Weaker neural suppression in autism

Schallmo, Michael-Paul; Kolodny, Tamar; Kale, Alexander M.; Millin, Rachel; Flevaris, Anastasia V.; Edden, Richard A.E.; Gerdts, Jennifer; Bernier, Raphael; Murray, Scott O.

doi:10.1038/s41467-020-16495-z

Cited by 38 publications

(37 citation statements)

References 84 publications

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“…Contrary to prior research that has demonstrated associations between GABA levels and sensory processing in ASD [ 33 – 35 ], no associations were found between GABA+ values in any VOI and sensory processing symptoms across all participants or within TD or ASD groups. Nevertheless, our results are consistent with a recent study that found no association between GABA+ concentrations and behavioral and fMRI measures of visual spatial suppression [ 67 ]. Rather, we observed significant correlations between rTPJ Glx levels and all four sensory processing quadrants across both groups, which was primarily the result of associations within the ASD group, for Sensitivity and Avoidance subscales; greater scores on these subscales, indicative of increased hypersensitivity to sensory input, were associated with atypically decreased Glx levels in the ASD group, suggesting that reduced glutamate may contribute to sensory processing impairments in ASD.…”

Section: Discussionsupporting

confidence: 93%

Associations between sensory processing and electrophysiological and neurochemical measures in children with ASD: an EEG-MRS study

Pierce

Kadlaskar

Edmondson

et al. 2021

J Neurodevelop Disord

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Background Autism spectrum disorder (ASD) is associated with hyper- and/or hypo-sensitivity to sensory input. Spontaneous alpha power, which plays an important role in shaping responsivity to sensory information, is reduced across the lifespan in individuals with ASD. Furthermore, an excitatory/inhibitory imbalance has also been linked to sensory dysfunction in ASD and has been hypothesized to underlie atypical patterns of spontaneous brain activity. The present study examined whether resting-state alpha power differed in children with ASD as compared to TD children, and investigated the relationships between alpha levels, concentrations of excitatory and inhibitory neurotransmitters, and atypical sensory processing in ASD. Methods Participants included thirty-one children and adolescents with ASD and thirty-one age- and IQ-matched typically developing (TD) participants. Resting-state electroencephalography (EEG) was used to obtain measures of alpha power. A subset of participants (ASD = 16; TD = 16) also completed a magnetic resonance spectroscopy (MRS) protocol in order to measure concentrations of excitatory (glutamate + glutamine; Glx) and inhibitory (GABA) neurotransmitters. Results Children with ASD evidenced significantly decreased resting alpha power compared to their TD peers. MRS estimates of GABA and Glx did not differ between groups with the exception of Glx in the temporal-parietal junction. Inter-individual differences in alpha power within the ASD group were not associated with region-specific concentrations of GABA or Glx, nor were they associated with sensory processing differences. However, atypically decreased Glx was associated with increased sensory impairment in children with ASD. Conclusions Although we replicated prior reports of decreased alpha power in ASD, atypically reduced alpha was not related to neurochemical differences or sensory symptoms in ASD. Instead, reduced Glx in the temporal-parietal cortex was associated with greater hyper-sensitivity in ASD. Together, these findings may provide insight into the neural underpinnings of sensory processing differences present in ASD.

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Section: Discussionsupporting

confidence: 93%

Associations between sensory processing and electrophysiological and neurochemical measures in children with ASD: an EEG-MRS study

Pierce

Kadlaskar

Edmondson

et al. 2021

J Neurodevelop Disord

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“…Experiments examining how it modulates visual performance and neuronal activity in visual cortex have found disparate attentional effects on stimulus-evoked neural responses, such as the contrast-response function attention field is small. Remarkably, previous psychophysical (Herrmann et al, 2010;Schallmo et al, 2020;Schwedhelm et al, 2016;Zhang et al, 2016), electroencephalography (Itthipuripat et al, 2014(Itthipuripat et al, , 2019, and voxel-based functional magnetic resonance imaging (Hara et al, 2014) studies have reported that the patterns of behavioral performance, steady-state visual evoked potentials, and voxel-averaged neurometric functions, respectively, are all consistent with the predictions of normalization model of attention. However, little is known regarding whether visual bottom-up attention with and without awareness is governed by this common neural computation: normalization and how awareness could modulate the gain changes induced by attentional selection.…”

