Global ETD Search

51	Cholinergic Projections to the Inferior Colliculus Noftz, William Andrew 31 August 2020 (has links) No description available. Neurosciences Biology Biomedical Research acetylcholine inferior colliculus auditory choline acetyltransferase ChAT midbrain viral tracing hearing neuromodulation arousal cochlear nucleus medial geniculate body NBIC intercollicular tegmentum VAChT
52	Differential Pathologies Resulting From Sound Exposure: Tinnitus Vs. Hearing Loss Longenecker, Ryan James 07 October 2015 (has links) No description available. Behavioral Sciences Biomedical Research Neurosciences Neurobiology Acoustics tinnitus noise-induced hearing loss neurophysiology acoustic startle reflex prepulse inhibition inferior colliculus hyperactivity burst firing
53	Inferred Response Properties of the Synaptic Inputs Underlying Duration-Tuned Neurons in the Big Brown Bat / Response Properties of Inputs to Duration-Tuned Neurons Valdizon-Rodriguez, Roberto January 2019 (has links) Duration tuning in the mammalian inferior colliculus (IC) is created by the interaction of excitatory and inhibitory synaptic inputs. We used extracellular recording and paired-tone stimulation to measure the strength and time-course of the contralateral inhibition and offset-evoked excitation underlying duration-tuned neurons (DTNs) in the IC of the awake bat. The onset time of a short, best duration (BD), excitatory probe tone was varied relative to the onset of a longer-duration, non-excitatory (NE) suppressor tone. Spikes evoked by the roving BD tone were suppressed or facilitated when the stationary NE tone was varied in frequency or amplitude. When the NE tone frequency was presented away from the cell’s best excitatory frequency (BEF) or at lower SPLs, the onset of inhibition was relatively constant whereas the offset and duration of inhibition decreased. Excitatory and inhibitory frequency response areas were measured and best inhibitory frequencies matched best excitatory frequencies; however, inhibitory bandwidths were broader than excitatory bandwidths. Excitatory rate-level and inhibitory suppression-level functions were also measured and the dynamic ranges and inflection points were similar, which is hypothesized to play a role in the level tolerance of responses measured from DTNs. We compared the latency of offset-locked facilitation to the onset or offset of inhibition as a function of frequency and amplitude; we found that the facilitation was more related to the onset of inhibition. Moreover, facilitation typically preceded the offset of inhibition – suggesting that it is a separate excitatory input to DTNs and not a rebound from inhibition. We conclude that DTNs receive inputs that generate and preserve temporal selectivity. / Dissertation / Doctor of Philosophy (PhD) Auditory Physiology Temporal Processing Inferior Colliculus Electrophysiology Hearing Duration Tuning Neuroscience Big Brown Bat Level Tolerance Rate-Level Function Suppression-Level Function Facilitation
54	Implications fonctionnelles du collicule inférieur chez l'humain Champoux, François 12 1900 (has links) No description available. collicule inférieur lésion unilatérale évaluation électrophysiologique processus auditif intégration multisensorielle évaluation comportementale Inferior colliculus unilateral lesion electrophysiological assessment auditory processing multisensory integration psychophysical assessments
55	Implications fonctionnelles du collicule inférieur chez l'humain Champoux, François 12 1900 (has links) Le rôle du collicule inférieur dans les divers processus auditif demeure à ce jour méconnu chez l’humain. À l’aide d’évaluations comportementales et électrophysiologiques, le but des études consiste à examiner l’intégrité fonctionnelle du système nerveux auditif chez une personne ayant une lésion unilatérale du collicule inférieur. Les résultats de ces études suggèrent que le collicule inférieur n’est pas impliqué dans la détection de sons purs, la reconnaissance de la parole dans le silence et l’interaction binaurale. Cependant, ces données suggèrent que le collicule inférieur est impliqué dans la reconnaissance de mots dans le bruit présentés monauralement, la discrimination de la fréquence, la reconnaissance de la durée, la séparation binaurale, l’intégration binaurale, la localisation de sources sonores et, finalement, l’intégration multisensorielle de la parole. / The role of the inferior colliculus in human auditory processing is still poorly understood. We report the results obtained from a 12-year-old boy who suffered a very circumscribed lesion at the level of the right inferior colliculus without additional neurological damage. The child