Crawford, John DouglasBaltaretu, Bianca-Ruxandra2021-07-062021-07-062021-042021-07-06http://hdl.handle.net/10315/38503The cortical correlates for transsaccadic perception (i.e., the ability to perceive, maintain, and update information across rapid eye movements, or saccades; Irwin, 1991) have been little investigated. Previously, Dunkley et al. (2016) found evidence of transsaccadic updating of object orientation in specific intraparietal (i.e., supramarginal gyrus, SMG) and extrastriate occipital (putative V4) regions. Based on these findings, I hypothesized that transsaccadic perception may rely on a single cortical mechanism. In this dissertation, I first investigated whether activation in the previous regions would generalize to another modality (i.e., motor/grasping) for the same feature (orientation) change, using a functional magnetic resonance imaging (fMRI) event-related paradigm that involved participants grasping a three-dimensional rotatable object for either fixations or saccades. The findings from this experiment further support the role of SMG in transsaccadic updating of object orientation, and provide a novel view of traditional reach/grasp-related regions in their ability to update grasp-related signals across saccades. In the second experiment, I investigated whether parietal cortex (e.g., SMG) plays a general role in the transsaccadic perception of other low-level object features, such as spatial frequency. The results point to the engagement of a different, posteromedial extrastriate (i.e., cuneus) region for transsaccadic perception of spatial frequency changes. This indirect assessment of transsaccadic interactions for different object features suggests that feature sensitive mechanisms may exist. In the third experiment, I tested the cortical correlates directly for two object features: orientation and shape. In this experiment, only posteromedial extrastriate cortex was associated with transsaccadic feature updating in the feature discrimination task, as it showed both saccade and feature modulations. Overall, the results of these three neuroimaging studies suggest that transsaccadic perception may be brought about by more than a single, general mechanism and, instead, through multiple, feature-dependent cortical mechanisms. Specifically, the saccade system communicates with inferior parietal cortex for transsaccadic judgements of orientation in an identified object, whereas as a medial occipital system is engaged for feature judgements related to object identity.Author owns copyright, except where explicitly noted. Please contact the author directly with licensing requests.NeurosciencesElectronic Thesis or Dissertation2021-07-06saccadestranssaccadic perceptionobject featuresorientationspatial frequencyshapesfMRIfunctional connectivity