Asociaciones entre función vestibular y habilidades cognitivas: un enfoque básico-clínico / Associations between vestibular function and cognitive abilities: from basic to clinical approach

RESUMEN El sistema vestibular tiene un rol fundamental en funciones sensorio-motoras, control del equilibrio y estabilidad de la mirada. En las últimas décadas un amplio número de trabajos ha descrito la importancia de las aferencias vestibulares en el funcionamiento de diversas áreas del cerebro relacionadas con funciones cognitivas tales como la atención, memoria, navegación y otras habilidades visuo-espaciales. Estudios en pacientes con vestibulopatía han demostrado que estos individuos presentan disminución de su rendimiento en algunas pruebas neuropsicológicas; y, a su vez, que personas con patología cognitiva como deterioro cognitivo leve y demencia por enfermedad de Alzheimer tienen mayor probabilidad de presentar pruebas vestibulares alteradas. Esta revisión se enfoca en el papel que cumple el sistema vestibular y su asociación con habilidades cognitivas; basándose en estudios básicos y clínicos que describen una red vestibular cerebral y que han llevado a proponer modelos teóricos que relacionan la función vestibular con la cognición.

ABSTRACT The vestibular system is widely known for its role in sensory-motor functions, balance control and gaze stability. In recent decades, several research articles have described the importance of vestibular afferents in the functioning of brain areas related to cognitive skills such as attention, spatial memory, spatial navigation and other visuospatial abilities. Studies involving subjects with vestibulopathy reveal that these individuals show decreased performance on neuropsychological tests; and that patients with neurocognitive pathologies, such as mild cognitive impairment and dementia due to Alzheimer's disease, have a greater probability of producing diminished or absent responses in clinical vestibular electrophysiological tests. This literature review focuses on the role played by the vestibular system and its association with cognitive abilities. The review incorporates a description of basic and clinical research that describe the cortical vestibular network and emerging theoretical models linking vestibular function to cognition.

MR Imaging of the Internal Auditory Canal and Inner Ear at 3T: Comparison between 3D Driven Equilibrium and 3D Balanced Fast Field Echo Sequences

OBJECTIVE: To compare the use of 3D driven equilibrium (DRIVE) imaging with 3D balanced fast field echo (bFFE) imaging in the assessment of the anatomic structures of the internal auditory canal (IAC) and inner ear at 3 Tesla (T). MATERIALS AND METHODS: Thirty ears of 15 subjects (7 men and 8 women; age range, 22-71 years; average age, 50 years) without evidence of ear problems were examined on a whole-body 3T MR scanner with both 3D DRIVE and 3D bFFE sequences by using an 8-channel sensitivity encoding (SENSE) head coil. Two neuroradiologists reviewed both MR images with particular attention to the visibility of the anatomic structures, including four branches of the cranial nerves within the IAC, anatomic structures of the cochlea, vestibule, and three semicircular canals. RESULTS: Although both techniques provided images of relatively good quality, the 3D DRIVE sequence was somewhat superior to the 3D bFFE sequence. The discrepancies were more prominent for the basal turn of the cochlea, vestibule, and all semicircular canals, and were thought to be attributed to the presence of greater magnetic susceptibility artifacts inherent to gradient-echo techniques such as bFFE. CONCLUSION: Because of higher image quality and less susceptibility artifacts, we highly recommend the employment of 3D DRIVE imaging as the MR imaging choice for the IAC and inner ear.