underwent an extensive battery of psychophysical and electrophysiological tests. Results revealed that tonal detection thresholds, speech recognition in the absence of competing auditory input and performance on binaural interaction tasks were unimpaired. However, the pattern of results suggests that auditory functions such as the recognition of low-redundancy speech presented monaurally, frequency discrimination, the recognition of tone-duration patterns, binaural separation, binaural integration, sound-source localization in space as well as mutlisensory integration depend on the integrity of the bilateral auditory pathways at the level of the inferior colliculus. collicule inférieur lésion unilatérale évaluation électrophysiologique processus auditif intégration multisensorielle évaluation comportementale Inferior colliculus unilateral lesion electrophysiological assessment auditory processing multisensory integration psychophysical assessments
56	Altered processing of communication signals in the subcortical auditory sensory pathway in autism Schelinski, Stefanie, Tabas, Alejandro, Kriegstein, Katharina von 04 June 2024 (has links) Autism spectrum disorder (ASD) is characterised by social communication difficulties. These difficulties have been mainly explained by cognitive, motivational, and emotional alterations in ASD. The communication difficulties could, however, also be associated with altered sensory processing of communication signals. Here, we assessed the functional integrity of auditory sensory pathway nuclei in ASD in three independent functional magnetic resonance imaging experiments. We focused on two aspects of auditory communication that are impaired in ASD: voice identity perception, and recognising speech-in-noise. We found reduced processing in adults with ASD as compared to typically developed control groups (pairwise matched on sex, age, and full-scale IQ) in the central midbrain structure of the auditory pathway (inferior colliculus [IC]). The right IC responded less in the ASD as compared to the control group for voice identity, in contrast to speech recognition. The right IC also responded less in the ASD as compared to the control group when passively listening to vocal in contrast to non-vocal sounds. Within the control group, the left and right IC responded more when recognising speech-in-noise as compared to when recognising speech without additional noise. In the ASD group, this was only the case in the left, but not the right IC. The results show that communication signal processing in ASD is associated with reduced subcortical sensory functioning in the midbrain. The results highlight the importance of considering sensory processing alterations in explaining communication difficulties, which are at the core of ASD. info:eu-repo/classification/ddc/610 ddc:610
57	Décodage neuronal dans le système auditif central à l'aide d'un modèle bilinéaire généralisé et de représentations spectro-temporelles bio-inspirées / Neural decoding in the central auditory system using bio-inspired spectro-temporal representations and a generalized bilinear model Siahpoush, Shadi January 2015 (has links) Résumé : Dans ce projet, un décodage neuronal bayésien est effectué sur le colliculus inférieur du cochon d'Inde. Premièrement, On lit les potentiels évoqués grâce aux électrodes et ensuite on en déduit les potentiels d'actions à l'aide de technique de classification des décharges des neurones. Ensuite, un modèle linéaire généralisé (GLM) est entraîné en associant un stimulus acoustique en même temps que les mesures de potentiel qui sont effectuées. Enfin, nous faisons le décodage neuronal de l'activité des neurones en utilisant une méthode d'estimation statistique par maximum à posteriori afin de reconstituer la représentation spectro-temporelle du signal acoustique qui correspond au stimulus acoustique. Dans ce projet, nous étudions l'impact de différents modèles de codage neuronal ainsi que de différentes représentations spectro-temporelles (qu'elles sont supposé représenter le stimulus acoustique équivalent) sur la précision du décodage bayésien de l'activité neuronale enregistrée par le système auditif central. En fait, le modèle va associer une représentation spectro-temporelle équivalente au stimulus acoustique à partir des mesures faites dans le cerveau. Deux modèles de codage sont comparés: un GLM et un modèle bilinéaire généralisé (GBM), chacun avec trois différentes représentations spectro-temporelles des stimuli d'entrée soit un spectrogramme ainsi que deux représentations bio-inspirées: un banc de filtres gammatones et un spikegramme. Les paramètres des GLM et GBM, soit le champ récepteur spectro-temporel, le