Search results for "Frontal eye fields"

showing 4 items of 4 documents

Eyes open and eyes closed as rest conditions: impact on brain activation patterns

2003

The patterns of associated brain activations during eyes-open and eyes-closed states in complete darkness considerably differ in fMRI. An "interoceptive" state with the eyes closed is characterized by visual cortex activation, while an "exteroceptive" state with the eyes open is characterized by ocular motor system activity. The impact of the chosen rest condition (eyes open or eyes closed in complete darkness) on the pattern of brain activations during visual stimulation was evaluated in 14 healthy volunteers. During fixation or dim light room illumination, the activation of the visual cortex was larger with the eyes-open rest condition than with the eyes-closed rest condition; however, ac…

AdultMaleAdolescentEye Movementsgenetic structuresRestCognitive NeuroscienceThalamusSensory systemFixation OcularLateral geniculate nucleusSomatosensory systemReference ValuesImage Interpretation Computer-AssistedmedicineHumansVisual PathwaysDominance CerebralPrefrontal cortexVision OcularVisual CortexBrain MappingBrainGeniculate BodiesAnatomyFrontal eye fieldsImage EnhancementMagnetic Resonance Imagingeye diseasesOxygenVisual cortexmedicine.anatomical_structureNeurologyOculomotor MusclesFixation (visual)Femalesense organsSensory DeprivationArousalPsychologyNeuroscienceNeuroImage
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Functional Magnetic Resonance Imaging Activations of Cortical Eye Fields during Saccades, Smooth Pursuit, and Optokinetic Nystagmus

2009

Saccades, smooth pursuit, and optokinetic nystagmus (OKN) are three basic eye movements in our ocular motor repertoire that enable us to explore the visual field. These eye movements are cortically controlled in different cortical eye fields, including the frontal eye fields (FEF) and parietal eye fields (PEF), as well as the motion-sensitive visual area MT+/V5. It is not known if this cortical control is organized in parallel cortico-cortical networks or in adjacent subregions of one system. Nor do we know where the specific eye fields are exactly located. Functional magnetic resonance imaging (fMRI) was used to investigate these open questions about the FEF, PEF, and MT+/V5. Activations o…

AdultMalegenetic structuresGeneral Biochemistry Genetics and Molecular BiologySmooth pursuitHistory and Philosophy of ScienceCortex (anatomy)SaccadesmedicineHumansAgedmedicine.diagnostic_testGeneral NeuroscienceEye movementOptokinetic reflexMiddle AgedFrontal eye fieldsMagnetic Resonance Imagingeye diseasesParietal eyeVisual fieldmedicine.anatomical_structureFemalesense organsVisual FieldsFunctional magnetic resonance imagingPsychologyNeuroscienceAnnals of the New York Academy of Sciences
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Functional Plasticity after Unilateral Vestibular Midbrain Infarction in Human Positron Emission Tomography.

2016

The aim of the study was to uncover mechanisms of central compensation of vestibular function at brainstem, cerebellar, and cortical levels in patients with acute unilateral midbrain infarctions presenting with an acute vestibular tone imbalance. Eight out of 17 patients with unilateral midbrain infarctions were selected on the basis of signs of a vestibular tone imbalance, e.g., graviceptive (tilts of perceived verticality) and oculomotor dysfunction (skew deviation, ocular torsion) in F18-fluordeoxyglucose (FDG)-PET at two time points: A) in the acute stage, and B) after recovery 6 months later. Lesion-behavior mapping analyses with MRI verified the exact structural lesion sites. Group su…

Male0301 basic medicineBrain Stem Infarctionslcsh:MedicinePathology and Laboratory MedicineMidbrainDiagnostic Radiology0302 clinical medicineThalamusMesencephalonCortex (anatomy)Medicine and Health SciencesMedicinelcsh:ScienceTomographyPostural BalanceVestibular systemNeuronal PlasticityMultidisciplinaryRadiology and ImagingBrainAnatomyFrontal eye fieldsMagnetic Resonance Imagingmedicine.anatomical_structureVestibular DiseasesInfarctionThalamic NucleiFemaleBrainstemAnatomyBrainstemResearch ArticleImaging TechniquesThalamusNeuroimagingResearch and Analysis Methods03 medical and health sciencesSigns and SymptomsDiagnostic MedicineOcular SystemHumansSkew deviationAgedbusiness.industrylcsh:RBiology and Life SciencesVestibular cortex030104 developmental biologyVisual cortexCase-Control StudiesPositron-Emission TomographyLesionsEyeslcsh:QbusinessHeadNeurosciencePositron Emission Tomography030217 neurology & neurosurgeryNeurosciencePLoS ONE
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The role of the claustrum in the bilateral control of frontal oculomotor neurons in the cat.

1991

The effect of claustrum (CL) stimulation on the spontaneous unitary activity of ipsi and contralateral frontal oculomotor neurons, was studied in chloralose-anaesthetized cats. A total of 205 units was bilaterally recorded in the medial oculomotor area, homologous of the primate "frontal eye fields"; 127 neurons were identified as projecting to the superior colliculus; for 33 of these last units stimulation of the ipsilateral CL provoked an excitatory effect lasting 10-25 ms and appearing with a latency of 5-15 ms; on 8 units the excitatory effect was followed by an inhibition lasting 100-250 ms. Ninety-eight of the 127 neurons were also tested through activation of the contralateral CL: 13…

Cerebral CortexNeuronsSuperior ColliculiOculomotor nerveGeneral NeuroscienceSuperior colliculusElectroencephalographyAnatomyFrontal eye fieldsBiologyCorpus callosumClaustrumBasal GangliaElectric StimulationStereotaxic Techniquesmedicine.anatomical_structureOculomotor NerveCerebral cortexStereotaxic techniqueNeural PathwaysmedicineExcitatory postsynaptic potentialCatsAnimalsNeuroscienceExperimental brain research
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