This research aims to examine changes in plastic potential of the visual system with time from stroke affecting primary visual cortex. We will measure structural and mechanistic aspects of progressive degeneration along the early visual pathways, correlating them with changes in visual performance, and in responsiveness to visual restoration training. This project will advance both scientific knowledge, as well as technical capability and clinical practices for restoring vision and quality of life for people suffering from cortical blindness.
Study Type
INTERVENTIONAL
Allocation
RANDOMIZED
Purpose
TREATMENT
Masking
DOUBLE
Enrollment
60
A computer software and chin-rest necessary to perform visual training will be loaned to each subject to be used at home. They will perform one to two daily training sessions in their home, consisting of 200-300 trials each. The visual task performed repetitively will involve discriminating the direction of motion of a small cloud of dots located at a predetermined location in the intact field. The computer program will automatically create a record of patient performance during each home training session. Subjects will train daily (about 40-60 minutes total), 5 to 7 days per week for at least one and up to 6 months.
A computer software and chin-rest necessary to perform visual training will be loaned to each subject to be used at home. They will perform one to two daily training sessions in their home, consisting of 200-300 trials each. The visual task performed repetitively will involve discriminating the direction of motion of a small cloud of dots located at a predetermined location in the blind field. The computer program will automatically create a record of patient performance during each home training session. Subjects will train daily (about 40-60 minutes total), 5 to 7 days per week for at least one and up to 6 months.
After the initial training period of one to six months, the same computer software will continue to be used for all subjects. The visual task performed repetitively will involve discriminating the direction of motion of a small cloud of dots located at a predetermined location in the blind field. The computer program will automatically create a record of patient performance during each home training session. Subjects will train daily (about 40-60 minutes total), 5 to 7 days per week for at least 6 months.
University of Rochester
Rochester, New York, United States
Direction Discrimination Threshold
For each subject, we will measure the ability to detect differences in the motion direction of visual stimuli relative to horizontal, measured in degrees of visual angle. These assessments will be based on what can be reliably detected at a 72-75% correct level of performance. These measures of change will be evaluated baseline to 6-months post-stroke, then 6- to 12-months post stroke, and baseline to 12-months.\*\* \*\*NOTE: Our protocol allows for a +1 month variance for all timepoints.
Time frame: baseline, 6 months, 12 months
Direction Integration Threshold
This will measure the ability of subjects to integrate across a range of motion directions measured in degrees of visual angle. These assessments will be based on what range of motion directions can be reliably integrated at a 72-75% correct level of performance. These measures of change will be evaluated baseline to 6-months post-stroke, then 6- to 12-months post stroke, and baseline to 12-months. \*\*NOTE: Our protocol allows for a +1 month variance for all timepoints.
Time frame: baseline, 6 months, 12 months
Contrast Sensitivity for Direction
Assessment of visual perception transfer to untrained psychophysical tasks of contrast sensitivity for direction discrimination. For each subject, we will measure the ability to correctly detect the motion direction of visual stimuli that are also varying in contrast against a grey background. We will measure the luminance contrast that can be reliably detected at a 72-75% correct level of performance. These measures of change will be evaluated baseline to 6-months post-stroke, then 6- to 12-months post stroke, and baseline to 12-months. \*\*NOTE: Our protocol allows for a +1 month variance for all timepoints.
Time frame: baseline, 6 months, 12 months
contrast sensitivity for static orientation
Assessment of visual perception transfer to untrained psychophysical tasks of contrast sensitivity for static orientation discrimination. For each subject, we will measure the ability to correctly detect the orientation of non-moving visual stimuli that vary in contrast against a grey background. We will measure the luminance that can be reliably detected at a 72-75% correct level of performance. These measures of change will be evaluated baseline to 6-months post-stroke, then 6- to 12-months post stroke, and baseline to 12-months. \*\*NOTE: Our protocol allows for a +1 month variance for all timepoints.
Time frame: baseline, 6 months, 12 months
Ganglion cell complex thickness laterality
Change in thickness of the ganglion cell complex will be measured by retinal optical coherence tomography (OCT) scans from baseline to 6- and 12- months post stroke.\*\* We will perform OCT imaging of the foveal region of the retina (6mm ETDRS) in both eyes of each patient. Images will be automatically segmented. Estimated thickness of the ganglion cell complex will be extracted and aligned with estimates of the blind field's visual sensitivity obtained from fundus-controlled MAIA perimetry. We will then compute a laterality index LI as follows: LIGCCT=(Tc-Ti)/(Tc+Ti) where Tc=thickness in the control lateral OCT quadrant, Ti=thickness in the impaired lateral OCT quadrant. \*\*NOTE: Our protocol allows for a +1 month variance for all timepoints.
Time frame: baseline, 6 months, 12 months
Ganglion cell complex volume laterality
Change in volume of the ganglion cell complex will be measured by retinal optical coherence tomography (OCT) scans from baseline to 6- and 12- months post stroke.\*\* We will perform OCT imaging of the foveal region of the retina (6mm ETDRS) in both eyes of each patient. Images will be automatically segmented. Estimated volume of the ganglion cell complex will be extracted and aligned with estimates of the blind field's visual sensitivity obtained from fundus-controlled MAIA perimetry. We will then compute a laterality index as follows: LIGCCT=(Tc-Ti)/(Tc+Ti) where Tc=thickness in the control lateral OCT quadrant, Ti=thickness in the impaired lateral OCT quadrant. \*\*NOTE: Our protocol allows for a +1 month variance for all timepoints.
Time frame: baseline, 6 months, 12 months
Optic Tract (OT) laterality
OT volume analysis will be performed from high resolution structural T1 MRI images of the brain. Mirrored masks of equal size will be hand-drawn over the OTs in each brain slice of a given subject, starting three slices posterior to the optic chiasm and continuing posteriorly until the OTs are no longer distinct from surrounding structures. The volume of each optic tract will be calculated from these masks by first establishing the maximum voxel intensity (range from 0 to 255) across the two OTs, then counting the number of voxels in each OT mask with brightness values between 5 and 85% of this maximum. We will then compute an OT laterality Index (LI85) to represent the relative difference in estimated volume between the two OTs of each participant, where LI85=(OTc-OTi)/(OTc+OTi), where OTc=number of voxels with brightness 5-85% of maximum in the contralesional OT and OTi = number of voxels with brightness 5-85% of maximum in the ipsilesional OT.
Time frame: baseline, 6 months, 12 months
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