Management of Vernal Keratoconjunctivitis

Mast cell stabilizers are the first-line drugs for VKC. Topical mast cell stabilizers are generally safe and have minimal ocular side effects, although there may be some tolerability concerns, since transient burning or stinging may occur upon application. Several studies have demonstrated the efficacy of 2% and 4% sodium cromoglicate (DSCG, cromolyn), nedocromil sodium 2%, lodoxamide tromethamine 0.1%, and spaglumic acid 4% [12‐14]. The recommended dosing schedule is 4–6 times daily, with a loading period of at least 7 days and an onset of activity after as much as 2 weeks. DSCG alone has limited effects in the treatment of VKC and is less well tolerated than newer anti-allergic compounds. Nedocromil appears to be more potent than DSCG [15], acting on multiple cells involved in allergic inflammation, including eosinophils, neutrophils, macrophages, mast cells, monocytes, and platelets.

Lodoxamide has long been available for the treatment of VKC. Its mechanism of action is thought to be similar to that of DSCG, since it was shown to prevent tryptase release [16]. Lodoxamide was shown to be more effective than DSCG for the inhibition of eosinophil activation, evaluated by measuring tear eosinophil cationic protein ECP before and after therapy [17], suggesting that lodoxamide has an effect on eosinophil activation. Inhibition of eosinophil activation and degranulation is the proposed mechanism for its efficacy against corneal signs such as keratitis and shield ulcers in severe allergic disease [17]. Lodoxamide was shown to be superior to placebo [18] and N-acetyl aspartyl glutamic acid (NAAGA) for treatment of VKC [19]. The recommended dosing schedule is four times daily. Lodoxamide may be used continuously for 3 months in children older than 2 years of age.

NAAGA 6% has been widely used in Europe as topical eye drops in the treatment of VKC [20]. NAAGA is known to inhibit leukotriene synthesis, histamine release by mast cells, and complement-derived anaphylatoxin production. This anti-allergic compound was also shown to directly inhibit leukocyte adhesion to endothelial cells induced by proinflammatory stimuli, and abrogates tumor necrosis factor α-induced expression of adhesion molecules on granulocytes and endothelial cells [21]. These pharmacological properties confer a potential anti-inflammatory activity.

Antihistamines act via histamine receptor (HR) antagonism to block the inflammatory effects of endogenous histamine and prevent or relieve the associated signs and symptoms. Most antihistamines used in the treatment of allergy are H₁ receptor antagonists, although some agents may have affinity for other receptor subtypes [22]. H₂ antagonists have been shown to modulate both cell growth and migration [22]. Ocular drugs with antihistaminic activity may offer therapeutic advantages to patients with allergic conjunctivitis, including VKC, by inhibiting proinflammatory cytokine secretion from conjunctival epithelial cells [23]. The first-generation antihistamines pheniramine and antazoline have a long safety record, but are known for their burn upon instillation, the rapid onset and disappearance of their effects, and their limited potency [24]. These are still available in over-the-counter products, particularly in combination with vasoconstrictors.

The newer antihistamines are still H₁ antagonists, but have a longer duration of action (4–6 h), and are better tolerated than their predecessors. These include levocabastine hydrochloride 0.5% and emedastine difumarate 0.05%.

Levocabastine 0.05% eye drops alone, instilled four times daily for 3 months, was effective, safe, and well tolerated by patients with VKC; however, it was less effective than lodoxamide [25] or NAAGA [20]. Interestingly, in an animal model, levocabastine reduced the clinical aspects of the late-phase reaction and the conjunctival expression of alpha(4)beta(1) integrin by reducing infiltration of eosinophils [26].

Emedastine 0.05% appears to be more potent and selective than levocabastine [27, 28]. Indeed, in direct comparison with levocabastine, emedastine proved significantly more effective in alleviating signs of seasonal allergic conjunctivitis [27, 28]. No specific studies in VKC have been performed.

A meta-analysis of randomized clinical trials in VKC showed a large number of studies (20) evaluated the efficacy of common anti-allergic eye drops (levocabastine, lodoxamide, mipragoside, NAAGA, nedocromil sodium, DCG). Among these, lodoxamide appeared to be the most effective [10].

