Your search keyword '"Broca's area"' showing total 1,720 results

1. Deep learning-based localization algorithms on fluorescence human brain 3D reconstruction: a comparative study using stereology as a reference

Author

Curzio Checcucci, Bridget Wicinski, Giacomo Mazzamuto, Marina Scardigli, Josephine Ramazzotti, Niamh Brady, Francesco S. Pavone, Patrick R. Hof, Irene Costantini, and Paolo Frasconi

Subjects

Cell detection, Deep-learning, Human brain, Broca’s area, 3D reconstruction, Fluorescence microscopy, Medicine, Science

Abstract

Abstract 3D reconstruction of human brain volumes at high resolution is now possible thanks to advancements in tissue clearing methods and fluorescence microscopy techniques. Analyzing the massive data produced with these approaches requires automatic methods able to perform fast and accurate cell counting and localization. Recent advances in deep learning have enabled the development of various tools for cell segmentation. However, accurate quantification of neurons in the human brain presents specific challenges, such as high pixel intensity variability, autofluorescence, non-specific fluorescence and very large size of data. In this paper, we provide a thorough empirical evaluation of three techniques based on deep learning (StarDist, CellPose and BCFind-v2, an updated version of BCFind) using a recently introduced three-dimensional stereological design as a reference for large-scale insights. As a representative problem in human brain analysis, we focus on a $$4~\text {-cm}^3$$ 4 -cm 3 portion of the Broca’s area. We aim at helping users in selecting appropriate techniques depending on their research objectives. To this end, we compare methods along various dimensions of analysis, including correctness of the predicted density and localization, computational efficiency, and human annotation effort. Our results suggest that deep learning approaches are very effective, have a high throughput providing each cell 3D location, and obtain results comparable to the estimates of the adopted stereological design.

Published

2024

2. Characteristics of oxyhemoglobin during the verbal fluency task in subthreshold depression: A multi-channel near-infrared spectroscopy study.

Author

Da, Hui, Xiang, Nian, Qiu, Min, Abbas, Sadia, Xiao, Qiang, and Zhang, Yan

Subjects

*DEPRESSION in college students, *NEAR infrared spectroscopy, *OXYHEMOGLOBIN, *MENTAL depression, *SPECTROSCOPIC imaging

Abstract

Subthreshold depression is an essential precursor and risk factor for major depressive disorder, and its accurate identification and timely intervention are important for reducing the prevalence of major depressive disorder. Therefore, we used functional near-infrared spectroscopic imaging (fNIRS) to explore the characteristics of the brain neural activity of college students with subthreshold depression in the verbal fluency task. A total of 72 subthreshold depressed college students (SDs) and 67 healthy college students (HCs) were recruited, and all subjects were subjected to a verbal fluency task (VFT) while a 53-channel fNIRS device was used to collect the subjects' cerebral blood oxygenation signals. The results of the independent samples t -test showed that the mean oxyhemoglobin in the right dorsolateral prefrontal (ch34, ch42, ch45) and Broca's area (ch51, ch53) of SDs was lower than that of HCs. The peak oxygenated hemoglobin of SDs was lower in the right dorsolateral prefrontal (ch34) and Broca's area (ch51, ch53).The brain functional connectivity strength was lower than that of HCs. Correlation analysis showed that the left DLPFC and Broca's area were significantly negatively correlated with the depression level. SDs showed abnormally low, inadequate levels of brain activation and weak frontotemporal brain functional connectivity. The right DLPFC has a higher sensitivity for the differentiation of depressive symptoms and is suitable as a biomarker for the presence of depressive symptoms. Dysfunction in Broca's area can be used both as a marker of depressive symptoms and as a biomarker, indicating the severity of depressive symptoms. • Hypoperfusion in right DLPFC and Broca's area is physiological mechanisms distinguishing subthreshold depression. • Higher depression is associated with lower levels of cortical activation in the left DLPFC and Broca's area. • Subthreshold depression can be associated with low strength of overall brain functional connectivity. • fNIRS may be a potential tool to improve diagnostic accuracy for subthreshold depression. [ABSTRACT FROM AUTHOR]

Published

2024

3. Cognitive control in written word production.

Author

Neophytou, Kyriaki, Wiley, Robert W., and Rapp, Brenda

Subjects

LEXICAL access, TASK performance, WRITTEN communication, WORD order (Grammar), COGNITIVE ability

Abstract

Introduction: Cognitive control processes have been extensively studied in spoken word production, however, relevant investigations of written word production are scarce. Using data from a group of post-stroke individuals we studied, for the first time, the neural substrates of cognitive control in written word production. We addressed three questions: Are control mechanisms: (1) shared by language and non-language domains; (2) shared by lexical and segmental levels of word production within the word production system; (3) related to both interference and facilitation effect types? Methods: To address these questions, for each participant we calculated cognitive control indices that reflected the interference and facilitation effects observed in written Blocked Cyclic Naming (written language production) and Simon (visuo-spatial processing) tasks. These behavioral cognitive control indices were studied both on their own, as well as in relation to the distribution of structural (gray matter) lesions. Results: For Question 1, we provide strong evidence of domain-specific control mechanisms used in written word production, as, among other findings, distinct regions within Broca’s Area were associated with control in written word production vs. control in visuo-spatial processing. For Question 2, our results provide no strong evidence of shared control mechanisms for lexical and segmental levels of written word production, while they highlight the role of BA45 in instantiating control mechanisms that are specific to the two levels. For Question 3, we found evidence that BA45 supports distinct mechanisms associated with facilitation and interference, while orbital frontal cortex supports control process(es) associated with both. Discussion: These findings significantly advance our understanding of the cognitive control mechanisms involved in written language production, as well as of the role of Broca’s Area in cognitive control and language production more generally. [ABSTRACT FROM AUTHOR]

Published

2024

4. How the Physical Environment Shaped Language

Author

Dornbierer-Stuart, Joanna and Dornbierer-Stuart, Joanna

Published

2024

5. Dissociation of Broca's area from Broca's aphasia in patients undergoing neurosurgical resections.

Author

Andrews, John P, Cahn, Nathan, Speidel, Benjamin A, Chung, Jason E, Levy, Deborah F, Wilson, Stephen M, Berger, Mitchel S, and Chang, Edward F

Subjects

Aphasia, Brain Disorders, Neurosciences, 2.1 Biological and endogenous factors, Aetiology, Humans, Broca Area, Aphasia, Broca, Brain, Magnetic Resonance Imaging, Brain Mapping, Frontal Lobe, Broca?s aphasia, Broca?s area, VLSM, voxel-based lesion-symptom mapping, neurosurgery, surgical technique, Broca’s aphasia, Broca’s area, Clinical Sciences, Neurology & Neurosurgery

Abstract

ObjectiveBroca's aphasia is a syndrome of impaired fluency with retained comprehension. The authors used an unbiased algorithm to examine which neuroanatomical areas are most likely to result in Broca's aphasia following surgical lesions.MethodsPatients were prospectively evaluated with standardized language batteries before and after surgery. Broca's area was defined anatomically as the pars opercularis and triangularis of the inferior frontal gyrus. Broca's aphasia was defined by the Western Aphasia Battery language assessment. Resections were outlined from MRI scans to construct 3D volumes of interest. These were aligned using a nonlinear transformation to Montreal Neurological Institute brain space. A voxel-based lesion-symptom mapping (VLSM) algorithm was used to test for areas statistically associated with Broca's aphasia when incorporated into a resection, as well as areas associated with deficits in fluency independent of Western Aphasia Battery classification. Postoperative MRI scans were reviewed in blinded fashion to estimate the percentage resection of Broca's area compared to areas identified using the VLSM algorithm.ResultsA total of 289 patients had early language evaluations, of whom 19 had postoperative Broca's aphasia. VLSM analysis revealed an area that was highly correlated (p < 0.001) with Broca's aphasia, spanning ventral sensorimotor cortex and supramarginal gyri, as well as extending into subcortical white matter tracts. Reduced fluency scores were significantly associated with an overlapping region of interest. The fluency score was negatively correlated with fraction of resected precentral, postcentral, and supramarginal components of the VLSM area.ConclusionsBroca's aphasia does not typically arise from neurosurgical resections in Broca's area. When Broca's aphasia does occur after surgery, it is typically in the early postoperative period, improves by 1 month, and is associated with resections of ventral sensorimotor cortex and supramarginal gyri.

Published

2023

6. Hemispheric dominance in HVC is experience-dependent in juvenile male zebra finches

Author

Sophia Y. Frank, Jesse L. Hunt, Andrea J. Bae, Napim Chirathivat, Sima Lotfi, Sahitya C. Raja, and Sharon M. H. Gobes

Subjects

Song learning, Lateralization, Zenk, Language learning, Broca’s area, Medicine, Science

Abstract

Abstract Juvenile male zebra finches (Taeniopygia guttata) must be exposed to an adult tutor during a sensitive period to develop normal adult song. The pre-motor nucleus HVC (acronym used as a proper name), plays a critical role in song learning and production (cf. Broca’s area in humans). In the human brain, left-side hemispheric dominance in some language regions is positively correlated with proficiency in linguistic skills. However, it is unclear whether this pattern depends upon language learning, develops with normal maturation of the brain, or is the result of pre-existing functional asymmetries. In juvenile zebra finches, even though both left and right HVC contribute to song production, baseline molecular activity in HVC is left-dominant. To test if HVC exhibits hemispheric dominance prior to song learning, we raised juvenile males in isolation from adult song and measured neuronal activity in the left and right HVC upon first exposure to an auditory stimulus. Activity in the HVC was measured using the immediate early gene (IEG) zenk (acronym for zif-268, egr-1, NGFI-a, and krox-24) as a marker for neuronal activity. We found that neuronal activity in the HVC of juvenile male zebra finches is not lateralized when raised in the absence of adult song, while normally-reared juvenile birds are left-dominant. These findings show that there is no pre-existing asymmetry in the HVC prior to song exposure, suggesting that lateralization of the song system depends on learning through early exposure to adult song and subsequent song-imitation practice.

