Abstract
We report a case of corneal melting through sterile infiltration presumably due to excessive use of nonsteroidal anti-inflammatory eye drops after corneal crosslinking (CXL). It was treated using steroids combined with amniotic membrane transplantation (AMT). A 33-year-old man with progressing keratoconus underwent left eye CXL. We prescribed betamethasone and levofloxacin eye drops 5 times daily and diclofenac sodium eye drops 3 times daily for 3 days. Three days after CXL, there was a persistent epithelial defect and the left corneal stroma was clouded. His visual acuity remained unchanged. We prescribed betamethasone hourly and 20 mg prednisolone daily. At 1 week after CXL, the corneal epithelial defect and infiltration were unchanged. He had not stopped using diclofenac at the prescribed time. On day 17, we performed AMT and his cornea and visual acuity improved. AMT may be effective against persistent epithelial defects and corneal melting after CXL.
Keywords: Amniotic membrane transplantation, Sterile infiltration, Corneal melting, Corneal crosslinking, Keratoconus
Introduction
Corneal collagen crosslinking (CXL) was first reported by Wollensak et al. in 2003 [1], using riboflavin as a photosensitizer being excited by ultraviolet A light (UVA) exposure. CXL is known to halt the progression of keratoconus. Although CXL has been considered a relatively safe treatment, a few complications such as sterile infiltrates (7.6%) and stromal scars (2.8%) have been reported [2].
Nonsteroidal anti-inflammatory drugs (NSAIDs) are used for control of acute or chronic pain or inflammation. NSAIDs inhibit cyclooxygenases and decrease prostaglandin production; their use for corneal wound healing is a matter of debate. Postoperative use of topical NSAIDs promotes faster wound healing [3]; however, Lee et al. [4] investigated the toxicity of NSAID eye solutions against corneal epithelial cells in vitro. Asai et al. [5] reported 3 cases of corneal melting caused by bromfenac sodium used to treat surface and postoperative inflammation.
Moreover, Gokhale and Vemuganti [6] reported a case of corneal melting and perforation 1 week after CXL for keratoconus. They speculated the concomitant postoperative use of topical diclofenac and proparacaine eye drops after CXL as the predisposing risk factors. Mohamed-Noriega et al. [7] presented a case of corneal melting and perforation 6 weeks after CXL for keratoconus. They proposed postoperative nepafenac eye drop use, a cornea thinner than 400 µm, and diabetes mellitus as the predisposing risk factors.
We report a case of corneal melting through sterile infiltration presumably due to excessive use of NSAID eye drops, treated with topical and general steroid applications, which finally required amniotic membrane transplantation (AMT).
Case Report
A 33-year-old man visited our institute complaining of vision reduction in his left eye. He had no significant personal or family history. His visual acuity was 0.2 (0.9 × s −1.00 D c −2.00 D AX 65°), OS. Slit lamp examination showed a cone-shaped cornea and corneal thinning. Intraocular pressure was 11 mm Hg. Anterior segment optical coherence topography (CASIA®; Tomey, Aichi, Japan) indicated that the steepest keratometric value was 48.6 D, and the thinnest corneal thickness was 441 µm, OS. He was diagnosed with keratoconus in the left eye. After one and a half year, his visual acuity deteriorated to 0.3 (0.7 × s −1.50 D c −3.00 D AX 55°), OS, and the steepest keratometric value increased to 49.7 D; CXL on his left eye was planned. His thinnest corneal thickness was 445 µm, OS. After topical anesthesia, the central epithelium of his left cornea was debrided with 20% ethanol. An accelerated protocol with 0.1% riboflavin instillation for 20 min followed by UVA irradiation with 18.0 mW/cm2 for 5 min (KXL System®; Avedro, Waltham, MA, USA) was performed. After UVA irradiation, a bandage contact lens was placed over the cornea following our standard protocol. Postoperatively, betamethasone and levofloxacin eye drops 5 times daily and diclofenac sodium eye drops 3 times daily were prescribed. The patient was instructed to stop the use of the diclofenac sodium eye drops after 3 days.
