Your search keyword '"Giraud, Anne-Lise"' showing total 9 results

1. Speech Reception in Young Children with Autism Is Selectively Indexed by a Neural Oscillation Coupling Anomaly.

Author

Xiaoyue Wang, Delgado, Jaime, Marchesotti, Silvia, Kojovic, Nada, Sperdin, Holger Franz, Rihs, Tonia A., Schaer, Marie, and Giraud, Anne-Lise

Subjects

CHILDREN with autism spectrum disorders, AUTISTIC children, SPEECH, AUTISM in children, AUTISM spectrum disorders, OSCILLATIONS

Abstract

Communication difficulties are one of the core criteria in diagnosing autism spectrum disorder (ASD), and are often characterized by speech reception difficulties, whose biological underpinnings are not yet identified. This deficit could denote atypical neuronal ensemble activity, as reflected by neural oscillations. Atypical cross-frequency oscillation coupling, in particular, could disrupt the joint tracking and prediction of dynamic acoustic stimuli, a dual process that is essential for speech comprehension. Whether such oscillatory anomalies already exist in very young children with ASD, and with what specificity they relate to individual language reception capacity is unknown. We collected neural activity data using electroencephalography (EEG) in 64 very young children with and without ASD (mean age 3; 17 females, 47 males) while they were exposed to naturalistic-continuous speech. EEG power of frequency bands typically associated with phrase-level chunking (δ, 1-3Hz), phonemic encoding (low-γ, 25-35Hz), and top-down control (β, 12-20Hz) were markedly reduced in ASD relative to typically developing (TD) children. Speech neural tracking by δ and θ (4-8Hz) oscillations was also weaker in ASD compared with TD children. After controlling gaze-pattern differences, we found that the classical θ/γ coupling was replaced by an atypical β/γ coupling in children with ASD. This anomaly was the single most specific predictor of individual speech reception difficulties in ASD children. These findings suggest that early interventions (e.g., neurostimulation) targeting the disruption of β/γ coupling and the upregulation of θ/γ coupling could improve speech processing coordination in young children with ASD and help them engage in oral interactions. [ABSTRACT FROM AUTHOR]

Published

2023

2. Scale-Free Amplitude Modulation of Neuronal Oscillations Tracks Comprehension of Accelerated Speech.

Author

Teixeira Borges, Ana Filipa, Giraud, Anne-Lise, Mansvelder, Huibert D., and Linkenkaer-Hansen, Klaus

Subjects

*NEUROSCIENCES, *NEURAL development, *SHORT-term memory, *BRAIN imaging, *NEURONS

Abstract

Speech comprehension is preserved up to a threefold acceleration, but deteriorates rapidly at higher speeds. Current models posit that perceptual resilience to accelerated speech is limited by the brain's ability to parse speech into syllabic units using δ, θ oscillations. Here, we investigated whether the involvement of neuronal oscillations in processing accelerated speech also relates to their scale-free amplitude modulation as indexed by the strength of long-range temporal correlations (LRTC). We recorded MEG while 24 human subjects (12 females) listened to radio news uttered at different comprehensible rates, at a mostly unintelligible rate and at this same speed interleaved with silence gaps.δ, θ, and low-γ oscillations followed the nonlinear variation of comprehension, with LRTC rising only at the highest speed. In contrast, increasing the rate was associated with a monotonic increase in LRTC in high-γ activity. When intelligibility was restored with the insertion of silence gaps, LRTC in the δ, θ, and low-γ oscillations resumed the low levels observed for intelligible speech. Remarkably, the lower the individual subject scaling exponents of δ, θ oscillations, tbe greater the comprehension of the fastest speech rate. Moreover, the strength of LRTC of the speech envelope decreased at the maximal rate, suggesting an inverse relationship with the LRTC of brain dynamics when comprehension halts. Our findings show that scale-free amplitude modulation of cortical oscillations and speech signals are tightly coupled to speech uptake capacity. [ABSTRACT FROM AUTHOR]

Published

2018

3. ϑ-Band and β-Band Neural Activity Reflects Independent Syllable Tracking and Comprehension of Time-Compressed Speech.

