Studies of gaze control in labyrinthine-deficient (LD) patients have revealed a variety of adaptive mechanisms that may be used to compensate for loss of the vestibuloocular reflex (VOR), including central preprogramming of eye movements and the potentiation of the pursuit, optokinetic, and cervicoocular reflexes. To investigate the mechanisms that compensate for loss of the VOR during head-free pursuit we examined the responses to pursuit of pseudorandom target motion in LD patients under head-free and head-fixed conditions, using a stimulus that covers the frequency range of normal head-free pursuit movements
AbstractLabyrinthine defective subjects (LDS) experience oscillopsia during head movements due to th...
In response to passive high-acceleration head impulses patients with low vestibulo-ocular reflex (VO...
Patients with vestibular deficit use slow eye movements or catch-up saccades (CUS) to compensate for...
Studies of gaze control in labyrinthine-deficient (LD) patients have revealed a variety of adaptive ...
During pursuit of smoothly moving targets with combined eye and head movements in normal subjects, a...
Eye and head movements were analysed during smooth pursuit in 16 patients with various forms of cere...
One of the primary functions of the vestibular system is to keep the eyes fixed on a target (gaze st...
Head and eye movements of human subjects have been recorded during head-free pursuit in the horizont...
Patients with bilateral vestibular de¢cits experience unsteady gait and oscillopsia that can reduce ...
We investigated how effectively briefly presented visual motion could be assimilated and used to tra...
Previous experiments have shown that the vestibulo-ocular reflex (VOR) is partially suppressed durin...
differs between normal subjects and patients with various neurological disorders. Abnormalities of V...
Daye PM, Blohm G, Lefevre P. Saccadic compensation for smooth eye and head movements during head-unr...
: Deficits in pursuit and vestibulo-ocular reflex (VOR)S usually go together, except when the VOR is...
An experimental study of head-free and head-fixed gaze shifts explores the role of the vestibulo-ocu...
AbstractLabyrinthine defective subjects (LDS) experience oscillopsia during head movements due to th...
In response to passive high-acceleration head impulses patients with low vestibulo-ocular reflex (VO...
Patients with vestibular deficit use slow eye movements or catch-up saccades (CUS) to compensate for...
Studies of gaze control in labyrinthine-deficient (LD) patients have revealed a variety of adaptive ...
During pursuit of smoothly moving targets with combined eye and head movements in normal subjects, a...
Eye and head movements were analysed during smooth pursuit in 16 patients with various forms of cere...
One of the primary functions of the vestibular system is to keep the eyes fixed on a target (gaze st...
Head and eye movements of human subjects have been recorded during head-free pursuit in the horizont...
Patients with bilateral vestibular de¢cits experience unsteady gait and oscillopsia that can reduce ...
We investigated how effectively briefly presented visual motion could be assimilated and used to tra...
Previous experiments have shown that the vestibulo-ocular reflex (VOR) is partially suppressed durin...
differs between normal subjects and patients with various neurological disorders. Abnormalities of V...
Daye PM, Blohm G, Lefevre P. Saccadic compensation for smooth eye and head movements during head-unr...
: Deficits in pursuit and vestibulo-ocular reflex (VOR)S usually go together, except when the VOR is...
An experimental study of head-free and head-fixed gaze shifts explores the role of the vestibulo-ocu...
AbstractLabyrinthine defective subjects (LDS) experience oscillopsia during head movements due to th...
In response to passive high-acceleration head impulses patients with low vestibulo-ocular reflex (VO...
Patients with vestibular deficit use slow eye movements or catch-up saccades (CUS) to compensate for...