Global ETD Search

11	Cellular physiology and synaptic pharmacology of the rat's external cortex of the inferior colliculus studied using in vitro brain slice techniques / Ahuja, Tarun Kumar, January 1900 (has links) Thesis (Ph. D.)--Carleton University, 2004. / Includes bibliographical references (p. 199-212). Also available in electronic format on the Internet.
12	Mechanisms for gain control and temporal processing in the auditory brainstem of the big brown bat, Eptesicus fuscus / Boatright, Rebecca D., January 1999 (has links) Thesis (Ph. D.)--University of Washington, 1999. / Vita. Includes bibliographical references (leaves 114-121).
13	Sound duration selectivity in bat midbrain inferior colliculus Wu, Chung-Hsin, January 2006 (has links) Thesis (Ph. D.) University of Missouri-Columbia, 2006. / The entire dissertation/thesis text is included in the research.pdf file; the official abstract appears in the short.pdf file (which also appears in the research.pdf); a non-technical general description, or public abstract, appears in the public.pdf file. Title from title screen of research.pdf file (viewed on August 9, 2007) Vita. Includes bibliographical references.
14	Audiovisual Integration in the Saccadic System of the Barn Owl Whitchurch, Elizabeth A., 1976- 12 1900 (has links) xiv, 152 p. Adviser: Terry Takahashi (Biology Dept.). Chapter 2 of this dissertation has been previously published in the Journal of Neurophysiology. Citation: Whitchurch EA and Takahashi TT. Combined auditory and visual stimuli facilitate head saccades in the barn owl (Tyto alba). J Neurophysiol 96: 730-745, 2006. / A print copy of this title is available through the UO Libraries under the call number: SCIENCE QL696.S85 W54 2006 / Survival depends on our ability to detect and integrate sensory information from multiple modalities, allowing for the most efficient behavioral response. For example, barn owls must combine sights and sounds from the environment to localize potential prey. A vole scurrying through a drift of dried leaves is more likely to meet its doom if a nearby owl can both faintly see and hear it. How does the brain take two physically discreet inputs and combine them into a unified representation of the surrounding multisensory world? Moreover, how is this internal representation transformed into the most efficient behavioral response? This dissertation comprises original research addressing these questions in the barn owl with two distinct approaches: First, Chapters II and III describe orientation behavior in response to auditory, visual, and audiovisual stimuli. Chapter II probes the effect of stimulus strength on saccadic behavior and the nature of audiovisual integration, and was taken from a co-authored publication. Chapter III explores the behavioral consequence of an induced stimulus asynchrony in audiovisual integration and was taken from a co-authored manuscript being prepared for publication. The second experimental approach is described in Chapters IV and V. These chapters probe the physiological basis of saccadic behavior by measuring single-neuron responses to auditory, visual, and audiovisual stimuli. Chapter IV describes how auditory responses of neurons from the external nucleus of the inferior colliculus depend on sound pressure level. Chapter V describes activity of optic tectum neurons in response to auditory, visual, and audiovisual stimuli. The behavioral findings described herein suggest that barn owls often incorporate both the speed of the auditory system and the accuracy of the visual system when localizing a multisensory stimulus, even when the two modalities are presented asynchronously. The physiological studies outlined in this dissertation show that sensory representations in the midbrain can be used to predict general trends in saccadic behavior: Neuronal thresholds were within the range of observed behavioral thresholds. Responses to multisensory stimuli were enhanced relative to unisensory stimuli, possibly corresponding to enhanced multisensory behavior. These data support fundamental rules in multisensory integration that may apply across species. Barn owl Behavior Electrophysiology Optic tectum Saccade Audiovisual Inferior colliculus
15	Neuronal correlates of implicit learning in the mammalian midbrain Cruces Solis, Hugo 26 April 2016 (has links) No description available. 570 plasticity inferior colliculus learning auditory processing auditory filtering Biologie (PPN619462639)