Published

2024

7. Rock music improvisation shows increased activity in Broca’s area and its right hemisphere homologue related to spontaneous creativity

Author

Atsumichi Tachibana, J. Adam Noah, Yumie Ono, Shun Irie, Muneto Tatsumoto, Daisuke Taguchi, Nobuko Tokuda, and Shuichi Ueda

Subjects

Creativity, Broca’s area, Improvisation, Brodmann area 46, Functional near-infrared spectroscopy, Motor control, Medicine, Biology (General), QH301-705.5, Science (General), Q1-390

Abstract

Abstract Objective The neural correlates of creativity are not well understood. Using an improvised guitar task, we investigated the role of Broca's area during spontaneous creativity, regardless of individual skills, experience, or subjective feelings. Results Twenty guitarists performed improvised and formulaic blues rock sequences while hemodynamic responses were recorded using functional near-infrared spectroscopy. We identified a new significant response in Broca’s area (Brodmann area [BA] 45L) and its right hemisphere homologue during improvised playing but not during formulaic playing. Our results indicate that bilateral BA45 activity is common during creative processes that involve improvisation across all participants, regardless of subjective feelings, skill, age, difficulty, history, or amount of practice. While our previous results demonstrated that the modulation of the neural network according to the subjectively experienced level of creativity relied on the degree of deactivation in BA46L, our current results independently show a common concurrent activity in BA45 in all participants. We suggest that this is related to the sustained execution of improvisation in “motor control,” analogous to motor planning in speech control.

Published

2024

8. A case of pure apraxia of speech after left hemisphere stroke: behavioral findings and neural correlates.

Author

Pracar, Alexis, Ivanova, Maria, Richardson, Amber, and Dronkers, Nina

Subjects

Broca’s area, aphasia, apraxia of speech, insula, speech production

Abstract

INTRODUCTION: Apraxia of speech (AOS) is a motor speech disorder impairing the coordination of complex articulatory movements needed to produce speech. AOS typically co-occurs with a non-fluent aphasia, or language disorder, making it challenging to determine the specific brain structures that cause AOS. Cases of pure AOS without aphasia are rare but offer the best window into the neural correlates that support articulatory planning. The goal of the current study was to explore patterns of apraxic speech errors and their underlying neural correlates in a case of pure AOS. METHODS: A 67-year-old right-handed man presented with severe AOS resulting from a fronto-insular lesion caused by an ischemic stroke. The participants speech and language were evaluated at 1-, 3- and 12-months post-onset. High resolution structural MRI, including diffusion weighted imaging, was acquired at 12 months post-onset. RESULTS: At the first assessment, the participant made minor errors on the Comprehensive Aphasia Test, demonstrating mild deficits in writing, auditory comprehension, and repetition. By the second assessment, he no longer had aphasia. On the Motor Speech Evaluation, the severity of his AOS was initially rated as 5 (out of 7) and improved to a score of 4 by the second visit, likely due to training by his SLP at the time to slow his speech. Structural MRI data showed a fronto-insular lesion encompassing the superior precentral gyrus of the insula and portions of the inferior and middle frontal gyri and precentral gyrus. Tractography derived from diffusion MRI showed partial damage to the frontal aslant tract and arcuate fasciculus along the white matter projections to the insula. DISCUSSION: This pure case of severe AOS without aphasia affords a unique window into the behavioral and neural mechanisms of this motor speech disorder. The current findings support previous observations that AOS and aphasia are dissociable and confirm a role for the precentral gyrus of the insula and BA44, as well as underlying white matter in supporting the coordination of complex articulatory movements. Additionally, other regions including the precentral gyrus, Brocas area, and Area 55b are discussed regarding their potential role in successful speech production.

Published

2023

9. Agrammatism in Malayalam-speaking Broca's Aphasics.

Author

Jacob, Stephy, Varamangalath, Mansoor, and Sebastian, Swapna

Subjects

AGRAMMATISM, APHASIA, AFFIXES (Grammar), MALAYALAM language, BROCA'S area

Abstract

The article presents the discussion on agrammatism, primarily associated with nonfluent aphasias like Broca's aphasia, characterized by omission of function words and inflectional affixes, leading to telegraphic utterances. Topics include hypotheses explaining agrammatism, including phonological deficit, syntactic deficit, and lexical-semantic deficit, and aims to study agrammatic deficits in Malayalam-speaking Broca's aphasics.

Published

2024

10. Hemispheric dominance in HVC is experience-dependent in juvenile male zebra finches.

Author

Frank, Sophia Y., Hunt, Jesse L., Bae, Andrea J., Chirathivat, Napim, Lotfi, Sima, Raja, Sahitya C., and Gobes, Sharon M. H.

Subjects

*CEREBRAL dominance, *BIRDSONGS, *ZEBRA finch, *SONGBIRDS, *AUDITORY perception, *DOMINANT language, *PRIOR learning

Abstract

Juvenile male zebra finches (Taeniopygia guttata) must be exposed to an adult tutor during a sensitive period to develop normal adult song. The pre-motor nucleus HVC (acronym used as a proper name), plays a critical role in song learning and production (cf. Broca's area in humans). In the human brain, left-side hemispheric dominance in some language regions is positively correlated with proficiency in linguistic skills. However, it is unclear whether this pattern depends upon language learning, develops with normal maturation of the brain, or is the result of pre-existing functional asymmetries. In juvenile zebra finches, even though both left and right HVC contribute to song production, baseline molecular activity in HVC is left-dominant. To test if HVC exhibits hemispheric dominance prior to song learning, we raised juvenile males in isolation from adult song and measured neuronal activity in the left and right HVC upon first exposure to an auditory stimulus. Activity in the HVC was measured using the immediate early gene (IEG) zenk (acronym for zif-268, egr-1, NGFI-a, and krox-24) as a marker for neuronal activity. We found that neuronal activity in the HVC of juvenile male zebra finches is not lateralized when raised in the absence of adult song, while normally-reared juvenile birds are left-dominant. These findings show that there is no pre-existing asymmetry in the HVC prior to song exposure, suggesting that lateralization of the song system depends on learning through early exposure to adult song and subsequent song-imitation practice. [ABSTRACT FROM AUTHOR]

Published

2024

11. Verb generation for presurgical mapping: Gaining specificity.

Author

Salillas, Elena, Luisi, Concetta, Arcara, Giorgio, Varlı, Elif Nur, d'Avella, Domenico, and Semenza, Carlo

Subjects

*PREFRONTAL cortex, *VERBS, *NOUNS, *VOXEL-based morphometry, *DICHOTIC listening tests, *BRAIN mapping, *LINGUISTIC rights

Abstract

Verb generation is among the most frequently used tasks in presurgical mapping. Because this task involves many processes, the overall brain effects are not specific. While it is necessary to identify the whole network involving noun comprehension or semantic retrieval and lexical selection to produce the verb, isolation of those components is also crucial. Here, we present data from four patients undergoing presurgical brain mapping. The study implied a reanalysis of magnetoencephalography data with a recategorization of the used items. It aimed to extract the task component that relies on the inferior frontal gyrus (IFG). The task could be applied with higher specificity when targeting frontal areas. For that, we based item classification on the selection demands imposed by the noun. It is a robust finding that the IFG carries out this selection and that a quantitative index can be calculated for each noun, which depends on the selection effort (Proceedings of the National Academy of Sciences of the United States of America, 1997; 94(26):14792–14797, Proceedings of the National Academy of Sciences of the United States of America, 1998; 95(26):15855–15860). Data showed focality and specificity, with a correlation between this derived index and source activations in the inferior frontal gyrus for all patients. Strikingly, we detected when the right‐hemisphere homologue area was involved in the selection process in two patients showing reorganization or language right lateralization. The present data are a step towards a dissection of broad specific tasks frequently used in presurgical protocols. [ABSTRACT FROM AUTHOR]

Published

2024

12. Rock music improvisation shows increased activity in Broca's area and its right hemisphere homologue related to spontaneous creativity.

