Editorial

Corneal Cross-linking for Keratoconus: Exploring the
Issues Regarding Accelerated Protocols and Thin

Corneas

Farhad Hafezi, MD, PhD, FARVO1,2,3,4,5

1Ocular Cell Biology Group, Center for Applied Biotechnology and Molecular Medicine, University of Zurich, Switzerland
2ELZA Institute AG, Dietikon/Zurich, Switzerland

3Department of Ophthalmology, University of Southern California, Los Angeles, CA, USA
4Faculty of Medicine, University of Geneva, Geneva, Switzerland

5Department of Ophthalmology, Wenzhou Medical University, Wenzhou, China

ORCID:
Farhad Hafezi: https://orcid.org/0000-0001-8935-4558

J Ophthalmic Vis Res 2021; 16 (3): 314–316

The current issue of Journal of Ophthalmic and
Vision Research (JOVR) observes the publication of
two useful additions to the cross-linking literature:
an in vitro confocal microscopy (IVCM) evaluation
of structural changes that occur in thin keratoconic
corneas following corneal cross-linking (CXL),[1]
and an evaluation of accelerated versus standard
Dresden protocol CXL for treatment of progressive
keratoconus in Syria.[2]

It is worth briefly reviewing the history of CXL.
For over 20 years, CXL has been used for the
treatment of corneal ectatic disorders such as
keratoconus, and involves saturating the corneal
stroma with riboflavin, followed by a period of
ultraviolet (UV)-A irradiation to photoactivate the
riboflavin and cause it to covalently cross-link
molecules within the corneal stroma (principally
collagen, but also other molecules such as
glycoproteins) and strengthen the cornea with the
intention of halting the progression of ectasia.[3]
Epithelial cells at the surface of the cornea are
effective barriers against riboflavin penetration into
the stroma, therefore these cells are typically
debrided before riboflavin is applied (the “epi-off”
approach). The original CXL protocol, developed
20 years ago, called the Dresden protocol, is
an epi-off protocol that involves irradiation of a
riboflavin-saturated cornea with 30 min of UV-A
light at an intensity of 3 mW/cm².[4] This delivers
a total UV-A fluence (or “dose”) of 5.4 J/cm² and
is still considered to be the gold standard for
strengthening ectatic corneas.

Nevertheless, the Dresden protocol has a
number of drawbacks. For safety reasons and to

protect corneal endothelial cells from potentially
dangerous levels of UV-A exposure, only corneas
400 µm or thicker may be treated with the Dresden
protocol.[4] In addition, 30 min of UV-A irradiation is
a long period and therefore accelerated protocols
that increase the intensity of illumination with a
proportionate reduction in irradiation time have
been pursued. However, the discovery that oxygen
is an essential component of the cross-linking
phenomenon (and its diffusion into the stroma is a
rate-limiting step) explains why increased intensity-
reduced time irradiation protocols result in less
effective cross-linking.[5–8] The current consensus
is that the most reasonable trade-off lies around
10 min of 9 mW/cm² irradiation which still provides
most of the effect of the full 30 min irradiation
protocol while cutting treatment time to one-third.[8]

The article by Salman et al[2] published in
this issue of JOVR reports a trial that compared
an accelerated epi-off CXL irradiation protocol
(10 mW/cm² for 9 min) with the standard Dresden
protocol (3 mW/cm² for 30 min). Amongst the visual,
corneal tomographic and topographic factors
examined, the researchers noted that “this [was]
the first study to compare the impact of different
CXL protocols on posterior corneal astigmatism.”
They found that accelerated CXL resulted in
significantly greater anterior corneal flattening, a
greater increase in posterior steepening, a larger
decrease in posterior astigmatism, and a greater
reduction in minimum thickness than the standard
CXL protocol. They noted that both protocols
showed improvement in postoperative visual
acuity (VA) and higher order aberrations, but the

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CXL for KCN; Farhad Hafezi

accelerated CXL protocol resulted in significantly
better VA than the standard protocol.

Although this study was performed on a
relatively small sample (63 eyes, 40 patients), it
adds to the body of evidence that accelerated
CXL protocols might result in a greater flattening
effect than standard CXL protocols, which is an
encouraging finding indicating that accelerated
CXL protocols might offer visual rehabilitation
in subjects with ectatic corneas, as flattening is
associated with a reduction in ectasia-associated
myopia.

Corneal ectasias, however, can result in corneas
that are thinner than 400 µm, and if these cases
cannot be treated with CXL, they may ultimately
require keratoplasty. A number of approaches have
been taken to artificially thicken the cornea,[9]
either through swelling the cornea to a thickness
≥400 µm using hypotonic riboflavin prior to
and during UV-A irradiation[10] or through the
placement of a riboflavin-soaked contact lens to
artificially bulk the cornea.[11] Both approaches
have drawbacks, that is, less predictable or
suboptimal strengthening outcomes,[5] but can still
offer corneal strengthening and some level of
protection against later ectasia progression.

