The purpose of this study is to determine whether individualized, topography-based corneal crosslinking for keratoconus can improve the optical outcomes of the treatment.
The study is designed as a prospective, open label, randomized controlled trial involving patients aged 12 years or older of both genders with uni- or bilateral keratoconus planned for routine corneal crosslinking (CXL) at the Department of Clinical Sciences / Ophthalmology, Umeå University Hospital, Umeå, Sweden. The study involves 25+25 eyes with keratoconus, which are randomized to receive either conventional pulsed crosslinking with a uniform, universal 8 mm treatment pattern of 5.4 J/cm2 (pCXL; n=25), or a modified treatment - individualized topography-based corneal crosslinking (KXL2; n=25). In the latter treatment zone has an individualized arcuate shape and spares a 2 mm central optical zone. The size of the treatment zone is based on Pentacam HR® corneal tomography, and is determined by the transition zone where the corneal curvature drops off by ≥2D. The energy distribution is based on the maximum corneal steepness (Kmax) value retrieved from the Pentacam HR® tomography: ≤47.0D - 7.2 J/cm2; 47.1-52.0D - 10 J/cm2; ≥52.1D - 15 J/cm2. Thus, the thin protruding areas of the cornea are crosslinked, whereas the parts with a more normal shape are not. The aim is to potentially improve the optical outcome after the treatment. Patients are randomized to either of the two treatment arms utilizing a computer list of unique random numbers between 1 and 50; an even number will be treated with KXL2 and an uneven number with pCXL. Bilateral inclusion is allowed, and the second eye to be treated will be assigned to the other group, i.e. eye number two will not get the same treatment as eye number 1. All patients are informed about the procedures and provide oral and written consent before inclusion in the study. At baseline, before treatment, each eye is evaluated with autorefractometer measurement (Oculus Parc-1®), uncorrected and best spectacle-corrected LogMAR visual acuity, Oculus Pentacam HR® Scheimpflug photography, Oculus CorVis® high-speed Scheimpflug photography, corneal endothelial photography with a specular microscope camera, Goldmann applanation tonometry and biomicroscopy. For the Pentacam HR® rotating Scheimpflug camera, each eye is photographed using the "25 pictures" program under standardized, mesopic light conditions. Multiple variables will be analyzed, and individual photographs also will be analyzed manually for light backscatter and for the occurrence of a demarcation line, by a masked observer. The corneal biomechanical characteristics are assessed with data from the Oculus CorVis®, and corneal endothelial morphometry, including endothelial cell density is assessed manually and automatically from specular microscopy photographs taken with the Topcon SP-2000 endothelial camera. All investigations are repeated at 1 month, 3 months, 6 months and 12 months after the treatment.
Study Type
INTERVENTIONAL
Allocation
RANDOMIZED
Purpose
TREATMENT
Masking
NONE
Enrollment
50
The keratoconus cornea is treated with epithelial debridement in local anesthesia, and then soaked in Riboflavin by repeated topical application every 3 minutes during 10 minutes. The cornea is then irradiated with pulsed ultraviolet light (1s on/1s off) in a topography-based arcuate shape with the Avedro KXL2® with an energy from 7.2-15.0 J/cm2 depending on the severity of the keratoconus.
The keratoconus cornea is treated with epithelial debridement in local anesthesia, and then soaked in Riboflavin by repeated topical application every 3 minutes during 10 minutes. The cornea is then irradiated with pulsed ultraviolet light (1s on/1s off) in a central round 8mm zone with the Avedro KXL2® with an energy of 5.4 J/cm2.
Change from baseline in refraction
Change from baseline in refractive errors, including lower and higher order aberrations in the cornea.
Time frame: 1, 3, 6 and 12 months after the treatment
Change from baseline in ETDRS LogMAR visual acuity
Changes from baseline in uncorrected and best spectacle corrected visual acuity assessed with the Early Treatment Diabetic Retinopathy Study (ETDRS) protocol, graded in logarithmic values of the minimal angle of resolution.
Time frame: 1, 3, 6 and 12 months after the treatment
Change from baseline in corneal densitometry
Change from baseline in corneal densitometry (corneal light backscatter), assessed with the Oculus Pentacam HR® rotating Scheimpflug camera. assessed with the Early Treatment Diabetic Retinopathy Study (ETDRS) protocol, graded in logarithmic values of the minimal angle of resolution.
Time frame: 1, 3, 6 and 12 months after the treatment
Change from baseline in corneal biomechanical stability measured with GAT
Change from baseline in biomechanical stability assessed with the Goldmann applanation tonometer (GAT).
Time frame: 1, 3, 6 and 12 months after the treatment
Change from baseline in corneal biomechanical stability measured with CorVis®
Change from baseline in biomechanical stability assessed with the Oculus CorVis high-speed Scheimpflug camera.
Time frame: 1, 3, 6 and 12 months after the treatment
Change from baseline in corneal endothelial morphometry
Change from baseline in corneal endothelial morphometry, including cell density.
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Riboflavin is added topically immediately before the treatment every 3 minutes during 10 minutes in the eye to be treated
The KXL II™ System crosslinking device from Avedro, Inc. is used for ultraviolet irradiation of the cornea after riboflavin application in both treatment arms.
Time frame: 1, 3, 6 and 12 months after the treatment