We noticed you’re blocking ads

Thanks for visiting CRSToday. Our advertisers are important supporters of this site, and content cannot be accessed if ad-blocking software is activated.

In order to avoid adverse performance issues with this site, please white list https://crstoday.com in your ad blocker then refresh this page.

Need help? Click here for instructions.

Up Front | Jan 2007

An Alternative Treatment for Keratoconus

Collagen cross-linking with ultraviolet A light and riboflavin followed customized topography-guided PRK may be an alternative to penetrating keratoplasty.

Keratoconus is usually a bilateral, asymmetric, progressive, and non-inflammatory degeneration of the cornea. Its incidence is approximately 1 in 2,000 in the general population. The disorder usually starts during puberty, and it progresses in approximately 20 of those affected to such an extent that penetrating keratoplasty (PKP) is indicated.1 Today, PKP remains the global gold standard for rehabilitating the vision of patients with advanced keratoconus,1 but intermediate and long-term visual rehabilitation in these patients remains challenging.1 An alternative treatment to PKP may be a procedure that includes collagen cross-linking with ultraviolet A light and riboflavin followed by customized topography-guided PRK (referred to hereafter as the Treatment).

CASE REPORT
Keratoconic Patient
A 26-year-old male patient with a long history of keratoconus and rigid gas-permeable contact lens wear for more than 8 years presented to my office. Due to the development of debilitating giant papillary conjunctivitis, contact lens use by the patient had become intolerable. His UCVA was 20/40 OD and 20/100 OS, his BSCVA was 20/15 OD and 20/50 OS, and his refraction -0.75 -0.75 X80 OD and -3.75 -4.50 X110 OS. Spectacle use was associated with a significant decrease in his vision quality and an increase in anisometropia problems.

I initially evaluated the patient for a corneal transplantation at the recommendation of several cornea specialists the patient had consulted previously (Figures 1 and 2). The corneal thickness was 520 and 440µm in the right and left eyes, respectively. The endothelial cell count was 2,800 and 2,750 cells/mm² in the right and left eyes, respectively, as measured by the Orbscan topographer (Bausch & Lomb, Rochester, NY) and ultrasound.

The patient and I spoke at length about his treatment options. I described the pros and cons of PKP1 and detailed the use of Intacs (Addition Technology Inc., Des Planes, IL) as a substitute treatment.2 I also shared my experience and that of my colleagues with the Treatment.3 The patient decided to undergo the Treatment prior to considering PKP.

Treatment Protocol
The Treatment was completed in two steps. The patient first underwent collagen cross-linking to stabilize corneal ectasia. This technique is described in several laboratory and clinical studies.2,4-10

Before treating the patient, I removed his corneal epithelium via 20 ethyl alcohol solution, which remained on the corneal surface for 20 seconds.

Special emphasis should be taken preoperatively to document a patient's minimal corneal thickness because of the potentially cytotoxic effects of ultraviolet A on corneal endothelial cells. Previous experimental studies in the rabbit cornea have investigated dose-dependent cytotoxicity to the corneal endothelium. Those studies have clearly shown that the surface irradiance, according to the protocol described herein, may not be used in corneas thinner than 400µm (including the epithelial layer) to prevent potential endothelial damage.2

For the Treatment, I used the Keracure prototypic device (Priavision, Menlo Park, CA). It emits 370nm of ultraviolet A light and 3mV/cm2 radiance through four light-emitting diodes for 30 minutes (defined by an automatic, built-in timer). The nursing staff simultaneously administered 0.1 riboflavin ophthalmic solution (Priavision) to the de-epithelialized cornea, one drop every 2 minutes, in order to "soak" the stromal bed. The riboflavin facilitates collagen cross-linking and, importantly, protects the iris, crystalline lens, and retina from ultraviolet A radiance.

A bandage contact lens was placed onto the de-epithelialized, cross-linked cornea. The patient received ofloxacin and prednisolone acetate 1 q.i.d. for 10 days. The contact lens was removed on postoperative day 4, when the patient's cornea had completely re-epithelialized.

Postoperative Results and Refractive Surgery
The patient's UCVA and BSCVA improved to 20/80 and 20/40, respectively, with a refraction of -3.50 -4.00 X115 at 3 months postoperatively. Based on the stability of these parameters and the corneal topography between months 1 and 12 of the Treatment, the patient and I decided to proceed with a limited topography-guided PRK in order to reduce the amount of irregular astigmatism and to facilitate visual rehabilitation (Figures 3 and 4).

At the time of refractive surgery, the patient's cornea at its thinnest point measured 450µm with pachymetry. I reduced the treatment values for myopia from -3.50D to -2.50D and from -4.00D to -3.00D for astigmatism. I decreased the treatment zone to 5.5mm from the standard 6.5mm that I use in routine PRK procedures. I performed the PRK using the 400Hz Allegretto Wave Eye-Q Excimer Laser System's (Wavelight, Inc., Sterling, VA) topography-guided, customized T-CAT software to visually rehabilitate this patient. The T-CAT with the 400Hz Allegretto Wave Eye-Q Excimer Laser System allows for treatment zones of 5.0 to 7.0mm in 0.5-mm increments.11 My goal was to remove no more than 50µm of central corneal tissue (Figure 5).

