Factors in Learning And Plasticity: Macular Degeneration

Purpose

A greater understanding of plasticity after central vision loss can inform new therapies for treating low vision and has the potential to benefit millions of individuals suffering from low vision. The treatment of low vision is particularly relevant to the mission of the NEI to support research on visual disorders, mechanisms of visual function, and preservation of sight. The comparison of different training and outcome factors is in line with the NIMH RDOC framework and studies in an aging population are consistent with the mission of the NIA.

Conditions

  • Central Visual Impairment
  • Macular Degeneration

Eligibility

Eligible Ages
Between 18 Years and 89 Years
Eligible Genders
All
Accepts Healthy Volunteers
No

Inclusion Criteria

  • Aged 18-89 - Severely impaired vision in both eyes (20/100 or worse) - diagnosis of Macular Degeneration by an Ophthalmologist - Light sensitivity in the macular retina that is at least 10 dB units worse than in peripheral regions, as demonstrated by a scanning laser ophthalmoscope (MAIA) - Medical record review indicating this level of disease severity has been present for at least 2 years - Reside within 50 miles of study site

Exclusion Criteria

  • Pacemaker or any ferromagnetic metal implanted in their body - Metal of any type implanted in their head (limited dental work is acceptable) - Claustrophobia - Being hearing-impaired - Weight over 300 pounds - Maximum body girth over 60 inches - Previous serious head injury - Presence of hallucinations or delusions - Excessive old, or colorful tattoos, especially near the head - Pregnancy - Braces/permanent retainer

Study Design

Phase
N/A
Study Type
Interventional
Allocation
Randomized
Intervention Model
Parallel Assignment
Primary Purpose
Basic Science
Masking
Single (Outcomes Assessor)

Arm Groups

ArmDescriptionAssigned Intervention
Experimental
Training visual sensitivity 		A standard Perceptual Learning approach to train early visual processes of discriminating the orientation of Gabor patches presented at threshold- level contrast. Preliminary data, using this method, in normally seeing and MD participants show both feasibility and preliminary evidence that this training gives rise to improvements in acuity.
  • Behavioral: Training visual sensitivity
    Investigators adopt a standard PL approach to train early visual processes of discriminating the orientation of Gabor patches presented at threshold contrast. Across training blocks, Gabors will range in spatial frequency, where contrast is adapted with a 3/1 staircase. Whenever a specific contrast threshold is reached, spatial frequency will increase by 2 cycles per degree and contrast will be reset. Preliminary data from this method in normally seeing and MD participants show both feasibility and tentative evidence that this training gives rise to improvements in acuity.
Experimental
Combination training 		In combination training, investigators test the extent to which a combined training gives rise to the joint benefits of each training individually, or integrative benefits potentially surpassing benefits of the individual training alone. The visual sensitivity task will alternate across blocks with the spatial integration task, using the timing of targets and location switches from spatial attention training.
  • Behavioral: Combination training
    Daily tasks involve a combination of being sensitive to basic visual features, being able to integrate these features, and directing attention and eye movements to better evaluate the information of potential interest. To address this integrative nature of real-world vision, this condition combines elements of training visual sensitivity, spatial integration, and spatial attention.

Recruiting Locations

UAB
Birmingham, Alabama 35294
Contact:
Rachel A Chua, MS
205-410-4041
r2chel@uab.edu

More Details

Status
Recruiting
Sponsor
University of Alabama at Birmingham

Study Contact

Rachel A Chua, MS
205-410-4041
r2chel@uab.edu

Detailed Description

Research on perceptual learning (PL) has been dominated by studies that seek to isolate and improve individual visual processes. However, an important translational outcome of PL research is to address the needs of patients with vision loss, who seek to improve performance on daily tasks such as reading, navigation, and face recognition. These more ecological cases of behavioral change and cortical plasticity, which are inherently complex and integrative, have revealed significant gaps in a more holistic understanding of how multiple visual processes and their associated brain systems jointly contribute to durable and generalizable PL. To address these gaps, here the investigators study simulated and natural central vision loss. The investigators focus on macular degeneration (MD), one of the most common causes of vision loss (projected to affect 248 million people worldwide by 2040), which results from damage to photoreceptors in the macula that disrupts central vision. Such central vision loss is a superb lens through which study to how ecologically relevant changes in the use of vision relate to changing brain activity and connectivity because it represents a massive alteration in visual experience requiring reliance on peripheral vision for daily tasks. With the use of eye-trackers and gaze-contingent displays that induce central scotomas, central vision loss can be simulated in normally seeing individuals, who then develop peripheral looking patterns that resemble compensatory vision strategies seen in MD patients. Ideal use of peripheral vision requires improvement in multiple vision domains, three of the most important being: early visual processing (e.g., visual sensitivity), mid-level visual processing (e.g., spatial integration), and attention and eye-movements. To date, no study has systematically investigated these three domains of PL and their neural underpinnings. The proposed research plan rests on rigorous prior work showing that PL influences multiple brain structures and functions related to these three domains. The investigators propose a novel approach of systematically measuring how different training regimes related to the three domains influence a broad range of psychophysical and ecological behaviors (Aim 1), how these changes arise from plasticity in brain structure and function (Aim 2), and how PL after simulated central vision loss compares to PL in MD (Aim 3). This work is significant and innovative as it will be the first integrated study of PL characterizing multiple trainable factors and their impact on diverse behavioral outcomes and on cutting-edge assessments of neural representations and dynamics. It is also the first study to directly compare PL in MD patients with PL in a controlled model system of central visual field loss with simulated scotomas, which if validated will allow the use of this model system to interrogate MD in larger samples of healthy individuals. The investigators will also share a unique dataset that will help the field to understand behavioral and neural plasticity after central vision loss and individual differences in responsiveness to training. Finally, this work will illuminate basic mechanisms of brain plasticity after sensory loss that may generalize to other forms of rehabilitation after peripheral or central damage.