Author

Tachibana, Atsumichi, Noah, J. Adam, Ono, Yumie, Irie, Shun, Tatsumoto, Muneto, Taguchi, Daisuke, Tokuda, Nobuko, and Ueda, Shuichi

Subjects

*MUSIC improvisation, *ROCK music, *NEAR infrared spectroscopy, *CREATIVE ability, *HEMODYNAMICS

Abstract

Objective: The neural correlates of creativity are not well understood. Using an improvised guitar task, we investigated the role of Broca's area during spontaneous creativity, regardless of individual skills, experience, or subjective feelings. Results: Twenty guitarists performed improvised and formulaic blues rock sequences while hemodynamic responses were recorded using functional near-infrared spectroscopy. We identified a new significant response in Broca's area (Brodmann area [BA] 45L) and its right hemisphere homologue during improvised playing but not during formulaic playing. Our results indicate that bilateral BA45 activity is common during creative processes that involve improvisation across all participants, regardless of subjective feelings, skill, age, difficulty, history, or amount of practice. While our previous results demonstrated that the modulation of the neural network according to the subjectively experienced level of creativity relied on the degree of deactivation in BA46L, our current results independently show a common concurrent activity in BA45 in all participants. We suggest that this is related to the sustained execution of improvisation in "motor control," analogous to motor planning in speech control. [ABSTRACT FROM AUTHOR]

Published

2024

13. Two models of mind blanking.

Author

Kaufmann, Angelica, Parmigiani, Sara, Kawagoe, Toshikazu, Zabaroff, Elliot, and Wells, Barnaby

Subjects

*TRANSCRANIAL magnetic stimulation, *ELECTROENCEPHALOGRAPHY

Abstract

Mind blanking is a mental state in which attention does not bring any perceptual input into conscious awareness. As this state is still largely unexplored, we suggest that a comprehensive understanding of mind blanking can be achieved through a multifaceted approach combining self‐assessment methods, neuroimaging and neuromodulation. In this article, we explain how electroencephalography and transcranial magnetic stimulation could be combined to help determine whether mind blanking is associated with a lack of mental content or a lack of linguistically or conceptually determinable mental content. We also question whether mind blanking occurs spontaneously or intentionally and whether these two forms are instantiated by the same or different neural correlates. [ABSTRACT FROM AUTHOR]

Published

2024

14. Is Broca's area critical for speech and language? Evidence from lesion-symptom mapping in chronic aphasia

Author

Timothy J. Herron, Krista Schendel, Brian C. Curran, Sandy J. Lwi, Maria G. Spinelli, Carl Ludy, Nina F. Dronkers, and Juliana V. Baldo

Subjects

speech, language, Broca's area, aphasia, Broca's aphasia, Language and Literature

Abstract

IntroductionThe specific role that Broca's area plays in speech and language has been hotly debated in the literature. Some research has pointed to a specific role in particular aspects of speech production, while other findings have suggested additional roles in aspects of language comprehension. In the current study, we had the opportunity to take a broad approach by analyzing lesion and behavioral data from a large cohort of left hemisphere stroke patients. In this brief report, our objective was to identify which speech-language measures show a significant association with Broca's area, specifically pars opercularis and pars triangularis.MethodsLesion site and neuropsychological data from 173 chronic left hemisphere stroke patients were analyzed in the current study. Univariate lesion-symptom mapping (LSM) with rigorous correction was used to identify brain regions associated with individual test performance on a large battery of speech and language tasks. Multivariate LSM analyses were conducted in subsequent runs to confirm findings.ResultsThe LSM results identified many predictable left hemisphere gray and white matter regions significantly associated with the speech-language data, but Broca's area was not implicated in performance on any speech or language measure. Regions adjacent to Broca's area, however, in left central opercular, precentral, and insular cortices were associated with speech production and motor speech performance.DiscussionThe current study failed to identify a single speech or language measure in our comprehensive test battery that was dependent on Broca's area. This finding could not be attributed to a lack of power, as Broca's area had among the highest power values and substantial lesion coverage. Interrogation of data at the individual patient level revealed the likely source of this null finding: Patients with lesions involving Broca's area varied widely in their speech-language performance, with profiles ranging from non-aphasic to Broca's to global aphasia. Given previous studies in acute stroke patients and healthy participants implicating Broca's area in speech-language, the current findings suggest that Broca's area plays a more supplementary than critical role and can be compensated by surrounding brain regions in chronic stroke.

Published

2024

15. Enhancing Speech Rehabilitation in a Young Adult with Trisomy 21: Integrating Transcranial Direct Current Stimulation (tDCS) with Rapid Syllable Transition Training for Apraxia of Speech.

Author

Nakamura-Palacios, Ester Miyuki, Falçoni Júnior, Aldren Thomazini, Tanese, Gabriela Lolli, Vogeley, Ana Carla Estellita, and Namasivayam, Aravind Kumar

Subjects

*TRANSCRANIAL direct current stimulation, *SPEECH apraxia, *DOWN syndrome, *YOUNG adults, *SPEECH, *TEMPOROPARIETAL junction

Abstract

Apraxia of speech is a persistent speech motor disorder that affects speech intelligibility. Studies on speech motor disorders with transcranial Direct Current Stimulation (tDCS) have been mostly directed toward examining post-stroke aphasia. Only a few tDCS studies have focused on apraxia of speech or childhood apraxia of speech (CAS), and no study has investigated individuals with CAS and Trisomy 21 (T21, Down syndrome). This N-of-1 randomized trial examined the effects of tDCS combined with a motor learning task in developmental apraxia of speech co-existing with T21 (ReBEC RBR-5435x9). The accuracy of speech sound production of nonsense words (NSWs) during Rapid Syllable Transition Training (ReST) over 10 sessions of anodal tDCS (1.5 mA, 25 cm) over Broca's area with the cathode over the contralateral region was compared to 10 sessions of sham-tDCS and four control sessions in a 20-year-old male individual with T21 presenting moderate–severe childhood apraxia of speech (CAS). The accuracy for NSW production progressively improved (gain of 40%) under tDCS (sham-tDCS and control sessions showed < 20% gain). A decrease in speech severity from moderate–severe to mild–moderate indicated transfer effects in speech production. Speech accuracy under tDCS was correlated with Wernicke's area activation (P3 current source density), which in turn was correlated with the activation of the left supramarginal gyrus and the Sylvian parietal–temporal junction. Repetitive bihemispheric tDCS paired with ReST may have facilitated speech sound acquisition in a young adult with T21 and CAS, possibly through activating brain regions required for phonological working memory. [ABSTRACT FROM AUTHOR]

Published

2024

16. Investigating the Impact of Semantic Operations on Persian-Speaking Aphasics: Further Evidence on the Localization View.

Author

Azad, Omid and Ghonchepour, Mousa

Subjects

*APHASIC persons, *PEOPLE with disabilities, *BROCA'S area, *SEMANTICS (Philosophy), *PARSING (Grammar)

Abstract

Introduction: Broca and Wernicke's patients perform satisfactorily regarding the processing of canonical syntactic structures, as maintained by previous studies; however, there has been a gap in the literature because no particular research has yet investigated the performance of these patients in the Persian circumstances once they were required to analyze sentences which would demand extra-semantic processing. This study clarifies the role of two critical semantic operations demanding extra-semantic processing at the sentential level: Aspectual coercion. It complements to provide some evidence on the localist view of the brain. Our rationale for selecting these operations was their pure semantic nature, not relying on morphosyntactic properties. Materials and Methods: Having recruited two age- and education-matched Broca, two Wernicke, and four healthy controls, we conducted a semantic judgment task in which the participants were asked to express their correct semantic judgment in the two coercion and two normal conditions. Results: Our results showed an approximately above-chance performance of the Broca group for all conditions; however, in the Wernicke group, the same result was not observed due to their poor performance in coercion conditions, though in ordinary sentences, they performed much better. Conclusion: Our findings, along with similar off-line and imaging studies, corroborate the view of localism, based on which Wernicke's area is mainly responsible for the primary semantic operations while Broca's area predominantly takes over syntactic parsing. [ABSTRACT FROM AUTHOR]

Published

2024

17. Cognitive control in written word production

Author

Kyriaki Neophytou, Robert W. Wiley, and Brenda Rapp

Subjects

Broca's area, cognitive control, written word production, domain-specificity, interference, facilitation, Language and Literature

Abstract

IntroductionCognitive control processes have been extensively studied in spoken word production, however, relevant investigations of written word production are scarce. Using data from a group of post-stroke individuals we studied, for the first time, the neural substrates of cognitive control in written word production. We addressed three questions: Are control mechanisms: (1) shared by language and non-language domains; (2) shared by lexical and segmental levels of word production within the word production system; (3) related to both interference and facilitation effect types?MethodsTo address these questions, for each participant we calculated cognitive control indices that reflected the interference and facilitation effects observed in written Blocked Cyclic Naming (written language production) and Simon (visuo-spatial processing) tasks. These behavioral cognitive control indices were studied both on their own, as well as in relation to the distribution of structural (gray matter) lesions.ResultsFor Question 1, we provide strong evidence of domain-specific control mechanisms used in written word production, as, among other findings, distinct regions within Broca's Area were associated with control in written word production vs. control in visuo-spatial processing. For Question 2, our results provide no strong evidence of shared control mechanisms for lexical and segmental levels of written word production, while they highlight the role of BA45 in instantiating control mechanisms that are specific to the two levels. For Question 3, we found evidence that BA45 supports distinct mechanisms associated with facilitation and interference, while orbital frontal cortex supports control process(es) associated with both.DiscussionThese findings significantly advance our understanding of the cognitive control mechanisms involved in written language production, as well as of the role of Broca's Area in cognitive control and language production more generally.

Published

2024

18. Neural correlates of semantic-driven syntactic parsing in sentence comprehension

Author

Yun Zhang, Marcus Taft, Jiaman Tang, and Le Li

Subjects

Broca's area, Semantic relation, Syntax, fMRI, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

For sentence comprehension, information carried by semantic relations between constituents must be combined with other information to decode the constituent structure of a sentence, due to atypical and noisy situations of language use. Neural correlates of decoding sentence structure by semantic information have remained largely unexplored. In this functional MRI study, we examine the neural basis of semantic-driven syntactic parsing during sentence reading and compare it with that of other types of syntactic parsing driven by word order and case marking. Chinese transitive sentences of various structures were investigated, differing in word order, case making, and agent-patient semantic relations (i.e., same vs. different in animacy). For the non-canonical unmarked sentences without usable case marking, a semantic-driven effect triggered by agent-patient ambiguity was found in the left inferior frontal gyrus opercularis (IFGoper) and left inferior parietal lobule, with the activity not being modulated by naturalness factors of the sentences. The comparison between each type of non-canonical sentences with canonical sentences revealed that the non-canonicity effect engaged the left posterior frontal and temporal regions, in line with previous studies. No extra neural activity was found responsive to case marking within the non-canonical sentences. A word order effect across all types of sentences was also found in the left IFGoper, suggesting a common neural substrate between different types of parsing. The semantic-driven effect was also observed for the non-canonical marked sentences but not for the canonical sentences, suggesting that semantic information is used in decoding sentence structure in addition to case marking. The current findings illustrate the neural correlates of syntactic parsing with semantics, and provide neural evidence of how semantics facilitates syntax together with other information.

