ECoG gamma activity during a language task: differentiating expressive and receptive speech areas

Towle, Vernon L.; Yoon, Hyunah; Castelle, Michael; Edgar, J. Christopher; Biassou, Nadia; Frim, David M.; Spire, Jean-Paul; Kohrman, Michael

doi:10.1093/brain/awn147

Cited by 224 publications

(254 citation statements)

References 80 publications

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“…Furthermore, the significance of lowfrequency oscillations in higher cognitive functions are unknown (Canolty and Knight, 2010). The finding of increased ECoG ERBP in the left ATL in a frequency distribution spanning both beta and gamma bands is surprising given previous ECoG lan- guage studies showing increased power at higher frequencies in classical language cortex (Towle et al, 2008;Miller et al, 2011). If power changes predominately occur in the sub-50 Hz range in the left ATL, it is possible that some of the variability of prior ATL fMRI studies results from poor correlation between the BOLD signal and ECoG power at lower frequencies (Ojemann et al, 1997;Devlin et al, 2000).…”

Section: Discussionmentioning

confidence: 75%

Direct Physiologic Evidence of a Heteromodal Convergence Region for Proper Naming in Human Left Anterior Temporal Lobe

Abel¹,

Rhone²,

Nourski³

et al. 2015

J. Neurosci.

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Retrieving the names of friends, loved ones, and famous people is a fundamental human ability. This ability depends on the left anterior temporal lobe (ATL), where lesions can be associated with impaired naming of people regardless of modality (e.g., picture or voice). This finding has led to the idea that the left ATL is a modality-independent convergence region for proper naming. Hypotheses for how proper-name dispositions are organized within the left ATL include both a single modality-independent (heteromodal) convergence region and spatially discrete modality-dependent (unimodal) regions. Here we show direct electrophysiologic evidence that the left ATL is heteromodal for proper-name retrieval. Using intracranial recordings placed directly on the surface of the left ATL in human subjects, we demonstrate nearly identical responses to picture and voice stimuli of famous U.S. politicians during a naming task. Our results demonstrate convergent and robust large-scale neurophysiologic responses to picture and voice naming in the human left ATL. This finding supports the idea of heteromodal (i.e., transmodal) dispositions for proper naming in the left ATL.

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Section: Discussionmentioning

confidence: 75%

Direct Physiologic Evidence of a Heteromodal Convergence Region for Proper Naming in Human Left Anterior Temporal Lobe

Abel¹,

Rhone²,

Nourski³

et al. 2015

J. Neurosci.

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“…In contrast, direct intracranial cortical recordings offer a unique opportunity to acquire neural signals with an unprecedented combination of temporal and spatial resolution. Several such studies have implicated the inferior frontal lobe in word production (14)(15)(16)(17)(18)(19), but did not focus on the specific role of Broca's area in production. Conversely, a recent intracranial study was, to our knowledge, the first to focus on Broca's area, finding evidence for lexical, grammatical, and phonological processing (20), but did not examine the processes required for overt word production (phonetic encoding and articulation).…”

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confidence: 99%

Redefining the role of Broca’s area in speech

Flinker

Korzeniewska

Shestyuk

et al. 2015

Proc. Natl. Acad. Sci. U.S.A.