filtre post décharge et l'entrée non linéaire (seulement pour le GBM) sont adaptés en utilisant un algorithme d'optimisation par maximum de vraisemblance (ML). Le rapport signal sur bruit entre la représentation reconstruite et la représentation originale est utilisé pour évaluer le décodage, c'est-à-dire la précision de la reconstruction. Nous montrons expérimentalement que la précision de la reconstruction est meilleure avec une représentation par spikegramme qu'avec une représentation par spectrogramme et, en outre, que l'utilisation d'un GBM au lieu d'un GLM augmente la précision de la reconstruction. En fait, nos résultats montrent que le rapport signal à bruit de la reconstruction d'un spikegramme avec le modèle GBM est supérieur de 3.3 dB au rapport signal à bruit de la reconstruction d'un spectrogramme avec le modèle GLM. / Abstract : In this project, Bayesian neural decoding is performed on the neural activity recorded from the inferior colliculus of the guinea pig following the presentation of a vocalization. In particular, we study the impact of different encoding models on the accuracy of reconstruction of different spectro-temporal representations of the input stimulus. First voltages recorded from the inferior colliculus of the guinea pig are read and the spike trains are obtained. Then, we fit an encoding model to the stimulus and associated spike trains. Finally, we do neural decoding on the pairs of stimuli and neural activities using the maximum a posteriori optimization method to obtain the reconstructed spectro-temporal representation of the signal. Two encoding models, a generalized linear model (GLM) and a generalized bilinear model (GBM), are compared along with three different spectro-temporal representations of the input stimuli: a spectrogram and two bio-inspired representations, i.e. a gammatone filter bank (GFB) and a spikegram. The parameters of the GLM and GBM including spectro-temporal receptive field, post spike filter and input non linearity (only for the GBM) are fitted using the maximum likelihood optimization (ML) algorithm. Signal to noise ratios between the reconstructed and original representations are used to evaluate the decoding, or reconstruction accuracy. We experimentally show that the reconstruction accuracy is better with the spikegram representation than with the spectrogram and GFB representation. Furthermore, using a GBM instead of a GLM significantly increases the reconstruction accuracy. In fact, our results show that the spikegram reconstruction accuracy with a GBM fitting yields an SNR that is 3.3 dB better than when using the standard decoding approach of reconstructing a spectrogram with GLM fitting. Décodage neuronal bayésien Codage neuronal Colliculus inférieur Modèle linéaire généralisé Modèle bilinéaire généralisé Spikegram Banc de filtres gammatones Bayesian neural decoding Neural encoding Inferior colliculus Maximum likelihood fitting Generalized linear model Generalized bilinear model Spikegram representation Gammatone filter bank
58	Modelling the Neural Representation of Interaural Level Differences for Linked and Unlinked Bilateral Hearing Aids Cheung, Stephanie 11 1900 (has links) Sound localization is a vital aspect of hearing for safe navigation of everyday environments. It is also an important factor in speech intelligibility. This ability is facilitated by the interaural level difference (ILD) cue, which arises from binaural hearing: a sound will be more intense at the nearer ear than the farther. In a hearing-impaired listener, this binaural cue may not be available for use and localization may be diminished. While conventional, bilateral, wide dynamic range compression (WDRC) hearing aids distort the interaural level difference by independently altering sound intensities in each ear, wirelessly-linked devices have been suggested to benefit this task by matching amplification in order to preserve ILD. However, this technology has been shown to have varying degrees of success in aiding speech intelligibility and sound localization. As hearing impairment has wide-ranging adverse impacts to physical and mental health, social activity, and cognition, the task of localization improvement must be urgently addressed. Toward this end, neural modelling techniques are used to determine neural representations of ILD cues for linked and unlinked bilateral WDRC hearing aids. Findings suggest that wirelessly-linked WDRC is preferable over unlinked hearing aids or unaided, hearing-impaired listening, although parameters for optimal benefit are dependent on sound level, frequency content, and preceding sounds. / Thesis / Master of Applied Science (MASc)

Search results