@article{2998028,
    title = "Idiothetic signal processing and spatial orientation in patients with unilateral hippocampal sclerosis",
    author = "Anagnostou, E. and Skarlatou, V. and Mergner, T. and Anastasopoulos, D.",
    journal = "Journal of Neurophysiology",
    year = "2018",
    volume = "120",
    number = "3",
    pages = "1256-1263",
    publisher = "American Physiological Society",
    issn = "0022-3077, 1522-1598",
    doi = "10.1152/jn.00016.2018",
    keywords = "adult;  Article;  clinical article;  controlled study;  darkness;  epilepsy;  female;  head;  hippocampal sclerosis;  human;  left hippocampus;  male;  priority journal;  proprioception;  right hippocampus;  rotation;  spatial orientation;  trunk;  vestibular evoked potential;  visual straight ahead direction;  visual system parameters;  depth perception;  hippocampus;  movement perception;  pathology;  pathophysiology;  physiology;  psychomotor performance;  sclerosis;  spatial behavior;  spatial orientation;  vestibular labyrinth, Adult;  Female;  Hippocampus;  Humans;  Male;  Motion Perception;  Orientation, Spatial;  Proprioception;  Psychomotor Performance;  Sclerosis;  Space Perception;  Spatial Processing;  Vestibule, Labyrinth",
    abstract = "The role of the hippocampus in spatial navigation and the presence of vestibular-responsive neurons in limbic areas are well-established from animal experiments. However, hippocampal spatial processing in humans is not fully understood. Here, we employed real whole body and head-on-trunk rotations to investigate how vestibular signals, either alone or in combination with neck-proprioceptive stimulation, shape the spatial frame of reference in patients with unilateral hippocampal sclerosis (HS). Patients were asked to point in darkness with a light spot, moved on a cylindrical screen by means of a joystick, into their visual straight-ahead direction (VSA), to remember this direction in space, and to revert back to this point after the rotations. Estimates in patients with HS were compared with those of healthy controls and of patients with epilepsy without hippocampal involvement. All groups produced similar errors after low-frequency vestibular stimuli. These errors were eliminated when rotations involved concurrent neck stimulation. Significantly increased variability was observed, however, in both the VSA and reposition estimates after the rotations in patients with HS compared with controls. These results suggest that cognitive processing of idiothetic signals for self-motion perception is inaccurate in patients with HS. Importantly, however, the responses of patients with HS showed no spatial lateralization with regard to right or left HS, suggesting that the underlying neuronal loss attenuates the precision of head-direction signal decoding in a nondirectional manner. Hence, patients are unable to use these signals as efficiently as normal subjects in the construction of a stable head-centric spatial frame of reference. NEW & NOTEWORTHY Spatial perception relies on combined processing of various idiothetic (vestibular and proprioceptive) and allothetic (visual and auditory) sensory signals. Despite the established knowledge of rodent vestibular-hippocampal interactions, human data are lacking. We investigated idiothetic orientational processing in subjects with unilateral hippocampal sclerosis using various combinations of vestibular and proprioceptive stimuli. Hippocampal impairment leads to less accurate, noisy decoding of the signal related to idiothetic orientation. However, patients did not show any lateralized deficits of visual straight-ahead perception or of target/self-displacement perception after idiothetic stimulation. © 2018 American Physiological Society. All rights reserved."
}