BACKGROUND: Several studies have shown that the ability to suppress automatic saccadic eye movements is impaired in patients with schizophrenia as well as in their first-degree relatives, and suggest that this impairment is a potential vulnerability marker for schizophrenia. The neurobiological mechanisms underlying normal saccade production and inhibition, revealed in primate studies, indicate that the impairment may result from a failure of the oculomotor system to effectively exert inhibitory control over brainstem structures. Functional localization of the affected brain structure(s) potentially provides a physiological measure for the investigation of vulnerability markers in schizophrenia. METHODS: The hemodynamic response to discrete visual stimuli was measured during prosaccades (saccades toward a peripheral stimulus), antisaccades (saccades toward a position opposite to a peripheral stimulus), and active fixation (holding fixation and ignoring a peripheral stimulus) in 16 patients with schizophrenia receiving atypical neuroleptics and 17 healthy control subjects using an event-related functional magnetic resonance imaging task design. RESULTS: Brain responses were detected in the frontal and parietal regions of the oculomotor system in all 3 tasks. Patients made more errors during inhibition tasks and exhibited a selective failure to activate the striatum during the inhibition of saccades. In other regions that were active during inhibition, specifically the supplementary and frontal eye fields, no difference was found between patients and control subjects. CONCLUSIONS: A frontostriatal network is engaged in the suppression of automatic eye movements. The results indicate that abnormalities in this network, rather than the selective dysfunction of prefrontal brain regions, underlie the saccade inhibition deficit in schizophrenia.
BACKGROUND: Several studies have shown that the ability to suppress automatic saccadic eye movements is impaired in patients with schizophrenia as well as in their first-degree relatives, and suggest that this impairment is a potential vulnerability marker for schizophrenia. The neurobiological mechanisms underlying normal saccade production and inhibition, revealed in primate studies, indicate that the impairment may result from a failure of the oculomotor system to effectively exert inhibitory control over brainstem structures. Functional localization of the affected brain structure(s) potentially provides a physiological measure for the investigation of vulnerability markers in schizophrenia. METHODS: The hemodynamic response to discrete visual stimuli was measured during prosaccades (saccades toward a peripheral stimulus), antisaccades (saccades toward a position opposite to a peripheral stimulus), and active fixation (holding fixation and ignoring a peripheral stimulus) in 16 patients with schizophrenia receiving atypical neuroleptics and 17 healthy control subjects using an event-related functional magnetic resonance imaging task design. RESULTS: Brain responses were detected in the frontal and parietal regions of the oculomotor system in all 3 tasks. Patients made more errors during inhibition tasks and exhibited a selective failure to activate the striatum during the inhibition of saccades. In other regions that were active during inhibition, specifically the supplementary and frontal eye fields, no difference was found between patients and control subjects. CONCLUSIONS: A frontostriatal network is engaged in the suppression of automatic eye movements. The results indicate that abnormalities in this network, rather than the selective dysfunction of prefrontal brain regions, underlie the saccade inhibition deficit in schizophrenia.
Authors: Ulrich Ettinger; Anne Schmechtig; Timothea Toulopoulou; Charmaine Borg; Claire Orrells; Sheena Owens; Kazunori Matsumoto; Neeltje E van Haren; Mei-Hua Hall; Veena Kumari; Philip K McGuire; Robin M Murray; Marco Picchioni Journal: Schizophr Bull Date: 2010-06-10 Impact factor: 9.306
Authors: Kara A Dyckman; Adrian K C Lee; Yigal Agam; Mark Vangel; Donald C Goff; Jason J S Barton; Dara S Manoach Journal: Schizophr Res Date: 2011-08-09 Impact factor: 4.939
Authors: Rajeev S Ramchandran; Dara S Manoach; Mariya V Cherkasova; Kristen A Lindgren; Donald C Goff; Jason J S Barton Journal: Exp Brain Res Date: 2004-07-29 Impact factor: 1.972
Authors: Matthijs Vink; René S Kahn; Mathijs Raemaekers; Martijn van den Heuvel; Maria Boersma; Nick F Ramsey Journal: Hum Brain Mapp Date: 2005-07 Impact factor: 5.038
Authors: Martina T Mitterschiffthaler; Cynthia H Y Fu; Jeffrey A Dalton; Christopher M Andrew; Steven C R Williams Journal: Hum Brain Mapp Date: 2007-11 Impact factor: 5.038
Authors: Dara S Manoach; Adrian K C Lee; Matti S Hämäläinen; Kara A Dyckman; Jesse S Friedman; Mark Vangel; Donald C Goff; Jason J S Barton Journal: Biol Psychiatry Date: 2013-02-04 Impact factor: 13.382