Author

Pefkou, Maria, Arnal, Luc H., Fontolan, Lorenzo, and Giraud, Anne-Lise

Subjects

NEURAL circuitry, PSYCHOPHYSICS, SPEECH, SYLLABICATION, AUDITORY pathways

Abstract

Recent psychophysics data suggest that speech perception is not limited by the capacity of the auditory system to encode fast acoustic variations through neural γ activity, but rather by the time given to the brain to decode them. Whether the decoding process is bounded by the capacity of ϑ rhythm to follow syllabic rhythms in speech, or constrained by a more endogenous top-down mechanism, e.g., involving c activity, is unknown. We addressed the dynamics of auditory decoding in speech comprehension by challenging syllable tracking and speech decoding using comprehensible and incomprehensible time-compressed auditory sentences. We recorded EEGs in human participants and found that neural activity in both ϑ and γ ranges was sensitive to syllabic rate. Phase patterns of slow neural activity consistently followed the syllabic rate (4 -14 Hz), even when this rate went beyond the classical ϑ range (4-8 Hz). The power of ϑ activity increased linearly with syllabic rate but showed no sensitivity to comprehension. Conversely, the power of β (14 -21 Hz) activity was insensitive to the syllabic rate, yet reflected comprehension on a single-trial basis. We found different long-range dynamics for ϑ and β activity, with β activity building up in time while more contextual information becomes available. This is consistent with the roles of θ and β activity in stimulus-driven versus endogenous mechanisms. These data show that speech comprehension is constrained by concurrent stimulus-driven ϑ and low-γ activity, and by endogenousβ activity, but not primarily by the capacity of ϑ activity to track the syllabic rhythm. [ABSTRACT FROM AUTHOR]

Published

2017

4. Temporal Tuning Properties along the Human Ventral Visual Stream.

Author

Gauthier, Baptiste, Eger, Evelyn, Hesselmann, Guido, Giraud, Anne-Lise, and Kleinschmidt, Andreas

Subjects

VISUAL cortex, VISUAL perception, MAGNETIC resonance imaging of the brain, SPATIOTEMPORAL processes, NEURAL stimulation, BRAIN function localization

Abstract

Both our environment and our behavior contain many spatiotemporal regularities. Preferential and differential tuning of neural populations to these regularities can be demonstrated by assessing rate dependence of neural responses evoked during continuous periodic stimulation. Here, we used functional magnetic resonance imaging to measure regional variations of temporal sensitivity along the human ventral visual stream. By alternating one face and one house stimulus, we combined sufficient low-level signal modulation with changes in semantic meaning and could therefore drive all tiers of visual cortex strongly enough to assess rate dependence. We found several dissociations between early visual cortex and middle- and higher-tier regions. First, there was a progressive slowing down of stimulation rates yielding peak responses along the ventral visual stream. This finding shows the width of temporal integration windows to increase at higher hierarchical levels. Next, for fixed rates, early but not higher visual cortex responses additionally depended on the length of stimulus exposure, which may indicate increased persistence of responses to short stimuli at higher hierarchical levels. Finally, attention, which was recruited by an incidental task, interacted with stimulation rate and shifted tuning peaks toward lower frequencies. Together, these findings quantify neural response properties that are likely to be operational during natural vision and that provide putative neurofunctional substrates of mechanisms that are relevant in several psychophysical phenomena as masking and the attentional blink. Moreover, they illustrate temporal constraints for translating the deployment of attention into enhanced neural responses and thereby account for lower limits of attentional dwell time. [ABSTRACT FROM AUTHOR]

Published

2012

5. Alpha-Band Phase Synchrony Is Related to Activity in the Fronto-Parietal Adaptive Control Network.

Author

Sadaghiani, Sepideh, Scheeringa, René, Lehongre, Katia, Morillon, Benjamin, Giraud, Anne-Lise, D'Esposito, Mark, and Kleinschmidt, Andreas