16	Envolvimento de receptores opióides µ1 e das redes neurais do colículo inferior na analgesia pós-ictal / Involvement of the µ1-opioid receptor-mediated system and inferior colliculus in the post-ictal analgesia Felippotti, Tatiana Tocchini 09 December 2005 (has links) A antinocicepção é descrita como redução na capacidade de perceber a dor, sendo importante componente para o organismo, quando este está envolvido em situações de emergência. Muitos neurotransmissores e seus receptores estão envolvidos nas diversas formas de analgesia, como por exemplo, monoaminas, acetilcolina e opióides endógenos. A analgesia pós-ictal é uma das muitas formas de antinocicepção em que o recrutamento de cada um desses neurotransmissores é descrito. Algumas evidências mostram o envolvimento de estruturas mesencefálicas em processos antinociceptivos (GEBHART & TOLEIKIS, 1978; COIMBRA e col., 1992; COIMBRA & BRANDÃO, 1997; CASTILHO e col., 1999) O colículo inferior é a estrutura mesencefálica responsável pela origem e expressão de crises audiogênicas (MCCOWN e col, 1987). Estruturas como a substância cinzenta periaquedutal, camadas profundas do colículo superior e núcleo central do colículo inferior, têm sido implicadas em processos convulsivos (DE PAULIS e col., 1990; CARDOSO e col., 1994, MCCOWN e col., 1984). Recentes relatos demonstraram que a estimulação dessas estruturas, em cujo substrato neural há neurônios positivos para beta-endorfina e leu-encefalina (EICHENBERGER e col., 2002; OSAKI e col., 2003) pode gerar processos antinociceptivos (CASTILHO e col., 1999; GEBHART & TOLEIKIS, 1978), seja de natureza opióide (NICHOLS e col., 1989), seja de natureza monoaminérgica (COIMBRA e col., 1992; COIMBRA & BRANDÃO, 1997). Neste trabalho, foi realizado o estudo periférico para investigar o envolvimento, mais especificamente, dos receptores opióides µ1 na analgesia que segue as crises convulsivas evocadas pela administração de um antagonista de canais de Cl- ligados ao GABA, como é o caso do pentilenotetrazol, administrado por via intraperitoneal, após o pré-tratamento com o bloqueador opióide específico, o naloxonazine, administrado em diferentes doses. Assim também, estudou-se a participação do colículo inferior nesse processo de inibição de dor, mensurado pelo teste de retirada de cauda. O pré-tratamento com naloxonazine, administrado por via intraperitoneal por tempo prolongado (24h), mas não agudamente (10 min), antagonizou a antinocicepção evocada por convulsões tônico-clônicas. Microinjeções de naloxonazine realizadas nos núcleos central, cortical externo e cortical dorsal do colículo inferior antagonizaram a analgesia induzida por crises convulsivas tônico-clônicas, efeito que segue uma curva dose-resposta, bem como, causaram a redução do tempo do processo convulsivo induzido pelo bloqueio ionóforo de canais de cloro ligados ao GABA. Em vista disso, podemos sugerir o envolvimento de receptores µ1-opióides e das redes neurais do colículo inferior na elaboração da analgesia pós-ictal, e na modulação de crises convulsivas tônico-clônicas. / The post-ictal analgesia is an impressive kind of antinociception, in wich the involvement of many neural systems has been demonstrated. The inferior colliculus is a brainstem structure responsible for the origin and elaboration of convulsive responses (MCCOWN e col, 1987) in the presence of audiogenic stimulus or during the treatment of supralimiar administration of GABAergic antagonists. Mesencephalic structures such as the periaqueductal gray matter, the deep layers of the superior colliculus and the central nucleus of the inferior colliculus have been implicated in convulsive processes (DE PAULIS e col., 1990; CARDOSO e col., 1994, MCCOWN e col., 1984). The stimulation of these areas, in whose neural substrates there are beta-endorphin- and leu-enkephalin-positive neurons (EICHENBERGER e col., 2002; OSAKI e col., 2003) evokes antinociceptive processes (CASTILHO e col., 1999; GEBHART & TOLEIKIS, 1978), of either opioid (NICHOLS e col., 1989) or monoaminergic COIMBRA e col., 1992; COIMBRA & BRANDÃO, 1997) nature. The aim of the present work is to investigate the involvement of the µ1-opioid receptor-mediated system in the post-ictal analgesia. The antinociceptive responses were recorded by the tail-flick test, after the pre-treatment with the specific opioid antagonist naloxonazine, administrated either by peripheral (intraperitoneally) or central (into the inferior colliculus neural network) way, in different doses. The peripheral lon-lasting (24h) but not acute (10 min) pre-treatment with naloxonazine antagonized the analgesia evoked by tonic-clonic convulsions. Microinjections of naloxonazine in the central, dorsal cortical and external cortical nuclei of inferior colliculus antagonized the analgesia induced by tonic-clonic reactions, whose effect followed a dose-response curve. Also, microinjections of naloxonazine into the inferior colliculus decrease the time of convulsions reactions. These findings suggest the involvement of µ1-opiate receptors and the neural networks of the inferior colliculus in this antinociceptive phenomenon, and, in addition, the involvement of these receptors in the modulation of tonic-clonic convulsive reactions has been suggested. In conclusion, the endogenous opioid peptides-mediated system of the neural networks of the inferior colliculus is clearly implicated in the elaboration of the post-ictal antinociception and in the modulation of tonic-clonic convulsions. In theses processes, µ1-opioid receptors of the central nucleus, as well as of the cortical dorsal and cortical external nuclei of the inferior colliculus are crucially involved. analgesia pós-ictal inferior colliculus Naloxonazine naloxonazine opioid opióides post-ictal analgesia receptores µ1 µ1-receptors
