Fact-checked by Grok 2 weeks ago

Allergic conjunctivitis

Allergic conjunctivitis is an inflammatory condition of the , the thin membrane covering the white part of the eye and inner eyelids, triggered by an allergic reaction to environmental allergens such as , mites, pet dander, or . It is characterized by intense ocular itching as the hallmark symptom, often accompanied by bilateral redness, watery discharge, and eyelid swelling, and typically occurs in individuals with a history of or allergies. Unlike infectious , it is not contagious and represents the most common form of ocular allergy, affecting both eyes simultaneously and often co-occurring with . The condition encompasses several subtypes, including seasonal allergic conjunctivitis (SAC), which is triggered by seasonal allergens like and affects up to 90% of ocular allergy cases; allergic conjunctivitis (), caused by year-round indoor allergens; (VKC), a more severe form common in children; atopic keratoconjunctivitis (AKC), associated with ; and giant papillary conjunctivitis (GPC), often linked to wear or ocular prostheses. Etiologically, it involves an IgE-mediated reaction, where allergens bind to mast cells and in the , releasing and other mediators that cause , increased , and . Risk factors include a personal or family history of , environmental exposure to allergens, and in some cases, or genetic predispositions. Epidemiologically, allergic conjunctivitis has a global prevalence estimated at 6-30% in the general population, with higher rates—up to 40%—in those with allergic diseases, and it is particularly common in areas with increased exposure. In the United States and , recent estimates indicate that up to 40% of the population experiences ocular symptoms, often in combination with nasal symptoms. Symptoms can range from mild and self-limiting to chronic and vision-threatening in severe forms like VKC or AKC, potentially leading to corneal involvement, scarring, or secondary infections if untreated. Management focuses on avoidance, such as using air filters or removing pets, alongside symptomatic relief with topical antihistamines, stabilizers (e.g., cromolyn sodium), or dual-action agents like . For moderate to severe cases, short-term topical corticosteroids or immunomodulators like cyclosporine may be prescribed, while oral antihistamines address associated systemic symptoms; is an option for persistent triggers. Early through clinical , slit-lamp examination, and sometimes allergy testing is essential to differentiate it from other forms of conjunctivitis and prevent complications.

Background

Definition

Allergic conjunctivitis is an inflammatory condition of the , the thin, transparent that lines the inner surface of the eyelids and covers the (the white part of the eyeball), triggered by a reaction to environmental allergens. This response involves the binding of allergen-specific (IgE) antibodies to sensitized mast cells in the conjunctival tissue, leading to their rapid and the release of inflammatory mediators such as , leukotrienes, and cytokines. The resulting causes localized symptoms distinct from those of infectious conjunctivitis, which is typically caused by bacterial or viral pathogens and is contagious, whereas allergic conjunctivitis is noninfectious and arises solely from immune-mediated allergic sensitization. The plays a protective role by lubricating the ocular surface, preventing microbial entry, and facilitating smooth eyelid movement over the eye. In allergic conjunctivitis, exposure to allergens—such as or dust mites—cross-links IgE on mast cells, initiating an early-phase response characterized by immediate and increased , followed by a late-phase influx of and other inflammatory cells that prolong the reaction. Ocular manifestations of allergic disease, including , were first described in 1819 by English physician in his account of "hay fever," where he detailed a patient's seasonal itchy eyes alongside nasal symptoms, linking them to exposure. This early recognition established allergic conjunctivitis as a component of systemic atopic responses, later differentiated from other forms through immunological studies in the 20th century.

