A STUDY OF THE RANDOM GAP DETECTION TEST-A TEST USED TO IDENTIFY DISORDERS OF AUDITORY TIMING

SWAISGOOD, ERIN K.

11 October 2001

No description available.

Health Sciences, Speech Pathology

central auditory processing

temporal processing

Random Gap Detection Test

Temporal Processing and Speech Perception in Cochlear Implant Recipients and Normal Hearing Listeners

Blankenship, Chelsea M.

27 September 2020

No description available.

Audiology

Cochlear Implant

Cortical Auditory Evoked Potential

Temporal Processing

Speech Perception

Gap Detection

Monaural and Binaural Response Properties of Duration-Tuned Neurons in the Big Brown Bat

Sayegh, Riziq

10 1900

<p>Neurons throughout the auditory pathway respond selectively to the frequency and amplitude of sound. In the auditory midbrain there exists a class of neurons that are also selective to the duration of sound. These duration-tuned neurons (DTNs) provide a potential neural mechanism underlying temporal processing in the central nervous system. Temporal processing is necessary for human speech, discriminating species-specific acoustic signals as well as echolocation. This dissertation aims to explore the role and underlying mechanisms of DTNs through single-unit in vivo electrophysiological recordings in the auditory midbrain of the big brown bat. The durations that DTNs are selective to in echolocating and non-echolocating species are first compared to the durations of each species vocalizations. This comparison reveals that the durations DTNs respond best to correlates to the durations of echolocation calls in echolocating species and to species-specific communication calls in non-echolocating species. The ability of DTNs in the bat to respond to stimulus parameters thought to be important for echolocation processing, such as pairs of pulses and binaural sound localization cues, are subsequently tested. The responses of DTNs to a paired tone spike suppressing paradigm presented monaurally and binaurally are also compared to characterize the role each ear plays in recruiting inhibition known to be involved in duration tuning. The results show that DTNs are able to respond to pairs of pulses at a timescale relevant to bat echolocation, and a majority also responded selectively to binaural sound localizing cues. Nearly half (48%) of DTNs did not show spike suppression to an ipsilaterally presented suppressing tone. When ipsilaterally evoked spike suppression occurred, the effect was significantly smaller than the suppression evoked by a contralateral suppressing tone. These findings provide evidence that DTNs may play a role in echolocation in bats as DTNs are able to respond to the outgoing pulse and returning echoes and localize the echo source and that the neural mechanism underlying duration tuning is monaural in nature.</p> / Doctor of Philosophy (PhD)

Auditory Physiology

Inferior Colliculus

Electrophysiology

Temporal Processing

Duration Tuning

Echolocation

Systems Neuroscience

Systems Neuroscience

The perceived timing of events across different sensory modalities : a psychophysical investigation of multisensory time perception in humans

Hanson, James Vincent Michael

January 2009

The experiments reported within this thesis use psychophysical techniques to examine the factors which determine perceived multisensory timing in humans. Chapters 1 and 2 describe anatomical and psychophysical features of temporal processing, respectively, whilst Chapter 3 introduces the reader to psychophysical methods. Chapter 4 examines the relationship between two measures of sensory latency, reaction time (RT) and crossmodal temporal order judgment (TOJ). Despite task and attentional manipulations the two measures do not correlate, suggesting that they measure some fundamentally different aspect(s) of temporal perception. Chapter 5 examines the effects of adaptation to asynchronous stimulus pairs on perceived audiovisual (AV), audiotactile (AT) and visuotactile (VT) temporal order. Significant temporal shifts are recorded in all three conditions. Evidence is also presented showing that crossmodal TOJs are intransitive. Chapter 6 shows that concurrent adaptation to two sets of asynchronous AV stimulus pairs causes perceived AV temporal order to recalibrate at two locations simultaneously, and that AV asynchrony adaptation effects are significantly affected by observers' attention during adaptation. Finally, Chapter 7 shows that when observers are accustomed to a physical delay between motor actions and sensory events, an event presented at a reduced delay appears to precede the causative motor action. The data are well-described by a simple model based on a strong prior assumption of physical synchrony between motor actions and their sensory consequences.

