Jos J Rozema1,2, Sarah Hershko1,2, Marie-José Tassignon1,2. 1. Department of Ophthalmology, Antwerp University Hospital, Edegem, Belgium. 2. Department of Medicine and Health Sciences, University of Antwerp, Wilrijk, Belgium.
Abstract
PURPOSE: To study the corneal and internal astigmatism and the age-related changes underlying the known refractive shift with-the-rule (WTR) towards against-the-rule (ATR) astigmatism. METHODS: Refractive and corneal biometry data were collected for a total of 1195 healthy Caucasian subjects, recruited by ophthalmological centres across Europe. After conversion of refractive and corneal surface astigmatism to power vectors J0 and J45 , the total corneal and internal astigmatism were calculated. RESULTS: Both refractive power vectors had leptokurtic distributions with a narrow peak at zero, and a broader, secondary distribution at its base, corresponding to eyes without balanced components. This may be fitted with a bigaussian function (J0 : r² = 0.87; J45 : r² = 0.98). Statistically significant changes in these distributions are seen with age: for refractive J0 the narrow peak shortens progressively, while the broad peak shifts positive from to negative values, corresponding to increased astigmatism and a shift from with-the-rule towards against-the-rule. For J45 the narrow peak shortens with age as well, while the broad peak flattens. These changes in refractive J0 result from statistically significant negative shifts in both the corneal and internal components with age (Kruskal-Wallis, p < 0.05). CONCLUSION: In young participants corneal and internal astigmatism partially cancel each other out. This balance between both is gradually lost after age 50, leading to larger amounts of refractive astigmatism, as well as a reorientation of the axis. Given the small amplitude of these changes, they are unlikely to have repercussions for long term stability toric cataract or refractive surgery outcomes.
PURPOSE: To study the corneal and internal astigmatism and the age-related changes underlying the known refractive shift with-the-rule (WTR) towards against-the-rule (ATR) astigmatism. METHODS: Refractive and corneal biometry data were collected for a total of 1195 healthy Caucasian subjects, recruited by ophthalmological centres across Europe. After conversion of refractive and corneal surface astigmatism to power vectors J0 and J45 , the total corneal and internal astigmatism were calculated. RESULTS: Both refractive power vectors had leptokurtic distributions with a narrow peak at zero, and a broader, secondary distribution at its base, corresponding to eyes without balanced components. This may be fitted with a bigaussian function (J0 : r² = 0.87; J45 : r² = 0.98). Statistically significant changes in these distributions are seen with age: for refractive J0 the narrow peak shortens progressively, while the broad peak shifts positive from to negative values, corresponding to increased astigmatism and a shift from with-the-rule towards against-the-rule. For J45 the narrow peak shortens with age as well, while the broad peak flattens. These changes in refractive J0 result from statistically significant negative shifts in both the corneal and internal components with age (Kruskal-Wallis, p < 0.05). CONCLUSION: In young participantscorneal and internal astigmatism partially cancel each other out. This balance between both is gradually lost after age 50, leading to larger amounts of refractive astigmatism, as well as a reorientation of the axis. Given the small amplitude of these changes, they are unlikely to have repercussions for long term stability toric cataract or refractive surgery outcomes.