Epidemiology

Allergic conjunctivitis is a common ocular manifestation of allergic disease, affecting an estimated 10% to 30% of the global population, with recent studies reporting rates as high as 15% to 40% in various regions. In industrialized countries, such as those in , up to 40% of individuals experience some form of , with allergic conjunctivitis comprising a significant portion of ocular allergies. The condition is particularly prevalent among atopic individuals, where it often co-occurs with and ; for instance, ocular symptoms are reported in up to 60% of patients with . The disease exhibits distinct age and patterns. It most frequently onset in individuals younger than 20 years, with decreasing in older age groups, though severe forms like (VKC) peak between ages 5 and 10, while atopic keratoconjunctivitis (AKC) is more common in adults aged 30 to 50. Seasonal and perennial forms affect all ages but are especially common in children and young adults. Regarding , there is a male predominance (2:1 to 3:1 ratio) in VKC and AKC, while overall allergic conjunctivitis shows no strong bias, though some studies note slight variations by subtype. Key risk factors include , , and environmental exposures. A family history of significantly elevates risk, with affected individuals showing higher susceptibility to allergic diseases, including . Association with other atopic conditions is strong; for example, 75% of patients with experience concomitant . Environmental factors such as pollen exposure, , , and contact with pets or dust mites further contribute, particularly in atopic populations. Geographically, prevalence varies with environmental conditions. Seasonal forms are more common in pollen-rich temperate regions during and summer, while perennial variants predominate in dusty, environments with ongoing exposure. VKC shows higher incidence in warm, dry climates, such as the , , , and , and is rarer in temperate zones. As of 2025, the incidence of allergic conjunctivitis continues to rise, driven by , which extends seasons and increases potency. Studies from 2020 to 2024 indicate that warmer temperatures and elevated CO2 levels have lengthened seasons by up to 20 days in and intensified symptoms globally, exacerbating population-level burden.

Classification

Seasonal and Perennial Allergic Conjunctivitis

Seasonal allergic conjunctivitis () and perennial allergic conjunctivitis () represent the most common and milder forms of allergic conjunctivitis, collectively accounting for the majority of cases worldwide. is the predominant subtype, comprising approximately 90% of all allergic conjunctivitis instances, while is the second most common. These conditions are IgE-mediated reactions triggered by environmental , leading to degranulation and release of inflammatory mediators such as and leukotrienes. They typically present with bilateral ocular involvement and are self-limiting in , resolving outside of allergen seasons, whereas exhibits recurrent, year-round symptoms. SAC is primarily triggered by seasonal airborne allergens, particularly pollen from trees (e.g., birch, oak) and grasses (e.g., ryegrass, timothy), with symptoms peaking during spring and summer months in temperate climates. Clinical manifestations include intense ocular pruritus, conjunctival hyperemia, chemosis, tearing, and mild photophobia, often accompanied by associated allergic rhinitis. These episodes are episodic and acute, with symptoms intensifying upon direct allergen exposure and subsiding when pollen counts decrease, typically off-season. Histologically, SAC features prominent eosinophil infiltration in the conjunctival epithelium and substantia propria, alongside mast cell activation, but with minimal to no corneal involvement, preserving visual acuity in most cases. In contrast, PAC arises from persistent exposure to indoor perennial allergens, such as house dust mites (e.g., Dermatophagoides pteronyssinus), animal , and mold spores, resulting in chronic, low-grade throughout the year. Symptoms mirror those of but are milder and more persistent, including intermittent itching, watery discharge, and subtle conjunctival injection, with exacerbations linked to indoor allergen levels (e.g., higher in autumn). Unlike the intense, seasonal flares of , PAC demonstrates a recurrent pattern without complete resolution, often fluctuating with environmental control measures. Histological findings include similar and predominance in the , with elevated tear levels of like IL-8, but again, corneal changes are rare and insignificant. The key distinctions between and lie in their temporal patterns and allergen sources: is characterized by acute, intense episodes tied to outdoor seasonal triggers, whereas involves persistent, lower-intensity symptoms from ubiquitous indoor s. Both forms share overlapping involving early-phase (immediate release within minutes) and late-phase ( recruitment hours later) responses, as detailed in broader discussions of allergic mechanisms.

Vernal and Atopic Keratoconjunctivitis

Vernal keratoconjunctivitis (VKC) represents a severe, chronic form of allergic ocular that primarily affects young males, typically those under 10 years of age at onset, with recurrences often linked to warm, dry climates such as those in the Mediterranean or ; it accounts for less than 1% of ocular allergy cases in temperate regions but higher prevalence (up to 10%) in endemic areas. It involves pronounced inflammatory changes in the limbal and tarsal , characterized by the development of giant papillae—cobblestone-like elevations exceeding 1 mm on the upper tarsal —and Horner-Trantas dots at the limbus, reflecting infiltration. These features distinguish VKC as a mixed IgE- and T-cell-mediated disorder, driven by Th2 cytokines, unlike purely IgE-dependent milder allergies. Complications can include shield ulcers, which are superficial corneal erosions filled with and mucus plaques, potentially leading to scarring if untreated. Although VKC is often an isolated ocular condition, it carries a strong association with , including personal or family histories of or eczema in up to 75% of cases. Atopic keratoconjunctivitis (AKC), in contrast, is a chronic, bilateral inflammatory disease of the ocular surface closely tied to systemic , occurring in approximately 95% of affected individuals, and predominantly impacts adults aged 20 to 50 years; it is rare, representing about 0.1-0.5% of ocular allergy referrals. It extends beyond the to involve deeper tissues, with signs including conjunctival keratinization, scarring, and —adhesions between the and —that heighten the risk of and permanent vision loss. Like VKC, AKC features a mixed involving IgE-mediated alongside T-cell-driven chronic inflammation, often as part of a broader atopic encompassing and in over 80% of patients. Both conditions underscore the interplay between local ocular and systemic , with VKC more episodic and pediatric-focused, while AKC persists as a lifelong threat in atopic adults, potentially progressing to blinding complications like corneal ulceration or without aggressive intervention.

