sítio de injeção abrangeu a região magnocelular do núcleo Rubro. Também foi verificado que no Complexo Trigeminal essa organização é semelhante em ambos os grupos normais e distróficos. Os resultados mostraram uma redução de 50% no número de neurônios do Complexo Trigeminal no mdx com a idade de 3 meses. Essa redução neuronal se manteve nos camundongos mdx nos grupos de 6 e 12 meses, não ocorrendo progressão desta perda com a idade. Além disso, o grupo de camundongos C57BL10 (normais) também não apresentou perda neuronal com a idade. Concluímos que a diferença observada no complexo trigeminal no grupo de 3 meses já está estabelecida e que não é progressiva com o avanço da idade; portanto, é bem provável que os camundongos mdx já nasçam com essa redução ou que a mesma ocorra logo nas primeiras semanas após o nascimento. / TEDE / BV UNIFESP: Teses e dissertações
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Změny v Srdeční Frekvenci Novorozenců v Reakci na Odoranty s Relativně Silnou a Slabou Trigeminální Komponentou / Heart Rate Response in Newborns to Relatively Strong and Mild Trigeminal OdorantsBoušová, Jiřina January 2017 (has links)
The widely accepted view nowadays is that experiencing odours as rather pleasant or unpleasant is, to a certain degree, shaped on a daily basis through individual experience within one's culture via evaluative conditioning or, rather marginally so, via mere exposure to that certain odour. In other words, humans are not born with any fixed set of olfactory likes or dislikes but rather, they acquire them throughout their lifetime. However, olfactory sensation is not a "pure" percept, as odorant stimuli generally elicit a qualitative percept of an odorant - generated mainly by the olfactory nerve - as well as some degree of chemesthesis - a tactile confound of the odour generated mainly by the trigeminal nerve. The olfactory and trigeminal system exhibit complex interactions at both the peripheral and central level of chemosensory processing, which is also reflected in perceptual characteristics of the final percept, including perceived pleasantness (hedonics). If the olfactory contribution alone does not easily predict neonatal odour hedonics, due to newborns' limited previous exposure to chemosensory inputs, one may hypothesize that together with the strength of the trigeminal contribution they may form a significant factor affecting neonatal appetitive/aversive responses to odours. In the present...
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Inhibition of Retinoic Acid Receptors Results in Defasciculation of the Trigeminal Nerve in Xenopus laevisThompson, Jeremy 09 May 2013 (has links)
The anatomy of the cranial peripheral nervous system has been studied for over a century, yet surprisingly little is known about how the nerves are guided to their targets. The study of the development of these nerves has important implications for our understanding of craniofacial anomalies and possible treatments for both injury and genetic disorders of nerve development such as Goldenhar-Gorlin syndrome. We have discovered that retinoic acid (RA) may play a role in the development of the trigeminal nerve. Inhibition of retinoic acid receptors (RAR) results in trigeminal nerves that become unbundled or defasciculated in the eye region. To further understand how RA is affecting trigeminal development we searched for genes downregulated in response to RAR inhibition by the inhibitor BMS-453 and have identified neurotrophin-3 (NT-3), activated leukocyte cell adhesion molecule (ALCAM) and Semaphorin 4B (Sema4B). We have analyzed the expression patterns of Sema4B and NT-3 by in situ hybridization and have found NT-3 expression in the eye and Sema4B in the embryonic target of the trigeminal nerve, lens of the eye and in the pharyngeal arches. ALCAM has been analyzed via qRT-PCR and its transcription is downregulated just prior to the observed defasciculation phenotype. The pattern of expression of these genes combined with known expression of NT-3 receptors allows us to suggest a model whereby RA signaling regulates Sema4B, ALCAM and NT-3, which support the survival, guidance and fasciculation of the trigeminal nerve. This work has the potential to better understanding of the complex nature of cranial nervous system development.
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Les mécanismes synaptiques et intrinsèques qui sous-tendent l’activité des cellules réticulospinales (RS) en réponse à une stimulation sensorielle de type cutané chez la lamproieFénelon, Karine 11 1900 (has links)
Chez diverses espèces animales, les informations sensorielles peuvent
déclencher la locomotion. Ceci nécessite l’intégration des informations sensorielles
par le système nerveux central. Chez la lamproie, les réseaux locomoteurs spinaux
sont activés et contrôlés par les cellules réticulospinales (RS), système descendant le
plus important. Ces cellules reçoivent des informations variées provenant notamment
de la périphérie. Une fois activées par une brève stimulation cutanée d’intensité
suffisante, les cellules RS produisent des dépolarisations soutenues de durées variées
impliquant des propriétés intrinsèques calcium-dépendantes et associées à l’induction
de la nage de fuite. Au cours de ce doctorat, nous avons voulu savoir si les afférences
synaptiques ont une influence sur la durée des dépolarisations soutenues et si
l’ensemble des cellules RS partagent des propriétés d’intégration similaires,
impliquant possiblement les réserves de calcium internes. Dans un premier temps,
nous montrons pour la première fois qu’en plus de dépendre des propriétés
intrinsèques des cellules réticulospinales, les dépolarisations soutenues dépendent des
afférences excitatrices glutamatergiques, incluant les afférences spinales, pour
perdurer pendant de longues périodes de temps. Les afférences cutanées ne
participent pas au maintien des dépolarisations soutenues et les afférences inhibitrices
glycinergique et GABAergiques ne sont pas suffisantes pour les arrêter. Dans un
deuxième temps, nous montrons que suite à une stimulation cutanée, l’ensemble des
cellules RS localisées dans les quatre noyaux réticulés possèdent un patron
d’activation similaire et elles peuvent toutes produire des dépolarisations soutenues
dont le maintien ne dépend pas des réserves de calcium internes. Enfin, les résultats obtenus durant ce doctorat ont permis de mieux comprendre les mécanismes
cellulaires par lesquels l’ensemble des cellules RS intègrent une brève information
sensorielle et la transforment en une réponse soutenue associée à une commande
motrice. / In various animal species, sensory information can initiate locomotion. This
relies on the integration of sensory inputs by the central nervous system. In lampreys,
the spinal locomotor networks are activated and controlled by the reticulospinal cells
(RS) which constitute the main descending system. In turn, RS cells receive
information coming from various synaptic inputs such as the sensory afferents. Once
activated by a brief cutaneous stimulation of sufficient strength, RS cells display
sustained depolarizations of various durations that rely on calcium-dependant
intrinsic properties and lead to the onset of escape swimming. During the course of
this Ph.D, we aimed at determining whether synaptic inputs can modulate the
duration of the sustained depolarizations and if the different populations of RS cells
share the same integrative properties, possibly involving the internal calcium stores.