Published

2024

19. Is There a Role of Inferior Frontal Cortex in Motor Timing? A Study of Paced Finger Tapping in Patients with Non-Fluent Aphasia

Author

Chrysanthi Andronoglou, George Konstantakopoulos, Christina Simoudi, Dimitrios Kasselimis, Ioannis Evdokimidis, Evangelos Tsoukas, Dimitrios Tsolakopoulos, Georgia Angelopoulou, and Constantin Potagas

Subjects

aphasia, Broca’s area, motor timing, finger tapping, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

The aim of the present study was to investigate the deficits in timing reproduction in individuals with non-fluent aphasia after a left hemisphere lesion including the inferior frontal gyrus, in which Broca’s region is traditionally localised. Eighteen stroke patients with non-fluent aphasia and twenty-two healthy controls were recruited. We used a finger-tapping Test, which consisted of the synchronisation and the continuation phase with three fixed intervals (450 ms, 650 ms and 850 ms). Participants firstly had to tap simultaneously with the device’s auditory stimuli (clips) (synchronisation phase) and then continue their tapping in the same pace when the stimuli were absent (continuation phase). Patients with aphasia demonstrated less accuracy and greater variability during reproduction in both phases, compared to healthy participants. More specifically, in the continuation phase, individuals with aphasia reproduced longer intervals than the targets, whereas healthy participants displayed accelerated responses. Moreover, patients’ timing variability was greater in the absence of the auditory stimuli. This could possibly be attributed to deficient mental representation of intervals and not experiencing motor difficulties (due to left hemisphere stroke), as the two groups did not differ in tapping reproduction with either hand. Given that previous findings suggest a potential link between the IFG, timing and working memory, we argue that patients’ extra-linguistic cognitive impairments should be accounted for, as possible contributing factors to timing disturbances.

Published

2023

20. Neuroanatomical Atlas of Key Presurgical and Cognitive Eloquent Cortex Regions

Author

Mohamed, Feroze B., Yannes, Michael P., Malik, Muhammed, Faro, Scott H., Faro, Scott H., editor, and Mohamed, Feroze B., editor

Published

2023

21. William James’ Ineffable ‘More’: In Philosophy of Language and Neuroscience

Author

Weed, Laura E., Knepper, Timothy D., Series Editor, Kalmanson, Leah E., Series Editor, Billimoria, Purushottoma, Editorial Board Member, Garfield, Jay, Editorial Board Member, Katz, Steven, Editorial Board Member, Komjathy, Louis, Editorial Board Member, Kopf, Gereon, Editorial Board Member, Kumalo, R. Simangaliso, Editorial Board Member, Neville, Robert Cummings, Editorial Board Member, Rustom, Mohammed, Editorial Board Member, Park, Jin Y, Editorial Board Member, Schilbrack, Kevin, Editorial Board Member, Singh, Nikky-Guninder Kaur, Editorial Board Member, Wildman, Wesley J, Editorial Board Member, You, Bin, Editorial Board Member, and Weed, Laura E., editor

Published

2023

22. Beyond Broca’s and Wernicke’s: Functional Mapping of Ancillary Language Centers Prior to Brain Tumor Surgery

Author

Ashley Lawrence, Michael Carvajal, and Jacob Ormsby

Subjects

fMRI, Broca’s area, Wernicke’s area, language laterality, intraoperative mapping, Computer applications to medicine. Medical informatics, R858-859.7

Abstract

Functional MRI is a well-established tool used for pre-surgical planning to help the neurosurgeon have a roadmap of critical functional areas that should be avoided, if possible, during surgery to minimize morbidity for patients with brain tumors (though this also has applications for surgical resection of epileptogenic tissue and vascular lesions). This article reviews the locations of secondary language centers within the brain along with imaging findings to help improve our confidence in our knowledge on language lateralization. Brief overviews of these language centers and their contributions to the language networks will be discussed. These language centers include primary language centers of “Broca’s Area” and “Wernicke’s Area”. However, there are multiple secondary language centers such as the dorsal lateral prefrontal cortex (DLPFC), frontal eye fields, pre- supplemental motor area (pre-SMA), Basal Temporal Language Area (BTLA), along with other areas of activation. Knowing these foci helps to increase self-assurance when discussing the nature of laterality with the neurosurgeon. By knowing secondary language centers for language lateralization, via fMRI, one can feel confident on providing neurosurgeon colleagues with appropriate information on the laterality of language in preparation for surgery.

Published

2023

23. Deep learning-based localization algorithms on fluorescence human brain 3D reconstruction: a comparative study using stereology as a reference

Author

Checcucci, Curzio, Wicinski, Bridget, Mazzamuto, Giacomo, Scardigli, Marina, Ramazzotti, Josephine, Brady, Niamh, Pavone, Francesco S., Hof, Patrick R., Costantini, Irene, and Frasconi, Paolo

Published

2024

24. Evolutionary neuroanatomical expansion of Broca's region serving a human-specific function.

Author

Friederici, Angela D.

Subjects

*FUNCTION spaces, *CHIMPANZEES, *PRIMATES

Abstract

Language and action have adjacent, but distinct localizations in the human brain within Broca's region, with language recruiting an anterior part Brodmann area (BA) 44 and action recruiting posterior part of BA 44. In humans, Broca's area, and in particular the cytoarchitectonically defined BA 44, shows an anterior expansion when compared to chimpanzees. The expansion of Broca's area in humans compared to non-human primates provides additional cortical space for the human-specific function of language. The question concerning the evolution of language is directly linked to the debate on whether language and action are dependent or not and to what extent Broca's region serves as a common neural basis. The debate resulted in two opposing views, one arguing for and one against the dependence of language and action mainly based on neuroscientific data. This article presents an evolutionary neuroanatomical framework which may offer a solution to this dispute. It is proposed that in humans, Broca's region houses language and action independently in spatially separated subregions. This became possible due to an evolutionary expansion of Broca's region in the human brain, which was not paralleled by a similar expansion in the chimpanzee's brain, providing additional space needed for the neural representation of language in humans. [ABSTRACT FROM AUTHOR]

Published

2023

25. Individual Variability of Broca's Area of the Brain in Women.

Author

Bogolepova, I. N., Krotenkova, M. V., Konovalov, R. N., Agapov, P. A., Malofeeva, I. G., and Bikmeev, A. T.

Subjects

*CEREBRAL sulci, *BRAIN, *NEUROLOGICAL disorders, *MENTAL illness

Abstract

In this article, we studied individual features of the macroscopic structure of Broca's area of the brains in 9 women (18 hemispheres) aged from 20 to 30 years, without any mental or neurological disorders. By using MRI, the structures of the sulci and gyri of the pars triangularis and pars opercularis of Broca's area were studied: the anterior and ascending rami of the lateral sulcus, the radial, diagonal, precentral, inferior frontal, and lateral sulci. We also studied the relationship between the pars triangularis and pars opercularis as well as their relationships with neighboring cortical structures. We measured the volume of the pars triangularis and pars opercularis and the thickness of their cortex. Significant individual variability in the location and relationships between the anterior ramus of the lateral sulcus and the ascending ramus of the lateral sulcus, as well as structural features of the pars triangularis and pars opercularis of Broca's area were demonstrated. [ABSTRACT FROM AUTHOR]

Published

2023

26. Language network self-inhibition and semantic similarity in first-episode schizophrenia: A computational-linguistic and effective connectivity approach.

