Neuroimaging studies of auditory perception and attention: The effect of pitch and location difference on concurrent vowel segregation and identification – Yi Du and Claude Alain

Human communication, during social gatherings and other noisy environments, involves the detection and identification of concurrent sound sources (e.g., voice, music). Difficulty in auditory stream segregation may contribute to the problems in speech perception often observed in older adults. Previous psychophysical studies have demonstrated that performance in identifying speech sounds improves with either increasing distance between the frequency bands (e.g. fundamental frequency, ƒ0) or increasing spatial separation of concurrent streams of sounds. This study records brain activity using whole head magnetoencephalography (MEG) underlying identification of concurrent English vowels. And the goals are to investigate the relative contribution of ƒ0 difference and location difference in parsing concurrent vowels, how fast and where in the brain do ƒ0-guided segregation and location-guided segregation take place, what is the interaction between these two neural processes, what’s the role of attention in ƒ0-guided and location-guided segregation.

Dynamical range mapping in the young and old brain - Antonio Vallesi

A dynamical range map is the collection of brain regions that, when considered as a network, are able to support a particular behavioral operation. We will examine how dynamical maps change with task demands and with senescence, using ERP and fMRI in participants performing psychophysical tasks. An important feature of psychophysical studies is that they allows us to minimize differences between age groups due to poor task performance or strategy by equating task performance. Data analyzed at the group level describe the dynamical range for a given task. Data from each participant will be analyzed at the single trial level to capture the dynamical range for that person.

Neuroelectric Correlates of Rapid Perceptual Learning of Speech Sounds - Claude Alain, Sandra Campeanu and Kelly Tremblay

Learning perceptual skills is characterized by rapid improvements in performance within the first hour of training (fast perceptual learning) followed by more gradual improvements that take place over several daily practice sessions (slow perceptual learning). While it is widely accepted that slow perceptual learning is accompanied by enhanced stimulus representation in sensory cortices, there is considerable controversy about the neural substrates underlying early and rapid improvements in learning perceptual skills. Here we measured event-related brain potentials (ERPs) while listeners were trained to identify two consonant-vowel syllables. Listeners were also presented with a broadband noise to examine whether training-related changes in ERPs were specific to the trained speech cue. Participants performed 10 blocks with 90 trials in each block. The ability to identify both speech sounds improved from the first to the fourth block of trials, and remained relatively constant thereafter. Behavioral improvement coincided with an increased negative peak (between 180-350 ms) over frontocentral sites, and an increase in sustained activity over the parietal regions. While the former was also observed for the noise, the latter was specific to speech sounds. The results are consistent with a top-down non-specific attention effect on neural activity during learning, as well as a more learning-specific modulation, reflecting behavioral improvements in speech identification.

Neuroimaging studies of auditory perception and attention: Detecting and Identifying sounds presented at high rate - Dawei Shen and Claude Alain

This study involves the recording of electrical brain activity (EEG) while you hear different short sequence of sounds presented at a high rate. In some sequences, there will be one or two target sounds embedded in the sequence. You will be asked to indicate whenever your hearing these target sounds by pressing a button. You may find the task difficult. We will be measuring your electrical potentials to these sounds. We ask that you try not to move around too much as this can interfere with the recording.

Modulations of the face and eye gaze processing networks - Roxane Itier, Claude Alain, Randy McIntosh

The human face is arguably the most important and complex social stimulus that we process everyday. Although numerous studies have focused on the difference in processing faces compared to objects, they have neglected the important social context of face processing wherein the need to attend to the eyes seems vital for proper social interactions. The eyes are central to all aspects of social communication such as identity, emotions or direction of attention, and it has been suggested that they could be processed by a dedicated mechanism. This hypothesis of an eye processor system in the human brain is supported by behavioural and clinical data, but has not been well studied in neuroimaging research. The goal of the present study is to test for the existence of this putative eye detector and to study its integration within the larger face processing system. We are using the ERP and fMRI techniques to characterize both the temporal and spatial dynamics of the face and eye brain networks. Participants are performing a categorization task (responding whether there are eyes or not in the picture) while viewing faces, isolated eyes, isolated mouths, faces without eyes and objects on a computer screen.

