Abstract
Purpose
To evaluate the efficacy of transepithelial corneal collagen crosslinking (TE-CXL) in patients with progressive keratoconus.
Patients and methods
This is a prospective interventional consecutive study carried out on 30 eyes of 18 patients with progressive keratoconus who underwent TE-CLX using both ParaCel™ (riboflavin 0.25%, hydroxy propyl methyl cellulose, NaCl, ethylenediaminetetraacetic acid [EDTA], Tris, and benzalkonium chloride) and vibeX-Xtra (riboflavin 0.22%, phosphate-buffered saline solution). The procedure was carried out at Ebsar Eye Center in Egypt in the period from 2012 to 2014. The follow-up visits were scheduled on days 1, 3, 6, and 12 months after treatment.
Results
There were statistically significant improvements (P<0.001) in the mean best-corrected visual acuity (0.54±0.22 preoperatively vs 0.61±0.19 at 12 months postoperatively), the mean manifest refraction spherical equivalent (MRSE; −6.16±3.90 diopters [D] preoperatively and −5.91±3.72 D at 12 months postoperatively), and the mean preoperative corneal astigmatism (−3.39±2.11 D preoperatively and −2.46±2.60 D at 12 months postoperatively).
Conclusion
TE-CXL could halt the progression of keratoconus in adult patients. TE-CXL resulted in a statistically significant improvement in best-corrected visual acuity, manifest refraction, refractive and corneal astigmatism and K values in keratoconus patients at the 12-month follow-up. Larger sample sizes and longer follow-ups are required in order to make meaningful conclusions.
Introduction
Keratoconus is the most common cause of primary keratectasia, which usually occurs bilaterally during puberty and progresses until the mid-age.Citation1,Citation2
Conventional treatment for keratoconus includes rigid contact lens, intracorneal ring segments, and penetrating keratoplasty. In recent years, the objectives of treatment were not only improvement of visual acuity but also preventing disease progression.Citation3
Corneal collagen crosslinking (CXL) aided by photosensitized riboflavin helps stabilize progressive keratoconus and may delay the need for keratoplasty.Citation4
CXL is the only treatment option that focused on disease pathology and increasing the biomechanical rigidity of the cornea.Citation5,Citation6
Epithelial debridement was conventionally done before exposing the corneal stroma to ultraviolet-A (UVA), which enhances the stromal penetration of photo-activated riboflavin. Debriding the corneal epithelium increases the risk of infection, sub-epithelial haze, sterile corneal infiltrates, corneal scarring, and endothelial damage.Citation1,Citation7–Citation10
Transepithelial (TE) technique has been introduced to combine the advantages of the conventional technique in addition to maintaining a higher safety profile.Citation11,Citation12
Our aim in this study is to evaluate the efficacy of TE-CLX in the treatment of keratoconus patients after 12-month follow-up.
Patients and methods
This is a prospective interventional consecutive study carried out on 30 eyes of 18 patients with progressive keratoconus who underwent TE-CLX. The procedure was carried out at Ebsar eye center in Egypt in the period from 2012 to 2014.
Inclusion criteria: patients with progressive keratoconus who have changes of ≥1.00 diopters (D) in the steepest keratometry (K) measurement over 12 months, keratometry between 47 and 55 D, and corneal thinnest point (CTP) >400 µm.
Exclusion criteria: previous history of corneal surgery or chemical injury and patients with CTP <400 µm.
All the patients had preoperative evaluation including manifest best-corrected visual acuity (BCVA; decimal), spherical equivalent, slit-lamp biomicroscopy, CTP, and corneal topographic analysis (K max and K astigmatism) using Scheimpflug corneal tomography (OCULUS Pentacam®; OCULUS Inc., Berlin, Germany).
Preoperative written informed consent was obtained from the patients. Written informed consent to publish the data of this paper was also obtained from the patients. This research has been approved by the Ebsar Eye Center Institutional Review Board.
The procedure
The procedure was carried out under strict aseptic conditions, through intact corneal epithelium. Benoxinate (0.04%) anesthetic drops were instilled twice, every 5 minutes. Sufficient amount of ParaCel™ (riboflavin 0.25%, hydroxy propyl methyl cellulose [HPMC], NaCl, ethylenediaminetetraacetic acid [EDTA], Tris, and benzalkonium chloride [BAC]) was applied to completely cover the cornea.