Author

Alonso-Sánchez, María Francisca, Limongi, Roberto, Gati, Joseph, and Palaniyappan, Lena

Subjects

*PREFRONTAL cortex, *SCHIZOPHRENIA, *LINGUISTIC analysis, *TEMPORAL lobe, *COMPUTATIONAL linguistics, *CAUSAL models

Abstract

A central feature of schizophrenia is the disorganization and impoverishment of language. Recently, we observed higher semantic similarity in first-episode-schizophrenia (FES) patients. In this study, we investigate if this aberrant similarity relates to the 'causal' connectivity between two key nodes of the word production system: inferior frontal gyrus (IFG) and the semantic-hub at the ventral anterior temporal lobe (vATL). Resting-state fMRI scans were collected from 60 participants (30 untreated FES and 30 healthy controls). The semantic distance was measured with the CoVec semantic tool based on GloVe. A spectral dynamic causal model with Parametrical Empirical Bayes was constructed modelling the intrinsic self-inhibitory and extrinsic-excitatory connections within the brain regions. We estimated the parameters of a fully connected model with the semantic distance as a covariate. FES patients chose words with higher semantic similarity when describing the pictures compared to the HC group. Among patients, an increased semantic similarity was related with an increase in intrinsic connections within both the vATL and IFG, suggesting that reduced 'synaptic gain' in these regions likely contribute to aberrant sampling of the semantic space during discourse in schizophrenia. Lexical impoverishment relates to increased self-inhibition in both the IFG and vATL. The associated reduction in synaptic gain may relate to reduced precision of locally generated neural activity, forcing the choice of words that are already 'activated' in a lexical network. One approach to improve word sampling may be via promoting synaptic gain via supra-physiological stimulation within the Broca's-vATL network; this proposal needs verification. [ABSTRACT FROM AUTHOR]

Published

2023

27. Clinic and pathophysiology of false sensory perceptions in the scientific views of Viktor Kandinsky

Author

E. V. Snedkov, A. E. Veraksa, and P. Y. Muchnik

Subjects

false perception, simple hallucinations, dream-like hallucinations, pseudohallucinations, involuntary speaking, consciousness, imagination, abstract concepts, sensory pathways, broca’s area, neural networks, functional connectivity, Psychiatry, RC435-571

Abstract

In the monograph «Kritische und klinische Betrachtungen im Gebiete der Sinnestäuschungen» (1885) and in its Russian version «On pseudohallucinations» (1890) V.Kh. Kandinsky was the first in the world to present a detailed differentiation of clinical forms of false sensory perceptions, specificating simple hallucinations, dream-like hallucinations and two varieties of pseudohallucinations. He set out descriptions of phenomena that resemble false perceptions, but are not them: unvoluntary speech, some forms of pathology of the ideation sphere, and pathology of the imaginary sphere. Several mental states described by the author later entered the psychiatric lexicon under new names: «speech-motor hallucinations» (Séglas), «delusion of the imagination» (Dupré and Logre), «autistic thinking» (Bleuler), «hypotonia of consciousness» (Berze), «oneiroid form of experience» (Mayer-Gross). Kandinsky supplemented clinical descriptions with an original pathophysiological hypothesis. The author believed that the thalamus, specific to each modality and multimodal cell groups of the sensory cortex, centers of abstract (symbolized) representations, and Broca’s center are involved in various configurations in the acts of sensory perception and the origin of the forms of his deceptions; the state of the frontal functions and the nature of the reflection of images of perception in consciousness are of paramount importance.The author illustrated his hypothesis with schemes of differentiated involvement of thalamocortical and transcortical networks. This article analyzes the reasons why Kandinsky’s hypothesis remained unknown to specialists until recently, and his descriptions of the forms of false sensory perceptions were taught in a distorted or simplified form. Despite the target testing of the hypothesis having never been carried out, all its main provisions are confirmed by the results of modern research. Russian psychiatrists successfully apply the systematics of hallucinations developed by Kandinsky in clinical practice. Remaining to this day the only clinical and pathophysiological hypothesis, Kandinsky´s clinical and pathophysiological hypothesis is extremely promising for studying the etiopathogenesis of mental illness and developing effective means of treating them.

Published

2023

28. Tumor location and reduction in functional MRI estimates of language laterality

Author

Połczyńska, Monika M, Beck, Lilian, Kuhn, Taylor, Benjamin, Christopher F, Ly, Timothy K, Japardi, Kevin, Cavanagh, Lucia, and Bookheimer, Susan Y

Subjects

Biomedical and Clinical Sciences, Neurosciences, Clinical Sciences, Clinical Research, Cancer, Brain Disorders, Rare Diseases, Neurological, brain tumor, laterality index, language, fMRI, functional MRI, Broca's area, oncology, Neurology & Neurosurgery, Clinical sciences

Abstract

ObjectiveBrain tumors located close to the language cortex may distort functional MRI (fMRI)-based estimates of language dominance. The nature of this distortion, and whether this is an artifact of numerous confounders, remains unknown. The authors hypothesized tumor bias based on laterality estimates independent of confounders and that the effects are the greatest for tumors proximal to Broca's area.MethodsTo answer this question, the authors reviewed more than 1113 patients who underwent preoperative fMRI to match samples on 11 known confounders (tumor location, size, type, and grade; seizure history; prior neurosurgery; aphasia presence and severity; and patient age, sex, and handedness). The samples included 30 patients with left hemisphere tumors (15 anterior and 15 posterior) and 30 with right hemisphere tumors (15 anterior and 15 posterior), thus totaling 60 patients (25 women; 18 left-handed and 4 ambidextrous; mean age 47 [SD 14.1] years). Importantly, the authors matched not only patients with left and right hemisphere tumors but also those with anterior and posterior tumors. Standard fMRI laterality indices (LIs) were calculated using whole-brain and region of interest (ROI) approaches (Broca's and Wernicke's areas).ResultsTumors close to Broca's area in the left hemisphere decreased LIs independently of known confounders. At the whole-brain level, this appeared to reflect a decrease in LI values in patients with left anterior tumors compared with patients with right anterior tumors. ROI analysis replicated these findings. Broca's area LIs were significantly lower (p = 0.02) in patients with left anterior tumors (mean LI 0.28) when compared with patients with right anterior tumors (mean LI 0.70). Changes in Wernicke's area-based LIs did not differ as a function of the tumor hemisphere. Therefore, in patients with left anterior tumors, it is essential to assess language laterality using left posterior ROIs. In all remaining tumor groups (left posterior tumors and right hemisphere tumors), language laterality derived from the anterior language ROI was the most robust measure of language dominance.ConclusionsPatients with tumors close to Broca's area showed more bilateral fMRI language maps independent of known confounders. The authors caution against the assumption that this reduced language laterality suggests no or little risk to language function following tumor resection in the left inferior frontal gyrus. Their results address how to interpret fMRI data for neurosurgical purposes, along with theoretical questions of contralesional functional compensation and disinhibition.

Published

2021

29. A case of pure apraxia of speech after left hemisphere stroke: behavioral findings and neural correlates.

Author

Pracar, Alexis L., Ivanova, Maria V., Richardson, Amber, and Dronkers, Nina F.

Subjects

SPEECH apraxia, FRONTAL lobe, SPEECH disorders, LANGUAGE disorders, MOVEMENT disorders, DIFFUSION magnetic resonance imaging

Abstract

Introduction: Apraxia of speech (AOS) is a motor speech disorder impairing the coordination of complex articulatory movements needed to produce speech. AOS typically co-occurs with a non-fluent aphasia, or language disorder, making it challenging to determine the specific brain structures that cause AOS. Cases of pure AOS without aphasia are rare but offer the best window into the neural correlates that support articulatory planning. The goal of the current study was to explore patterns of apraxic speech errors and their underlying neural correlates in a case of pure AOS. Methods: A 67-year-old right-handed man presented with severe AOS resulting from a fronto-insular lesion caused by an ischemic stroke. The participant's speech and language were evaluated at 1-, 3- and 12-months post-onset. High resolution structural MRI, including diffusion weighted imaging, was acquired at 12 months post-onset. Results: At the first assessment, the participant made minor errors on the Comprehensive Aphasia Test, demonstrating mild deficits in writing, auditory comprehension, and repetition. By the second assessment, he no longer had aphasia. On the Motor Speech Evaluation, the severity of his AOS was initially rated as 5 (out of 7) and improved to a score of 4 by the second visit, likely due to training by his SLP at the time to slow his speech. Structural MRI data showed a fronto-insular lesion encompassing the superior precentral gyrus of the insula and portions of the inferior and middle frontal gyri and precentral gyrus. Tractography derived from diffusion MRI showed partial damage to the frontal aslant tract and arcuate fasciculus along the white matter projections to the insula. Discussion: This pure case of severe AOS without aphasia affords a unique window into the behavioral and neural mechanisms of this motor speech disorder. The current findings support previous observations that AOS and aphasia are dissociable and confirm a role for the precentral gyrus of the insula and BA44, as well as underlying white matter in supporting the coordination of complex articulatory movements. Additionally, other regions including the precentral gyrus, Broca's area, and Area 55b are discussed regarding their potential role in successful speech production. [ABSTRACT FROM AUTHOR]

Published

2023

30. Beyond Broca's and Wernicke's: Functional Mapping of Ancillary Language Centers Prior to Brain Tumor Surgery.

Author

Lawrence, Ashley, Carvajal, Michael, and Ormsby, Jacob

Subjects

LANGUAGE schools, BRAIN surgery, TUMOR surgery, BRAIN tumors, FRONTAL lobe, CEREBRAL dominance

Abstract

Functional MRI is a well-established tool used for pre-surgical planning to help the neurosurgeon have a roadmap of critical functional areas that should be avoided, if possible, during surgery to minimize morbidity for patients with brain tumors (though this also has applications for surgical resection of epileptogenic tissue and vascular lesions). This article reviews the locations of secondary language centers within the brain along with imaging findings to help improve our confidence in our knowledge on language lateralization. Brief overviews of these language centers and their contributions to the language networks will be discussed. These language centers include primary language centers of "Broca's Area" and "Wernicke's Area". However, there are multiple secondary language centers such as the dorsal lateral prefrontal cortex (DLPFC), frontal eye fields, pre- supplemental motor area (pre-SMA), Basal Temporal Language Area (BTLA), along with other areas of activation. Knowing these foci helps to increase self-assurance when discussing the nature of laterality with the neurosurgeon. By knowing secondary language centers for language lateralization, via fMRI, one can feel confident on providing neurosurgeon colleagues with appropriate information on the laterality of language in preparation for surgery. [ABSTRACT FROM AUTHOR]

Published

2023

31. Power spectral analysis can determine language laterality from resting‐state functional MRI data in healthy controls.

