Your search keyword '"human vestibular cortex"' showing total 3 results

1. Direction-dependent activation of the insular cortex during vertical and horizontal hand movements

Author

Luciano Fadiga, Thierry Pozzo, Lilian Fautrelle, Olivier White, Charalambos Papaxanthis, Célia Rousseau, Cognition, Action, et Plasticité Sensorimotrice [Dijon - U1093] (CAPS), Université de Bourgogne (UB)-Institut National de la Santé et de la Recherche Médicale (INSERM), Centre de Recherche sur le Sport et le Mouvement (CeRSM), Université Paris Nanterre (UPN), Université Paris Nanterre - UFR Sciences et techniques des activités physiques et sportives (UPN STAPS), IIT Genoa, Human Physiology, Università degli Studi di Ferrara (UniFE), Institut Universitaire de France (IUF), Ministère de l'Education nationale, de l’Enseignement supérieur et de la Recherche (M.E.N.E.S.R.), Department of Robotics, Brain and Cognitive Sciences (RBCS), Istituto Italiano di Tecnologia (IIT), Institut national de la santé et de la recherche médicale (INSERM)Conseil Général de Bourgogne (France) Fonds européen de développement régional (FEDER) Progetti di Ricerca di Interesse Nazionale (PRIN) Italian Ministry of University (2010MEFNF7 PRIN), ANR-14-CE30-0007,MOTION,Contrôle et prédiction du mouvement dans le champ terrestre gravito-inertiel(2014), European Project: 288382,EC:FP7:ICT,FP7-ICT-2011-7,POETICON++(2012), Cognition, Action, et Plasticité Sensorimotrice [Dijon - U1093] ( CAPS ), Université de Bourgogne ( UB ) -Institut National de la Santé et de la Recherche Médicale ( INSERM ), Centre de Recherche sur le Sport et le Mouvement ( CeRSM ), Université Paris Nanterre ( UPN ), Université Paris Nanterre - UFR Sciences et Techniques des Activités Physiques et Sportives ( UPN STAPS ), University of Ferrara [Ferrara], Institut Universitaire de France ( IUF ), Ministère de l'Éducation nationale, de l’Enseignement supérieur et de la Recherche ( M.E.N.E.S.R. ), Department of Robotics, Brain and Cognitive Sciences ( RBCS ), Istituto Italiano di Tecnologia ( IIT ), ANR-14-CE30-0007,MOTION,Contrôle et prédiction du mouvement dans le champ terrestre gravito-inertiel ( 2014 ), European Project : 288382,EC:FP7:ICT,FP7-ICT-2011-7,POETICON++ ( 2012 ), and Università degli Studi di Ferrara = University of Ferrara (UniFE)

Subjects

Adult, Male, 0301 basic medicine, Visual perception, genetic structures, Horizontal and vertical, Movement, Socio-culturale, fMRI, Gravitational force, Hand movements, Insular cortex, Internal model, Neuroscience (all), gravity-field, Motor Activity, arm movements, Brain mapping, Visual control, positron-emission-tomography, Young Adult, 03 medical and health sciences, 0302 clinical medicine, sensory prediction, motion, internal-models, Vertical direction, Humans, gravitational force, pointing movements, Cerebral Cortex, Vestibular system, Brain Mapping, internal model, human vestibular cortex, Neural correlates of consciousness, hand movements, General Neuroscience, Brain, Middle Aged, manual interceptions, Hand, Magnetic Resonance Imaging, 030104 developmental biology, [ SDV.NEU ] Life Sciences [q-bio]/Neurons and Cognition [q-bio.NC], insular cortex, [SDV.NEU]Life Sciences [q-bio]/Neurons and Cognition [q-bio.NC], Psychology, Neuroscience, 030217 neurology & neurosurgery, Gravitation

Abstract

International audience; The planning of any motor action requires a complex multisensory processing by the brain. Gravity - immutable on Earth - has been shown to be a key input to these mechanisms. Seminal fMRI studies performed during visual perception of falling objects and self-motion demonstrated that humans represent the action of gravity in parts of the cortical vestibular system; in particular, the insular cortex and the cerebellum. However, little is known as to whether a specific neural network is engaged when processing non-visual signals relevant to gravity. We asked participants to perform vertical and horizontal hand movements without visual control, while lying in a 3T-MRI scanner. We highlighted brain regions activated in the processing of vertical movements, for which the effects of gravity changed during execution. Precisely, the left insula was activated in vertical movements and not in horizontal movements. Moreover, the network identified by contrasting vertical and horizontal movements overlapped with neural correlates previously associated to the processing of simulated self-motion and visual perception of the vertical direction. Interestingly, we found that the insular cortex activity is direction-dependent which suggests that this brain region processes the effects of gravity on the moving limbs through non-visual signals.

