Comparing the Fit and Performance of Scleral Lenses With Oval and Circular Limbal Zones (CHIMERA)

Scleral lenses are large diameter rigid contact lenses with a wide range of clinical applications. Traditionally, scleral lenses are used for visual rehabilitation of patients with irregular corneas, such as patients with keratoconus or corneal scarring. In these patients, scleral lenses are the mainstay of treatment, as they significantly improve visual acuity and quality. Recently, scleral lenses have gained popularity amongst patients without corneal abnormalities for their ability to correct high prescriptions and provide relief from dry eye symptoms. Scleral lenses are a growing field of interest in eye care, and many new technologies have emerged in recent years to assist with scleral lens fitting.

Fitting scleral lenses, however, is not without challenges, and currently available scleral lens fitting strategies may not be adequate for the long-term needs of all patients. In particular, fitting of scleral lenses over the limbal area is known to be suboptimal. The limbus is the transitional area between the clear cornea and the white sclera. It contains numerous limbal stem cells crucial to maintaining long-term corneal health. Currently, the majority of contemporary scleral lens designs only involve a uniform circular-shaped area to fit over the limbus. However, several reports have recently shown that the human limbus is of an oval rather than a circular shape. Furthermore, there is currently limited information on the elevation/height of the limbal zone, including whether the height of the limbal zone is the same or different in each quadrant and whether this should be compensated for in lens design and fitting. The mismatch between the limbal zone design in a scleral lens and the true limbal shape leads to inappropriate fit of scleral lenses in the limbal area: typically, there can be excessive and inadequate clearance over the limbus in different parts of the same eye. Excessive and inadequate clearance both cause stress to the limbal stem cells, which is hypothesized to compromise patient comfort and risk the health of the cornea long-term.

To enhance lens comfort and minimize the risk of compromising ocular health, scleral lenses must be designed with an accurate understanding of the limbus's shape and dimensions. Achieving this requires a reliable and efficient method for capturing and analyzing limbal data. One such method involves a computational approach that uses Zernike polynomial-based modeling to identify limbal points on a corneoscleral topography scan, a technique previously validated on model eye scans. The proposed study will evaluate the performance of scleral lenses with oval versus circular limbal zones, using limbal width measurements obtained through a customized MATLAB program based on this method. The hypothesis is that when compared to scleral lenses designed with a standard, circular, non-customized limbal zone, scleral lenses with an oval limbal zone may result in more even limbal clearance 360, which leads to less corneal observations (e.g. corneal staining, corneal microcysts) related to scleral lens fit issues in the limbal area (e.g. limbal congestion, limbal touch, conjunctival prolapse), less lens decentration and better subjective comfort when worn.

The study lenses are marketed and commercially available in Canada.