New antihistamines that combine mast cell stabilizing properties and histamine receptor antagonism, such as alcaftadine, azelastine, bepotastine, epinastine, ketotifen, and olopatadine, are presently available and show evident benefits in treating all forms of ocular allergy. The advantage offered by these agents is the rapidity of symptomatic relief given by immediate histamine receptor antagonism, which alleviates itching and redness, coupled with the long-term disease-modifying benefit of mast cell stabilization. All of these medications are well tolerated and none are associated with significant ocular drying effects. Although widely used in the treatment of VKC, specific studies in VKC are very few. Olopatadine and ketotifen have shown efficacy in relieving signs and symptoms in patients with VKC. These two drugs may have also anti-inflammatory properties, reducing eosinophil activation and cytokine release. A significant difference in favor of ketotifen-treated patients has being shown in a single-center, simple-masked study comparing these two drugs [29]. However, both drugs were efficient and safe relieving the main symptoms and signs of VKC, including itching, tearing, conjunctival hyperemia, mucous discharge and photophobia. Olopatadine hydrochloride 0.1% was effective for relieving the signs and symptoms of VKC and reducing the number of goblet cells during treatment [30].

Decongestants are a useful adjunctive therapy to mast cell stabilizers and/or antihistamines in mild and moderate forms of VKC, or in adult patients who have demonstrated a notable improvement in symptomatology after adolescence. However, topical decongestants do not reduce the allergic response because they do not antagonize any of the mediators of allergic inflammation. Burning or stinging on instillation is a common side effect. Prolonged use of topical decongestants, as well as the discontinuation of these agents following prolonged use, can lead to rebound hyperemia and conjunctivitis medicamentosa [31]. These events are usually associated with topical first-generation antihistamines such as pheniramine and antazoline that are available as over-the-counter products.

Generally NSAIDS employed in ocular allergy treatment inhibit both cyclooxygenase (COX)-1 and COX-2 enzymes. Ketorolac, diclofenac, and pranoprofen, may also be valid alternatives to steroids, since they have a proven effect on itching, intercellular adhesion molecule-1 expression, and tear tryptase levels [32]. Indomethacin 1% [33], ketorolac 0.5% [34], and diclofenac 0.1% have shown effectiveness in the treatment of VKC [35].

Moderate to severe VKC needs repeated topical steroid treatment to downregulate conjunctival inflammation. Persistent severe symptoms, thick mucous discharge with moderate to severe corneal involvement, numerous and inflamed limbal infiltrates and/or giant papillae, indicate a need for corticosteroids. However, corticosteroids should be avoided as the first line of defense in the treatment of VKC. If steroids are used, those with low intraocular absorption, such as hydrocortisone, clobetasone, desonide, fluorometholone, loteprednol, difluprednate and rimexolone, should be used first. Dosages are chosen based on the inflammatory state of the eye, with therapy prescribed in pulses of 3–5 days. Loteprednol etabonate is usually indicated for 7–8 days in the treatment of the acute phase. Prednisolone, dexamethasone, or betamethasone should be used only when the above-mentioned first-choice steroids have proven ineffective. Steroid–antibiotic combination eye drops should be avoided, as VKC is an allergic inflammation, rather than an infection. Corticosteroids should not be recommended for long-term use because of possible ocular adverse effects, including increases in intraocular pressure (IOP), induction or exacerbation of glaucoma, formation of cataracts, delayed wound healing, and increased susceptibility to infection or superinfection. These adverse effects depend, in part, on the structure, dose, duration of treatment and gender disposition [36]. In fact, following daily administration of corticosteroids for 4–6 weeks, approximately one-third of the normal population will be “high or moderate responders” with an increase in IOP of between 6 and 15 mm Hg [36]. Forty-one of 145 (28.3%) patients with severe VKC in a Singapore case series developed a corticosteroid response, of which eight (5.5%) progressed to glaucoma [37]. Six of these patients (n = 8 eyes) required trabeculectomy/mitomycin-C. The main risk factor for trabeculectomy was a greater increase in IOP from baseline, which was independent of potential confounders such as type and duration of corticosteroid use [38].