Subjects

BRAIN function localization, SENSORY neurons, SYNCHRONIZATION, COGNITION, MAGNETIC resonance imaging of the brain, NEURAL circuitry, RESPONSE inhibition, ADAPTIVE control systems

Abstract

Neural oscillations in the alpha band (8 -12 Hz) are increasingly viewed as an active inhibitory mechanism that gates and controls sensory information processing as a function of cognitive relevance. Extending this view, phase synchronization of alpha oscillations across distant cortical regions could regulate integration of information. Here, we investigated whether such long-range cross-region coupling in the alpha band is intrinsically and selectively linked to activity in a distinct functionally specialized brain network. If so, this would provide new insight into the functional role of alpha band phase synchrony. We adapted the phase-locking value to assess fluctuations in synchrony that occur over time in ongoing activity. Concurrent EEG and functional magnetic resonance imaging (fMRI) were recorded during resting wakefulness in 26 human subjects. Fluctuations in global synchrony in the upper alpha band correlated positively with activity in several prefrontal and parietal regions (as measured by fMRI). fMRI intrinsic connectivity analysis confirmed that these regions correspond to the well known fronto-parietal (FP) network. Spectral correlations with this network's activity confirmed that no other frequency band showed equivalent results. This selective association supports an intrinsic relation between large-scale alpha phase synchrony and cognitive functions associated with the FP network. This network has been suggested to implement phasic aspects of top-down modulation such as initiation and change in moment-to-moment control. Mechanistically, long-range upper alpha band synchrony is well suited to support these functions. Complementing our previous findings that related alpha oscillation power to neural structures serving tonic control, the current findings link alpha phase synchrony to neural structures underpinning phasic control of alertness and task requirements. [ABSTRACT FROM AUTHOR]

Published

2012

6. Brain-Speech Alignment Enhances Auditory Cortical Responses and Speech Perception.

Author

Saoud, Houda, Josse, Goulven, Bertasi, Eric, Truy, Eric, Chait, Maria, and Giraud, Anne-Lise

Subjects

SPEECH perception, CEREBRAL hemispheres, AUDITORY cortex, PARALINGUISTICS, WORD recognition, BIOLOGICAL rhythms

Abstract

Asymmetry in auditory cortical oscillations could play a role in speech perception by fostering hemispheric triage of information across the two hemispheres. Due to this asymmetry, fast speech temporal modulations relevant for phonemic analysis could be best perceived by the left auditory cortex, while slower modulations conveying vocal and paralinguistic information would be better captured by the right one. It is unclear, however, whether and how early oscillation-based selection influences speech perception. Using a dichotic listening paradigm in human participants, where we provided different parts of the speech envelope to each ear, we show that word recognition is facilitatedwhenthe temporal properties of speech match the rhythmic properties of auditory cortices.Wefurther show that the interaction between speech envelope and auditory cortices rhythms translates in their level of neural activity (as measured with fMRI). In the left auditory cortex, the neural activity level related to stimulus- brain rhythm interaction predicts speech perception facilitation. These data demonstrate that speech interacts with auditory cortical rhythms differently in right and left auditory cortex, and that in the latter, the interaction directly impacts speech perception performance. [ABSTRACT FROM AUTHOR]

Published

2012

7. Intrinsic Connectivity Networks, Alpha Oscillations, and Tonic Alertness: A Simultaneous Electroencephalography/Functional Magnetic Resonance Imaging Study.