Giant Papillary Conjunctivitis

Giant papillary conjunctivitis (GPC) is a form of ocular surface characterized by the formation of giant papillae exceeding 1 mm in diameter on the superior tarsal ; while not a primary subtype of airborne allergic conjunctivitis, it affects 1-5% of soft contact lens wearers globally. This condition arises primarily from chronic mechanical irritation rather than allergens, most commonly associated with wear—particularly soft lenses, which account for the majority of cases—along with ocular prostheses or exposed sutures. The incidence of GPC affects 1-5% of soft contact lens wearers, with a lower rate observed among rigid gas-permeable users due to reduced deposit accumulation and . Key risk factors include poor , extended wearing schedules, infrequent replacement of non-disposable lenses, and individual to protein deposits on lenses; may also predispose affected individuals. Clinically, GPC typically begins with ocular itching and excessive discharge, advancing to intolerance, increased awareness, and potential if the irritant persists untreated. Histologically, GPC features infiltration of the by mast cells in the , eosinophils in the or substantia propria, and , alongside plasma cells and lymphocytes, reflecting a mixed inflammatory response. While appear in conjunctival scrapings of less than one-fourth of cases, the condition involves both type I and mechanisms, with comparatively reduced IgE-mediated involvement relative to other forms of allergic conjunctivitis.

Clinical Presentation

Signs and Symptoms

Allergic conjunctivitis typically presents with intense ocular itching, which is considered the hallmark symptom and often worsens with eye rubbing. Patients commonly experience watery or excessive tearing, along with a sensation in the eyes. Additional symptoms may include burning or stinging sensations and stringy mucoid . Clinical signs are primarily ocular and bilateral in most cases, featuring conjunctival hyperemia or redness, (conjunctival swelling), and , which is often more pronounced in the morning. In severe forms, and mild papillary reactions on the may occur. The condition frequently accompanies , with associated nasal symptoms such as sneezing and congestion; eye rubbing can further exacerbate both ocular and nasal irritation. Subtype variations influence symptom patterns, with seasonal allergic conjunctivitis (SAC) causing acute episodes lasting hours to days during pollen seasons, while perennial allergic conjunctivitis (PAC) and atopic keratoconjunctivitis (AKC) present with more persistent, chronic symptoms year-round. Allergic conjunctivitis significantly impacts , leading to sleep disturbances, reduced , and discomfort that can interfere with daily activities. In pediatric patients, severe symptoms may contribute to school absenteeism and affect both children and their parents' sleep quality.

Causes and Pathophysiology

Causes

Allergic conjunctivitis is primarily triggered by exposure to environmental allergens that provoke an in sensitized individuals. Airborne allergens, such as from trees, grasses, and weeds, as well as mold spores, are common culprits, particularly during seasonal peaks. Indoor allergens including house dust mites, animal , and feathers contribute to year-round exposure, often exacerbating symptoms in enclosed environments. Contact allergens, such as applied near the eyes and preservatives like in or solutions, can directly irritate the ocular surface and induce localized reactions. Host factors play a critical role in susceptibility, with genetic predisposing individuals to heightened IgE-mediated responses following prior to allergens. Specific (HLA) associations, including HLA-DR/Dw2 alleles, have been implicated in atopic responses that increase the risk of allergic conjunctivitis. This interacts with environmental exposures to facilitate allergen-specific IgE production upon re-exposure. Precipitating events often align with patterns of exposure, such as seasonal surges that trigger acute episodes. Occupational settings, like farming, heighten risk through prolonged contact with and materials, leading to in workers. Iatrogenic factors, including preservatives in solutions, precipitate giant papillary in lens wearers by promoting chronic mechanical and allergic irritation. While not primary causes, non-allergic contributors like from and can exacerbate allergic conjunctivitis by enhancing airway and ocular in sensitized individuals. Recent analyses indicate that is intensifying aeroallergen potency and extending seasons, thereby amplifying the triggers for allergic diseases, as noted in assessments.

