|Year : 2020 | Volume
| Issue : 4 | Page : 309-311
Cyclosporine 0.1% (Ikervis®) as a corticoid-sparing agent in Lyell syndrome with KeraKlear® keratoprosthesis
Miriam Rahhal-Ortuno, Alex-Samir Fernández-Santodomingo, Carla Villena-Alvarado, Emma Marín-Payá, Marina Aguilar-González, Salvador García-Delpech
Department of Ophthalmology, Hospital Universitari i Politecnic La Fe, Valencia, Spain
|Date of Submission||09-Aug-2019|
|Date of Acceptance||24-Dec-2019|
|Date of Web Publication||21-Apr-2020|
Dr. Miriam Rahhal-Ortuno
Calle Hebreísta Pérez Bayer 11, 6-A; Valencia, Postal Code 46002
Source of Support: None, Conflict of Interest: None
Cyclosporine 0.1% was used in a patient with Lyell syndrome, which had undergone a KeraKlear® keratoprosthesis implant due to the severe ocular involvement to avoid overuse of corticoid agents. To the best of our knowledge, this is the first reported case of cyclosporine 0.1% eye drops to use in Lyell syndrome previously treated with keratoprosthesis implant.
Keywords: Cyclosporine 0.1%, KeraKlear, keratoprosthesis, Lyell syndrome
|How to cite this article:|
Rahhal-Ortuno M, Fernández-Santodomingo AS, Villena-Alvarado C, Marín-Payá E, Aguilar-González M, García-Delpech S. Cyclosporine 0.1% (Ikervis®) as a corticoid-sparing agent in Lyell syndrome with KeraKlear® keratoprosthesis. Taiwan J Ophthalmol 2020;10:309-11
|How to cite this URL:|
Rahhal-Ortuno M, Fernández-Santodomingo AS, Villena-Alvarado C, Marín-Payá E, Aguilar-González M, García-Delpech S. Cyclosporine 0.1% (Ikervis®) as a corticoid-sparing agent in Lyell syndrome with KeraKlear® keratoprosthesis. Taiwan J Ophthalmol [serial online] 2020 [cited 2022 May 17];10:309-11. Available from: https://www.e-tjo.org/text.asp?2020/10/4/309/283011
| Introduction|| |
Lyell syndrome or toxic epidermal necrolysis is a rare idiosyncratic hypersensitivity reaction being bullous cutaneous lesions, mucositis, and conjunctivitis its main clinical manifestations. In most cases, it is associated with drug intake.,
Ophthalmological symptoms may lead to corneal blindness for which numerous therapeutic options have been described, although not satisfactory in many cases. KeraKlear ® keratoprosthesis, an epidescement prosthesis that is implanted into a stromal pocket, is part of the available therapeutic spectrum, being our patient thefirst one suffering from Lyell syndrome with ocular involvement in whom a KeraKlear ® keratoprosthesis was implanted. However,how can we avoid fibrinous reactions from taking place once the prosthesis is implanted?
| Case Report|| |
A 39-year-old Caucasian male was referred to our ophthalmology department after Lyell syndrome diagnosis secondary to ibuprofen intake 24 months ago, for which he was hospitalized for over 3 months. Severe ocular and esophageal sequelae remained after the acute episode.
Slit-lamp examination showed symblepharon, trichiasis, and conjunctivalization and neovascularization of the cornea affecting both eyes, which impeded the anterior chamber and fundus examination [Figure 1]a. Visual acuity was light perception. Ocular motility was significantly reduced due to fibrinous adherence.
|Figure 1: Right eye with severe ocular involvement. (a) Decreased eye-opening and extensive corneal neovascularization, conjunctivalization, and symblepharon have shown with fluorescein stain. (b) Eye.opening and ocular surface improvement after KeraKlearR keratoprosthesis implant. (c) Conformer over keratoprosthesis with fibrinous reaction reappearing and decreased eye.opening due to the formation of new adherences. (d) Ocular surface improvement after mitomycin use|
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As topical steroids and previous surgical interventions (oral mucosa grafting) had failed to stop corneal conjunctivalization and neovascularization and graft rejection risk is very high in this type of disease, we decided to implant a KeraKlear ® keratoprosthesis in his right eye to restore vision. A stromal pocket was created after intensive debridement to place the epidescement prosthesis, and symblepharon half rings were used to aid fornix reconstruction.
Follow-up reviews after keratoprosthesis implantation showed no signs of extrusion [Figure 1]b. However, although mechanical debridement was daily carried out associated with topical steroids and anti-glaucomatous eye drops, extensive pseudomembranous conjunctivitis affecting the patient's ocular surface appeared. Symblepharon half rings were removed, and a conformer covering the prosthesis was placed instead to avoid new conjunctivalization and further symblepharon formation.