Author

Ahmed, Syed Rakin, Jenabi, Mehrnaz, Gene, Madeleine, Moreno, Raquel, Peck, Kyung K., and Holodny, Andrei

Subjects

*FUNCTIONAL magnetic resonance imaging, *LATERAL dominance, *POWER spectra, *CEREBRAL dominance, *VISUAL cortex, *FRONTAL lobe

Abstract

Background and Purpose: Resting‐state functional magnetic resonance imaging (rsfMRI) has been proposed as an alternative to task‐based fMRI including clinical situations such as preoperative brain tumor planning, due to advantages including ease of performance and time savings. However, one of its drawbacks is the limited ability to accurately lateralize language function. Methods: Using the rsfMRI data of healthy controls, we carried out a power spectra analysis on three regions of interest (ROIs): Broca's area (BA) in the frontal cortex for language, hand motor (HM) area in the primary motor cortex, and the primary visual cortex (V1). Spike removal, motion correction, linear trend removal, and spatial smoothing were applied. Spontaneous low‐frequency fluctuations (0.01‐0.1 Hz) were filtered to enable functional integration. Results: BA showed greater power on the left hemisphere relative to the right (p =.0055), while HM (p =.1563) and V1 (p =.4681) were not statistically significant. A novel index, termed the power laterality index (PLI), computed to estimate the degree of power lateralization for each brain region, revealed a statistically significant difference between BA and V1 (p <.00001), where V1 was used as a control since the primary visual cortex does not lateralize. Validation studies used to compare PLI to a laterality index computed using phonemic fluency, a task‐based, language fMRI paradigm, demonstrated good correlation. Conclusions: The power spectra for BA revealed left language lateralization, which was not replicated in HM or V1. This work demonstrates the feasibility and validity of an ROI‐based power spectra analysis on rsfMRI data for language lateralization. [ABSTRACT FROM AUTHOR]

Published

2023

32. Domain‐general and domain‐specific functional networks of Broca's area underlying language processing.

Author

Bulut, Talat

Subjects

*PREFRONTAL cortex, *BASAL ganglia, *FUNCTIONAL connectivity

Abstract

Introduction: Despite abundant research on the role of Broca's area in language processing, there is still no consensus on language specificity of this region and its connectivity network. Methods: The present study employed the meta‐analytic connectivity modeling procedure to identify and compare domain‐specific (language‐specific) and domain‐general (shared between language and other domains) functional connectivity patterns of three subdivisions within the broadly defined Broca's area: pars opercularis (IFGop), pars triangularis (IFGtri), and pars orbitalis (IFGorb) of the left inferior frontal gyrus. Results: The findings revealed a left‐lateralized frontotemporal network for all regions of interest underlying domain‐specific linguistic functions. The domain‐general network, however, spanned frontoparietal regions that overlap with the multiple‐demand network and subcortical regions spanning the thalamus and the basal ganglia. Conclusions: The findings suggest that language specificity of Broca's area emerges within a left‐lateralized frontotemporal network, and that domain‐general resources are garnered from frontoparietal and subcortical networks when required by task demands. [ABSTRACT FROM AUTHOR]

Published

2023

33. Exploring the neurobiology of Merge at a basic level: insights from a novel artificial grammar paradigm.

Author

Yang Liu, Chenyang Gao, Peng Wang, Friederici, Angela D., Zaccarella, Emiliano, and Luyao Chen

Subjects

PREFRONTAL cortex, NATURAL languages, GRAMMAR, IMPLICIT learning, NEUROBIOLOGY, BINARY operations

Abstract

Introduction: Human language allows us to generate an infinite number of linguistic expressions. It’s proposed that this competence is based on a binary syntactic operation, Merge, combining two elements to form a new constituent. An increasing number of recent studies have shifted from complex syntactic structures to two-word constructions to investigate the neural representation of this operation at the most basic level. Methods: This fMRI study aimed to develop a highly flexible artificial grammar paradigm for testing the neurobiology of human syntax at a basic level. During scanning, participants had to apply abstract syntactic rules to assess whether a given two-word artificial phrase could be further merged with a third word. To control for lower-level template-matching and working memory strategies, an additional non-mergeable word-list task was set up. Results: Behavioral data indicated that participants complied with the experiment. Whole brain and region of interest (ROI) analyses were performed under the contrast of “structure > word-list.” Whole brain analysis confirmed significant involvement of the posterior inferior frontal gyrus [pIFG, corresponding to Brodmann area (BA) 44]. Furthermore, both the signal intensity in Broca’s area and the behavioral performance showed significant correlations with natural language performance in the same participants. ROI analysis within the language atlas and anatomically defined Broca’s area revealed that only the pIFG was reliably activated. Discussion: Taken together, these results support the notion that Broca’s area, particularly BA 44, works as a combinatorial engine where words are merged together according to syntactic information. Furthermore, this study suggests that the present artificial grammar may serve as promising material for investigating the neurobiological basis of syntax, fostering future cross-species studies. [ABSTRACT FROM AUTHOR]

Published

2023

34. 'European Intelligence' From the Perspectives of Cognitive Psychology-Neurobiology: Why are the Europeans what they are Today?

Author

Ayim-Aboagye, Desmond

Subjects

*BLACK children, *HUMAN beings, *SCIENTIFIC method, *WHITE people, ROMAN Empire, 30 B.C.-A.D. 476

Abstract

Black women and Black men gave birth to white children who suppose to be brothers to Black children. But over thousands of years in isolation, white people developed fictitious theories to make themselves look different and distinct. The Neanderthals they tend to associate themselves with through sexual contact left no civilization, so it is difficult to judge the outcome of this sexual relationship. While the paintings in the caves in modern France look suspicious, Black people, on the other hand, built civilizations all over the planet: Ancient Egyptians, Nubians, the Incas, Ancient Rome, Mesopotamia, Indian Dravidians, etc. Evidence from history through the Roman Empire shows that White people were human beings like all others and, therefore, they did not treat them differently. The investigation used cognitive psychology and neurobiology perspectives to explain the successful experiences of Germanic tribes and the Slavs in Central Asia. The theoretical investigation uses existing data and argues that they are not distinct though there had been a mixture of genes with some tribes in Central Asia. Europeans' use of their local languages and the employment of scientific theories and methods of inquiry have something to do with their intelligence and overall success in the world. The relegation of the religion's authority and the replacement with reason and science methods has enabled Europeans to become successful with cognitive intelligence. Intelligence has something to do with knowledge acquisition with the blood language and sciences in imbibing knowledge. Where human beings use their local languages and the addition of the methods of scientific inquiry, there will be marginal differences in intelligence acquisition. The discoveries the researchers Paul Broca and Carl Wernicke made with neurobiology show that language speaking is a complex human phenomenon that human beings should take seriously in daily discourses. No wonder it gave the Europeans unique problems when they had to depend on Latin to imbibe knowledge and use it to carry out responsibilities. Intelligence has something to do with the blood language, local language, or culturally provided language in imbibing knowledge in the physical world. Scientific theories and appropriate scientific methods should be driven by the use of Mathematics and logic. Emerging technological societies, such as China, Malaysia, Singapore, etc., testify to these modern methods of reaching progress in education. [ABSTRACT FROM AUTHOR]

Published

2023

35. Involvement of Broca's Area and Its Right Hemispheric Homologue in Acquiring Abstract and Concrete Semantics: Transcranial Direct Current Stimulation Study.

Author

Gnedykh, D. S., Blagovechtchenski, E. D., Kostromina, S. N., Mkrtychyan, N. A., and Shtyrov, Y. Y.

Subjects

*TRANSCRANIAL direct current stimulation, *CONCRETE, *SEMANTICS

Abstract

The study compared effects of transcranial direct current stimulation (tDCS) of Broca's area and of its right hemispheric homologue on the acquisition of novel concrete and abstract words. Word/concept acquisition was achieved through reading sets of sentences, which incorporated novel words, gradually revealing their meaning through context. Before the learning session, a 15-min anodal or cathodal stimulation of one of the target areas was applied. A lexical decision task was used to assess the learning outcomes immediately after the learning session and 24 h later. The results showed a larger number of correct responses after right hemispheric tDCS, in comparison with that of Broca's area in the left hemisphere. These results suggest that the right hemispheric counterpart of Broca's area is involved in the processing and acquisition of new concrete and abstract semantics. Furthermore, they demonstrate facilitating effects of tDCS on the processes of overnight consolidation of newly formed word memory traces. [ABSTRACT FROM AUTHOR]

Published

2023

36. El Área del Lenguaje Articulado, Perspectiva Histórica y Denominación Epónima Equívoca: Entre Dax y Broca.

Author

Duque Parra, Jorge Eduardo, Marulanda Galvis, Juan David, and Gabriel Chavez, Jeferson

Subjects

*PREFRONTAL cortex, *ORAL communication, *MEDICAL sciences, *NEUROANATOMY, *PERIODICAL articles, *FRONTAL lobe, *NEUROSCIENCES, *FUSIFORM gyrus

Abstract

The eponymous Broca's area is a human cerebral cortical region that controls the expression of oral language, and which is not always located in the inferior frontal gyrus of the frontal lobe in the left hemisphere. In a study of 25 articles published in 2022, and 25 teaching books on neuroanatomy, neurophysiology, neuroscience or associated areas, it was found that the term Broca's area was established and quantified. In books there was a 96 % eponymous inclusion of this cerebral cortical area and in journal articles there was 100 % of the same eponym. Furthermore, no other eponyms were found in any of the books and articles. Although over time, eponyms have been used in medical sciences to identify anatomical structures, as in the designation of the area in the brain that controls oral language, this term does not provide any descriptive or functional information. The result is contradictory to current morphological thought and also leads to confusion, erroneously suggesting that the initial discovery was made by Broca, when in fact Marc Dax was the first to discover this area some 30 years earlier. [ABSTRACT FROM AUTHOR]