17	Effects of Aging and Corticofugal Modulation on Startle Behavior and Auditory Physiology Marisa A Dowling (6689462) 10 June 2019 (has links) Frequency-modulated (FM) sweeps play a key role in species specific communication. Evidence from previous studies have shown that central auditory processing has been shown to vary based on the language spoken, which leads to the idea of experience-driven pitch encoding. Other studies have also shown that there is a decrease in this pitch encoding with aging. Using both iterated rippled noise (IRN) and frequency modulated amplitude modulation (FM/AM) methods to create complex pitch sweeps mimicking speech, allows for the processing of pitch to be determined. Neuromodulation using pharmacogenetics allows for the targeted inhibition of a specific neural pathway. Based on previous studies, the primary auditory cortex to inferior colliculus (A1/IC) pathway is hypothesized to be important in pitch encoding. However, there is a lack of evidence on specifically how the pitch information is encoded in the auditory system and how aging impacts the processing. To solve these issues, age-related changes in pitch encoding and maintaining pitch encoding through neuromodulation were characterized in the using behavioral and electrophysiology methods. Behavioral discrimination abilities, measured by modulation of the acoustic startle response, between pitch sweep direction and pitch sweep creation methods highlighted a reduced discrimination in aging and A1/IC inhibited rats. Electrophysiology changes was assessed using envelope-following responses (EFRs) and suggested a decreased initial frequency locking in aging and decrease in frequency locking overall with A1/IC pathway inhibition. Comparison of behavioral and electrophysiology to IRN and FM/AM stimuli show that the decrease in age-related processing as well as A1/IC pathway processing is larger in the behavioral pitch sweep discrimination than in the reduction in EFRs. auditory neuroscience auditory DREADDs inferior colliculus auditory cortex
18	Papel dos mecanismos GABAérgicos do colículo inferior e da substância cinzenta periaquedutal na interface sensoriomotora do medo e ansiedade / Role of GABAergic mechanisms in the inferior colliculus and periaqueductal gray matter on the sensorimotor gating of fear and anxiety Saito, Viviane Mitsuko Neves 19 May 2016 (has links) As reações incondicionadas de defesa observadas em mamíferos são organizadas pelo Sistema Encefálico de Aversão (SEA), composto, entre outras estruturas, pela substância cinzenta periaquedutal dorsal (SCPd) e o colículo inferior (CI). Tem sido proposto que o CI seja parte do circuito sensoriomotor para os estímulos auditivos de natureza aversiva e a SCPd como a principal via de saída (output) do SEA para a elaboração de comportamentos defensivos. Ambas as estruturas são reguladas tonicamente pelo neurotransmissor inibitório ácido gama-aminobutírico (GABA). Este trabalho aborda a mediação química GABA/Benzodiazepínica (BZD) do processamento da informação aversiva no CI e das respostas de medo elaboradas pela SCPd. Grupos independentes de animais submetidos ao implante de quimitrodos (eletrodos acoplados a cânulas-guia para injeção de drogas) foram usados para avaliar no CI e SCPd os efeitos de injeções locais de muscimol (agonista de receptores GABA-A), semicarbazida (inibidor da síntese da enzima precursora do GABA descarboxilase do ácido glutâmico) ou midazolam (agonista BZD). Foram registrados potenciais evocados auditivos (PEA) no CI como medida eletrofisiológica da ativação neuronial, além da determinação dos limiares de congelamento e fuga, com o procedimento de estimulação elétrica (EE), tanto do CI quanto da SCPd. A mesma abordagem farmacológica com injeções de drogas intra-CI foi empregada em animais submetidos ao teste do Labirinto em Cruz Elevado (LCE), um modelo animal tradicional de ansiedade. Adicionalmente, investigou-se a participação de ambas as estruturas na expressão do comportamento de desligar uma luz de intensidade aversiva em um novo teste de medo incondicionado (Light Switch Off Test; LSOT) recentemente proposto pelo nosso grupo. Encontramos uma clara segregação funcional entre a porção dorsal e ventral do CI, sendo a última envolvida nos comportamentos defensivos. Mecanismos GABAérgicos em ambas as estruturas influenciam a amplitude do PEA e o congelamento pós-fuga da EE, sugerindo uma relação funcional entre as duas estruturas. Já no LSOT, os resultados indicam o envolvimento de mecanismos GABAérgicos do vCI, mas não da SCPd, na modulação da resposta incondicionada à luz em ratos. Os resultados obtidos permitem ampliar o conhecimento atual sobre a neurobiologia dos estados de medo e ansiedade, em uma abordagem integrada dos mecanismos de processamento das informações sensoriais e da expressão de reações de defesa. / Unconditioned defense reactions observed in mammals are organized by the Brain Aversive System, comprising, among other structures, the dorsal periaqueductal gray matter (dPAG) and the inferior colliculus (IC). It has been proposed that the IC is part of the sensorimotor circuitry that processes aversive auditory information and the dPAG is considered the main neural substrate for the expression of defensive