Caractéristiques spatiales des cellules auditives des couches profondes du collicule supérieur du rat

Mémoire numérisé par la Direction des bibliothèques de l'Université de Montréal

Implications fonctionnelles du collicule inférieur chez l'humain

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

Auditory Event-Related Potentials Associated With Music Perception in Cochlear Implant Users

A short review of the literature on auditory event-related potentials and mismatch negativities (MMN) in cochlear implant users engaged in music-related auditory perception tasks is presented. Behavioral studies that have measured the fundamental aspects of music perception in CI users have found that they usually experience poor perception of melody, pitch, harmony as well as timbre (Limb and Roy, 2014). This is thought to occur not only because of the technological and acoustic limitations of the device, but also because of the biological alterations that usually accompany deafness. In order to improve music perception and appreciation in individuals with cochlear implants, it is essential to better understand how they perceive music. As suggested by recent studies, several different electrophysiological paradigms can be used to reliably and objectively measure normal-hearing individuals' perception of fundamental musical features. These techniques, when used with individuals with cochlear implants, might contribute to determine how their peripheral and central auditory systems analyze musical excerpts. The investigation of these cortical activations can moreover give important information on other aspects related to music appreciation, such as pleasantness and emotional perception. The studies reviewed suggest that cochlear implantation alters most fundamental musical features, including pitch, timbre, melody perception, complex rhythm, and duration (e.g., Koelsch et al., 2004b; Timm et al., 2012, 2014; Zhang et al., 2013a,b; Limb and Roy, 2014). A better understanding of how individuals with cochlear implants perform on these tasks not only makes it possible to compare their performance to that of their normal-hearing peers, but can also lead to better clinical intervention and rehabilitation

The Right Hemisphere Planum Temporale Supports Enhanced Visual Motion Detection Ability in Deaf People: Evidence from Cortical Thickness

After sensory loss, the deprived cortex can reorganize to process information from the remaining modalities, a phenomenon known as cross-modal reorganization. In blind people this cross-modal processing supports compensatory behavioural enhancements in the nondeprived modalities. Deaf people also show some compensatory visual enhancements, but a direct relationship between these abilities and cross-modally reorganized auditory cortex has only been established in an animal model, the congenitally deaf cat, and not in humans. Using T1-weighted magnetic resonance imaging, we measured cortical thickness in the planum temporale, Heschl’s gyrus and sulcus, the middle temporal area MT+, and the calcarine sulcus, in early-deaf persons. We tested for a correlation between this measure and visual motion detection thresholds, a visual function where deaf people show enhancements as compared to hearing. We found that the cortical thickness of a region in the right hemisphere planum temporale, typically an auditory region, was greater in deaf individuals with better visual motion detection thresholds. This same region has previously been implicated in functional imaging studies as important for functional reorganization. The structure-behaviour correlation observed here demonstrates this area’s involvement in compensatory vision and indicates an anatomical correlate, increased cortical thickness, of cross-modal plasticity

Audiovisual Segregation in Cochlear Implant Users

It has traditionally been assumed that cochlear implant users de facto perform atypically in audiovisual tasks. However, a recent study that combined an auditory task with visual distractors suggests that only those cochlear implant users that are not proficient at recognizing speech sounds might show abnormal audiovisual interactions. The present study aims at reinforcing this notion by investigating the audiovisual segregation abilities of cochlear implant users in a visual task with auditory distractors. Speechreading was assessed in two groups of cochlear implant users (proficient and non-proficient at sound recognition), as well as in normal controls. A visual speech recognition task (i.e. speechreading) was administered either in silence or in combination with three types of auditory distractors: i) noise ii) reverse speech sound and iii) non-altered speech sound. Cochlear implant users proficient at speech recognition performed like normal controls in all conditions, whereas non-proficient users showed significantly different audiovisual segregation patterns in both speech conditions. These results confirm that normal-like audiovisual segregation is possible in highly skilled cochlear implant users and, consequently, that proficient and non-proficient CI users cannot be lumped into a single group. This important feature must be taken into account in further studies of audiovisual interactions in cochlear implant users

