Glaucoma and AMD are the most common causes of irreversible blindness worldwide.2 Both conditions are highly heritable, with recognised Mendelian and complex inheritance.10,37,38 There are a paucity of screening protocols for both diseases and current guidelines are not cost-effective, in part due to poor sensitivity or specificity. To our knowledge this is the first prospective study to apply PRS testing for glaucoma and AMD in individuals from the general population, specifically recruited for this purpose.
The current NHMRC screening guidelines in Australia lack specific guidance, and are mainly relevant to those with a family history of glaucoma.18 PRS testing for glaucoma is likely to be useful for those who do not have a known family history and have an unrecognised underlying risk. These individuals are less likely to be identified early by current screening guidelines given screening at an earlier age is only recommended for those with a family history and people of African ancestry.18 There are no current screening guidelines for AMD in Australia. Detection is reliant on an individual experiencing symptoms and seeking ophthalmic review, or opportunistic recognition of disease during a routine assessment. The findings from this study will assist in the development of better screening guidelines for glaucoma and AMD.
Currently, risk estimation for developing glaucoma and AMD are based on a combination of demographic and clinical factors. The predictive ability of polygenic risk models for POAG and AMD are well established, particularly in European populations, and are summarised elsewhere.39 For glaucoma, risk factors include increasing age, family history of glaucoma, African ancestry, and elevated IOP.6,7 Genetic risk has been largely estimated through family history alone. A positive family history carried a 9-fold risk for first-degree relatives compared to controls in one study, but this required full examination of all first degree relatives rather than self-report.40 The accuracy of self-reported family history for glaucoma has been studied and found to be an unreliable measure as many patients are unaware of family members with diagnosed glaucoma, or have erroneous views as to what caused vision loss in relatives.41 More recent data indicates that PRS provides a more accurate representation of risk with family history in an Australian population based study.22 Several risk calculators have been developed to aid clinicians in screening and treatment decisions, however there remains no consensus regarding optimal timing and frequency of population screening for glaucoma.42,43 PRS provides a more accurate estimation of risk than traditional methods alone, with risk prediction optimised when all factors are combined.22 AMD risk involves an interplay of genetic and environmental factors. There are several recognised environmental risk factors including age and smoking, with sex, ancestry, cardiovascular disease, and diet also suggested to be implicated.31 A prediction model incorporating genetic, demographic and environmental risk factors was independently associated with incidence and prevalence of advanced AMD, all with strong predictive power.44 Effective risk algorithms incorporating environmental, clinical and genetic risk factors will need to be developed. While environmental and clinical risk factors may change over time, the genetic contribution to overall risk will remain constant given genetic disease liability is fixed from conception. Therefore, an important benefit of polygenic risk testing is that PRS can be calculated at any stage of life and may be useful to inform disease prognosis and response to treatment before individuals exhibit vision loss.
Glaucoma genetic testing is currently limited to Mendelian genes (e.g. MYOC) which explain less than 5% of adult onset glaucoma.11,12 PRS testing, however, captures a much larger component of glaucoma genetic risk. Those with high polygenic risk had a comparable glaucoma risk to those with the most common Mendelian variant (OR 2.77 vs OR 4.19), as well as being ~ 15 times more prevalent.11 At present, genetic testing for AMD is not recommended and exists predominantly in research contexts.31,45,46 Direct to consumer tests incorporating various PRS tests for both diseases are available, however these lack prospective evidence demonstrating their effectiveness.47,48 This study will assess the clinical validity of PRS testing in a sample representative of the general population in Australia in order to determine its application in the community.
We have previously demonstrated strong interest in polygenic risk testing for glaucoma among various groups, including those with diagnosed glaucoma, those with a first-degree relative with glaucoma, and those without any personal or family history of the condition.32,49 Although PRS testing for glaucoma was theoretically accepted, we identified a number of concerns and potential barriers to implementation, including residing in a rural location and unwillingness to pay for testing. There are a number of additional questions which must first be addressed before PRSs can be integrated into clinical practice.