Published

2023

37. Surgical Anatomy of the Frontal Lobe

Author

Chaddad-Neto, Feres, Silva da Costa, Marcos Devanir, Chaddad-Neto, Feres, and Silva da Costa, Marcos Devanir

Published

2022

38. Broca’s Area of Brain to Analyze the Language Impairment Problem and Behavior Analysis of Autism

Author

Islam, Md Ashiqul, Karim, Rafat, Ahmed, Faruq, Maksuda, Hossen, Md Sagar, Akter, Shamima, Chlamtac, Imrich, Series Editor, Jeyanthi, P. Mary, editor, Choudhury, Tanupriya, editor, Hack-Polay, Dieu, editor, Singh, T P, editor, and Abujar, Sheikh, editor

Published

2022

39. Mirror Neurons, Empathy, and the Other

Author

Iacoboni, Marco

Published

2022

40. A case of pure apraxia of speech after left hemisphere stroke: behavioral findings and neural correlates

Author

Alexis L. Pracar, Maria V. Ivanova, Amber Richardson, and Nina F. Dronkers

Subjects

aphasia, apraxia of speech, insula, Broca’s area, speech production, Neurology. Diseases of the nervous system, RC346-429

Abstract

IntroductionApraxia of speech (AOS) is a motor speech disorder impairing the coordination of complex articulatory movements needed to produce speech. AOS typically co-occurs with a non-fluent aphasia, or language disorder, making it challenging to determine the specific brain structures that cause AOS. Cases of pure AOS without aphasia are rare but offer the best window into the neural correlates that support articulatory planning. The goal of the current study was to explore patterns of apraxic speech errors and their underlying neural correlates in a case of pure AOS.MethodsA 67-year-old right-handed man presented with severe AOS resulting from a fronto-insular lesion caused by an ischemic stroke. The participant’s speech and language were evaluated at 1-, 3- and 12-months post-onset. High resolution structural MRI, including diffusion weighted imaging, was acquired at 12 months post-onset.ResultsAt the first assessment, the participant made minor errors on the Comprehensive Aphasia Test, demonstrating mild deficits in writing, auditory comprehension, and repetition. By the second assessment, he no longer had aphasia. On the Motor Speech Evaluation, the severity of his AOS was initially rated as 5 (out of 7) and improved to a score of 4 by the second visit, likely due to training by his SLP at the time to slow his speech. Structural MRI data showed a fronto-insular lesion encompassing the superior precentral gyrus of the insula and portions of the inferior and middle frontal gyri and precentral gyrus. Tractography derived from diffusion MRI showed partial damage to the frontal aslant tract and arcuate fasciculus along the white matter projections to the insula.DiscussionThis pure case of severe AOS without aphasia affords a unique window into the behavioral and neural mechanisms of this motor speech disorder. The current findings support previous observations that AOS and aphasia are dissociable and confirm a role for the precentral gyrus of the insula and BA44, as well as underlying white matter in supporting the coordination of complex articulatory movements. Additionally, other regions including the precentral gyrus, Broca’s area, and Area 55b are discussed regarding their potential role in successful speech production.

Published

2023

41. Domain‐general and domain‐specific functional networks of Broca's area underlying language processing

Author

Talat Bulut

Subjects

Broca's area, domain‐general, domain‐specific, functional connectivity, language, meta‐analytic connectivity modeling, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Abstract Introduction Despite abundant research on the role of Broca's area in language processing, there is still no consensus on language specificity of this region and its connectivity network. Methods The present study employed the meta‐analytic connectivity modeling procedure to identify and compare domain‐specific (language‐specific) and domain‐general (shared between language and other domains) functional connectivity patterns of three subdivisions within the broadly defined Broca's area: pars opercularis (IFGop), pars triangularis (IFGtri), and pars orbitalis (IFGorb) of the left inferior frontal gyrus. Results The findings revealed a left‐lateralized frontotemporal network for all regions of interest underlying domain‐specific linguistic functions. The domain‐general network, however, spanned frontoparietal regions that overlap with the multiple‐demand network and subcortical regions spanning the thalamus and the basal ganglia. Conclusions The findings suggest that language specificity of Broca's area emerges within a left‐lateralized frontotemporal network, and that domain‐general resources are garnered from frontoparietal and subcortical networks when required by task demands.

Published

2023

42. Enhancing Speech Rehabilitation in a Young Adult with Trisomy 21: Integrating Transcranial Direct Current Stimulation (tDCS) with Rapid Syllable Transition Training for Apraxia of Speech

Author

Ester Miyuki Nakamura-Palacios, Aldren Thomazini Falçoni Júnior, Gabriela Lolli Tanese, Ana Carla Estellita Vogeley, and Aravind Kumar Namasivayam

Subjects

apraxia of speech, trisomy 21 (down syndrome), transcranial Direct Current Stimulation (tDCS), Rapid Syllable Transition Training (ReST), Broca’s area, Wernicke’s area, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Apraxia of speech is a persistent speech motor disorder that affects speech intelligibility. Studies on speech motor disorders with transcranial Direct Current Stimulation (tDCS) have been mostly directed toward examining post-stroke aphasia. Only a few tDCS studies have focused on apraxia of speech or childhood apraxia of speech (CAS), and no study has investigated individuals with CAS and Trisomy 21 (T21, Down syndrome). This N-of-1 randomized trial examined the effects of tDCS combined with a motor learning task in developmental apraxia of speech co-existing with T21 (ReBEC RBR-5435x9). The accuracy of speech sound production of nonsense words (NSWs) during Rapid Syllable Transition Training (ReST) over 10 sessions of anodal tDCS (1.5 mA, 25 cm) over Broca’s area with the cathode over the contralateral region was compared to 10 sessions of sham-tDCS and four control sessions in a 20-year-old male individual with T21 presenting moderate–severe childhood apraxia of speech (CAS). The accuracy for NSW production progressively improved (gain of 40%) under tDCS (sham-tDCS and control sessions showed < 20% gain). A decrease in speech severity from moderate–severe to mild–moderate indicated transfer effects in speech production. Speech accuracy under tDCS was correlated with Wernicke’s area activation (P3 current source density), which in turn was correlated with the activation of the left supramarginal gyrus and the Sylvian parietal–temporal junction. Repetitive bihemispheric tDCS paired with ReST may have facilitated speech sound acquisition in a young adult with T21 and CAS, possibly through activating brain regions required for phonological working memory.

Published

2024

43. Altered Language-Related Effective Connectivity in Patients with Benign Childhood Epilepsy with Centrotemporal Spikes.

Author

Yang, Fei, Tan, Juan, Huang, Yue, Xiao, Ruhui, Wang, Xiaoming, and Han, Yanbing

Subjects

*CHILDHOOD epilepsy, *FUNCTIONAL magnetic resonance imaging, *CINGULATE cortex

Abstract

Benign childhood epilepsy with centrotemporal spikes (BECTS) is one of the most common childhood epilepsy syndromes and may be associated with language deficits. Resting-state functional magnetic resonance imaging (fMRI) data were collected from a total of 78 children: 52 patients with BECTS (28 drug-naïve and 24 medicated) and 26 healthy controls (HC). Granger causality analysis (GCA) was used to investigate alterations in effective connectivity (EC) between the language network core node (Broca's area) and the whole brain. EC from Broca's area to the left Heschl's gyrus (HG), right putamen, and anterior cingulate cortex (ACC) was significantly increased, while EC from the bilateral putamen and left ACC to Broca's area was significantly decreased in BECTS. Moreover, altered EC of Broca's area to the right putamen was significantly positively correlated with verbal IQ (VIQ), while altered EC of Broca's area to the ACC showed significantly negative correlations with the frequency of seizures. Altered EC from the left putamen to Broca's area was also significantly negatively correlated with performance IQ (PIQ) and full-scale IQ (FSIQ) in the drug-naïve group. In addition, there was a significant positive correlation between the EC of Broca's area to the left HG and the number of seizures, as well as between the EC of Broca's area to the right putamen and the age at onset in the medicated group. These findings suggest abnormal causal effects on the language network related to Broca's area in children with BECTS. Longitudinal investigation of language network development and further follow-up may be needed to illuminate the changes in organization and rebalancing over time. [ABSTRACT FROM AUTHOR]

Published

2023

44. The atypical functional connectivity of Broca's area at multiple frequency bands in autism spectrum disorder.

Author

Cheng, Lulu, Zhan, Linlin, Huang, Lina, Zhang, Hongqiang, Sun, Jiawei, Huang, Guofeng, Wang, Yadan, Li, Mengting, Li, Huayun, Gao, Yanyan, and Jia, Xize

Abstract

As a developmental disorder, autism spectrum disorder (ASD) has drawn much attention due to its severe impacts on one's language capacity. Broca's area, an important brain region of the language network, is largely involved in language-related functions. Using the Autism Brain Image Data Exchange (ABIDE) dataset, a mega-analysis was performed involving a total of 1454 participants (including 618 individuals with ASD and 836 healthy controls (HCs). To detect the neural pathophysiological mechanism of ASD from the perspective of language, we conducted a functional connectivity (FC) analysis with Broca's area as the seed in multiple frequency bands (conventional: 0.01–0.08 Hz; slow-4: 0.027–0.073 Hz; slow-5: 0.01–0.027 Hz). We found that compared with HC, ASD patients demonstrated increased FC in the left thalamus, left precuneus, left anterior cingulate and paracingulate gyri, and left medial orbital of the superior frontal gyrus in the conventional frequency band (0.01–0.08 Hz). The results of the slow-5 frequency band (0.01–0.027 Hz) presented increased FC values of the left precuneus, left medial orbital of the superior frontal gyrus, right medial orbital of the superior frontal gyrus and right thalamus. No significant cluster was detected in the slow-4 frequency band (0.027–0.073 Hz). In conclusion, the abnormal functional connectivity in patients with ASD has frequency-specific properties. Furthermore, the slow-5 frequency band (0.01–0.027 Hz) mainly contributed to the findings of the conventional frequency band (0.01–0.08 Hz). The current study might shed new light on the neural pathophysiological mechanism of language impairments in people with ASD. [ABSTRACT FROM AUTHOR]

Published

2022

45. Transcranial direct stimulation over left inferior frontal gyrus improves language production and comprehension in post-stroke aphasia: A double-blind randomized controlled study.