Pathophysiology

Allergic conjunctivitis is fundamentally driven by a reaction, in which environmental allergens bind to (IgE) antibodies already attached to the surface of sensitized cells and in the conjunctival tissue. This cross-linking of IgE molecules triggers rapid degranulation of these cells, releasing preformed mediators such as , as well as newly synthesized lipid mediators including leukotrienes and prostaglandins. These events initiate an acute inflammatory response characterized by increased and smooth muscle contraction in the ocular surface. The inflammatory cascade unfolds in two distinct phases. The early phase, occurring within minutes of allergen exposure, is dominated by the effects of and other immediate mediators, leading to , conjunctival hyperemia, and intense itching due to stimulation of H1 receptors on sensory nerves. This phase typically resolves within 20-30 minutes but sets the stage for the late phase, which peaks 4-8 hours later and involves recruitment of additional inflammatory cells. In the late phase, such as eotaxin and cytokines including interleukin-4 (IL-4) and IL-5 are released, promoting the migration and activation of , , and T helper 2 (Th2) lymphocytes to the . , in particular, contribute to tissue damage through the release of major basic protein and other cytotoxic granules. Tissue-specific features of the amplify this response, with a notably higher of mast cells compared to , facilitating a more pronounced local reaction. The conjunctival , which serves as a barrier, becomes disrupted during , allowing further penetration and leading to (chemosis) from fluid . This epithelial compromise also exposes goblet cells, enhancing mucus production and contributing to the characteristic tearing and discharge. Variations in pathophysiology exist across subtypes. Seasonal allergic conjunctivitis (SAC) and perennial allergic conjunctivitis (PAC) primarily involve a pure IgE-mediated mechanism with episodic activation, resulting in milder, self-limiting . In contrast, (VKC) and atopic keratoconjunctivitis (AKC) feature a mixed Th2-dominated response, where chronic T-cell infiltration and release (e.g., IL-4, IL-13) drive activation and deposition. These severe forms exhibit persistent survival due to resistance to , mediated by IL-5 and other survival factors. In chronic cases, particularly VKC and AKC, repeated inflammatory episodes lead to conjunctival remodeling, including subepithelial , , and potential cicatricial changes that alter tissue architecture over time. This remodeling perpetuates a cycle of and structural damage, distinguishing these from the more acute and .

Diagnosis

Clinical Evaluation

The clinical evaluation of allergic conjunctivitis begins with a comprehensive history to establish an allergic etiology and identify potential triggers. Key elements include assessing personal and family history of , such as , , or eczema, which is common, particularly in severe forms like VKC where up to 90% of cases have such a history. Seasonal patterns should be explored, with symptoms often correlating to exposure in spring or fall for seasonal allergic conjunctivitis, while perennial forms may relate to indoor allergens like dust mites or pet dander. Exposure history encompasses environmental factors, occupational irritants, and use, which is particularly relevant for giant papillary conjunctivitis. The symptom timeline is crucial, with bilateral ocular itching typically onsetting rapidly after allergen exposure and often accompanied by nasal symptoms, with up to 94% of patients experiencing concomitant . Physical examination focuses on ocular structures to confirm characteristic signs and rule out complications. External inspection reveals bilateral conjunctival hyperemia, chemosis, and eyelid edema, with patients frequently demonstrating rubbing behavior due to intense pruritus. Slit-lamp biomicroscopy is essential for detailed assessment, revealing fine papillae on the tarsal conjunctiva, graded by size and distribution to differentiate subtypes—such as larger papillae in . Fluorescein staining evaluates epithelial integrity, identifying punctate erosions or shield ulcers in severe cases. Eversion of the upper eyelid, performed gently with a , allows inspection for giant papillae greater than 1 mm, a hallmark of vernal or giant papillary forms. Objective confirmatory tests support the during . Conjunctival scraping, obtained via a sterile under topical , demonstrates , providing histopathological evidence of allergic in vernal cases. Tear film breakup time, measured via slit-lamp after fluorescein instillation, is often reduced below 10 seconds, indicating instability exacerbated by allergic mediators. In pediatric patients, incorporates parental input on symptom frequency and severity, as children may not articulate discomfort clearly; reports of frequent eye rubbing or seasonal exacerbations are particularly indicative, with peaking in boys aged 5-10 years. As of 2025, advancements in telemedicine facilitate remote clinical through smartphone-based , where adapters attach to devices for anterior segment , enabling of conjunctival injection and papillae in follow-up for conditions like allergic conjunctivitis with high concordance to in-person exams.