Specificity of human face and eye processing - Roxane Itier, Claude Alain

Faces and eyes trigger an early brain response recorded on the scalp and known as the N170 component. This response is always larger for faces and eyes than other objects and for this reason, the N170 is believed to reflect the early processes necessary to encode the structure of a face into memory. However, whether this face sensitivity is specific to human faces or simply reflect a sensitivity to the broad category of faces is debated. This project aims at determining whether faces and eyes of humans are processed in the same way as faces and eyes of other animals. The N170 in response to human, ape, dog and cat faces, eyes and faces-without-eyes are compared. The inversion effect, a manipulation that disrupts the face configuration and reflects specific face processing mechanisms is used. This study will inform us on the particular neural properties underlying face and eye processing.

Brain activity during the learning of words for later recall: An event-related potential study - Endel Tulving, Terence Picton, and Alice Kim

Previous studies have demonstrated that the ability to remember verbal and visual items can be predicted by the magnitude of activation in various brain regions during the encoding of these items. Previous studies have not, however, examined what is responsible for the different patterns of neural activation that are associated with the encoding of subsequently remembered and subsequently forgotten items. To test a possible answer to this question, as provided by a new scientific idea that we refer to as “camatosis”, we will examine how the encoding of items in single-trial free recall lists depends on the encoding of preceding items in the list. To do so, we will examine participants’ free recall performance and then compare the event-related potentials (ERPs) recorded during encoding between recalled and non-recalled items. The camatosis hypothesis will be specifically tested by comparing the ERPs to items that follow an item that was later recalled to the ERPs to items that follow an item that was not recalled.

The Involvement of the Inferior Parietal Lobe in Sound Localization, as Demonstrated with Functional Magnetic Resonance Imaging - Claude Alain, and Laura Vecchio

There is a considerable body of evidence to support the ‘dual pathway hypothesis’ in the human auditory system, suggesting that identifying a sound and localizing a sound involve distinct and separate cortical pathways. Past studies involving both primates and humans revealed that a dorsal stream is responsible for sound localization, while a ventral stream is responsible for identification. Some researchers, however, believe that activity in the dorsal stream, particularly in the parietal cortex, is a result of goal-directed behaviour. The ‘sensory-motor account’ asserts that activity in the inferior parietal lobe (IPL) is a result of the sensory integration and goal-directed processes involved in making a response to auditory stimuli. The ‘memory account’ suggests activity in the parietal lobe to be a result of localizing a sound and encoding spatial information to auditory working memory. The present study employs functional magnetic resonance imaging (fMRI) to examine the cortical regions activated during location and pitch tasks. Participants are presented with groups of two sounds, and instructed to make judgements regarding the pitch or location of the second sound relative to the first. The aim is to study activity patterns in the IPL during sound localization and pitch discrimination. If activity in this region were primarily observed during location tasks, it would imply that at least some activity in this region is a result of processing spatial information and thus support the ‘memory account’. If there were no difference in the patterns of activity during location and pitch tasks, it would suggest that most neurons in the IPL are active as a result of sensory integration and goal directed processes.