150.724

Preadolescent Musical Training Influences Spatial Listening and Temporal Processing Skills

Schneiderman, Brett, Dula, Erin, Elangovan, Saravanan

03 March 2017

We examined the hypothesis that neural plasticity following preadolescent musical training improves spatial listening and temporal processing. Two groups of children with (>2 years) and without (< 6 months) significant musical training were assessed on binaural processing, spatial memory, and gap detection. Results demonstrated the musician group had an advantage in spatial listening and auditory memory. These findings suggest an early emergence of listening benefits and also support musical training as a rehabilitative strategy to ameliorate specific auditory processing deficits.

preadolescent

musical training

spatial listening

temporal processing skills

auditory processing

Audiology and Speech-Language Pathology

Speech Pathology and Audiology

Temporal Processing in Low-Frequency Channels: Effects of Age and Hearing Loss in Middle-Aged Listeners

Leigh-Paffenroth, Elizabeth D., Elangovan, Saravanan

01 July 2011

Background: Hearing loss and age interfere with the auditory system's ability to process temporal changes in the acoustic signal. A key unresolved question is whether high-frequency sensorineural hearing loss (HFSNHL) affects temporal processing in the low-frequency region where hearing loss is minimal or nonexistent. A second unresolved question is whether changes in hearing occur in middle-aged subjects in the absence of HFSNHL. Purpose: The purpose of this study was twofold: (1) to examine the influence of HFSNHL and aging on the auditory temporal processing abilities of low-frequency auditory channels with normal hearing sensitivity and (2) to examine the relations among gap detection measures, self-assessment reports of understanding speech, and functional measures of speech perception in middle-aged individuals with and without HFSNHL. Research Design: The subject groups were matched for either age (middle age) or pure-tone sensitivity (with or without hearing loss) to study the effects of age and HFSNHL on behavioral and functional measures of temporal processing and word recognition performance. These effects were analyzed by individual repeated-measures analyses of variance. Post hoc analyses were performed for each significant main effect and interaction. The relationships among the measures were analyzed with Pearson correlations. Study Sample: Eleven normal-hearing young adults (YNH), eight normal-hearing middle-aged adults (MANH), and nine middle-aged adults with HFSNHL were recruited for this study. Normal hearing sensitivity was defined as pure-tone thresholds ≤25 dB HL for octave frequencies from 250 to 8000 Hz. HFSNHL was defined as pure-tone thresholds ≤25 dB HL from 250 to 2000 Hz and ≥35 dB HL from 3000 to 8000 Hz. Data Collection and Analysis: Gap detection thresholds (GDTs) were measured under within-channel and between-channel conditions with the stimulus spectrum limited to regions of normal hearing sensitivity for the HFSNHL group (i.e., <2000 >Hz). Self-perceived hearing problems were measured by a questionnaire (Abbreviated Profile of Hearing Aid Benefit), and word recognition performance was assessed under four conditions: quiet and babble, with and without low-pass filtering (cutoff frequency = 2000 Hz). Results: The effects of HFSNHL and age were found for gap detection, self-perceived hearing problems, and word recognition in noise. The presence of HFSNHL significantly increased GDTs for stimuli presented in regions of normal pure-tone sensitivity. In addition, middle-aged subjects with normal hearing sensitivity reported significantly more problems hearing in background noise than the young normal-hearing subjects. Significant relationships between self-report measures of hearing ability in background noise and word recognition in babble were found. Conclusions: The conclusions from the present study are twofold: (1) HFSNHL may have an off-channel impact on auditory temporal processing, and (2) presenescent changes in the auditory system of MANH subjects increased self-perceived problems hearing in background noise and decreased functional performance in background noise compared with YNH subjects.

speech perception

gap detection

hearing loss

normal hearing sensitivity

temporal processing

Audiology and Speech-Language Pathology

Speech Pathology and Audiology

Categorical Perception and Auditory Temporal Processing in Bilingual English-Spanish Speakers

Elangovan, Saravanan, Stuart, Andrew

01 January 2008

No description available.

categorical perception

auditory temporal processing

bilingual

language

Spanish

English

speech language pathology

Audiology and Speech-Language Pathology

Speech Pathology and Audiology

Hormone Replacement Therapy (HRT) Modulates Peripheral and Central Auditory System Processing With Aging

