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RESEARCH PRODUCT
Functional Plasticity after Unilateral Vestibular Midbrain Infarction in Human Positron Emission Tomography.
Andreas ZwergalMathias SchreckenbergerThomas BrandtBernhard BaierHans-georg BuchholzSandra Becker-benseMarianne DieterichPeter Bartensteinsubject
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 & neurosurgeryNeurosciencedescription
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 subtraction analyses and comparisons with healthy controls were performed with Statistic Parametric Mapping for the PET data. A comparison of PET A of acute-stage patients with that of healthy controls showed increases in glucose metabolism in the cerebellum, motion-sensitive visual cortex areas, and inferior temporal lobe, but none in vestibular cortex areas. At the supratentorial level bilateral signal decreases dominated in the thalamus, frontal eye fields, and anterior cingulum. These decreases persisted after clinical recovery in contrast to the increases. The transient activations can be attributed to ocular motor and postural recovery (cerebellum) and sensory substitution of vestibular function for motion perception (visual cortex). The persisting deactivation in the thalamic nuclei and frontal eye fields allows alternative functional interpretations of the thalamic nuclei: either a disconnection of ascending sensory input occurs or there is a functional mismatch between expected and actual vestibular activity. Our data support the view that both thalami operate separately for each hemisphere but receive vestibular input from ipsilateral and contralateral midbrain integration centers. Normally they have gatekeeper functions for multisensory input to the cortex and automatic motor output to subserve balance and locomotion, as well as sensorimotor integration.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2016-11-08 | PLoS ONE |