Daniel Sharoh

Presentations

Displaying 1 - 13 of 13
  • Sharoh, D., Norris, D., & Hagoort, P. (2024). Functional laminar connectivity of the inferior frontal cortex during reading. Poster presented at the Highlights in the Language Sciences Conference 2024, Nijmegen, The Netherlands.
  • Giglio, L., Sharoh, D., Ostarek, M., & Hagoort, P. (2023). Cortico-cortical and cortico-cerebellar connectivity during syntactic structure building in speaking and listening. Poster presented at the 19th NVP Winter Conference on Brain and Cognition, Egmond aan Zee, The Netherlands.

    Abstract

    The neural infrastructure for sentence production and comprehension has been found to be mostly shared. The same regions are engaged during speaking and listening, with some differences in their loading depending on modality (Giglio et al., 2022). In this fMRI study (n=40), we investigated whether modality affects the connectivity between inferior frontal and temporal regions, previously found to be involved in syntactic processing across modalities, and with the cerebellum, which has been historically linked with motor aspects of production. Participants produced or listened to word sequences of increasing constituent size. We found that constituent size reliably increased the connectivity between the inferior frontal gyrus and the posterior temporal lobe in both modalities. Preliminary cerebellar results suggest that different sub-regions presented different patterns of connectivity. Connectivity between Lobule VI and (pre)motor regions was increased during production relative to comprehension. Connectivity between Crus I/II and fronto-temporal regions was instead increased as a function of constituent size, and in particular during production. These results thus show that the connectivity between fronto-temporal regions is upregulated for syntactic structure building in both sentence production and comprehension, while cortico-cerebellar connectivity is enhanced both in response to syntactic processing and during production.
  • Sharoh, D., Norris, D. G., & Hagoort, P. (2023). Layer-resolved FMRI activation and connectivity of the left inferior frontal cortex during reading. Poster presented at the 15th Annual Meeting of the Society for the Neurobiology of Language (SNL 2023), Marseille, France.
  • Sharoh, D., Ruijters, L., Weber, K., Norris, D. G., & Hagoort, P. (2023). Sentence-level meaning and compositionality in a left fronto-temporal network. Poster presented at the 15th Annual Meeting of the Society for the Neurobiology of Language (SNL 2023), Marseille, France.
  • Giglio, L., Hagoort, P., Sharoh, D., & Ostarek, M. (2022). Diverging neural dynamics of syntactic structure building in naturalistic speaking and listening. Talk presented at the 14th Annual Meeting of the Society for the Neurobiology of Language (SNL 2022). Philadelphia, PA, USA. 2022-10-06 - 2022-10-08.
  • Giglio, L., Ostarek, M., Sharoh, D., & Hagoort, P. (2022). Neural correlates of syntactic processing in narrative production and comprehension. Poster presented at the 18th NVP Winter Conference on Brain and Cognition, Egmond aan Zee, The Netherlands.
  • Giglio, L., Ostarek, M., Sharoh, D., & Hagoort, P. (2022). Neural correlates of syntactic processing in narrative production and comprehension. Poster presented at the IMPRS Conference 2022, Nijmegen, the Netherlands.
  • Sharoh, D., Weber, K., Ruijters, L., Norris, D. G., & Hagoort, P. (2022). Neurobiology of linguistic compositionality as revealed by task-dependent connectivity in FMRI. Poster presented at the 18th NVP Winter Conference on Brain and Cognition, Egmond aan Zee, The Netherlands.
  • Sharoh, D., Weber, K., Ruijters, L., Norris, D., & Hagoort, P. (2021). Compositional meaning influences the BOLD response in language critical cortex via interaction between LIFG and LMTG. Poster presented at the 13th Annual Meeting of the Society for the Neurobiology of Language (SNL 2021), online.
  • Sharoh, D., Van Mourik, T., Bains, L., Segaert, K., Weber, K., & Hagoort, P. (2020). Laminar specific fMRI reveals directed interactions in distributed networks during language processing. Poster presented at the 27th Annual Meeting of the Cognitive Neuroscience Society (CNS 2020), online.
  • Sharoh, D., Van Mourik, T., Bains, L., Segaert, K., Weber, K., Hagoort, P., & Norris, D. (2017). Depth-dependent BOLD as a measure of directed connectivity during language processing. Poster presented at the 23rd Annual Meeting of the Organization for Human Brain Mapping (OHBM 2017), Vancouver, Canada.
  • Sharoh, D., Van Mourik, T., Bains, L., Segaert, K., Weber, K., Hagoort, P., & Norris, D. (2017). Approaching directed connectivity in the language network with Laminar fMRI. Poster presented at the 13th International Conference for Cognitive Neuroscience (ICON), Amsterdam, The Netherlands.
  • Sharoh, D., van Mourik, T., Bains, L. J., Segaert, K., Weber, K., Hagoort, P., & Norris, D. G. (2016). Investigation of depth-dependent BOLD during language processing. Poster presented at the Eighth Annual Meeting of the Society for the Neurobiology of Language (SNL 2016), London, UK.