This procedure was repeated every 90 seconds for a total of 4 minutes. The cornea was then rinsed with vibeX-Xtra (riboflavin 0.22%, phosphate-buffered saline solution).
Sufficient vibeX-Xtra was applied to completely cover the cornea. This procedure was repeated every 90 seconds for a total of 5 minutes. Slit-lamp verification of the stromal saturation was done before the UVA radiation.
The UV treatment was then initiated using Xlink system (OptoXLink, Opto Global Pty Ltd, Adelaide, Australia) at 3 mW/cm2 for 30 minutes. The size of the treatment beam should be the largest possible but smaller than limbus diameter to avoid destruction of corneal stem cells.
Under the UV treatment, vibeX-Xtra was applied every 5 minutes during irradiation until the end of the procedure. The cornea then rinsed with balanced salt solution (BSS).
Postoperative care
Antibiotic eye drops (tobramycin 0.3%) and topical steroids eye drops (fluorometholone 0.1%) were given 5 times daily for 2 weeks with tapering of corticosteroid eye drops over another 2 weeks. Artificial eye drops were given for 3 months.
Follow-up of the patient was scheduled for day 1 and day 7 postoperatively and subsequently at 3, 6, and 12 months postoperatively.
BCVA, spherical equivalent, corneal topography, and CTP were documented at each follow-up visit.
Statistical analysis
Statistical analysis was performed to compare the postoperative data with the preoperative data using the paired t-test with IBM Statistical Package for the Social Sciences (SPSS) Statistics v19.0 (IBM, Armonk, NY, USA). P<0.05 was considered statistically significant.
Results
Thirty eyes of 18 patients with a mean age of 25.2±6.19 years, ranged (17–38 years), were enrolled in this prospective clinical study. The 30 eyes with progressive keratoconus had TE-CXL treatment and were followed-up for 12 months.
Functional results after TE-CXL
The preoperative mean BCVA was 0.54±0.227. At 3 months postoperatively the mean BCVA was 0.54±0.21, at 6 months postoperatively the mean BCVA was 0.60±0.20, and was 0.61±0.19 at 12 months postoperatively ().
Figure 1 Mean best-corrected visual acuity (BCVA) in decimal pre- and post-transepithelial corneal crosslinking in keratoconus patients.
The mean BCVA improved significantly at 3, 6, and 12 months postoperatively (P<0.05). At 12 months postoperatively, the mean BCVA improved by one or more Snellen lines in 63.33% (19 eyes), remained stable in 26.66% (8 eyes), and 3 eyes (10%) lost 1 Snellen line.
Refractive changes after TE-CXL
The preoperative mean manifest refraction spherical equivalent (MRSE) was −6.16±3.90. At 3 months postoperatively, it was −5.85±3.82. At 6 months postoperatively, it was −5.69±3.78. At 12 months postoperatively, it was −5.91±3.72 ().
Figure 2 Mean MRSE in diopter (D) pre- and posttransepithelial corneal crosslinking in keratoconus patients.
There was statistically significant improvement in the mean MRSE at 3, 6, and 12 months postoperatively (P<0.05).
Preoperatively, the mean refractive astigmatism was −3.01±2.64. At 3 months postoperatively, it was −2.83±2.72. At 6 months postoperatively, it was −2.27±2.35. At 12 months postoperatively, it was −2.46±2.60 ().
Figure 3 Mean refractive astigmatism in diopter (D) pre- and posttransepithelial corneal crosslinking in keratoconus patients.
The mean preoperative refractive astigmatism was statistically significant difference from postoperative visit (P<0.05).
The mean refractive astigmatism improved by −1.00 D or more in 5 eyes (16.66%), changed between −0.5 D and −1 D in 19 eyes (63.33%) and remained stable in 6 eyes (20%).
Topography changes after TE-CXL
The preoperative mean K maximum was 49.81±3.79. At 3 months postoperatively, it was 49.22±3.65. At 6 months postoperatively, it was 48.74±3.81. At 12 months postoperatively, it was 48.86±3.94.