Firstly, results must lead to actionable and cost-effective measures. Guidelines will be needed to clarify which PRS classifications warrant intervention. Those identified to be at high risk for developing glaucoma or AMD may receive more regular follow-up with an optometrist or ophthalmologist, allowing for timely treatment initiation. Treatment may be commenced before the disease becomes symptomatic. Early interventions for glaucoma may include topical IOP-lowering medication or laser therapy. Earlier surgical intervention may be considered for those with a PRS indicating a likelihood to progress rapidly or to advanced disease. While treatment options for early AMD are lacking, there are a large number of treatments under research including various pharmaceutical agents, gene therapies and surgical interventions.50 Antioxidant supplements based on the Age-Related Eye Disease Studies (AREDS) may have benefit in those with intermediate disease in one or both eyes to reduce the risk of progressing to late AMD, or in those with late stage disease in only one eye to reduce the risk of developing it in the other eye.51 Smoking is the only established modifiable risk factor for AMD, with the risk of progression to neovascular AMD shown to be double for those who had ever smoked.52 Despite there being few treatment options for AMD, risk factor modification and antioxidant supplementation may still be valuable interventions in high-risk individuals. Progression from early to advanced AMD may occur rapidly and result in severe vision loss if treatment is delayed. Using tools such as an Amsler grid, individuals who are recognised to be at higher risk of this occurring could be educated to self-monitor for progression, with a pathway to access rapid assessment if symptomatic. Conversely, PRS may prevent unnecessary follow-up or treatment in those presumed to be at higher risk based on traditional risk prediction models. This may improve the cost-effectiveness of the PRS.
Secondly, it will be critical to develop frameworks which allow PRS results to be reported and communicated in a meaningful manner. Pilot reports need to be developed and tested to assess communication preferences and understanding of reported results among different stakeholders, including patients and healthcare professionals. We have previously demonstrated that the preferred method of receiving results may depend on the result itself, so report content and structure will likely vary depending on risk classification.32,49 This study will form the foundations of future research to develop our understanding of the clinical implementation of PRS testing for glaucoma and AMD.
Finally, there are a number of health economic elements which need to be considered before implementing PRS into clinical practice. Population-based screening for glaucoma or AMD is not currently cost-effective, so public health frameworks need to be developed which allow identification of those at increased risk while also ensuring adequate access to further treatment. Disease prevention is at the forefront of public health policy, and polygenic risk stratification has the potential to enhance primary, secondary and tertiary facets of this. Ultimately, enhanced disease screening will minimise the personal and economic costs of significant vision loss. Improved risk stratification will alleviate workload created by over investigation and treatment of those at high risk calculated using traditional risk factors, but at low genetic risk. However, it will be important to integrate genetic risk with clinical or environmental risk factors. Individuals with a strong family history would still be recommended to have regular clinical testing, even if shown to have a low PRS, due to the influence of Mendelian variants or other factors not covered by the PRS. We have shown that financial implications appear to be important to people and while some are unwilling to pay for testing the majority of individuals would be prepared to pay varying amounts.32 Subsidisation may improve uptake, however will only be an option if it is cost-effective for the healthcare system which remains to be demonstrated.
Current PRSs for glaucoma or AMD are based on predominantly European populations and have not yet been comprehensively tested across other ethnicities. Individuals of non-European ancestry are not excluded from the study, although the accuracy of their risk predictions may be reduced. Better validation of a single pan-ancestry PRS, or ancestry-specific scores covering all ethnicities, are a major unmet need to avoid future health disparities.
In conclusion, this prospective study aims to demonstrate the clinical validity of PRS to stratify individuals from the general population and identify those who are at high risk of developing glaucoma or AMD. This will help to move towards the implementation of PRS into clinical practice and provide an objective screening tool for glaucoma and AMD. The ability to identify at-risk individuals will allow for closer monitoring and timely intervention, and ultimately reduce irreversible vision loss. Further studies will need to look into how PRS testing could alleviate some of the socioeconomic burden resulting from vision loss. The outcomes from this study will form the basis for future interventional studies to further enable a shift in the detection, treatment and prevention of diseases with complex inheritance.