Williamson, Tanika

08 November 2016

After the findings were reported for the Women’s Health Initiative (WHI) study in the past decade, there has been a significant decline in the overall use of hormone replacement therapy (HRT) among women. However, there are still millions of middle-aged, menopausal women in the U.S. who are currently undergoing hormone therapy. Their reasons for continuing treatment include relief of severe menopausal symptoms, aid in the management of osteoporosis and reduction in the risk of colon cancer (Ness et al., 2005). The purpose of the following investigation was to evaluate the impact of HRT on the central and peripheral auditory systems both during and after treatment. Over the course of the study, hormone treatments were administered to female aging CBA/CaJ mice to observe what effects estrogen (E) and progestin (P) have on the peripheral and central auditory systems. Female CBA/CaJ middle age mice were ovariectomized and placed into 4 HRT groups (E, P, E+P and Placebo [Pb]). Hormone treatment lasted 6 months followed by a recovery/washout period of 1 month. During this time, electrophysiology tests such as auditory brainstem responses (ABR) and ABR gap in noise (GIN) were used to measure neural activity for the auditory nerve and brainstem. Distortion product otoacoustic emission (DPOAE) testing was also implemented to assess the functional status of the outer hair cells (OHC) and their ability to amplify sound in the cochlea. After 6 months of treatment, animals treated with E exhibited the least amount of changes in ABR thresholds and ABR GIN amplitudes than any other subject groups. Interestingly, P animals exhibited an abrupt increase in ABR thresholds only 3 months after treatment; however, for ABR GIN amplitude levels a progressive reduction observed throughout the study. E+P and Pb animals showed signs of accelerated age-related hearing loss (ARHL) with significantly elevated ABR thresholds and dwindling ABR GIN amplitude levels. No significant signs of recovery were observed for any of the hormone groups. Therefore, in the present murine investigation, the effects of HRT were long lasting. To further expand on the results obtained for the electrophysiology tests, molecular biology experiments were performed to evaluate the expression of IGF-1R and FoxO3 in the cochlea during hormone therapy, from both in vitro and in vivo perspectives. Both genes play significant roles in the PI3K/AKT pathway and were specifically chosen because of their role in anti-apoptotic responses and cell survival. It was hypothesized that E attenuates the effects of ARHL via the PI3K/AKT pathway by up-regulating IGF-1R and FoxO3 to counteract the effects of oxidative stress in the aging mammalian cochlea. qPCR experiments were performed with stria vascularis (SV) lateral wall cells extracted from the cochlea of each animal in the hormone groups post-treatment (in vivo) and in SVK-1 cells treated with HRT over various lengths of time (in vitro) to evaluate the expression levels of IGF-1R and FoxO3. In-vivo experiments showed that the E-treated animals had significantly higher IG-1R levels compared to the other subject groups after treatment was discontinued. Similarly, IGF-1R levels steadily increased for E-treated SVK-1 cells over the course of hormone therapy, compared to P and E+P cells. FoxO3 expression, on the other hand, declined for all of the hormone-treated cells groups, relative to control SVK-1 cells (in vitro), and no statistical differences were detected for FoxO3 levels among the post-treatment animals (in vivo). These findings indicate that there is cross talk between E and IGF-1R involving the PI3K/AKT pathway, which contributes to the delayed onset of ARHL observed during HRT with E. Meanwhile, FoxO3 may not play a role in neuro-protective properties in the cochlea during HRT, as initially hypothesized.

Estrogen

Progesterone

Auditory Brainstem Responses (ABRs)

Temporal Processing

IGF-1 Pathway

FOXO3

Neurosciences

Pharmacology

Speech Pathology and Audiology

Memory for random time patterns in the sensory system / Mémoire de séquences temporelles aléatoires dans un système sensoriel

