Robust Effects of Working Memory Demand during Naturalistic Language Comprehension in Language-Selective Cortex

Shain, Cory; Blank, Idan; Fedorenko, Evelina; Gibson, Edward; Schuler, William

doi:10.1523/jneurosci.1894-21.2022

Cited by 47 publications

(32 citation statements)

References 195 publications

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“…The data pattern we observe here, along with the findings reported in past studies of language comprehension (e.g., Fedorenko et al, 2010, 2012a, 2020; Pallier et al, 2011; Blank et al, 2016; Shain, Blank et al, 2020)—whereby phrase-structure building demands elicit strong responses across the language network during both comprehension and production—aligns with recent evidence from Shain et al (in press). Shain and colleagues report a large-scale fMRI study that suggests that language comprehension involves computationally demanding word-by-word structure building operations even when participants passively listen to naturalistic stories.…”

Section: Discussionsupporting

confidence: 92%

“…The response to phrase-structure building demands (evidenced by a stronger response during sentence production than word-list production) was reliable in every language fROI. This distributed nature of phrase-structure building a) parallels the distributed effects of syntactic demands during language comprehension (e.g., Blank et al, 2016; Shain, Blank et al, 2020; Shain et al, in press), and b) aligns with evidence from aphasia, where damage to both frontal and temporal language areas and the white matter tracts connecting them can result in syntactic deficits (e.g., Kempler et al, 1991; Caplan et al, 1996; Dick et al, 2001; Wilson & Saygin, 2004; Mesulam et al, 2015; Wilson et al, 2022; see deBleser, 1987 for a discussion of earlier evidence), thus adding to the growing evidence against focal implementation of combinatorial linguistic processing. Importantly, we showed that the sentence > word-list effect in production cannot be explained by general cognitive demands.…”

Section: Discussionmentioning

confidence: 85%

“…Swets et al, 2013; Goldberg & Ferreira, 2022), comprehension is possible even when word order and other morpho-syntactic cues are degraded or absent (e.g., Ferreira et al, 2002; Ferreira, 2003; Levy, 2008; Levy et al, 2009; Gibson et al, 2013; Ferreira & Lowder, 2016; Mollica et al, 2020; Mahowald, Diachek et al, 2022; cf. Shain et al, in press for evidence that comprehenders compute fine-grained syntactic representations even during passive listening in naturalistic paradigms). Matchin & Hickok (2019), based largely on data from aphasia, recently proposed that such a mechanism may be housed in the inferior frontal component of the language network (in contrast with its posterior temporal component, which they hypothesized supports morpho-syntactic demands in both comprehension and production).…”

Section: Main Textmentioning

confidence: 99%

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Precision fMRI reveals that the language-selective network supports both phrase-structure building and lexical access during language production

Hu¹,

Small

Kean

et al. 2021

Preprint

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A network of left frontal and temporal brain regions has long been implicated in language comprehension and production. However, because of relatively fewer investigations of language production, the precise role of this 'language network' in production-related cognitive processes remains debated. Across four fMRI experiments that use picture naming/description to mimic the translation of conceptual representations into words and sentences, we characterize the response of the language regions to production demands. In line with prior studies, sentence production elicited strong responses throughout the language network. Further, we report three novel results. First, we demonstrate that production-related responses in the language network are robust to output modality (speaking vs. typing). Second, the language regions respond to both lexical access and sentence-generation demands. This pattern implies strong integration between lexico-semantic and combinatorial processes, mirroring the picture that has emerged in language comprehension. Finally, some have previously hypothesized the existence of production-selective mechanisms given that syntactic encoding is a critical part of sentence production, whereas comprehension is possible even when syntactic cues are degraded or absent. Contrary to this hypothesis, we find no evidence of brain regions that selectively support sentence generation. Instead, language regions respond overall more strongly during production than during comprehension, which suggests that production incurs a greater cost for the language network. Together, these results align with the idea that language comprehension and production draw on the same knowledge representations, which are stored in the language-selective network and are used both to interpret linguistic input and generate linguistic output.

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Section: Discussionsupporting

confidence: 92%

Section: Discussionmentioning

confidence: 85%

Section: Main Textmentioning

confidence: 99%

See 1 more Smart Citation

Precision fMRI reveals that the language-selective network supports both phrase-structure building and lexical access during language production

Hu¹,

Small

Kean

et al. 2021

Preprint

Self Cite

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“…In spite of some claims about regional dissociation between lexico-semantic and syntactic/combinatorial processing based on this and other paradigms(e.g., Dapretto and Bookheimer, 1999; Embick et al, 2000; Friederici et al, 2000; Kuperberg et al, 2000; see Fedorenko et al, 2020 for a recent review of this literature), studies that rely on robust individual-subject analyses have shown that these two aspects of language processing do not dissociate: all areas of the language network show a profile whereby the response is strongest to sentences, lower to lists of words and Jabberwocky sentences, and lowest to lists of nonwords (e.g., Fedorenko et al, 2010; Bedny et al, 2011; Shain et al, 2021; see Dick et al, 2001 for early arguments against the dissociation between lexical and syntactic processing). This ubiquitous sensitivity to both word meanings and syntactic structure building aligns with studies that have reported robust sensitivity to structure building across all parts of the language network (Blank et al, 2016; Fedorenko et al, 2020; Shain, Blank et al, 2020; Shain et al 2022a) and supports views of language whereby sentence structure building is deeply intertwined with the processing of word meanings (e.g., Bybee, 1999, 2013; Goldberg, 2003; Jackendoff, 2007; Arnon and Snider, 2010; Jackendoff and Audring, 2020).…”

