The neural circuits recruited for the production of signs and fingerspelled words

Emmorey, Karen; Mehta, Shilpa; McCullough, Stephen; Grabowski, Thomas J.

doi:10.1016/j.bandl.2016.07.003

Cited by 41 publications

(39 citation statements)

References 61 publications

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“…Regions containing greater representational structure for sign, than speech, were found in the bilateral occipital cortices, as well as in the left superior parietal lobule. This is consistent with the greater visual and body-space processing demands of sign language perception 29 and the growing evidence for superior parietal cortex involvement in sign perception and production 50 . As for speech, a subset of regions showing greater representational structure for sign than speech showed a significant fit with the semantic model, and this was driven by item-level encoding, consistent with visual sign form representations.…”

Section: Discussionsupporting

confidence: 82%

Evidence for shared conceptual representations for sign and speech

Evans

Price

Diedrichsen

et al. 2019

Preprint

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Do different languages evoke different conceptual representations? If so, greatest divergence might be expected between languages that differ most in structure, such as sign and speech. Unlike speech bilinguals, hearing sign-speech bilinguals use languages conveyed in different modalities. We used functional magnetic resonance imaging and representational similarity analysis (RSA) to quantify the similarity of semantic representations elicited by the same concepts presented in spoken British English and British Sign Language in hearing, early sign-speech bilinguals. We found shared representations for semantic categories in left posterior middle and inferior temporal cortex. Despite shared category representations, the same spoken words and signs did not elicit similar neural patterns. Thus, contrary to previous univariate activation-based analyses of speech and sign perception, we show that semantic representations evoked by speech and sign are only partially shared. This demonstrates the unique perspective that sign languages and RSA provide in understanding how language influences conceptual representation.

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Section: Discussionsupporting

confidence: 82%

Evidence for shared conceptual representations for sign and speech

Evans

Price

Diedrichsen

et al. 2019

Preprint

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“…These findings from sign comprehension fit well with a PET study of sign production (Emmorey et al, 2016) showing increased in SPL activity for one-handed signs that contacted the body, compared to one-handed signs or two-handed signs produced in neutral space.…”

Section: Introductionsupporting

confidence: 85%

“…It may be tempting to conclude that for sign language production, for which visual guidance is not necessary and motor plans are retrieved from memory rather than being determined by the physical environment, the role of SPL has shifted to generation of phonologically-based forward models at the expense of finer control. However, in the present study (as well as Emmorey et al, 2016) SPL activity is prevalent for a subset of signs: those involving contact between the hand and body. These are cases where finer control is necessary to reach a target location, although some variation is still permitted.…”

Section: Discussionmentioning

confidence: 42%

“…However, for phonological feature errors there was a reliable interaction (Z 1 =2.60, p=.004; Z 2 =1.76, p=.039) indicating that TMS to SPL selectively increased the number of phonological feature errors while leaving the other two error types unaffected; see Figure 3 for overall response times and errors of different types by experimental condition. Because previous literature implies increased engagement of SPL in producing signs requiring coordination of hand/s with body locations (Emmorey et al, 2016;Parkinson et al, 2010;Striemer et al, 2011), we divided the signs into those produced with one or two hands, and those that involved handto-hand contact or no contact (there were insufficient numbers of signs produced with handto-body contact). Signs without contact showed no effects of TMS (both |Z|<1), but the number of phonological feature errors more than doubled under TMS to left SPL for twohanded signs with hand-to-hand contact (Z 1 =1.90, p=.023; Z 2 =1.98, p=.024); see Table 1.…”