Kang, HiJee

18 December 2017

Le temps est une dimension universelle traitée par les systèmes sensoriels, qui est essentielle pour attribuer un sens à des stimuli comme la parole ou la musique pour l'audition. Cependant, les mécanismes requis pour le traitement temporel restent en grande part méconnus. Dans cette thèse, nous avons examiné un type de mécanisme faisant sans doute partie intégrante de tout traitement temporel : la formation de nouvelles traces mnésiques pour l’information temporelle. Nous avons étudié principalement la modalité auditive, mais aussi d'autres modalités sensorielles, comme le toucher, la vision, et la stimulation électrique directe du système auditif périphérique avec un implant cochléaire. Toutes les expériences ont utilisé un nouveau paradigme expérimental, adapté de précédentes études conçues pour étudier la mémoire auditive (Agus, Thorpe, & Pressnitzer, 2010). Au lieu d'utiliser du bruit comme stimulus, nous avons utilisé des séquences d’intervalles de temps irréguliers délimités par de brèves impulsions d'énergie, adaptées à la modalité étudiée. Dans une première série d'expériences, nous avons étudié la modalité auditive chez des auditeurs normo-entendants, en utilisant des trains de clics audio comme stimuli. Nous avons démontré, pour la première fois, un apprentissage rapide de sons contenant uniquement des informations temporelles. Dans une seconde série d'expériences, nous avons appliqué le même paradigme à trois modalités sensorielles (audition, toucher et vision), en utilisant des clics audio, des impulsions de mouvement au bout des doigts, et des flashs de lumière pour délimiter les intervalles de temps dans les différences modalités. Nous avons observé des formes qualitativement similaires d'apprentissage perceptif pour les trois modalités, avec un apprentissage rapide dans tous les cas, ainsi qu'un transfert d'apprentissage au toucher ou à la vision pour des séquences initialement apprises de façon auditive. Dans une troisième série d'expériences, nous avons testé des malentendants stimulés électriquement par leur implant cochléaire avec des séquences d'impulsions irrégulières. Nous avons trouvé des indications d’une plasticité préservée pour l'apprentissage rapide des informations temporelles chez ces auditeurs. Enfin, nous présentons des résultats préliminaires en utilisant une nouvelle technique susceptible de révéler certains des mécanismes neuronaux sous-jacents à l'apprentissage perceptuel rapide. Nous avons mesuré la dilatation pupillaire pendant que les auditeurs effectuaient la tâche de mémoire auditive et observé des changements systématiques de la taille de la pupille avec l'apprentissage. En conclusion, la thèse montre une capacité remarquable des systèmes perceptifs à apprendre des séquences temporelles complexes lorsqu'elles apparaissent plusieurs fois dans l'environnement, et suggère de nouvelles méthodes expérimentales pour étudier plus avant les mécanismes neuronaux sous-jacents. / Time is a universal feature of all information processed by sensory systems, and temporal patterning is often essential for attributing meaning to external stimuli such as speech or music in audition. However, many of the mechanisms needed for temporal processing are still unclear. In this thesis, we investigated one type of mechanism arguably integral to any kind of temporal processing: the formation of novel memories for temporal patterns. We studied mainly the auditory modality, but also other sensory modalities such touch, vision, and electric hearing with a cochlear implant. All experiments used a novel experimental paradigm, adapted from a previous study designed to explore auditory memory of random noise (Agus, Thorpe, & Pressnitzer, 2010). Instead of using noise as the complex stimulus to learn, we used irregular time patterns made of random time intervals delineated by modality-adapted brief energy pulses. In a first series of experiments, we investigated the auditory modality in normal hearing listeners, using click trains as stimuli. We demonstrated for the first time a rapid learning of stimuli containing solely temporal cues. In a second series of experiments, we applied the same paradigm to multiple sensory modalities (audition, touch, and vision), using audio clicks, motion pulses to the fingertips, and light to delineate time intervals. We found a qualitatively similar forms of perceptual learning for all three modalities, with rapid learning in all cases, as well as a transfer of learning to touch or vision for patterns learnt initially learnt in audition. In a third series of experiments, we tested hearing impaired listeners stimulated through their cochlear implant with sequences of electrical pulses. We found evidence for preserved plasticity for the rapid learning of time patterns in those listeners. Finally, we present preliminary data using a novel technique for studying the underlying neural mechanisms of rapid perceptual learning. We measured pupil dilation while listeners performed the memory task and observed systematic changes in pupil size with perceptual learning. In conclusion, the thesis shows a remarkable ability of perceptual systems to learn complex time patterns as they re-occur in the environment, and suggests new experimental methods to further study the underlying neural mechanisms.

Audition

Apprentisage perceptif

Traitement temporel

Vision

Toucher

Activité neuronale

Auditon

Perceptual leanring

Temporal processing

Vision

Touch

Neuronal activity

153

152.1

Auditory tracking and scene analysis - perceptual timescales and neural correlates

Ravinderjit Singh (12437493)

20 April 2022

<p>Temporal processing and temporal coherence processing are fundamental components of auditory processing and the focus of this thesis. Cortical temporal processing in particular is understudied in humans. This dissertation makes three contributions that help characterize auditory temporal processing, and its relationship to auditory perception in humans. Experiment 1 develops a novel systems identification approach utilizing modified maximum length sequences (m-seq) to robustly measure cortical temporal processing noninvasively. Using this technique, it is found that cortex's ability to track dynamic spatial auditory cues can explain the ability to utilize dynamic binaural information to do a spatial unmasking task. This result combined with behavioral data that shows FM tracking extends out to similar rates as spatial tracking demonstrates how auditory tracking broadly is constrained by the temporal properties of cortex. Experiment 2 develops a novel measure of temporal processing, called the modulation temporal response function (mod-TRF), which can separate the underlying sources contributing to modulation processing along the auditory system from short, middle, and late latency regions. The mod-TRF has a robust SNR at the individual level giving it the potential to become an ubiquitous tool to assess temporal processing and auditory activity generally across individuals. The utility of the mod-TRF is demonstrated by evaluating how attention affects different sources along the auditory pathway. Other studies utilizing the mod-TRF could explore how temporal processing in early and late areas of the auditory system changes with aging, hearing loss, musicianship, and neuropsychiatric disorders. Experiment 3 establishes a novel physiological measure of across channel temporal coherence processing to measure auditory binding ability across individuals. It  is demonstrated how this novel temporal coherence measure can explain performance on a behavioral temporal coherence detection task, speech-in-noise task, and comodulation masking release. Lastly, it is explored how social and communicative features in individuals, measured via the Autism Quotient, align with differences in auditory ability at various tasks. </p>

neuroscience,

EEG

Electroencephalography (EEG

Hearing

auditory binding

Temporal Processing

Autism

temporal coherence

mod-TRF