Section: Discussionsupporting

confidence: 84%

Neural populations in the language network differ in the size of their temporal receptive windows

Regev

Casto

Hosseini

et al. 2022

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A left-lateralized network of frontal and temporal brain regions is specialized for language processing-spoken, written, or signed. Different regions of this 'language network' have all been shown to be sensitive to various forms of linguistic information, from combinatorial sentence structure to word meanings, to sub-lexical regularities. However, whether neural computations are the same across and within these different brain regions remains debated. Here, we examine responses during language processing recorded intracranially in patients with intractable epilepsy. Across two datasets (Dataset 1: n=6 participants, m=177 language-responsive electrodes; Dataset 2: n=16 participants, m=362 language-responsive electrodes), we clustered language-responsive electrodes and found three distinct response profiles, with differences in response magnitude between linguistic conditions (e.g., sentences vs. lists of words), different temporal dynamics over the course of the stimulus, and different degrees of stimulus locking. We argue that these profiles correspond to different temporal receptive windows that vary in size between sub-lexical units and multi-word sequences. These results demonstrate the functional heterogeneity of neural responses in the language network and highlight the diversity of neural computations that may be needed in order to extract meaning from linguistic input. Importantly, electrodes that exhibit these distinct profiles do not cluster spatially and are instead interleaved across frontal and temporal language areas, which likely made It difficult to uncover functional differences in past fMRI studies. This mosaic of neural responses across the language network suggests that all language regions have direct access to distinct response types-a property that may be crucial for the efficiency and robustness of language processing mechanisms.

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“…Several metrics have been proposed in the past for quantifying syntactic complexity on a continuous basis (Gibson, 1998; Szmrecsanyi, 2004; Roark et al, 2007, 2011; Baumann, 2014; Jing and Liu, 2015; Ambati et al, 2016). In attempt to move towards studying language under more naturalistic conditions, such metrics can be useful when studying uncontrolled stimuli such as speech, as recently been shown by studies that associated such scores with fluctuations in the neural response (Brennan et al, 2016; Nelson et al, 2017; Lopopolo et al, 2021; Shain et al, 2021). Here we used the mean-dependency distance (MDD), computed per clause, which has been hypothesized to reflect working memory demands (Liu, 2008; Gildea and Temperley, 2010; Collins, 2014; Futrell et al, 2015; Liu et al, 2017), yet to our knowledge, the neural correlates of MDD have not been tested before.…”

Section: Discussionmentioning

confidence: 99%

“Um…, it’s really difficult to… um… speak fluently”: Neural tracking of spontaneous speech

Agmon

Jaeger

Tsarfaty

et al. 2022

Preprint

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Spontaneous real-life speech is imperfect in many ways. It contains disfluencies and ill-formed utterances that the brain needs to contend with in order to extract meaning out of speech. Here, we studied how the neural speech-tracking response is affected by three specific factors that are prevalent in spontaneous colloquial speech: (1) the presence of non-lexical fillers, (2) the need to detect syntactic boundaries in disfluent speech and (3) the effort involved in processing syntactically complex phrases. Neural activity (EEG) was recorded from individuals as they listened to an unscripted, spontaneous narrative, which was analyzed in a time-resolved fashion to identify fillers, detect syntactic boundaries and assess the syntactic complexity of different phrases. When considering these factors in the speech-tracking analysis, we found that it was affected by all of them. The most consistent effect, observed for all three factors, was modulation of a centro-frontal negative response that peaked around 350 ms, highly resembling the well-known N400 ERP response linked to various aspects of lexical access and semantic processing. This response was observed for lexical words but not for fillers, was larger for opening vs. closing words of a clause and was enhanced in response to high-complexity phrases. These findings broaden ongoing efforts to understand neural processing of speech under increasingly realistic conditions. They highlight the importance of considering the imperfect nature of real-life spoken language, linking past research on linguistically well-formed and meticulously controlled speech to the type of speech that the brain actually deals with on a daily basis.

show abstract

Robust Effects of Working Memory Demand during Naturalistic Language Comprehension in Language-Selective Cortex

Cited by 47 publications

References 195 publications

Precision fMRI reveals that the language-selective network supports both phrase-structure building and lexical access during language production

Precision fMRI reveals that the language-selective network supports both phrase-structure building and lexical access during language production

Neural populations in the language network differ in the size of their temporal receptive windows

“Um…, it’s really difficult to… um… speak fluently”: Neural tracking of spontaneous speech

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