Section: Naming Latencies and Errorsmentioning

confidence: 99%

“…If SPL is reliably engaged in retrieval of BSL signs or initiation of overt sign production, applying TMS should broadly affect both speed and accuracy: slowing response initiation relative to a control condition, and increasing the rate of naming errors. Because previous studies, both of sign language production and other types of actions, suggest greater SPL engagement during complex coordination or precise target-directed movement (Bernier and Grafton, 2010;Parkinson et al, 2010;Tagliabue and McIntyre, 2014;Emmorey et al, 2016), TMS effects on response times might be limited to signs requiring coordinated movement of both hands or precisely-defined place of articulation. However, if SPL is more engaged in generating internal plans for monitoring language-specific forms (Emmorey et al, 2004;2007;2014;, effects on response initiation should not occur.…”

Section: Introductionmentioning

confidence: 99%

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Transcranial magnetic stimulation during British Sign Language production reveals monitoring of discrete linguistic units in left superior parietal lobule

Vinson

Fox

Devlin

et al. 2019

Preprint

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Successful human hand and arm movements are typically carried out by combining visual, motoric, and proprioceptive information in planning, initiation, prediction, and control. The superior parietal lobule (SPL) has been argued to play a key role in integrating visual and motoric information particularly during grasping of objects and other such tasks which prioritise visual information. However, sign language production also engages SPL even though fluent signers do not visually track their hands or fixate on target locations. Does sign language production simply rely on the motoric/ proprioceptive processes engaged in visually guided action, or do the unique characteristics of signed languages change these processes? Fifteen fluent British Sign Language users named pictures while we administered transcranial magnetic stimulation (TMS) to left SPL, a control site, or no TMS.TMS to SPL had very specific effects: an increased rate of (sign-based) phonological substitution errors for complex two-handed signs (those requiring hand contact), but TMS did not slow or otherwise impair performance. Thus, TMS decreased the likelihood of detecting or correcting phonological errors during otherwise successful bimanual coordination, but it did not noticeably alter fine movement control. These findings confirm that for fluent signers SPL has adapted to monitor motor plans for discrete hand configurations retrieved from memory as well as more fine-grained aspects of visually guided actions.Some studies of reaching and grasping manipulate the availability of visual cues and/or their consistency with proprioceptive cues (e.g. Jackson and Husain, 2006;Reichenbach et al., 2014). The findings from this research suggest different action control systems (Chib et al., 2009) with proprioceptive-only systems distinct from combined sensory systems that take both types of information into account in movement correction. The tasks, however, are still explicitly visual in that specific visual properties of the target must determine the motor plan. To avoid this issue, Parkinson et al. (2010) asked blindfolded participants to make reaching hand movements to a button box near their waist, thus

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Functional neuroanatomy of language without speech: An ALE meta‐analysis of sign language

Trettenbrein

Papitto

Friederici

et al. 2020

Human Brain Mapping

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Sign language (SL) conveys linguistic information using gestures instead of sounds. Here, we apply a meta‐analytic estimation approach to neuroimaging studies (N = 23; subjects = 316) and ask whether SL comprehension in deaf signers relies on the same primarily left‐hemispheric cortical network implicated in spoken and written language (SWL) comprehension in hearing speakers. We show that: (a) SL recruits bilateral fronto‐temporo‐occipital regions with strong left‐lateralization in the posterior inferior frontal gyrus known as Broca's area, mirroring functional asymmetries observed for SWL. (b) Within this SL network, Broca's area constitutes a hub which attributes abstract linguistic information to gestures. (c) SL‐specific voxels in Broca's area are also crucially involved in SWL, as confirmed by meta‐analytic connectivity modeling using an independent large‐scale neuroimaging database. This strongly suggests that the human brain evolved a lateralized language network with a supramodal hub in Broca's area which computes linguistic information independent of speech.

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The neural circuits recruited for the production of signs and fingerspelled words

Cited by 41 publications

References 61 publications

Evidence for shared conceptual representations for sign and speech

Evidence for shared conceptual representations for sign and speech

Transcranial magnetic stimulation during British Sign Language production reveals monitoring of discrete linguistic units in left superior parietal lobule

Functional neuroanatomy of language without speech: An ALE meta‐analysis of sign language

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