Cyclosporine A (CsA) is effective in controlling VKC-associated ocular inflammation by blocking Th2 lymphocyte proliferation and interleukin-2 production. It inhibits histamine release from mast cells and basophils through a reduction in IL-5 production, and may reduce eosinophil recruitment and effects on the conjunctiva and cornea [39]. CsA is lipophilic and thus must be dissolved in an alcohol-oil base [39]. Unavailability of a commercial preparation of topical CsA, technical difficulties in dispensing eye drops and legal restrictions on its topical use in many countries, preclude its widespread use for VKC treatment. The 2% formulation has the longest track record, but lower concentrations (1%, 0.5%, and 0.05%) have been used and shown to be effective. So far, there is no general consensus regarding the minimum effective concentration of CsA. Only the 0.05% formulation is commercially available for the treatment of dry eye.

After long cycles of treatment, CsA has a marked steroid-sparing effect, potentially allowing control of symptomatology without steroids [40]. When necessary, additional topical steroids can be used in short cycles. Systemic absorption of CsA was not detectable by clinical laboratory methods. Burning and irritation are frequent side effects. Treatment can be prescribed seasonally or perennially, reducing doses in the non-active phases of the disease. Adverse events, such as bacterial or viral infections are rare, while IOP changes have not been reported.

CsA 1% or 2% emulsion in castor or olive oil instilled four times daily can be considered for treatment of moderate to severe VKC and can serve as a good alternative to steroids [39, 41]. After 2 weeks, CsA 1% four times daily significantly reduced signs and symptoms and tear levels of ECP in a group of VKC patients [42].

CsA 1% was reported to be the minimum effective concentration in the treatment of shield ulcers, with recurrence observed at lower concentrations [43]. In a randomized, controlled trial, the effects of CsA 0.05% were similar to placebo [44]. Conversely, in another study, CsA 0.05% decreased the severity of symptoms and clinical signs significantly after 6 months and the need for steroids was reduced, suggesting that CsA at low doses is an effective steroid-sparing agent in VKC [45]. In a clinical prospective and observational study in 594 patients, CsA 0.1% was shown to be effective and safe for the treatment of VKC [46]. A recent systematic review and meta-analysis study suggests that topical CsA is effective and safe for the treatment of VKC, since signs and symptoms significantly improve after treatment, regardless of the CsA dosage [47].

A randomized, controlled two-year crossover study demonstrated the safety and efficacy of CsA 0.05% for long-term prevention of VKC relapses [40]. Patients treated with ketotifen had a risk of recurrences 2.4 times higher than patients treated with CsA. In addition, CsA significantly improved itching, photophobia and conjunctival hyperemia scores in comparison with ketotifen. These data are of great importance for the long-term management of pediatric patients at risk of visual impairment, whether due to steroid abuse or to continued recurrences of acute inflammation [40].

Tacrolimus is a potent drug, similar to CsA in its mode of action, but chemically distinct. A tacrolimus skin ointment is licensed for the treatment of moderate to severe atopic eyelid diseases and may have secondary benefits for AKC [48‐50]. Conjunctival application of tacrolimus ointment 0.03% and 0.1% were effective, well tolerated, and safe in the treatment of severe allergic conjunctivitis [49, 51]. In a multicenter, randomized, double-masked, placebo-controlled clinical trial, tacrolimus ophthalmic suspension 0.1% was shown to be effective in treating severe allergic conjunctivitis. Patients were treated twice daily for 4 weeks. Objective signs, subjective symptoms, giant papillae and corneal involvement were significantly improved. The most frequent tacrolimus-related adverse event was ocular irritation [52]. In the same study it is also reported that the dose of tacrolimus was based on the results from a previous dose-ranging study in which tacrolimus ophthalmic suspension 0.01%, 0.03%, and 0.1% were tested. Since 0.1% showed stronger improvement and similar safety profile compared with 0.01% and 0.03%, the 0.1% was considered an optimal dose.

Documentation on the quality, safety and efficacy of the different preparations used in the different clinical reports will be necessary before tacrolimus is granted orphan medication status for VKC.

A prospective double-masked randomized comparative trial comparing the efficacy of 0.1% tacrolimus ophthalmic ointment with CsA 2% showed that both were equally effective in the treatment of VKC [53].

Short-term, low-dose, topical mitomycin-C 0.01% has been considered for treating acute exacerbations in patients with severe VKC refractory to conventional treatment [54]. A significant decrease in signs and symptoms compared with the placebo group was shown at the end of the 2-week treatment period. Unavailability of commercial topical preparations, the short duration of studies, and the lack of data on the safety profile and long-term outcomes are major limitations in recommending mitomycin for the treatment of VKC.