The recent introduction of accelerated cross-linking (CXL) has sparked a great amount of interest in the ophthalmic community. CXL causes corneal stromal collagen fibre stiffening through photopolymerisation of riboflavin.1, 2 The settings of conventional CXL, as per Dresden protocol, are 3 mW/cm2 irradiance from a 370-nm light source to illuminate the riboflavin-treated eye for 30 min leading to a cumulative dose of 5.4 J/cm2.3 The concept of accelerated CXL is based on the Bunden–Roscoe reciprocity law,4 where an overall cumulative dose of 5.4 J/cm2 is achieved with treatment parameters set at higher intensity and simultaneous reduction in exposure time. In accordance with this, animal studies found that an equivalent corneal stiffness increase to conventional CXL can be achieved with illumination intensity of up to 40–45 mW/cm2, corresponding to illumination times of ∼2 min.5 Although the Bunden–Roscoe reciprocity law may be valid for a certain dose range and therefore a true linear relationship between dose and time is unlikely to exist, the radicals that generate the cross-links are formed in a shorter period of time when the radiation intensity is increased from 3 to 10 mW/cm2.6 Initial studies, performed on porcine eyes, showed that accelerated CXL performed at 10 mW/cm2 for 9 min was equivalent to conventional CXL in biomechanical stiffness.6, 7

When the cornea is treated with conventional CXL a demarcation line is seen at ∼300 μm.8, 9 This demarcation line, seen in anterior segment optical coherence tomography (AS-OCT), demonstrates the depth of treatment with the corneal stroma lying anterior to this demarcation line that has been cross-linked and hence strengthened. Although keratoconus, at least during its early stages, is a predominantly posterior corneal disease, it is thought to be the anterior weaker stroma that needs to be strengthened to halt disease progression and subsequent ectasia. It is precisely this part of the cornea that is treated and stiffened with accelerated CXL, as a demarcation line is seen with AS-OCT at an average depth of 100–150 μm.10 In addition, the fact that the photodynamic reaction is limited to the anterior 100–150 μm of the cornea enables treatment, at least in theory, of thin corneas (<400 μm) whose treatment is not routinely advisable with standard conventional CXL. Accelerated CXL would allow treatment of a considerably larger amount of patients compared with the conventional CXL.

Log in or create a free account to read this content

Gain free access to this article, as well as selected content from this journal and more on nature.com

Access through your institution

or

Sign in or create an account
Continue with Google
Continue with ORCiD