On the day after CXL, his left cornea revealed a corneal epithelial defect and mild ciliary injection, but the underneath stroma was translucent, and no remarkable infiltration was observed. Three days after CXL, his left cornea revealed a persistent epithelial defect, and the underneath corneal stroma was clouded. Severe ciliary injection was also observed. His visual acuity was 0.01 (noncorrigunt), OS. We estimated that the corneal lesion was not an infection from the clinical feature. We scraped the surface of corneal erosion and carried out a bacterial examination on day 3, but no microbial agent was detected. We instructed the patient to use betamethasone eye drops every hour and also prescribed 20 mg of oral prednisolone per day. One week after CXL, the corneal epithelial defect and infiltration were unchanged. At the follow-up visit, he reported that he had continued the use of diclofenac sodium eye drops 5 times per day for 5 days, despite our presurgical instructions. We prescribed 20% serum eye drops 5 times per day. Nevertheless, that area did not show epithelialization; superficial corneal stroma melt was observed, and the underneath stroma was visibly edematous (Fig. 1).
Fig. 1.
Clinical photograph and corneal pachymetry map 3 days after corneal crosslinking. Left: Slit-lamp microscopy shows that the persistent epithelial defect remains. The underneath corneal stroma is melted and clouded by edema. Right: Pachymetry map shows the corneal swelling.
Twelve days after CXL, we performed AMT on his left cornea, and we covered the entire corneal surface with an amniotic membrane, sutured it with 8-0 vicryl. After that, his cornea showed improvement. The amniotic membrane was dissolved about 2 weeks after AMT. The epithelium began to recover thereafter, and the underneath stroma became dehydrated (Fig. 2). We removed the bandage contact lens 50 days after AMT. His visual acuity had improved to 0.2 (0.7 × s +0.25 D c −3.50 D, AX 100°), OS 60 days after CXL (48 days after AMT), and we stopped the use of the serum eye drops.
Fig. 2.
Clinical photograph and corneal pachymetry map 3 months after crosslinking. Left: Epithelialization is achieved and the corneal stroma shows mild scarring. Right: The axial map of the left cornea shows that the steepest keratometric value improved to 54.0 D after crosslinking.
Discussion
In the present case, persistent epithelial defect, sterile infiltration, and corneal melting were probably caused by excessive postoperative use of NSAIDs. The corneal involvement could not be improved by intensive topical and general steroid application; however, it finally improved after performance of AMT.
In the present case, the excessive use of topical NSAIDs by the patient, despite our presurgical instructions, presumably caused delayed re-epithelialization, and proinflammatory cytokines released from the damaged epithelial cells further obscured epithelial healing. NSAIDs are widely used after various ocular surgeries, expecting anti-inflammatory and analgesic effects via inhibition of the enzymes cyclooxygenase 1/2. On the other hand, the toxicity of NSAIDs against corneal re-epithelialization has been investigated both in vitro [4] and in vivo [8]. Çerman et al. [9] suggested that proinflammatory cytokines directly secreted from damaged epithelial cells may be released into the stroma and consequently trigger the migration of inflammatory cells to the affected stroma.
For the treatment against sterile infiltration and corneal melting, topical and general steroid application has been reported to be effective [10]. However, steroid application had only limited effect in the present case. Therefore, we performed AMT on the 17th day after CXL. AMT, which was first used by Kim and Tseng [11] for ocular surface reconstruction, has recently found widespread use in ophthalmology as a patch for conjunctival reconstruction [12], corneal surface reconstruction [12], forniceal reconstruction [12], and glaucoma surgery [13]. The amniotic membrane has been reported to contain growth factors that promote epithelial wound healing on the ocular surface [14]. Anti-inflammatory and antiscarring effects of the amniotic membrane have been reported [15]. Moreover, in the present case, AMT reduced inflammation, promoted epithelial healing, and consequently halted corneal melting. Although corneal stromal opacity remained, visual acuity recovered, and the corneal curvature returned to its preoperative condition.
The present case may indicate the possible risk of NSAIDs after CXL regarding epithelial healing. After encountering the present case, we no longer prescribe diclofenac sodium eye drops postoperatively. Frequent observation within 1 week after CXL is crucial. Furthermore, one should consider that AMT could be effective in cases where persistent epithelial defects and corneal melting occur.
Statement of Ethics
The authors have no ethical conflicts to disclose.
Disclosure Statement
The authors have no conflicts of interest to disclose.
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