The conformer was again not enough to avoid fibrosis and conjunctivalization of the patient's ocular surface [Figure 1]c, being the risk of surgical failure very high as if the fibrinous reaction consolidated it would cover the prosthesis's optic area.
We then decided to use out-of-label 0.02% mitomycin C, which we applied twice using impregnated sponge spears. Mitomycin C use slowed down pseudomembrane's formation and improved ocular motility as new adherences were not being formed [Figure 1]d. However, after having undergone so many procedures to stop fibrinous reactions from taking place, we did not consider abandoning anti-inflammatory medication, and we decided to use cyclosporine 0.1% (Ikervis ®) eye drops as corticoid-sparing agents once a day. Topical steroids were tapered down over a period of 4 weeks after introducing cyclosporine 0.1%. Eight weeks after their use, ocular inflammation and fibrin formation are stabilized for thefirst time since the process began [Figure 2].
|Figure 2: Stabilization of fibrin formation 8 weeks after starting topical cyclosporine|
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| Discussion|| |
Cyclosporine is an immunosuppressant agent that prevents T-cell immunity activation  and its use in ophthalmology has been described in inflammatory diseases such as dry eye disease.
Its use in toxic epidermal necrolysis has been mostly described when administered orally, has shown to increase survival rates. However, its role in controlling ophthalmological symptoms has been reported to a lesser extent in medical literature, focusing on its role in acute inflammation , (showing promising results) and not as a long-term treatment.
We decided to use cyclosporine 0.1% in our patient as after so many therapeutic options had failed due to excessive fibrinous reactions taking place, we considered that long-term management of ocular surface inflammation was fundamental. Steroid eye drops would be the best option to minimize the high relapse risk, but continuing their use would mean high intraocular pressure (IOP) and optic nerve damage.
It is important to take into account that IOP is very difficult to measure in patients with keratoprosthesis being fundus examination as well as digital palpation of IOP of extreme importance in these cases. However, digital palpation is inaccurate, and waiting for optic nerve damage to take place means irreversible vision loss taking place. Therefore, the use of corticoid-sparing agents such as cyclosporine could aid surface inflammation control without rising IOP, which is difficult to monitor in these patients. The fact that corticoid-induced elevations of IOP cannot be easily examined in keratoprosthesis users makes it of extreme importance to avoid or reduce long-term corticoid use in these patients and associate their use to anti-glaucomatous eye drops whenever possible.
In addition, it is also very important to take into account the inflammation that we are triggering due to the manipulation of the patient's eye. This is why we decided to use KeraKlear ® keratoprosthesis in this patient, as it is an epidescement prosthesis that does not need to associate a corneal graft as other prostheses do, meaning less manipulation, and hence less induced inflammation.
To the best of our knowledge, the use of topical cyclosporine 0.1% as a long-term corticoid-sparing agent in patients with Lyell syndrome and KeraKlear ® keratoprosthesis implant has not been previously reported.
The importance of reporting this case relies on the fact that new therapeutic options have to be explored to manage different forms of corneal blindness, for example, in patients with severe ocular involvement secondary to Lyell syndrome due to the high rates of therapeutic failure.
Declaration of patient consent
The authors certify that they have obtained all appropriate patient consent forms. In the form, the patient has given his consent for his images and other clinical information to be reported in the journal. The patient understands that name and initials will not be published and due efforts will be made to conceal the identity, but anonymity cannot be guaranteed.
Financial support and sponsorship
Conflicts of interest
The authors declare that there are no conflicts of interests of this paper.
| References|| |
Agustín Godoy D, Alvarez E, Amigot A, Di Napoli M, Massoti L. Potentially fatal Lyell syndrome. Bol Asoc Med P
Ventura F, Fracasso T, Leoncini A, Gentile R, de Stefano F. Death caused by toxic epidermal necrolysis (Lyell syndrome). J Forensic Sci 2010;55:839-41.
Salvador-Culla B, Kolovou PE. Keratoprosthesis: A review of recent advances in the field. J Funct Biomater 2016;7. pii: E13.
Onaran Z, Usta G, Koçak M, Ornek K, Büyükkoçak U. Topical ophthalmic cyclosporine in the treatment of toxic epidermal necrolysis. Case Rep Med 2011;2011:416842.
Ames P, Galor A. Cyclosporine ophthalmic emulsions for the treatment of dry eye: A review of the clinical evidence. Clin Investig (Lond) 2015;5:267-85.
Valeyrie-Allanore L, Wolkenstein P, Brochard L, Ortonne N, Maître B, Revuz J, et al
. Open trial of ciclosporin treatment for Stevens-Johnson syndrome and toxic epidermal necrolysis. Br J Dermatol 2010;163:847-53.
Fu Y, Gregory DG, Sippel KC, Bouchard CS, Tseng SC. The ophthalmologist's role in the management of acute Stevens-Johnson syndrome and toxic epidermal necrolysis. Ocul Surf 2010;8:193-203.
[Figure 1], [Figure 2]