There was a significant decrease in the mean K maximum value between preoperative and 12 months postoperative follow-up (P<0.05). There was also a significant decrease in the mean K maximum at 3 and 6 months, respectively (P<0.05).
The mean K maximum value decreased by 1 D or more in 23 eyes (76.66%), remained unchanged in 4 eyes (13.33%) and increased by 1 D in 3 eyes (10%).
The preoperative mean K was 46.42±3.08. At 3 months postoperatively, it was 45.92±3.02. At 6 months postoperatively, it was 45.9±3.09. At 12 months postoperatively, it was 45.68±3.19.
There was a significant decrease in the mean K value at 12 months postoperatively (P<0.05). The mean K value decreased by 1 D in 19 eyes (63.33%) and remained unchanged in 7 eyes (23.33%) and it increased by 1 D in 4 eyes (13.33%).
The preoperative mean corneal astigmatism was 3.39±2.11. At 3 months postoperatively, it was 3.25±2.18. At 6 months postoperatively, it was 2.80±1.67. At 12 months postoperatively, it was 3.003±1.93.
Changes in the mean corneal astigmatism at 3 months postoperatively were statistically insignificant (P>0.05). However, the changes in the mean corneal astigmatism at 6 and 12 months postoperatively were statistically significant (P<0.05; ).
Figure 4 Mean corneal astigmatism in diopter (D) pre- and posttransepithelial corneal crosslinking in keratoconus patients.
The preoperative mean corneal thickness at thinnest local was 473.16±43.69. At 1 month postoperatively, it was 443.06±45.24. At 3 months postoperatively, it was 458.24±46.83. At 12 months postoperatively, it was 457.67±40.10.
The mean CTP at 3, 6, and 12 months postoperatively was statistically significant changed (P<0.05). After TE-CXL, CTP thins and then recovered toward the preoperative thickness.
Discussion
CXL is one of the most recent treatments that halts the progression of keratoconus. It strengthens the cornea by covalently crosslinking the collagen fibers and increases rigidity by 300%.Citation13
The epithelial-off procedure is effective in increasing corneal stiffness,Citation6 stabilization of keratoconus, and in some cases in improving the refractive and topographic features,Citation14,Citation15 but may lead to serious complications, such as infection,Citation16,Citation17 stromal haze,Citation18 and corneal melting.Citation19
Epithelium-on or TE-CXL, which keeps the epithelial intact, has been introduced by Boxer et al.Citation20
Several approaches have been introduced to improve the efficacy of penetration of riboflavin through the epithelium, which is impermeable to riboflavin because of its high molecular weight (>100 Da).Citation21
The replacement of the isotonic by hypotonic riboflavin solution has been introduced to increase the penetration of riboflavin through the intact epithelium.Citation22 Other approaches such as BAC,Citation23 trometamol, EDTA,Citation24 tetracaine,Citation25 ethanol,Citation26 partial grid-like pattern de-epithelialization,Citation26 and excimer laser superficial epithelial removalCitation27 were applied.
This is a prospective interventional consecutive study carried out on 30 eyes of 18 patients with a mean age of 25.2±6.19 years, ranged from 17 to 38 years.
The included eyes had progressive keratoconus and underwent TE-CXL treatment using combination of ParaCel™ (riboflavin 0.25%, HPMC, NaCl, EDTA, Tris, and BAC) and vibeX-Xtra (riboflavin 0.22%, phosphate-buffered saline solution). Follow-up at 12 months postoperatively was recorded.
There was a significant improvement of more than one line of mean BCVA at 12 months postoperatively.
Nineteen eyes (63.33%) gained one or more Snellen lines of BCVA, 8 eyes remained stable (26.66%), and only 3 eyes (10%) lost 1 line of BCVA postoperatively.
Caporossi et alCitation28 reported no statistically significant increase in uncorrected distance visual acuity (UDVA) and BCVA in the first 3 months in cases of keratoconus that were treated with TE-CXL, while Stojanovic et alCitation11 reported no cases with a loss of ≥2 lines of BCVA.
Koppen et alCitation29 reported a statistically significant improvement in BCVA at 6 and 12 months in the TE-CLX group. Bernardo et alCitation30 showed significant increase in BCVA in 36 eyes with progressive keratoconus that were treated with TE-CLX after 6 months of follow-up.