I placed 20 dilute alcohol on the corneal surface for 20 seconds to remove the epithelium, and then I performed the laser treatment. I applied a Weck-Cel sponge (Medtronic Xomed Ophthalmics, Inc., Minneapolis, MN) soaked in mitomycin C 0.2 solution to the ablated tissue for 30 seconds and then irrigated the tissue with 10mL of chilled balanced salt solution. Finally, I applied a bandage contact lens on the cornea.

The laser treatment must be applied with caution, because more rigid corneas (the actual effect that the cross-linking achieves) may have a different ablation depth per pulse than the untreated cornea. In this case the correction achieved was more than what was expected from the planned treatment , suggesting that a special nomogram is required for the ablation of a previously cross-linked cornea. In short, one should aim for less. Therefore, my recommendation would be to use 75 to 80 of the measured sphere and cylinder as a correction parameter when planning the ablation with the T-CAT software.

The patient's visual treatment was very rewarding on postoperative day 7 following the bandage contact lens' removal on day 5. One can appreciate the difference map between pre- and post-ultraviolet A, collagen cross-linked treatment (Figure 6) as well as the difference map between pre- and posttopography-guided treatment (Figures 7) and the actual ablation profile that was used for the treatment (Figure 5). The qualitative changes on the corneal surface are interesting. In both the treatment plan and the difference map (Figure 8), there is strong evidence of a deeper ablation over the steep cone. Another important factor is the attempt in the treatment plan and actual effect in the difference map of a midperipheral steepening effect of the diametrically opposite cornea to the cone's center. This effect is achieved by flattening the outer edge of the middle cornea that is to be steepened. Normalization of the cornea is achieved with the T-CAT software by (1) flattening the cone's apex by a small diameter via an eccentric PTK-like treatment, and (2) steepening the diametrically opposite cornea to achieve an effect that resembles a hyperopic treatment. The advantage of a topography-guided treatment in this case is that it removes far less (almost one-third less) tissue in comparison to similar wavefront-guided treatments. This benefit is very important, especially in keratoconic patients, because there is a tremendous limitation in the amount of tissue that can be removed.

I prescribed topical ofloxacin and prednisolone acetate 1 q.i.d. for 10 days postoperatively. The patient then used prednisolone acetate 1 alone q.i.d. for 3 additional weeks and b.i.d. for the next 4 weeks. I encouraged him to protect his eyes from all natural light with sunglasses and to take 1,000mg of vitamin C daily for 60 days (my standard protocol for post-PRK patients).

At 1 month postoperatively, the patient's UCVA was 20/20, and he reported seeing well at night. During the first 18 months postoperatively, he enjoyed a UCVA of 20/20 and a BSCVA 20/15 with plano -0.50 X150. He considers his left treated eye better when compared to his right eye. The corneal endothelium had 2,750 cells/mm² at 1 month after the treatment, and it had not changed at 1 and 12 months after topography-guided PRK. The postoperative regression of ectasia was impressive and stable for 12 months (Figure 6).

CONCLUSION
The persistance of stable results more than 1 year postoperatively indicates the utility of the Treatment and suggests that the procedure may in the near future have wider applications for preventing the development of keratoconus, ectasia, and other biomechanical corneal changes following LASIK. I feel that the Treatment may hold significant promise for the management of keratoconus, and it may help relieve the tremendous burden this condition places on patients' everyday lives when they cannot wear contact lenses. The Treatment's utility may further be improved by adjusting the nomogram. For example, reducing the treatment for myopia and astigmatism by 25 (as described earlier), is something that each surgeon may adjust in regards to the laser platform that he uses in the ablation of cross-linked cornea tissue to avoid a refractive overcorrection. Larger comparative studies establishing the safety and efficacy of the Treatment and longer follow up, however, are necessary to further validate the results discussed herein and potentially make this treatment available for early cases of keratoconus.

A. John Kanellopoulos, MD, is a cornea and refractive surgery specialist. Dr. Kanellopoulos is Director of the Laservision.gr Eye Institute in Athens, Greece; an attending surgeon at the Department of Ophthalmology, Manhattan Eye, Ear, and Throat Hospital in New York; and Clinical Associate Professor of Ophthalmology at New York University Medical School in New York. He acknowledged no financial interest in the products or companies mentioned herein. Dr. Kanellopoulos may be reached at 30 21 07 47 27 77; laservision@internet.gr.



Advertisement - Issue Continues Below
Publication Ad Publication Ad
End of Advertisement - Issue Continues Below

Jan 2007