Author

Sadaghiani, Sepideh, Scheeringa, René, Lehongre, Katia, Morillon, Benjamin, Giraud, Anne-Lise, and Kleinschmidt, Andreas

Subjects

HUNTINGTON disease, ELECTROENCEPHALOGRAPHY, MAGNETIC resonance imaging, LABORATORY mice, THALAMUS

Abstract

Trial-by-trial variability in perceptual performance on identical stimuli has been related to spontaneous fluctuations in ongoing activity of intrinsic functional connectivity networks (ICNs). In a paradigm requiring sustained vigilance for instance, we previously observed that higher prestimulus activity in a cingulo-insular-thalamic network facilitated subsequent perception. Here, we test our proposed interpretation that this network underpins maintenance of tonic alertness. We used simultaneous acquisition of functional magnetic resonance imaging (fMRI) and electroencephalography (EEG) in the absence of any paradigm to test an ensuing hypothesis, namely that spontaneous fluctuations in this ICN's activity (as measured by fMRI) should show a positive correlation with the electrical signatures of tonic alertness (as recorded by concurrent EEG). We found in human subjects (19 male, 7 female) that activity in a network comprising dorsal anterior cingulate cortex, anterior insula, anterior prefrontal cortex and thalamus is positively correlated with global field power (GFP) of upper alpha band (10-12 Hz) oscillations, the most consistent electrical index of tonic alertness. Conversely, and in line with earlier findings, alpha band power was negatively correlated with activity in another ICN, the so-called dorsal attention network which is most prominently involved in selective spatial attention. We propose that the cingulo-insular-thalamic network serves maintaining tonic alertness through generalized expression of cortical alpha oscillations. Attention is mediated by activity in other systems, e.g., the dorsal attention network for space, selectively disrupts alertness-related suppression and hence manifests as local attenuation of alpha activity. [ABSTRACT FROM AUTHOR]

Published

2010

8. Three Stages and Four Neural Systems in Time Estimation.

Author

Morillon, Benjamin, Kell, Christian A., and Giraud, Anne-Lise

Subjects

BIOLOGICAL neural networks, SCALAR field theory, TIME perception, PARIETAL lobe, CEREBELLAR cortex

Abstract

Gibbon's scalar expectancy theory assumes three processing stages in time estimation: a collating level in which event durations are automatically tracked, a counting level that reads out the time-tracking system, and a comparing level in which event durations are matched to abstract temporal references. Pöppel's theory, however, postulates a dual system for perception of durations below and above 2 s. By testing the neurophysiological plausibility of Gibbon's proposal using functional magnetic resonance imaging, we validate a three-staged model of time estimation and further show that the collating process is duplicated. Although the motor system automatically tracks durations below 2 s, mesial brain regions of the so-called "default mode network" keep track of longer events. Our results further support unique counting and comparing systems, involving prefrontal and parietal cortices in collators' readout, and the temporal cortex in contextual time estimation. These findings provide a coherent neuroanatomical framework for two theories of time perception. [ABSTRACT FROM AUTHOR]

Published

2009

9. Dual Neural Routing of Visual Facilitation in Speech Processing.

Author

Arnal, Luc H., Morillon, Benjamin, Kell, Christian A., and Giraud, Anne-Lise

Subjects

SPEECH perception, AUDITORY perception, MAGNETOENCEPHALOGRAPHY, LABORATORY monkeys, HUMAN beings

Abstract

Viewing our interlocutor facilitates speech perception, unlike for instance when we telephone. Several neural routes and mechanisms could account for this phenomenon. Using magnetoencephalography, we show that when seeing the interlocutor, latencies of auditory responses (M100) are the shorter the more predictable speech is from visual input, whether the auditory signal was congruent or not. Incongruence of auditory and visual input affected auditory responses ~20 ms after latency shortening was detected, indicating that initial content-dependent auditory facilitation by vision is followed by a feedback signal that reflects the error between expected and received auditory input (prediction error). We then used functional magnetic resonance imaging and confirmed that distinct routes of visual information to auditory processing underlie these two functional mechanisms. Functional connectivity between visual motion and auditory areas depended on the degree of visual predictability, whereas connectivity between the superior temporal sulcus and both auditory and visual motion areas was driven by audiovisual (AV) incongruence. These results establish two distinct mechanisms by which the brain uses potentially predictive visual information to improve auditory perception. A fast direct corticocortical pathway conveys visual motion parameters to auditory cortex, and a slower and indirect feedback pathway signals the error between visual prediction and auditory input. [ABSTRACT FROM AUTHOR]

Published

2009