The Motor System's [Modest] Contribution to Speech Perception

Stokes, Ryan E.; Venezia, Jonathan H.; Hickok, Gregory

doi:10.31234/osf.io/rp5ma

Cited by 10 publications

(20 citation statements)

References 52 publications

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“…In addition, in the same survey, only 50% of respondents agreed on the precise location of Broca's region in the triangular and opercular part of the left inferior frontal gyrus (IFG; Tremblay & Dick, 2016). Furthermore, the strict functional division between language production in Broca's region and language comprehension in Wernicke's region is not valid because many fMRI studies have demonstrated that both language modalities share neural resources (Menenti, Gierhan, Segaert, & Hagoort, 2011;Segaert, Menenti, Weber, Petersson, & Hagoort, 2012;Stokes, Venezia, & Hickok, 2019).…”

Section: Introductionmentioning

confidence: 99%

A Review on Treatment-Related Brain Changes in Aphasia

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et al. 2020

Neurobiology of Language

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Numerous studies have investigated brain changes associated with interventions targeting a range of language problems in patients with aphasia. We strive to integrate the results of these studies to examine (1) whether the focus of the intervention (i.e. phonology, semantics, orthography, syntax or rhythmic-melodic) determines in which brain regions changes occur, (2a) whether the most consistent changes occur within the language network or outside, and (2b) whether these are related to individual differences in language outcomes. The results of 32 studies with 204 unique patients were considered. Concerning (1), the location of treatment-related changes does not clearly depend on the type of language processing targeted. However, there is some support that rhythmic-melodic training has more impact on the right hemisphere than linguistic training. Concerning (2), we observed that language recovery is not only associated with changes in traditional language-related structures in the left hemisphere and homolog regions in the right hemisphere. Treatment-related changes also occurred more medially and subcortically (e.g. precuneus and basal ganglia). Although it is difficult to draw strong conclusions, because there is a lack of systematic large-scale studies on this topic, this review highlights the need for an integrated approach to investigate how language interventions impact on the brain. Future studies need to focus on larger samples preserving subject-specific information (such as lesion effects) to cope with the inherent heterogeneity of stroke-induced aphasia. In addition, recovery-related changes in whole-brain connectivity patterns need more investigation to provide a comprehensive neural account of treatment-related brain plasticity and language recovery.

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Section: Introductionmentioning

confidence: 99%

A Review on Treatment-Related Brain Changes in Aphasia

Schevenels

Price

Zink

et al. 2020

Neurobiology of Language

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“…These routes are thought to participate in acoustic/phonological transcoding (Catani et al, 2005). The recurrent motor-perceptual interaction is known to facilitate speech perception of unfamiliar speech stimuli, e.g., distorted speech and novel or low-frequency words (Wu et al, 2014;Stokes et al, 2019). Therefore, greater involvement of the entire perisylvian network into the APW compared to the NPW response in our experiment may indicate that newly learned semantic association boosted perceptual processing of incoming novel linguistic stimuli.…”

Section: Semantic Learning Effectsmentioning

confidence: 76%

Rapid Cortical Plasticity Induced by Active Associative Learning of Novel Words in Human Adults

et al. 2020

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“…A prominent challenge to the classic view is the motor theory of speech perception, which posits that gesturesnot speech soundsare the objects of speech perception, thus implicating motor brain regions in receptive speech (Liberman, 1957;Liberman and Mattingly, 1985;Galantucci et al, 2006). Although the motor theory of speech perception was initially rebuked due to its failure to account for the classic neuropsychological findings, among other shortcomings (Diehl et al, 2004;Holt and Lotto, 2008;Lotto et al, 2009;Scott et al, 2009;Venezia and Hickok, 2009;Stokes et al, 2019), it experienced a major resurgence when modern, non-invasive brain imaging methods revealed unequivocally that inferior frontal brain regions are engaged during speech perception (Rizzolatti and Craighero, 2004;Pulvermuller and Fadiga, 2010;D'Ausilio et al, 2012). More recently, even sensory-oriented speech researchers have come to acknowledge that frontal motor regions play at least some role in speech perception, leading to a moderation of the classic model in which bottom-up sensory processing is subserved by superior temporal brain regions while inferior frontal regions contribute to top-down or task-sensitive aspects of speech perception (Binder et al, 2004;Hickok and Poeppel, 2007;Venezia et al, 2012).…”

