Search results for "internal-models"

showing 4 items of 4 documents

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

2016

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 sc…

AdultMale0301 basic medicineVisual perceptiongenetic structuresHorizontal and verticalMovementSocio-culturalefMRI; Gravitational force; Hand movements; Insular cortex; Internal model; Neuroscience (all)gravity-fieldMotor Activityarm movementsInsular cortexBrain mappingVisual controlpositron-emission-tomographyYoung Adult03 medical and health sciences0302 clinical medicinesensory predictionmotioninternal-modelsVertical directionHumansgravitational forcepointing movementsCerebral CortexVestibular systemBrain Mappinginternal modelhuman vestibular cortexNeural correlates of consciousnessNeuroscience (all)hand movementsGeneral NeurosciencefMRIBrainMiddle Agedmanual interceptionsHandMagnetic Resonance Imaging030104 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]PsychologyNeuroscience030217 neurology & neurosurgeryGravitationNeuroscience
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CATCHING FALLING OBJECTS: THE ROLE OF THE CEREBELLUM IN PROCESSING SENSORY-MOTOR ERRORS THAT MAY INFLUENCE UPDATING OF FEEDFORWARD COMMANDS. AN fMRI …

2011

Import JabRef | WosArea Neurosciences and Neurology; International audience; The human motor system continuously adapts to changes in the environment by comparing differences between the brain's predicted outcome of a certain behavior and the observed outcome. This discrepancy signal triggers a sensory-motor error and it is assumed that the cerebellum is a key structure in updating this error and associated feedforward commands. Using fMRI, the aim of the present study was to determine the main cerebellar structures that are involved in the processing of sensory-motor errors and in updating feedforward commands when simply catching a falling ball without displacement of the hand. Subjects o…

AdultMaleCORTEXREPRESENTATIONgenetic structuresTRANSFORMATIONSMovementSpeech recognitionREACHING MOVEMENTS[ SCCO.PSYC ] Cognitive science/PsychologyImage processingSensory systemBrain mappingMECHANISMS03 medical and health sciences0302 clinical medicineCerebellumMotor systemImage Processing Computer-AssistedHumansADAPTATION030304 developmental biologyARM MOVEMENTSNeuronsBrain Mapping0303 health sciencesCommunicationbusiness.industry[SCCO.NEUR]Cognitive science/NeuroscienceGeneral NeuroscienceFeed forwardGRIPCognitionHUMAN BRAINMagnetic Resonance ImagingFunctional imagingbody regionsnervous system[SCCO.PSYC]Cognitive science/Psychology[ SCCO.NEUR ] Cognitive science/NeuroscienceBall (bearing)INTERNAL-MODELSbusinessPsychologyhuman activitiesPsychomotor Performance030217 neurology & neurosurgerypsychological phenomena and processes
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Grip Force Adjustments Reflect Prediction of Dynamic Consequences in Varying Gravitoinertial Fields

2018

International audience; Humans have a remarkable ability to adjust the way they manipulate tools through a genuine regulation of grip force according to the task. However, rapid changes in the dynamical context may challenge this skill, as shown in many experimental approaches. Most experiments adopt perturbation paradigms that affect only one sensory modality. We hypothesize that very fast adaptation can occur if coherent information from multiple sensory modalities is provided to the central nervous system. Here, we test whether participants can switch between different and never experienced dynamical environments induced by centrifugation of the body. Seven participants lifted an object …

Gravity (chemistry)object manipulationPhysiologyComputer science[SDV.MHEP.PHY] Life Sciences [q-bio]/Human health and pathology/Tissues and Organs [q-bio.TO]Context (language use)gravity sensing03 medical and health sciencesAcceleration0302 clinical medicinePhysiology (medical)internal-modelsmotor control[SDV.MHEP.PHY]Life Sciences [q-bio]/Human health and pathology/Tissues and Organs [q-bio.TO]movements[SDV.NEU] Life Sciences [q-bio]/Neurons and Cognition [q-bio.NC]uncertaintySimulationhypergravityOriginal Research030304 developmental biologybayesian integration0303 health sciencessensorimotor memoryswitchinggrip forceGRASPsize cuesrecision gripgravity[SDV.NEU]Life Sciences [q-bio]/Neurons and Cognition [q-bio.NC]Grip force030217 neurology & neurosurgerysensory information
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The role of left supplementary motor area in grip force scaling

2013

Skilled tool use and object manipulation critically relies on the ability to scale anticipatorily the grip force (GF) in relation to object dynamics. This predictive behaviour entails that the nervous system is able to store, and then select, the appropriate internal representation of common object dynamics, allowing GF to be applied in parallel with the arm motor commands. Although psychophysical studies have provided strong evidence supporting the existence of internal representations of object dynamics, known as "internal models", their neural correlates are still debated. Because functional neuroimaging studies have repeatedly designated the supplementary motor area (SMA) as a possible …

MaleTRANSCRANIAL MAGNETIC STIMULATIONAnatomy and PhysiologyBrain activity and meditationmedicine.medical_treatmentSocial SciencesBRAIN ACTIVITYSocial and Behavioral SciencesFunctional LateralityACTIVATIONBehavioral NeuroscienceTask Performance and AnalysisHuman PerformancePsychologyMotor skillPhysicsMultidisciplinaryHand StrengthSupplementary motor areaQMotor CortexRPRECISION GRIPSMA*Transcranial Magnetic Stimulationmedicine.anatomical_structureMotor SkillsPREMOTOR AREASFMRIMedicineSensory PerceptionOBJECTSResearch ArticleMotor cortexAdultCognitive NeuroscienceScienceNeurophysiologyNeurological SystemLateralization of brain functionNeuropsychologyHand strengthPsychophysicsmedicineLearningHumansFRONTAL-LOBEBiologyMotor SystemsBehaviorMOVEMENTSCognitive PsychologyEvoked Potentials MotorHandTranscranial magnetic stimulationINTERNAL-MODELSNeuroscienceNeuroscience
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