Pathologic myopia, or extreme nearsightedness, is a leading cause of blindness worldwide, particularly in Asian populations. It has been estimated that up to 2.3 billion people are myopic globally (with a prevalence as high as 80% in Southeast Asia) and the numbers are rising. Although minimal levels of near-sightedness are considered a minor inconvenience, high (pathologic) myopia can lead to irreversible vision loss. Myopia is often due to excessive eye elongation. Pathologic myopia is due to progressive, lifelong and extreme eye elongation with subsequent eye wall (sclera) thinning, which allows for localized outpouchings (called staphyloma). Development of staphyloma often immediately precedes irreversible vision loss. The long-term goal of my laboratory is to stunt myopia progression and identify patients at risk of vision loss. Although scleral collagen dysfunction has been proposed to underlie staphyloma formation, there is no safe, effective therapy to fortify the eye wall collagen or a standard quantitative method to assess for staphyloma progression. We now have a group of chemicals (beta-nitroalcohols or BNAs) that can stiffen tissue by crosslinking collagen in animal models and imaging technology that can assess the eye wall in vivo and potentially monitor scleral strength and pliability in both animals as well as human patients. Taken together, we can now test whether BNAs can stunt physiologic as well as pathologic eye elongation as assessed by in vivo imaging in animal models. We also hypothesize that the same imaging modalities can be used to identify myopic patients at risk of vision loss. Specifically, we propose to employ various BNAs to crosslink scleral collagen to act as a mortar, stiffening the eye wall.
In Aim 1, we test which BNAs effectively and safely stunt physiologic eye elongation in growing adolescent rabbits and guinea pig pups.
In Aim 2, we will apply the most effective BNAs in an attempt to stunt pathologic eye elongation in a guinea pig model of myopia, recently shown capable of forming staphyloma. We will phenotype these animals using multimodal imaging established in our pilot work. These imaging modalities will be used concurrently in Aim 3 where we perform natural history studies in highly myopic patients with and without staphyloma to elucidate a quantitative measure of susceptibility to staphyloma development/progression and key time points or anatomic locations toward which therapy should be directed. Our goal is to identify the type of patients who would most benefit from BNA treatment. We hypothesize that crosslinking the component collagen will stiffen the eye wall, thereby halting myopia progression and avoiding permanent vision loss and that at-risk patients can be identified by the pliability of staphyloma. This work has the potential to aid millions of pathologic myopia patients with weakened staphyloma, otherwise destined for permanent vision loss. Fortifying eyes that have prematurely reached adult eye length, but have yet to reach physical maturity, may allow billions of young patients to avoid myopia altogether.

Public Health Relevance

Myopia, or near-sightedness, is commonly a result of excessive eye elongation. Although mild myopia is considered a minor inconvenience, high or 'pathologic' myopia occurs at extreme levels of life-long eye elongation that can lead to a breakdown in the structural integrity of the eye wall and permanent vision loss. This is a public health concern, especially in Asia where myopia is consider epidemic in certain populations, and pathologic myopia is the leading cause of health disparity and blindness in Japanese and second leading cause in Chinese populations.

Agency
National Institute of Health (NIH)
Institute
National Eye Institute (NEI)
Type
Clinical Investigator Award (CIA) (K08)
Project #
5K08EY023595-04
Application #
9334880
Study Section
Special Emphasis Panel (ZEY1)
Program Officer
Agarwal, Neeraj
Project Start
2014-09-01
Project End
2018-07-01
Budget Start
2017-09-01
Budget End
2018-07-01
Support Year
4
Fiscal Year
2017
Total Cost
Indirect Cost
Name
Columbia University (N.Y.)
Department
Ophthalmology
Type
Schools of Medicine
DUNS #
621889815
City
New York
State
NY
Country
United States
Zip Code
10032
Piekutowska-Abramczuk, Dorota; Kocy?a-Karczmarewicz, Beata; Ma?kowska, Maja et al. (2016) No Evidence for Association of SCO2 Heterozygosity with High-Grade Myopia or Other Diseases with Possible Mitochondrial Dysfunction. JIMD Rep 27:63-8
Jung, Jesse J; Hoang, Quan V; Arain, Mohammad Z Y et al. (2016) Aflibercept anti-vascular endothelial growth factor therapy in vitrectomized eyes with neovascular age-related macular degeneration. Acta Ophthalmol 94:e249-50
McFadden, Sally A (2016) Understanding and Treating Myopia: What More We Need to Know and Future Research Priorities. Optom Vis Sci 93:1061-3
Jung, Jesse J; Hoang, Quan V; Ridley-Lane, Megan L et al. (2016) LONG-TERM RETROSPECTIVE ANALYSIS OF VISUAL ACUITY AND OPTICAL COHERENCE TOPOGRAPHIC CHANGES AFTER SINGLE VERSUS DOUBLE PEELING DURING VITRECTOMY FOR MACULAR EPIRETINAL MEMBRANES. Retina 36:2101-2109
Dolz-Marco, Rosa; Hoang, Quan V; Gallego-Pinazo, Roberto et al. (2016) ASSESSMENT OF THE SIGNIFICANCE OF CYSTIC CHANGES AFTER EPIRETINAL MEMBRANE SURGERY WITH INTERNAL LIMITING MEMBRANE REMOVAL. Retina 36:727-32
Hoang, Quan V; Chen, Ching-Lung; Garcia-Arumi, Jose et al. (2016) Radius of curvature changes in spontaneous improvement of foveoschisis in highly myopic eyes. Br J Ophthalmol 100:222-6
de Mello, PatrĂ­cia Correa; Berensztejn, Patricia; Brasil, Oswaldo Ferreira Moura (2015) Re: The 'pitchfork sign' a distinctive optical coherence tomography finding in inflammatory choroidal neovascularization. Retina 35:e23-4
SepĂșlveda, Gonzalo; Chang, Stanley; Freund, K Bailey et al. (2014) Late recurrence of myopic foveoschisis after successful repair with primary vitrectomy and incomplete membrane peeling. Retina 34:1841-7