Section: Introductionmentioning

confidence: 99%

“…Frontal brain circuits may be especially important for recognition of degraded speech or speech in background noise. Indeed, this notion has been embraced by motor theorists, with recent variants of the motor theory suggesting that top-down motor predictions figure most prominently in speech perception when the input signal is corrupted or otherwise ambiguous (Stokes et al, 2019), and by the nascent field of cognitive hearing science, which posits a significant role for domain general or cognitive systems when speech is either intrinsically (e.g., with hearing loss) or extrinsically (e.g., with background noise) distorted (Arlinger et al, 2009;Rönnberg et al, 2011;Pichora-Fuller et al, 2016). Notably, while these perspectives differ in terms of their emphasis on frontal-motor versus frontal-cognitive mechanisms, they fundamentally agree that frontal contributions scale with the demands of the task and thus do not constitute a core component of bottom-up speech perception.…”

Section: Introductionmentioning

confidence: 99%

Cortical Networks for Recognition of Speech with Simultaneous Talkers

Herrera¹,

Whittle²,

Leek³

et al. 2021

Preprint

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The relative contributions of superior temporal (auditory) vs. inferior frontal and parietal (sensorimotor) networks to recognition of speech against competing speech remain unclear, although the contributions themselves are well established. Here, we use fMRI with spectrotemporal receptive field (STRF) modeling to examine the speech information represented in temporal vs. frontoparietal networks for two speech recognition tasks with and without a competing talker. We also generate ‘neurometric functions’ that describe the relative contributions of these networks to speech recognition performance. Specifically, 25 listeners completed two versions of a 3-Alternative Forced-Choice (3-AFC) competing speech task: “Unison” and “Competing”, in which a female (target) and a male (competing) talker uttered identical or different phrases, respectively. Spectrotemporal modulation filtering was applied to the two-talker mixtures and a “boosting” procedure was used to generate STRF models to predict brain activation from differences in spectrotemporal distortion on each trial. STRF model predictive accuracy was better for Competing than Unison in a bilateral temporal lobe network, and better for Unison than Competing in a large network of frontoparietal and midline brain regions. Agglomerative STRF clustering further revealed three subnetworks: a bilateral superior temporal Intelligibility network, a frontoparietal Distortion network, and a Semantic network distributed across classic semantic memory regions. The Intelligibility and Semantic networks responded primarily to spectrotemporal cues associated with speech intelligibility, regardless of condition, while the Distortion network responded to the absence of such cues in both conditions, but also to the absence (presence) of target-talker (competing-talker) vocal pitch in the Competing condition, suggesting a generalized response to signal degradation. Neurometric function analysis showed that: (i) activation in the Intelligibility network was strongly positively correlated with behavioral performance and that this relation was entirely STRF-mediated; and (ii) activation in the Distortion network was strongly negatively correlated with performance and this relation was only partially STRF-mediated. The contributions to performance from these networks were partially independent and of roughly equal magnitude. Finally, activation in the Semantic network was weakly positively correlated with performance and this relation was entirely superseded by those in the Intelligibility and Distortion networks. We conclude: (a) superior temporal regions play a bottom-up, perceptual role in competing speech tasks; (b) frontoparietal regions play a top-down, task-dependent role in competing speech tasks that scales with listening effort; and (c) performance ultimately relies on dynamic interactions between these networks, with additional contributions from semantic regions that likely scale with the semantic predictability of the speech material.

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The Motor System's [Modest] Contribution to Speech Perception

Cited by 10 publications

References 52 publications

A Review on Treatment-Related Brain Changes in Aphasia

A Review on Treatment-Related Brain Changes in Aphasia

Rapid Cortical Plasticity Induced by Active Associative Learning of Novel Words in Human Adults

Cortical Networks for Recognition of Speech with Simultaneous Talkers

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