Abstract
Riboflavin/UVA-induced corneal collagen cross-linking has become an effective clinical application to treat keratoconus and other ectatic disorders of the cornea. Its beneficial effects are attributed to a marked stiffening of the unphysiologically weak stroma. Previous studies located the stiffening effect predominantly within the anterior cornea. In this study, we present an atomic force microscopy-derived analysis of the depth-dependent distribution of the Young's modulus with a depth resolution of 5 µm in 8 cross-linked porcine corneas and 8 contralateral controls. Sagittal cryosections were fabricated from every specimen and subjected to force mapping. The mean stromal depth of the zone with effective cross-linking was found to be 219±67 µm. Within this cross-linked zone, the mean Young's modulus declined from 49±18 kPa at the corneal surface to 46±17 kPa, 33±11 kPa, 17±5 kPa, 10±4 kPa and 10±4 kPa at stromal depth intervals of 0–50 µm, 50–100 µm, 100–150 µm, 150–200 µm and 200–250 µm, respectively. This corresponded to a stiffening by a factor of 8.1 (corneal surface), 7.6 (0–50 µm), 5.4 (50–100 µm), 3.0 (100–150 µm), 1.6 (150–200 µm), and 1.5 (200–250 µm), when compared to the Young's modulus of the posterior 100 µm. The mean Young's modulus within the cross-linked zone was 20±8 kPa (2.9-fold stiffening), while it was 11±4 kPa (1.7-fold stiffening) for the entire stroma. Both values were significantly distinct from the mean Young's modulus obtained from the posterior 100 µm of the cross-linked corneas and from the contralateral controls. In conclusion, we were able to specify the depth-dependent distribution of the stiffening effect elicited by standard collagen cross-linking in porcine corneas. Apart from determining the depth of the zone with effective corneal cross-linking, we also developed a method that allows for atomic force microscopy-based measurements of gradients of Young's modulus in soft tissues in general.
Highlights
Keratoconus and other forms of corneal ectasia represent refractive pathologies of the eye characterized by a marked protrusion of the cornea [1,2,3,4]
Unfixed sagittal cryosections with a thickness of 16 mm were fabricated from every sample, mounted on HistobondH+ adhesion microscope slides (Paul Marienfeld GmbH & CoKG, Lauda-Konigshofen, Germany) and kept frozen until atomic force microscopy (AFM) analysis
In all non-cross-linked control eyes, the Young’s modulus (YM) followed a lognormal distribution (Figure 2C). Such a distribution has been found for other types of tissue [32,33,34]
Summary
Keratoconus and other forms of corneal ectasia represent refractive pathologies of the eye characterized by a marked protrusion (i.e. outward bulging) of the cornea [1,2,3,4]. The exact molecular processes involved in CXL are largely unknown, covalent bond formation due to UVA-induced radical ions and singlet oxygen seems to play a central role [19,20,21,22]. It has been shown, that classical CXL predominantly strengthens the anterior stroma, while having no significant effect on the posterior cornea [23,24,25]. The only measurements available at present allowing for a deduction of biomechanical depth profiles throughout the entire stroma stem from confocal Brillouin microscopy [24,27]
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