In our study, there was a statistically significant improvement in the MRSE at 12 months postoperatively.
In our study, the mean refractive astigmatism improved by 1.00 D or more in 5 eyes (16.66%), changed between −0.5 and −1 D in 19 eyes (63.33%), and remained stable in 6 eyes (20%).
Our result is similar to the study by Koppen et alCitation29 that recorded significant improvement in the mean refractive astigmatism in the TE-CLX group.
The mean K maximum value decreased by 1 D or more in 23 eyes (76.66%), remained unchanged in 4 eyes (13.33%), and increased by 1 D in 3 eyes (10%).
Stojanovic et alCitation11 reported significant decrease in the K maximum without changes in the mean K, while Soeters et alCitation31 reported increase of K maximum more than 1 D after 1 year (range 1.3–5.4 D) in 23% of TE group.
Changes in the CTP at 3, 6, and 12 months postoperatively were statistically significant reduced, but they recovered toward the preoperative values in our study (P<0.05).
Bernardo et alCitation30 did not report statistically significant changes in the mean corneal thickness at the thinnest point, while another study reported statistically significant reduction of corneal thickness at the thinnest point.Citation32
Previous studies evaluated the anterior chamber depth and anterior chamber value in cases of keratoconus that were treated with CXL. They reported no statistically significant changes in the postoperative value as compared preoperatively.Citation30,Citation32
There were no complications recorded in our study. Analysis of the results of our study showed that TE-CLX could halt the progression of keratoconus in adult patients.
The main drawbacks of our study are lack of control group and the need of longer follow-up of patients.
Conclusion
TE-CXL could halt the progression of keratoconus in adult patients. TE-CXL resulted in a statistically significant improvement in BCVA, manifest refraction, refractive and corneal astigmatism, and K values in keratoconus patients at the 12-month follow-up. Larger sample sizes and longer follow-ups are required to make meaningful conclusions.
Acknowledgments
This work was self-funded by the authors.
Disclosure
The study was performed at Ebsar Eye Centre, Benha, Egypt. This study was presented as a poster in European Society of Cataract & Refractive Surgery (ESCRS) 2015. The authors report no conflicts of interest in this work.
References
- KennedyRHBourneWMDyerJAA 48-year clinical and epidemiologic study of keratoconusAm J Ophthalmol198610132672733513592
- AbbeyAMYooSHAnatomy, physiology, and molecular biologyWangMSwartzTSKeratoconus and Keratoectasia: Prevention, Diagnosis, and TreatmentThorofare, NJSLACK2010312
- JhanjiVSharmaNVajpayeeRBManagement of keratoconus: current scenarioBr J Ophthalmol20119581044105020693553
- HovakimyanMGuthoffRFStachsOCollagen cross-linking: current status and future directionsJ Ophthalmol2012201240685022288005
- WollensakGCrosslinking treatment of progressive keratoconus: new hopeCurr Opin Ophthalmol200617435636016900027
- WollensakGSpoerlESeilerTRiboflavin/ultraviolet-a induced collagen crosslinking for the treatment of keratoconusAm J Ophthalmol2003135562062712719068
- SpoerlEHoyerAPillunatLERaiskupFCorneal cross-linking and safety issuesOpen Ophthalmol J20115141621399770
- DhawanSRaoKNatrajanSComplications of corneal collagen cross-linkingJ Ophthalmol2011201186901522254130
- KymionisGDPortaliouDMBouzoukisDIHerpetic keratitis with iritis after corneal crosslinking with riboflavin and ultraviolet A for keratoconusJ Cataract Refract Surg200733111982198417964410
- WollensakGIomdinaEBiomechanical and histological changes after corneal crosslinking with and without epithelial debridementJ Cataract Refract Surg200935354054619251149
- StojanovicAChenXJinNSafety and efficacy of epithelium-on corneal collagen cross-linking using a multifactorial approach to achieve proper stromal riboflavin saturationJ Ophthalmol2012201249843522900147