    Abstract

    Neocortex is known to be histologically organized with respect to depth, and neuronal connections across cortical layers form part of the brain's functional organization[1]. Efferent (outgoing) and afferent (incoming) inter-regional connections are found to originate and terminate at different depths, and this structure relates to the internal/external origin of neuronal activity. Specifically, efferent, inter-regional connections are associated with internally directed, top-down activity; afferent inter-regional connections are associated with bottom-up activity originating from external stimulation. The contribution of top-down and bottom-up neuronal activity to the BOLD signal can perhaps be inferred from depth-related fluctuations in BOLD. By dissociating top-down from bottom-up effects in fMRI, investigators could observe the relative contribution of internally and externally generated activity to the BOLD signal, and potentially test hypotheses regarding the directionality of BOLD connectivity. Previous investigation of depth-dependent BOLD has focused on human visual cortex[2]. In the present work, we have designed an experiment to serve as a proof of principle that (1) depth-dependent BOLD can be measured in higher cortical areas during a language processing task, and (2) that differences in the relative contribution of the BOLD signal at discrete depths, to the total BOLD signal, vary as a function of experimental condition. Data were collected on the Siemens 7T scanner at the Hahn Institute in Essen, Germany. Submillimeter (0.8mm3), T1-weighted data were acquired using MP2RAGE, along with near whole-brain, submillimeter (0.9x0.9x0.943mm x112 slices) 3D-EPI task data. The field of view fully covered bilateral temporal and fusiform regions, but excluded superior brain areas on the order of several centimeters. Participants were presented with an event-related paradigm involving the presentation of words, pseudowords and nonwords in visual and auditory modalities. Only the visual modality is discussed here. Cortical segmentation was performed using FreeSurfer's surface-pipeline. We parcellated the gray matter volume into discrete depths, and the analysis of depth-dependent BOLD was performed with the Laminar Analysis Toolbox (van Mourik). Further analysis was performed using FreeSurfer, AFNI and in-house MATLAB code. Regions included in the depth-dependent analysis were determined by first-level analysis. We have presently collected data from 10 participants. 4 were excluded due to equipment malfunction. In the first-level analysis (volume registration, smoothing, GLM, and significance testing), we observe fusiform activation for Realword>Nonword and Pseudoword>Nonword contrasts. These contrasts additionally show activation along middle temporal gyrus. The depth-dependent analysis was performed on fusiform clusters generated during the first-level analysis. These clusters appeared to show depth-dependent signal differences as a function of experimental condition. We suspect these differences may be related to layer-specific activation and reflect the relative contribution of top-down and bottom-up activity in the observed signal. These are preliminary results, and part of an ongoing effort to establish novel, depth-dependent analysis techniques in higher cortical areas and within the language domain. Future analysis will investigate the nature of the depth-dependent differences and the connectivity profiles of depth-dependent variation among distal cortical regions.[1]DouglasR.J.&MartinK.A.C.(2004).Neuronal Circuits of the Neocortex.Annual Review of Neuroscience,27,419-551.[2]Kok,P.,et al.(2016).Selective Activation of the Deep Layers of the Human Primary Visual Cortex by Top-Down Feedback.Current Biology,26,371-376.

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