Author

Sheng Zheng, Zhong, Xing-Long Wang, Kevin, Millan, Henry, Lee, Sharon, Howard, Melissa, Rothbart, Aaron, Rosario, Emily, and Schnakers, Caroline

Subjects

*PREFRONTAL cortex, *WORD deafness, *APHASIC persons, *BEHAVIOR therapy, *LANGUAGE ability, *TRANSCRANIAL direct current stimulation

Abstract

• Aphasia patients received 5 days of anodal Broca's tDCS or sham, paired with speech therapy. • Broca's tDCS improved spontaneous speech and auditory verbal comprehension. • tDCS improved both expressive and receptive language, but sham only improved expressive. • Evidence supports tDCS as a promising adjunct to behavioral aphasia therapy. Transcranial direct current stimulation (tDCS) targeting Broca's area has shown promise for augmenting language production in post-stroke aphasia (PSA). However, previous research has been limited by small sample sizes and inconsistent outcomes. This study employed a double-blind, parallel, randomized, controlled design to evaluate the efficacy of anodal Broca's tDCS, paired with 20-minute speech and language therapy (SLT) focused primarily on expressive language, across 5 daily sessions in 45 chronic PSA patients. Utilizing the Western Aphasia Battery-Revised, which assesses a spectrum of linguistic abilities, we measured changes in both expressive and receptive language skills before and after intervention. The tDCS group demonstrated significant improvements over sham in aphasia quotient, auditory verbal comprehension, and spontaneous speech. Notably, tDCS improved both expressive and receptive domains, whereas sham only benefited expression. These results underscore the broader linguistic benefits of Broca's area stimulation and support the integration of tDCS with SLT to advance aphasia rehabilitation. [ABSTRACT FROM AUTHOR]

Published

2024

46. Passive Intraoperative Language Mapping Using Electrocorticographic Signals

Author

Sinkin, M. V., Volkova, K. V., Kondratova, M. S., Voskoboynikov, A. M., Lebedev, M. A., Ivanova, M. D., Ossadtchi, A. E., Kacprzyk, Janusz, Series Editor, Pal, Nikhil R., Advisory Editor, Bello Perez, Rafael, Advisory Editor, Corchado, Emilio S., Advisory Editor, Hagras, Hani, Advisory Editor, Kóczy, László T., Advisory Editor, Kreinovich, Vladik, Advisory Editor, Lin, Chin-Teng, Advisory Editor, Lu, Jie, Advisory Editor, Melin, Patricia, Advisory Editor, Nedjah, Nadia, Advisory Editor, Nguyen, Ngoc Thanh, Advisory Editor, Wang, Jun, Advisory Editor, Velichkovsky, Boris M., editor, Balaban, Pavel M., editor, and Ushakov, Vadim L., editor

Published

2021

47. Verbal Short-Term Memory

Author

Papagno, Costanza, Martino, Juan, Mandonnet, Emmanuel, editor, and Herbet, Guillaume, editor

Published

2021

48. Association fiber tracts related to Broca's area: A comparative study based on diffusion spectrum imaging and fiber dissection.

Author

Yupeng Wu, Jihui Liu, Guoning Yu, Ronghui Jv, Yibao Wang, and Peizhuo Zang

Subjects

PREFRONTAL cortex, MOTOR cortex, FRONTAL lobe, PARIETAL lobe, CEREBRAL hemispheres

Abstract

Broca's area, made up of Brodmann areas (BA) 44 and 45 in the ventrolateral frontal region, is associated with language production and articulation. A comprehensive network analysis of Broca's area is necessary for understanding language function, which is still lacking. In this study, we attempted to investigate the association fiber tracts related to Broca's area using both diffusion spectrum imaging (DSI) and postmortem fiber dissection. DSI was performed on 10 healthy subjects and an atlas comprising the average data of 842 healthy subjects from the Human Connectome Project. Fiber dissection was implemented in 10 cerebral hemispheres of cadaver donors. The following five association fiber tracts related to Broca's area were identified: first, the distinct fasciculus of the inferior fronto-occipital fasciculus (IFOF), from Broca's area (BA44, BA45) and pars orbitalis (BA47) to the parietal and occipital lobes; second, the ventral superior longitudinal fasciculus (SLFIII), from the supramarginal gyrus (BA40) to the ventral precentral gyrus (PreG, BA6) and posterior Broca's area (BA44); third, the arcuate fascicle (AF), from the superior, middle, and inferior temporal gyrus (BA20, BA21, BA22) to Broca's area (BA44, BA45) and ventral PreG; fourth, the frontal aslant tract (FAT), from Broca's area (BA44, BA45) to the lateral superior frontal gyrus (SFG), medial SFG, and supplementary motor area (BA6, BA8, BA9); and fifth, the frontal longitudinal fasciculus (FLF), a novel intralobar frontal association fiber tract, from the anterior part of the middle frontal gyrus (MFG, BA46) and Broca's area (BA45) to the caudal MFG (BA8), caudal SFG, and dorsal PreG (BA6). Moreover, compared with the left FAT, the right FAT covered almost the entire inferior frontal gyrus (BA44, BA45, BA47). The cross validation between DSI and fiber dissection revealed a good consistence in the association fiber tracts of Broca's area. Combining DSI and fiber dissection, this study first identified five association fiber tracts related to Broca's area and characterized their structure and anatomy comprehensively. The frameworks provided key elements for functional research in Broca's area. [ABSTRACT FROM AUTHOR]

Published

2022

49. Neural classification maps for distinct word combinations in Broca's area.

Author

Schell, Marianne, Friederici, Angela D., and Zaccarella, Emiliano

Subjects

NEUROLINGUISTICS, FUNCTIONAL magnetic resonance imaging, GRAMMATICAL categories

Abstract

Humans are equipped with the remarkable ability to comprehend an infinite number of utterances. Relations between grammatical categories restrict the way words combine into phrases and sentences. How the brain recognizes different word combinations remains largely unknown, although this is a necessary condition for combinatorial unboundedness in language. Here, we used functional magnetic resonance imaging and multivariate pattern analysis to explore whether distinct neural populations of a known language network hub--Broca's area--are specialized for recognizing distinct simple word combinations. The phrases consisted of a noun (flag) occurring either with a content word, an adjective (green flag), or with a function word, a determiner (that flag). The key result is that the distribution of neural populations classifying word combination in Broca's area seems sensitive to neuroanatomical subdivisions within this area, irrespective of task. The information patterns for adjective + noun were localized in its anterior part (BA45) whereas those for determiner + noun were localized in its posterior part (BA44). Our findings provide preliminary answers to the fundamental question of how lexical and grammatical category information interact during simple word combination, with the observation that Broca's area is sensitive to the recognition of categorical relationships during combinatory processing, based on different demands placed on syntactic and semantic information. This supports the hypothesis that the combinatorial power of language consists of some neural computation capturing phrasal differences when processing linguistic input. [ABSTRACT FROM AUTHOR]

Published

2022

50. Online neurostimulation of Broca’s area does not interfere with syntactic predictions: A combined TMS-EEG approach to basic linguistic combination.

Author

Maran, Matteo, Numssen, Ole, Hartwigsen, Gesa, and Zaccarella, Emiliano

Abstract

Categorical predictions have been proposed as the key mechanism supporting the fast pace of syntactic composition in language. Accordingly, grammar-based expectations are formed—e.g., the determiner “a” triggers the prediction for a noun—and facilitate the analysis of incoming syntactic information, which is then checked against a single or few other word categories. Previous functional neuroimaging studies point towards Broca’s area in the left inferior frontal gyrus (IFG) as one fundamental cortical region involved in categorical prediction during incremental language processing. Causal evidence for this hypothesis is however still missing. In this study, we combined Electroencephalography (EEG) and Transcranial Magnetic Stimulation (TMS) to test whether Broca’s area is functionally relevant in predictive mechanisms for language. We transiently perturbed Broca’s area during the first word in a two-word construction, while simultaneously measuring the Event-Related Potential (ERP) correlates of syntactic composition. We reasoned that if Broca’s area is involved in predictive mechanisms for syntax, disruptive TMS during the first word would mitigate the difference in the ERP responses for predicted and unpredicted categories in basic two-word constructions. Contrary to this hypothesis, perturbation of Broca’s area at the predictive stage did not affect the ERP correlates of basic composition. The correlation strength between the electrical field induced by TMS and the ERP responses further confirmed this pattern. We discuss the present results considering an alternative account of the role of Broca’s area in syntactic composition, namely the bottom-up integration of words into constituents, and of compensatory mechanisms within the language predictive network. [ABSTRACT FROM AUTHOR]

Published

2022