421

305

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For over a century neuroscientists have debated the dynamics by which human cortical language networks allow words to be spoken. Although it is widely accepted that Broca's area in the left inferior frontal gyrus plays an important role in this process, it was not possible, until recently, to detail the timing of its recruitment relative to other language areas, nor how it interacts with these areas during word production. Using direct cortical surface recordings in neurosurgical patients, we studied the evolution of activity in cortical neuronal populations, as well as the Granger causal interactions between them. We found that, during the cued production of words, a temporal cascade of neural activity proceeds from sensory representations of words in temporal cortex to their corresponding articulatory gestures in motor cortex. Broca's area mediates this cascade through reciprocal interactions with temporal and frontal motor regions. Contrary to classic notions of the role of Broca's area in speech, while motor cortex is activated during spoken responses, Broca's area is surprisingly silent. Moreover, when novel strings of articulatory gestures must be produced in response to nonword stimuli, neural activity is enhanced in Broca's area, but not in motor cortex. These unique data provide evidence that Broca's area coordinates the transformation of information across large-scale cortical networks involved in spoken word production. In this role, Broca's area formulates an appropriate articulatory code to be implemented by motor cortex.Broca | speech | ECoG S poken word production is fundamental to human communication. Paul Broca was the first to link word production to a cortical region in the posterior inferior frontal gyrus, since referred to as "Broca's area" (1). His iconic findings are among the most influential in the field of cortical specialization, and Broca's area is still considered to be critically involved in speech production (2, 3).The role of Broca's area in production has been extensively studied using paradigms that vary in complexity from single words to full discourse (4, 5). Although these tasks engage multiple different cognitive demands (e.g., phonological, semantic, and syntactic processing), they all share a common set of core operations consisting of retrieving a word's phonological representation, translating it into an articulatory code, and coordinating the fine motor movements of the vocal articulators (6). However, current neuropsychological and neurolinguistic theories still debate the exact role that Broca's area plays in this set of core operations (7-9). Indefrey and Levelt (4) proposed that Broca's area accesses a phonological word representation that is compiled sequentially into segments of syllables (i.e., syllabification). This segmental representation is then forwarded to motor regions where it is transformed into an articulatory (i.e., phonetic) code. Recent models of speech production (9), as well as the dual-stream model of speech processing (10), do not limit the artic...

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“…6-11) and word-level processes (e.g., refs. [12][13][14][15][16][17][18][19][20][21][22][23][24][25][26]. However, the most distinctive feature of human language is its compositionality: the ability to create and understand complex meanings from novel combinations of words structured into phrases and sentences (27).…”

mentioning

confidence: 99%

Neural correlate of the construction of sentence meaning

Fedorenko

Scott

Brunner

et al. 2016

Proc. Natl. Acad. Sci. U.S.A.

180

211

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The neural processes that underlie your ability to read and understand this sentence are unknown. Sentence comprehension occurs very rapidly, and can only be understood at a mechanistic level by discovering the precise sequence of underlying computational and neural events. However, we have no continuous and online neural measure of sentence processing with high spatial and temporal resolution. Here we report just such a measure: intracranial recordings from the surface of the human brain show that neural activity, indexed by γ-power, increases monotonically over the course of a sentence as people read it. This steady increase in activity is absent when people read and remember nonword-lists, despite the higher cognitive demand entailed, ruling out accounts in terms of generic attention, working memory, and cognitive load. Response increases are lower for sentence structure without meaning ("Jabberwocky" sentences) and word meaning without sentence structure (word-lists), showing that this effect is not explained by responses to syntax or word meaning alone. Instead, the full effect is found only for sentences, implicating compositional processes of sentence understanding, a striking and unique feature of human language not shared with animal communication systems. This work opens up new avenues for investigating the sequence of neural events that underlie the construction of linguistic meaning.ow does a sequence of sounds emerging from one person's mouth create a complex meaning in another person's mind? Although we have long known where language is processed in the brain (1-3), we still know almost nothing about how neural circuits extract and represent the meaning of a sentence. A powerful method for addressing this question is intracranial recording of neural activity directly from the cortical surface in neurosurgery patients (i.e., electrocorticography or ECoG) (4, 5). Although opportunities for ECoG data collection are rare, determined by clinical-not scientific-priorities, they nonetheless offer an unparalleled combination of spatial and temporal resolution, and further provide direct measures of actual neural activity, rather than indirect measures via blood flow (as in PET, fMRI, and near infrared spectroscopy/optical imaging). ECoG data are particularly valuable for the study of uniquely human functions like language, where animal models are inadequate. Here we used ECoG to identify the neural events that occur online as the meaning of a sentence is extracted and represented.Prior intracranial recording studies of language have largely focused on speech perception and production (e.g., refs. 6-11) and word-level processes (e.g., refs. 12-26). However, the most distinctive feature of human language is its compositionality: the ability to create and understand complex meanings from novel combinations of words structured into phrases and sentences (27). As a first step toward understanding the neural basis of sentence comprehension, we recorded intracranial responses while participants read sentences and...

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ECoG gamma activity during a language task: differentiating expressive and receptive speech areas

Cited by 224 publications

References 80 publications

Direct Physiologic Evidence of a Heteromodal Convergence Region for Proper Naming in Human Left Anterior Temporal Lobe

Direct Physiologic Evidence of a Heteromodal Convergence Region for Proper Naming in Human Left Anterior Temporal Lobe

Redefining the role of Broca’s area in speech

Neural correlate of the construction of sentence meaning

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