Published

2016

2. Electroencephalographic correlates of continuous postural tasks of increasing difficulty

Author

Edwards, A, Guven, O, Furman, M, Arshad, Q, and Bronstein, A

Subjects

Science & Technology, Neurology & Neurosurgery, Neurosciences, postural control, VISUAL-SPATIAL ATTENTION, coherence, PARIETAL CORTEX, 1701 Psychology, continuous balance, CEREBRAL-CORTEX, BALANCE, POSTERIOR PARIETAL, HUMAN VESTIBULAR CORTEX, hemispheric asymmetry, Neurosciences & Neurology, EEG, ALPHA-RHYTHMS, MODULATION, CORTICAL ACTIVITY, 1109 Neurosciences, Life Sciences & Biomedicine

Abstract

Cortical involvement in postural control is well recognized, however the role of non-visual afferents remains unclear. Parietal cortical areas are strongly implicated in vestibulo-spatial functions, but topographical localization during balance tasks remains limited. Here, we use electroencephalography (EEG) during continuous balance tasks of increasing difficulty at single electrode positions. Twenty-four healthy, right-handed individuals performed four balance tasks of increasing difficulty (bipedal and unipedal) and a seated control condition with eyes closed. Subjective ratings of task difficulty were obtained. EEG was recorded from 32 electrodes; 5 overlying sensory and motor regions of interest (ROIs) were chosen for further investigation: C3, Cz, C4, P3, P4. Spectral power and coherence during balance tasks were analyzed in theta (4–8 Hz) and alpha (8–12 Hz) bands. Alpha power reduced as task difficulty increased and this reduction correlated with subjective difficulty ratings. Alpha coherence increased with task difficulty between C3–Cz–C4 electrode pairs. Differential changes in power were observed in Cz, suggestive of a distinct role at this electrode location, which captures lower limb cortical representation. Hemispheric asymmetry was observed, as reflected by greater reductions in theta and alpha power in right-sided areas. Our results demonstrate the functional importance of bilateral central and parietal cortices in continuous balance control. The hemispheric asymmetry observed implies that the non-dominant hemisphere is involved with online monitoring of postural control. Although the posterior parietal asymmetry found may relate to vestibular, somatosensory or multisensory feedback processing, we argue that the finding relates to active balance control rather than simple sensory-intake or reflex circuit activation.

Published

2018

3. Multisensory mechanisms in temporo-parietal cortex support self-location and first-person perspective

Author

Dominique Chapuis, Michael Mouthon, Bigna Lenggenhager, Silvio Ionta, Eleonora Fornari, Lukas Heydrich, Roger Gassert, Olaf Blanke, University of Zurich, and Blanke, Olaf

Subjects

Male, Ventral Intraparietal Area, Functional Laterality, User-Computer Interface, 0302 clinical medicine, Parietal Lobe, Surveys and Questionnaires, Image Processing, Computer-Assisted, Of-Body Experience, media_common, Human Vestibular Cortex, Brain Mapping, Visual-Perception, medicine.diagnostic_test, 10093 Institute of Psychology, General Neuroscience, 05 social sciences, Out-of-body experience, 2800 General Neuroscience, Brain, Robotics, Magnetic Resonance Imaging, Temporal Lobe, medicine.anatomical_structure, Neural Basis, Female, Psychology, Cognitive psychology, Adult, Diagnostic Imaging, Consciousness, Neuroscience(all), media_common.quotation_subject, Temporoparietal junction, Posterior parietal cortex, Premotor Cortex, 050105 experimental psychology, Premotor cortex, 03 medical and health sciences, Young Adult, medicine, Body Image, Reaction Time, Humans, 0501 psychology and cognitive sciences, Analysis of Variance, Perspective (graphical), Multisensory integration, Self Concept, Oxygen, Touch, Brain Injuries, Space Perception, Stimulation, Temporoparietal Junction, Functional magnetic resonance imaging, 150 Psychology, 030217 neurology & neurosurgery, Photic Stimulation

Abstract

SummarySelf-consciousness has mostly been approached by philosophical enquiry and not by empirical neuroscientific study, leading to an overabundance of diverging theories and an absence of data-driven theories. Using robotic technology, we achieved specific bodily conflicts and induced predictable changes in a fundamental aspect of self-consciousness by altering where healthy subjects experienced themselves to be (self-location). Functional magnetic resonance imaging revealed that temporo-parietal junction (TPJ) activity reflected experimental changes in self-location that also depended on the first-person perspective due to visuo-tactile and visuo-vestibular conflicts. Moreover, in a large lesion analysis study of neurological patients with a well-defined state of abnormal self-location, brain damage was also localized at TPJ, providing causal evidence that TPJ encodes self-location. Our findings reveal that multisensory integration at the TPJ reflects one of the most fundamental subjective feelings of humans: the feeling of being an entity localized at a position in space and perceiving the world from this position and perspective.