behaviors. Both structures are tonically regulated by the inhibitory neurotransmitter gamma-aminobutyric acid (GABA). This work addresses the chemical mediation of GABA/Benzodiazepine (BZD) on aversive information processing in the IC and the elaboration of fear responses by dPAG. Independent groups of animals implanted with chemitrodes (electrodes attached to a guide cannula for drug injection) have been used to evaluate the IC and dPAG regarding the effects of local injections of GABAergic agents (muscimol, semicarbazide, and midazolam). Auditory evoked potentials (AEP) have been recorded in the IC as a measure of electrophysiological neuronal activation, in addition to determining the thresholds of defensive freezing and flight behaviors, using the electrical stimulation (EE) procedure in both IC and dPAG. The same pharmacological regimen of drug injections intra-dPAG and intra-CI have been applied to animals subjected to the elevated plus maze (EPM), a well-known animal model of anxiety, and also to a novel animal test for innate fear (Light Switch Off Test, LSOT) that has been developed and proposed by our group. We found a clear functional segregation between the dorsal and ventral portions of the IC, the latter being the specific collicular substrate of defensive behaviors. GABAergic mechanisms in both structures influence the amplitude of the AEP and post-stimulation freezing of EE, suggesting a functional link between the two structures. In the LSOT, our data indicate the involvement of GABAergic mechanisms of the ICv, but not the dPAG, in the modulation of the unconditioned response to light in rats. These original findings presented here contribute to broaden the current knowledge on the neurobiology of fear and anxiety, in an integrative approach of the mechanisms underlying sensory processing and the expression of defensive behaviors. Ansiedade. anxiety. Colículo inferior fear GABA GABA Inferior colliculus Medo periaqueductal gray matter Substância cinzenta periaquedutal
19	Anatomical and physiological properties of the superior paraolivary nucleus in the rat Kulesza, Randy J., January 2002 (has links) Thesis (Ph. D.)--West Virginia University, 2002. / Title from document title page. Document formatted into pages; contains x, 181 p. : ill. (some col.). Vita. Includes abstract. Includes bibliographical references (p. 161-179).
20	Descending control of responses in the auditory midbrain Seluakumaran, Kumar January 2007 (has links) [Truncated abstract] The mammalian inner ear is innervated by the efferent olivocochlear system which is divided into medial and lateral systems. In anaesthetised animals, medial olivocochlear (MOC) axons can be electrically stimulated at the floor of the IVth ventricle. MOC stimulation suppresses the spontaneous activity and sound-evoked responses of primary afferents by its actions on outer hair cells. Effects of MOC stimulation have been also reported on responses of neurons in the cochlear nucleus, the first central auditory center receiving cochlear input. However, very little is known about the net results of MOC effects in higher order neurons. This issue was investigated by electrically stimulating MOC axons at the IVth ventricle and recording extracellular single unit activities in the central nucleus of the inferior colliculus (CNIC) of anaesthetised guinea pigs. For the first part of the study, anatomical and neurophysiological studies were carried out to establish that the focal midline MOC stimulation can selectively stimulate MOC axons without any current spread to adjacent ascending fibers. The MOC stimulation and CNIC recordings were then carried out in a series of experiments that included normal hearing animals, animals treated acutely with gentamicin (in which the acetylcholine-mediated peripheral suppression of the olivocochlear efferents is selectively eliminated) and partially deafened animals. ... However, in other CNIC neurons, effects could not be so explained, showing either additional suppression or even marked excitatory effects. (4) MOC stimulation also suppressed the spontaneous activity of CNIC neurons in normal hearing animals. When similar efferent stimulation was carried out in partially deafened animals, the abnormally high spontaneous activity of some CNIC neurons in the deafened frequency regions was also transiently suppressed by MOC shocks. The results from this study clearly demonstrate that the MOC system can modulate the responses of midbrain neurons in a more complex manner compared to the effects seen in the periphery. The more complex effects seen for responses to tones in quiet and in noisy background are likely to result from a complex interplay between altered afferent input in the cochlea and central circuitry. In addition, the ability of MOC efferents in suppressing the normal and abnormal spontaneous activity in the midbrain also could have implications for the role of the descending system in the pathophysiology and treatment of tinnitus. Acoustic nerve Inferior colliculus Auditory pathways Cochlear nucleus Guinea pigs -- Physiology Electrocochleography Olivocochlear system

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