Human event-related potentials - tpear - Terry Picton and Sasha John

Objective: To evaluate how the amplitudes and latencies of auditory steady-state responses (ASSRs) to multiple stimuli presented at rates between 80 and 105 Hz vary with the ear of stimulation, the handedness or gender of a participant and the rate of stimulation. Design: ASSRs were recorded in a group of 40 young adults (19 female, 12 left-handed) using several stimulus conditions. In the two main conditions, four sinusoidally amplitude-modulated tones (each uniquely modulated using rates between 80 and 105 Hz) with carrier frequencies of 500, 1000, 2000 and 4000 Hz, were presented concurrently to each ear (eight total). In the first condition the modulation rates for the left ear were slower than those for the right and in the second condition this relationship was reversed. Other conditions evaluated the responses to single stimuli, to multiple stimuli presented in one ear only and to multiple stimuli (4 in each ear) presented with rates that decreased rather than increased with increasing carrier frequency. All stimuli were presented at an intensity of 73 dB SPL. Results: Multiple-stimulus ASSRs were significantly reduced (monotic or dichotic) compared to single-stimulus ASSRs, especially at 1000 and 2000 Hz. There were significant differences between monotic and dichotic stimulation. When the stimuli were presented dichotically, the amplitude of the response was largely determined by the relative rates of modulation for the stimuli presented in each ear. ASSRs were larger in the ear with the higher rate when the carrier frequencies were 500 and 1000 Hz and when the modulation rates were less than 90 Hz. Female participants showed larger responses than male participants, particularly at frequencies 1000 and 2000 Hz, but this difference reached only borderline levels of significance. In some of the analyses, the responses in the right ear were significantly larger than in the left. The estimated latency of the responses increased with decreasing carrier frequency and was significantly shorter for the female participants than for the male participants, and for dichotic rather than monotic stimuli. There was no significant effect of handedness, nor any interaction of handedness with ear, for either the amplitude or the latency of the responses. Conclusions. Presenting multiple stimuli at 73 dB SPL in the same ear decreases the amplitude of the ASSR compared to when the stimuli are presented singly. This is caused by the masking effect of low on higher frequencies and some other effect (such as suppression) of high on lower frequencies. Dichotic stimulation can increase the amplitude of the response to stimuli modulated more rapidly (and concomitantly decrease the responses to the stimuli modulated more slowly). This effect occurs only for the carrier frequencies less than 2000 Hz and for modulation frequencies less than 90 Hz. Dichotic stimulation also causes a small but highly significant decrease in the latency of the response compared to monotic stimulation. Female participants had significantly earlier responses than male participants.

Responding to relevant and irrelevant aspects of sound - Ben Dyson

This on-going project is concerned with how we allocate attention to both relevant and irrelevant aspects of our sound world. Stimuli are presented which vary according to a number of parameters, only one of which will be task-relevant at any one point in time. Both behavioural and ERP measures are of interest in order to further uncover the mechanisms of attentional distribution as a function of the environment.

The Effect of Attention and Processing Time on Consolidation of Words During Episodic Encoding: An Event-related Potential Study - Erol Ozcelik

Recent research on visual cognition proposes that human beings have a significant limitation on the consolidation of early perceptual representations to a more durable form of memory. Although several studies have examined the nature of consolidation on working memory, no research has investigated this post-perceptual process on episodic memory. The goal of this study is to investigate the role of attention and processing time on the short-term consolidation of information during episodic encoding and to reveal neural activity associated with successful episodic encoding by contrasting recordings of event-related potentials for words that are remembered and forgotten.

Envelope-following responses to slow (2-8 Hz) speech envelopes in sentences - Steve Aiken and T.W. Picton

Recent research suggests that the speech envelope (the pattern of slow amplitude changes between 2 and 8 Hz) is very important for speech understanding. Speech can be understood when everything except the envelope information is removed, as long a the envelope information is maintained in more than one frequency band. Conversely, removal of the envelope information greatly reduces speech intelligibility. Near-perfect intelligibility is maintained when these slow envelope modulations are presented at least eight discrete bands. It is not known how the brain uses this envelope information to understand speech, and there have been few studies investigating the representation of envelope information in the brain. The present study will seek to elucidate the representation of envelope informaton in the brain. This will be accomplished by measuring electrical brain responses to sentences (using a 65-electrode cap) and then calculating the coherence between this activity at the scalp and the sentence envelopes (in discrete frequency bands). If coherence between sentence envelope information and brain activity can be reliably detected, it may be possible to use envelope-following responses to speech envelopes as a tool to assess the encoding of speech information in the brain of children and other difficult-to-test populations.

Envelope-following responses to vowels (VEFR) - Steve Aiken

Envelope following responses to vowels will be recorded in normal hearing people, using a high recording bacndwidth (30-3000 Hz). One goal is to determine the frequency range at which significant envelope following responses can be reliably recorded to the harmonics in speech. Such responses provide frequency specific information about speech encoding in the brainstem, and may be useful for validating hearing aid fittings in infants. Another goal is to determine whether responses are reliably related to the phase of the stimulus, or are relatively insensitive to stimulus phase. The final goal is to determine whether responses can be recorded to vowel formants when no harmonics are present.