The IVCM paper by Sufi et al[1] offers some
insight on the use of hypertonic riboflavin to cross-
link thin corneas. In this paper, 10 eyes from 10
patients with progressive keratoconus and corneal
thickness ranging from 350 to 399 µm received
CXL with hypotonic riboflavin and were examined
by IVCM at postoperative months 1, 3, and 6.
The authors observed evidence of edema at one
month, which reduced gradually over the next
five months; that the subepithelial nerve plexus
was completely absent one month after CXL, but
regenerated gradually over the next five months
(albeit poorly in 2 out of 10 eyes); and stromal
keratocyte apoptosis in the anterior stroma in all
cases (which extended to the posterior stroma
in four eyes) with gradual repopulation over the
remainder of the study course. However, it was
clear that thin cornea CXL significantly decreased
the specular endothelial cell count by 8%, albeit
without signs of endothelial trauma.

The study by Sufi et al[1] is a small report
with its inherent limitations, but raises important
questions about the UV dose applied to thin
(<400 µm) corneas during cross-linking: there is
less tissue in these thin corneas, the increased
mass is simply 0.1% riboflavin solution. Although
riboflavin absorbs UV energy (and is consumed

during the process), it may be the case that the
tissue bulk in riboflavin-soaked corneas naturally
thicker than 400 µm absorbs more UV energy
and therefore shields the endothelial cells from
UV-A energy better than the relatively sparse
tissue in thin corneas artificially thickened by
hypotonic riboflavin solution. Fortunately, a newer
approach is now available that adjusts the total
fluence of UV-A based on immediate pre-irradiation
corneal thickness; the so-called sub400 protocol[12]
delivers a UV dose intended to avoid irradiating the
70 µm posterior stroma safety zone first defined in
the Dresden protocol without resorting to artificial
thickening approaches. The sub400 protocol can
even be used with the simplest first-generation
cross-linking machines by only altering the duration
of UV-A irradiation.

REFERENCES

1. Sufi ARS, Gohil MN, Keenan JD, Prajna NV. Structural
changes in thin keratoconic corneas following crosslinking
with hypotonic riboflavin: findings on in vivo confocal
microscopy. J Ophthalmic Vis Res 2021;16:325–337.

2. Salman AMDTR, Haddad YH, Shabaan RH, Askar MZ.
Accelerated versus standard corneal cross-linking for
progressive keratoconus in Syria. J Ophthalmic Vis Res
2021;16:338–348.

3. Randleman JB, Khandelwal SS, Hafezi F. Corneal cross-
linking. Surv Ophthalmol 2015;60:509–523.

4. Wollensak G, Sporl E, Seiler T. [Treatment of keratoconus
by collagen cross linking]. Ophthalmologe 2003;100:44–
49.

5. Kling S, Richoz O, Hammer A, Tabibian D, Jacob S, Agarwal
A, et al. Increased biomechanical efficacy of corneal cross-
linking in thin corneas due to higher oxygen availability. J
Refract Surg 2015;31:840–846.

6. Richoz O, Hammer A, Tabibian D, Gatzioufas Z, Hafezi F.
The biomechanical effect of corneal collagen cross-linking
(CXL) with riboflavin and UV-A is oxygen dependent.
Transl Vis Sci Technol 2013;2:6.

7. Torres-Netto EA, Kling S, Hafezi N, Vinciguerra P,
Randleman JB, Hafezi F. Oxygen diffusion may limit the
biomechanical effectiveness of iontophoresis-assisted
transepithelial corneal cross-linking. J Refract Surg
2018;34:768–774.

8. Hammer A, Richoz O, Arba Mosquera S, Tabibian D,
Hoogewoud F, Hafezi F. Corneal biomechanical properties
at different corneal cross-linking (CXL) irradiances. Invest
Ophthalmol Vis Sci 2014;55:2881–2884.

9. Deshmukh R, Hafezi F, Kymionis GD, Kling S, Shah R,
Padmanabhan P, et al. Current concepts in crosslinking
thin corneas. Indian J Ophthalmol 2019;67:8–15.

10. Hafezi F, Mrochen M, Iseli HP, Seiler T. Collagen
crosslinking with ultraviolet-A and hypoosmolar
riboflavin solution in thin corneas. J Cataract Refract
Surg 2009;35:621–624.

JOURNAL OF OPHTHALMIC AND VISION RESEARCH VOLUME 16, ISSUE 3, JULY-SEPTEMBER 2021 315



CXL for KCN; Farhad Hafezi

11. Jacob S, Kumar DA, Agarwal A, Basu S, Sinha P, Agarwal
A. Contact lens-assisted collagen cross-linking (CACXL):
a new technique for cross-linking thin corneas. J Refract
Surg 2014;30:366–372.

12. Hafezi F, Kling S, Gilardoni F, Hafezi N, Hillen M,
Abrishamchi R, et al. Individualized corneal cross-linking
with riboflavin and UV-A in ultrathin corneas: the Sub400
protocol. Am J Ophthalmol 2021;224:133–142.

Correspondence to:

Farhad Hafezi, MD, PhD, FARVO. ELZA Institute,
Webereistrasse 2, 8953 Dietikon, Switzerland.
Email: farhad@hafezi.ch
Received: 20-05-2021 Accepted: 29-04-2021

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DOI: 10.18502/jovr.v16i3.9425

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How to cite this article: Hafezi F. Corneal Cross-linking for Keratoconus:
Exploring the Issues Regarding Accelerated Protocols and Thin Corneas. J
Ophthalmic Vis Res 2021;16:314–316.

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