Abstract
Prism adaptation induces rapid recalibration of visuomotor coordination. The neural mechanisms of prism adaptation have come under scrutiny since the observations that the technique can alleviate hemispatial neglect following stroke, and can alter spatial cognition in healthy controls. Relative to non-imaging behavioral studies, fMRI investigations of prism adaptation face several challenges arising from the confined physical environment of the scanner and the supine position of the participants. Any researcher who wishes to administer prism adaptation in an fMRI environment must adjust their procedures enough to enable the experiment to be performed, but not so much that the behavioral task departs too much from true prism adaptation. Furthermore, the specific temporal dynamics of behavioral components of prism adaptation present additional challenges for measuring their neural correlates. We developed a system for measuring the key features of prism adaptation behavior within an fMRI environment. To validate our configuration, we present behavioral (pointing) and head movement data from 11 right-hemisphere lesioned patients and 17 older controls who underwent sham and real prism adaptation in an MRI scanner. Most participants could adapt to prismatic displacement with minimal head movements, and the procedure was well tolerated. We propose recommendations for fMRI studies of prism adaptation based on the design-specific constraints and our results.
Highlights
Prism adaptation has been used for over a hundred years to investigate the coordination of sensory inputs and motor performance (Harris, 1965; Hay, Langdon, & Pick, 1971; Hay & Pick, 1966; Held & Freedman, 1963; Held & Mikaelian, 1964; von Helmholtz, 1962; Stratton, 1896; for a review see Redding & Wallace, 1997)
Pointing error data In order to test for effective prism adaptation, each participant’s closed-loop pointing (CLP) and openloop pointing (OLP) errors were averaged across each block of six trials separately for the sham and prism run and pooled for analysis
Our behavioral results show the presence of two patterns in the CLP and OLP errors of the participants that are characteristic of prism adaptation
Summary
Prism adaptation has been used for over a hundred years to investigate the coordination of sensory inputs and motor performance (Harris, 1965; Hay, Langdon, & Pick, 1971; Hay & Pick, 1966; Held & Freedman, 1963; Held & Mikaelian, 1964; von Helmholtz, 1962; Stratton, 1896; for a review see Redding & Wallace, 1997). The precise neuronal circuitry that mediates this form of sensorimotor plasticity remains unclear. A typical prism adaptation protocol begins with a person seated at a table with their hands resting close to their chest and two or more targets positioned at arm’s length from their body.
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