As the final remnants of winter thaw and the new season takes hold, we anticipate the growth and renewal that comes with this time of year. Spring brings a slow but steady increase in outdoor activity, and the inevitable arrival of the first blooms of flowers and trees—followed quickly by the first sneezes and eye rubs of yet another allergy season.
Seasonal and perennial allergies are a significant global health issue affecting approximately 15% of the world’s population; these percentages are even higher in the industrialized countries of Western Europe, Eastern Asia, Australia and North America.
Ocular allergy, or allergic conjunctivitis (AC), is typically cited as one of the most frequent reasons patients seek medical treatment for seasonal allergies.
While there have been improvements in therapy over the past two decades, there has also been an increase in prevalence of the disease.
As we prepare for this coming season, let’s take a look at the current treatments for ocular allergies, review the therapeutic developments in years past and describe areas where future efforts could have the most impact.
Specific pharmacological treatments for ocular allergy were nonexistent prior to the early 1970s; typically, patients were instructed to use cold compresses and to avoid the offending allergen.
The patient shown has severe vernal conjunctivitis, with a marked papillary response.
A second group of drugs, the mast cell stabilizers, first became available for topical ophthalmic use in the 1980s.
As we discuss below, patients typically used anti-allergics as needed, regardless of label (or practitioner) instructions and so, for the mast cell stabilizers, the arrival of symptoms is too late for drug treatment.
The first topical H1-antihistamines for ocular use (pheniramine and antazoline) came to market in 1990.
With atopic keratoconjunctivitis, the lower eyelid is typically affected more than the upper lid and the conjunctiva lining the eyelids is usually red and swollen.
In the last two decades, a number of second-generation H1-antihistamines have been developed to improve upon earlier drugs in terms of duration of action, safety profile and comfort. Important drugs in this group include levocabastine hydrochloride and emedastine difumarate, both of which were available as single-agent topicals.,
A progression of antihistamines followed, including azelastine hydrochloride, bepotastine besilate, ketotifen fumarate and olopatadine
Causes and Conditions
Like other allergies, AC is caused by a type-1 (IgE-dependent) hypersensitivity reaction.
Exposure to allergens triggers mast cell release of inflammatory mediators, including histamine, that induce symptoms such as ocular itching and hyperemia. , Akdis CA, Blaser K. Histamine in the immune regulation of allergic inflammation. J Allergy Clin Immunol. 2003 Jul;112(1):15-22. Additional symptoms include swelling of the surrounding eyelids, chemosis and tearing., Conjunctival swab cultures provide an unequivocal differential diagnosis of an infectious vs. allergic etiology, but the key feature that distinguishes AC from other forms of conjunctivitis is itching. More severe, chronic forms of ocular allergy include rare conditions such as atopic keratoconjunctivitis (AKC), vernal keratoconjunctivitis (VKC) and giant papillary conjunctivitis (GPC).
, Butrus S, Portela R. Ocular allergy: diagnosis and treatment. Ophthalmol Clin North Am. 2005 Dec;18(4):485-92. ,Leonardi A. Emerging drugs for ocular allergy. Expert Opin Emerg Drugs. 2005 Aug;10(3):505-20. Both AKC and VKC are allergic conditions in which the inflammatory response has been exacerbated to the point of significant conjunctival erythema and significant risk of corneal ulceration. In contrast, GPC is a condition specifically associated with contact lens use, and is due to a response to allergens deposited in the contact. All three of these conditions tend to be chronic, and are typically treated with a combination of antihistamines, mast cell stabilizers and topical steroids.
hydrochloride.
Patients with asthma, hay fever or animal allergies may be at greater risk for GPC; its etiology may be immunological, where contact lens deposits act as allergens.
In addition to this dual-action effect (or perhaps because of it), these newer drugs all have a longer duration of action than either levocabastine or emedastine. They are indicated for twice-daily dosing to relieve itching due to AC.