Section: Introductionsupporting

confidence: 68%

Awareness-dependent normalization framework of visual bottom-up attention

Wang

Huang

Chen

et al. 2021

Preprint

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Although bottom-up attention can improve visual performance with and without awareness, whether they are governed by a common neural computation remains unclear. Using a modified Posner paradigm with backward masking, we found that both the attention-triggered cueing effect with and without awareness displayed a monotonic gradient profile (Gaussian-like). The scope of this profile, however, was significantly wider with than without awareness. Subsequently, for each subject, the stimulus size was manipulated as their respective mean scopes with and without awareness while stimulus contrast was varied in a spatial cueing task. By measuring the gain pattern of contrast-response functions, we observed changes in the cueing effect consonant with changes in contrast gain for bottom-up attention with awareness and response gain for bottom-up attention without awareness. Our findings indicate an awareness-dependent normalization framework of visual bottom-up attention, placing a necessary constraint, namely, awareness, on our understanding of the neural computations underlying visual attention.

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“…In addition, the macromolecular contamination of GABA acquired using the MEGA-PRESS sequence could have a major impact on the correlation with behaviour (Mikkelsen et al 2018a). A recent study using a large sample size (N = 62) also showed no correlation between surround suppression and GABA+ (Schallmo et al 2020). This lends further support to the view that the involvement of cortical inhibition in spatial context effects is likely to be more complex than previously thought.…”

Section: Cortical Inhibition and Spatial Context Modulationmentioning

confidence: 58%

“…Together, these have presented mixed evidence supporting a role of neurochemistry in surround suppression. While some studies reported a link between GABA+ and orientation (Yoon et al 2010), contrast (Cook et al 2016) and motion-specific (Pitchaimuthu et al 2017) surround suppression, two recent studies have not supported a relationship (Schallmo et al 2018(Schallmo et al , 2020. Schallmo et al (2018) applied multiple complementary methods, including multimodal neuroimaging, computational modelling, and pharmacology to evaluate whether higher GABA+ led to stronger surround suppression.…”

Section: Cortical Inhibition and Spatial Context Modulationmentioning

confidence: 99%

Investigating the neurochemistry of the human visual system using magnetic resonance spectroscopy

Bridge

2021

Brain Struct Funct

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Biochemical processes underpin the structure and function of the visual cortex, yet our understanding of the fundamental neurochemistry of the visual brain is incomplete. Proton magnetic resonance spectroscopy (1H-MRS) is a non-invasive brain imaging tool that allows chemical quantification of living tissue by detecting minute differences in the resonant frequency of molecules. Application of MRS in the human brain in vivo has advanced our understanding of how the visual brain consumes energy to support neural function, how its neural substrates change as a result of disease or dysfunction, and how neural populations signal during perception and plasticity. The aim of this review is to provide an entry point to researchers interested in investigating the neurochemistry of the visual system using in vivo measurements. We provide a basic overview of MRS principles, and then discuss recent findings in four topics of vision science: (i) visual perception, plasticity in the (ii) healthy and (iii) dysfunctional visual system, and (iv) during visual stimulation. Taken together, evidence suggests that the neurochemistry of the visual system provides important novel insights into how we perceive the world.

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Weaker neural suppression in autism

Cited by 38 publications

References 84 publications

Associations between sensory processing and electrophysiological and neurochemical measures in children with ASD: an EEG-MRS study

Associations between sensory processing and electrophysiological and neurochemical measures in children with ASD: an EEG-MRS study

Awareness-dependent normalization framework of visual bottom-up attention

Investigating the neurochemistry of the human visual system using magnetic resonance spectroscopy

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