Analysis of the results of modified personalized topographically and tomographically oriented technique of ultraviolet corneal collagen crosslinking

Abstract

The study aims to develop a modified personalized topographically and tomographically oriented technique of ultraviolet corneal collagen cross-linking (UVCXL) to affect the area of the cornea with weakest biomechanical properties as determined by mathematical modeling. Modeling of the biomechanics of keratoconic cornea under conditions of external diagnostic action was done using COMSOL Multiphysics® software. Finite-element analysis procured 3D images of stress/deformation distribution pattern throughout the cornea. Matching these 3D images with primary topographic and tomographic Pentacam AXL maps and Corvis ST findings allowed determining localization and dimensions of impaired regions of the cornea. The acquired data helped develop the modified corneal collagen cross-linking technique, which was applied in the treatment of 36 persons (36 eyes) with degrees I and II keratoconus. Uncorrected and best-corrected visual acuity (UCVA and BCVA logMAR) in all patients after modified UVCXL increased after the follow-up period lasting 6-12 months by 0.2±0.19 (23%) and 0.1±0.14 (29%) (p<0.05), respectively, in comparison with preoperative values. Maximum keratometry (Kmax) decreased by 1.35±1.63% (3%; p<0.05) in all cases at 6-12 months follow-up. Improvement of corneal biomechanical strength was determined by statistically significant increase in corneal stiffness index (SP-A1) and corneal stress-strain index (SSI) measured with Pentacam AXL and Corvis ST at 6-12 months follow-up by 15.1±5.04 (18%) and 0.21±0.20 (23%) (p<0.05), respectively. Effectiveness of the developed UVCXL technique is also confirmed by the appearance of a characteristic morphological marker - «demarcation line» at the cross-linking site in keratoconus projection at the depth of 240±10.2 µm. The developed personalized topographically and tomographically oriented UVCXL technique provides an evident stabilizing effect on the cornea in the form of an increase in its biomechanical strength, improvement of clinical, functional indicators and safety of keratoconus treatment.