Most recently, two agents have been approved for once-daily dosing—a higher concentration formula (0.2%) of olopatadine hydrochloride, (Pataday, Alcon), and the newest ocular antihistamine, alcaftadine (Lastacaft, Allergan).
A noteworthy aspect of histamine antagonists is that, unlike the pure mast cell stabilizers, these drugs are effective whenever the patients experience allergic symptoms. This was a significant step forward, and many would say it changed the landscape of ocular allergy therapy. In addition, the high efficacy of these drugs meant that most patients moved from an everyday, “prevention-based” dosing to a more “as-needed” use.
Ironically, it’s possible that antihistamine/mast cell stabilizers could be more effective if used prophylactically; evidence suggests that prevention of acute allergic responses may be one way to minimize the growing trend toward chronic allergies.
Despite this continued improvement in AC therapy, many patients with ocular allergies (some estimates put the number at 30% in the U.S.) show poor response to most currently available therapies.
The first group consists of those with the combination of seasonal and perennial allergies; for these patients, it is always allergy season. The second group includes patients with robust responses to seasonal allergens, so that on days with particularly high pollen levels they present an allergic response that simply overwhelms the ability of any topical antihistamine to suppress.
Both types involve conjunctival recruitment of immune cells in addition to mast cells, and so the goal of any new therapy is to “calm” the conjunctiva, allow the recruited cells time to dissipate and also reduce the inflammatory features of the chronic, late phase response. These patients can be considered chronic ocular allergy sufferers, and they are symptomatically similar to those with more severe allergic conditions such as AKC.
Chronic allergy differs from the more acute forms in that it is primarily mediated by cellular factors, and is dependent upon the activity of immune cells such as basophils and eosinophils that have infiltrated the conjunctiva over the course of prolonged allergen exposure.
In the last two decades, a number of secondgeneration H1-antihistamines have been developed to improve upon earlier drugs in terms of duration of action, safety profile and comfort.
exposure to allergy-exacerbating agents, such as air pollutants and volatile chemicals.
Evidence suggests that these chemicals can prime the immune response to perennial allergens, such as dust mites and molds.
Currently, the best available treatments for chronic ocular allergy sufferers are topical steroids, such as prednisolone acetate or loteprednol etabonate.
Newer anti-inflammatory compounds are likely candidates for future studies of chronic AC. Beyond trials of compounds with theoretical or demonstrable antiinflammatory effects, however, it is necessary to establish a clear strategy for identifying and developing the next class of ocular anti-allergics.
Researchers at Ora, Inc. have spent the past 30 years developing and refining methods to test new drugs and formulations for ocular allergy. In that time, our conjunctival allergen challenge (CAC) model has become an industry standard, and has been employed for studies used to gain FDA approval for all ocular anti-allergics currently marketed in the U.S.
The success of clinical models such as the CAC underscores the fundamental importance of study design in the drug development process. The research group at Ora, like others in the ocular therapeutics industry, is focused on how to accurately assess the efficacy of either new chemical entities or repurposed drugs as therapies for chronic ocular allergy. Key to these efforts is the ability to accurately identify the “nonresponder” population from the greater population of allergics.
In addition, trials need to employ robust experimental standards that elicit the chronic allergic signs and symptoms, similar to the CAC model for acute allergy. Future therapies will likely employ drugs that interfere with cytokine signaling, or those that can disrupt the intracellular processes that mediate this chronic feedback loop.
Results of pre-clinical studies have focused on a number of factors that define the chronic allergic subject. Prolonged or high levels of allergen exposure lead to infiltration and accumulation of basophils, eosinophils and increased numbers of mast cells. These cells respond to continued presence of allergens by releasing a smorgasbord of cytokines, chemo-attractants, proteases and other signaling molecules. The net effect is continued recruitment of immune and inflammatory cells, breakdown of the ocular surface’s extracellular matrix and destabilization of the protective, barrier function of the conjunctival and corneal epithelium.
Mr. Gomes is vice president of Allergy at Ora, Inc. Ora has provided clinical research services for each product mentioned.