First, our results show for the first time that excitatory glutamatergic inputs, including
ascending spinal feedback, contribute to prolong the sustained depolarizations for
long periods of time. Cutaneous inputs do not contribute to maintain the sustained
depolarizations and inhibitory glycinergic and GABAergic inputs are not sufficient to
stop them. Second, we show that in response to cutaneous stimulation, the RS located
in the four reticular nuclei display a similar activation pattern and can all produce
sustained depolarizations which do not depend on internal calcium release to be
maintained. Finally, the results obtained during this Ph.D allowed us to better
understand the cellular mechanisms by which the RS cells integrate and transform a
brief sensory information into a sustained response associated with a motor
command.
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Les mécanismes synaptiques et intrinsèques qui sous-tendent l’activité des cellules réticulospinales (RS) en réponse à une stimulation sensorielle de type cutané chez la lamproieFénelon, Karine 11 1900 (has links)
Chez diverses espèces animales, les informations sensorielles peuvent
déclencher la locomotion. Ceci nécessite l’intégration des informations sensorielles
par le système nerveux central. Chez la lamproie, les réseaux locomoteurs spinaux
sont activés et contrôlés par les cellules réticulospinales (RS), système descendant le
plus important. Ces cellules reçoivent des informations variées provenant notamment
de la périphérie. Une fois activées par une brève stimulation cutanée d’intensité
suffisante, les cellules RS produisent des dépolarisations soutenues de durées variées
impliquant des propriétés intrinsèques calcium-dépendantes et associées à l’induction
de la nage de fuite. Au cours de ce doctorat, nous avons voulu savoir si les afférences
synaptiques ont une influence sur la durée des dépolarisations soutenues et si
l’ensemble des cellules RS partagent des propriétés d’intégration similaires,
impliquant possiblement les réserves de calcium internes. Dans un premier temps,
nous montrons pour la première fois qu’en plus de dépendre des propriétés
intrinsèques des cellules réticulospinales, les dépolarisations soutenues dépendent des
afférences excitatrices glutamatergiques, incluant les afférences spinales, pour
perdurer pendant de longues périodes de temps. Les afférences cutanées ne
participent pas au maintien des dépolarisations soutenues et les afférences inhibitrices
glycinergique et GABAergiques ne sont pas suffisantes pour les arrêter. Dans un
deuxième temps, nous montrons que suite à une stimulation cutanée, l’ensemble des
cellules RS localisées dans les quatre noyaux réticulés possèdent un patron
d’activation similaire et elles peuvent toutes produire des dépolarisations soutenues
dont le maintien ne dépend pas des réserves de calcium internes. Enfin, les résultats obtenus durant ce doctorat ont permis de mieux comprendre les mécanismes
cellulaires par lesquels l’ensemble des cellules RS intègrent une brève information
sensorielle et la transforment en une réponse soutenue associée à une commande
motrice. / In various animal species, sensory information can initiate locomotion. This
relies on the integration of sensory inputs by the central nervous system. In lampreys,
the spinal locomotor networks are activated and controlled by the reticulospinal cells
(RS) which constitute the main descending system. In turn, RS cells receive
information coming from various synaptic inputs such as the sensory afferents. Once
activated by a brief cutaneous stimulation of sufficient strength, RS cells display
sustained depolarizations of various durations that rely on calcium-dependant
intrinsic properties and lead to the onset of escape swimming. During the course of
this Ph.D, we aimed at determining whether synaptic inputs can modulate the
duration of the sustained depolarizations and if the different populations of RS cells
share the same integrative properties, possibly involving the internal calcium stores.
First, our results show for the first time that excitatory glutamatergic inputs, including
ascending spinal feedback, contribute to prolong the sustained depolarizations for
long periods of time. Cutaneous inputs do not contribute to maintain the sustained
depolarizations and inhibitory glycinergic and GABAergic inputs are not sufficient to
stop them. Second, we show that in response to cutaneous stimulation, the RS located
in the four reticular nuclei display a similar activation pattern and can all produce
sustained depolarizations which do not depend on internal calcium release to be
maintained. Finally, the results obtained during this Ph.D allowed us to better
understand the cellular mechanisms by which the RS cells integrate and transform a
brief sensory information into a sustained response associated with a motor
command.
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