Speech and Non-Speech Audio-Visual Illusions: A Developmental Study

It is well known that simultaneous presentation of incongruent audio and visual stimuli can lead to illusory percepts. Recent data suggest that distinct processes underlie non-specific intersensory speech as opposed to non-speech perception. However, the development of both speech and non-speech intersensory perception across childhood and adolescence remains poorly defined. Thirty-eight observers aged 5 to 19 were tested on the McGurk effect (an audio-visual illusion involving speech), the Illusory Flash effect and the Fusion effect (two audio-visual illusions not involving speech) to investigate the development of audio-visual interactions and contrast speech vs. non-speech developmental patterns. Whereas the strength of audio-visual speech illusions varied as a direct function of maturational level, performance on non-speech illusory tasks appeared to be homogeneous across all ages. These data support the existence of independent maturational processes underlying speech and non-speech audio-visual illusory effects

Occlusion of LTP-Like Plasticity in Human Primary Motor Cortex by Action Observation

Passive observation of motor actions induces cortical activity in the primary motor cortex (M1) of the onlooker, which could potentially contribute to motor learning. While recent studies report modulation of motor performance following action observation, the neurophysiological mechanism supporting these behavioral changes remains to be specifically defined. Here, we assessed whether the observation of a repetitive thumb movement – similarly to active motor practice – would inhibit subsequent long-term potentiation-like (LTP) plasticity induced by paired-associative stimulation (PAS). Before undergoing PAS, participants were asked to either 1) perform abductions of the right thumb as fast as possible; 2) passively observe someone else perform thumb abductions; or 3) passively observe a moving dot mimicking thumb movements. Motor evoked potentials (MEP) were used to assess cortical excitability before and after motor practice (or observation) and at two time points following PAS. Results show that, similarly to participants in the motor practice group, individuals observing repeated motor actions showed marked inhibition of PAS-induced LTP, while the “moving dot” group displayed the expected increase in MEP amplitude, despite differences in baseline excitability. Interestingly, LTP occlusion in the action-observation group was present even if no increase in cortical excitability or movement speed was observed following observation. These results suggest that mere observation of repeated hand actions is sufficient to induce LTP, despite the absence of motor learning

Évolution temporelle des concentrations de mercure dans les plumes d’oiseaux de proie au Québec

Des analyses de mercure ont été effectuées sur des plumes de 7 espèces d’oiseaux de proie récoltées au Québec entre les années 1906 à 2002. Une diminution temporelle des concentrations a été observée chez les aigles royaux et les autours des palombes. Chez les jeunes balbuzards pêcheurs élevés à proximité des réservoirs hydroélectriques, une diminution des concentrations de mercure d’environ 33 % est observée entre 1989-1991 et 1997. Cette diminution serait liée à la baisse des concentrations de mercure chez les poissons vivant dans les réservoirs. Les espèces se nourrissant dans les milieux aquatiques, le pygargue à tête blanche et le balbuzard pêcheur, présentent des concentrations de mercure de 2 à 30 fois plus élevées que celles qui s’alimentent en milieux terrestres. Chez le pygargue à tête blanche, les concentrations apparaissent élevées et augmentent avec l’âge des oiseaux échantillonnés.Feathers collected from 7 raptor species in Québec between 1906 and 2002 were screened for mercury. The concentrations found in golden eagle and northern goshawk feathers decreased over time. In addition, over the 6- to 8-year period between 1989-1991 and 1997, a 33% decrease in mercury levels was observed in feathers collected from osprey chicks reared in nests close to hydroelectric reservoirs. This decrease is likely linked to a reduction in the mercury levels in the tissues of fish within the reservoirs. In general, however, feathers from bald eagles and ospreys, which feed in aquatic environments, showed mercury levels from 2 to 30 times higher than those from species foraging in terrestrial environments. In the case of the bald eagle, mercury levels were high and the concentration increased with the age of the birds