- SuriKHammersmithKMNagraPKCorneal collagen cross-linking: Ectasia and beyondCurr Opin Ophthalmol201223428028722569470
- SpörlEHuhleMKasperMSeilerTArtificial stiffening of the cornea by induction of intrastromal cross-linksDer Ophthalmologe19979412902906 German9487761
- CaporossiABaiocchiSMazzottaCTraversiCCaporossiTPara-surgical therapy for keratoconus by riboflavin-ultraviolet type A rays induced cross-linking of corneal collagen: preliminary refractive results in an Italian studyJ Cataract Refract Surg200632583784516765803
- GrewalDSBrarGSJainRSoodVSinglaMGrewalSPSCorneal collagen crosslinking using riboflavin and ultraviolet-A light for keratoconus: one-year analysis using Scheimpflug imagingJ Cataract Refract Surg200935342543219251133
- ZamoraKVMalesJJPolymicrobial keratitis after a collagen cross-linking procedure with postoperative use of a contact lens: a case reportCornea200928447447619411973
- Pérez-SantonjaJJArtolaAJavaloyJAlióJLAbadJLMicrobial keratitis after corneal collagen crosslinkingJ Cataract Refract Surg20093561138114019465303
- MazzottaCBalestrazziABaiocchiSTraversiCCaporossiAStromal haze after combined riboflavin-UVA corneal collagen cross-linking in keratoconus: in vivo confocal microscopic evaluationClin Exp Ophthalmol200735658058217760642
- EberweinPAuw-HädrichCBirnbaumFMaierPCReinhardTCorneal melting after cross-linking and deep lamellar keratoplasty in a keratokonus patientKlin Monbl Augenheilkd200822519698 German18236379
- Boxer WachlerBSPinelliRErtanAChanCCSafety and efficacy of trans-epithelial crosslinking (C3-R/CXL)J Cataract Refract Surg2010361188189
- BaiocchiSMazzottaCCerretaniDCaporossiTCaporossiACorneal crosslinking: riboflavin concentration in corneal stroma exposed with and without epitheliumJ Cataract Refract Surg200935589389919393890
- RaiskupFSpoerlECorneal cross-linking with hypo-osmolar riboflavin solution in thin keratoconic corneasAm J Ophthalmol20111521283221529763
- KissnerASpoerlEJungRSpeklKPillunatLERaiskupFPharmacological modification of the epithelial permeability by benzalkonium chloride in UVA/Riboflavin corneal collagen cross-linkingCurr Eye Res201035871572120673048
- FilippelloMStagniEO’BrartDTrans-epithelial corneal collagen crosslinking: bilateral studyJ Cataract Refract Surg201238228329122104644
- HayesSO’BrartDPLamdinLSEffect of complete epithelial debridement before riboflavin-ultraviolet-A corneal collagen crosslinking therapyJ Cataract Refract Surg200834465766118361990
- SamarasKO’BrartDPDoutchJHayesSMarshallJMeekKMEffect of epithelial retention and removal on riboflavin absorption in porcine corneasJ Refract Surg200925977177519772262
- BakkeEFStojanovicAChenXDrolsumLPenetration of riboflavin and postoperative pain in corneal collagen crosslinking: excimer laser superficial versus mechanical full-thickness epithelial removalJ Cataract Refract Surg20093581363136619631121
- CaporossiAMazzottaCParadisoALBaiocchiSMariglianiDCaporossiTTrans-epithelial corneal collagen crosslinking for progressive keratoconus: 24-month clinical resultsJ Cataract Refract Surg20133981157116323790530
- KoppenC1WoutersKMathysenDRozemaJTassignonMJRefractive and topographic results of benzalkonium chloride-assisted trans-epithelial crosslinkingJ Cataract Refract Surg20123861000100522624899
- BernardoaMDCapassoLTortoribALanzaMCaliendoaLRosaaNTrans-epithelial corneal collagen crosslinking for progressive keratoconus; 6 months follow upCont Lens Anterior Eye201437643844125172670
- SoetersNWisseRPGodefrooijDAImhofSMTahzibNGTrans-epithelial versus epithelium-off corneal cross-linking for the treatment of progressive keratoconus: a randomized controlled trialAm J Ophthalmol2015159582182825703475
- BernardoMDCapassoLLanzaMLong-term results of corneal collagen crosslinking for progressive keratoconusJ Optom20158318018626105541