Differential Diagnosis

Differentiating allergic conjunctivitis from other causes of is essential to avoid misdiagnosis and ensure targeted treatment, as symptoms like conjunctival injection and can overlap with infectious, toxic, and inflammatory conditions. The hallmark bilateral itching and watery in allergic conjunctivitis contrast with features such as purulent exudate or unilateral involvement in other etiologies. Infectious causes must be ruled out promptly due to their contagious nature and potential for complications. Bacterial conjunctivitis often presents unilaterally with purulent discharge, eyelid swelling, and a more rapid onset compared to the chronic or seasonal pattern of allergic disease. Viral conjunctivitis, particularly adenovirus-associated, typically features watery discharge, a follicular conjunctival response, preauricular , and may start unilaterally before becoming bilateral, without the intense pruritus seen in allergic cases. Other infectious mimics include chlamydial or molluscum contagiosum-related conjunctivitis, which may show or lid lesions on examination. Other allergic or hypersensitivity reactions can mimic allergic conjunctivitis but stem from different triggers. Drug-induced allergic conjunctivitis, often linked to topical antibiotics, preservatives like , or systemic medications, presents with similar redness and itching but is tied to recent exposure history and may resolve upon discontinuation. , involving allergens such as , , or neomycin, frequently affects the eyelids and periocular skin alongside conjunctival involvement, leading to eczematous changes rather than isolated bulbar injection. Non-infectious mimics include several ocular surface disorders that lack the allergic component. is distinguished by a gritty or burning sensation outweighing itching, reduced , and minimal discharge, often exacerbated by environmental factors without seasonal correlation. Superior limbic keratoconjunctivitis features superior bulbar conjunctival inflammation, linear staining of the upper with , and foreign body sensation or , but lacks the pronounced bilateral itching of allergic conjunctivitis. , an intraocular inflammation, manifests with significant , ciliary flush, pain, and vision loss due to anterior chamber cells and flare, contrasting the superficial symptoms of allergic conjunctivitis. Red flags necessitating ophthalmologic referral include any vision changes, severe pain, photophobia beyond mild discomfort, or corneal involvement suggestive of , such as epithelial defects or infiltrates, which could indicate progression to more serious conditions like herpetic or bacterial . These features prompt urgent evaluation to prevent permanent damage. Diagnostic aids can support differentiation when clinical history and exam are inconclusive. skin prick testing or serum-specific IgE levels help identify environmental allergens triggering the reaction, confirming an IgE-mediated process. Conjunctival scrapings may reveal , a supportive finding for , while bacterial or viral cultures can exclude ; conjunctival is rarely indicated except in atypical or refractory cases to rule out cicatrizing diseases.

Management

Avoidance and Non-Pharmacological Measures

Avoidance of allergens is a cornerstone of managing allergic conjunctivitis, as reducing exposure can significantly alleviate symptoms without the need for medications. For pollen-related allergic conjunctivitis, patients are advised to stay indoors during peak pollen seasons, particularly on windy days, and to keep windows closed while using air conditioning with high-efficiency particulate air (HEPA) filters to minimize indoor pollen infiltration. Similarly, for dust mite allergens, encasing mattresses, pillows, and box springs in allergen-proof covers, washing bedding weekly in hot water (at least 130°F or 54°C), and maintaining indoor humidity below 50% through dehumidifiers are effective measures to reduce mite populations and associated symptoms. Pet dander can be mitigated by establishing pet-free zones in bedrooms and using HEPA-filtered vacuums regularly to capture airborne particles. Hygiene practices play a vital role in preventing exacerbation. Frequent washing of hands and face, especially after outdoor activities, removes allergens that may transfer to the eyes. For wearers, removing lenses during symptom flares and adhering to rigorous cleaning protocols—such as daily rubbing with preservative-free solutions and weekly enzymatic treatments—helps prevent giant papillary (GPC), a subtype linked to lens deposits. Wearing wraparound outdoors acts as a barrier against wind-borne allergens like . Modifications to the home and office environment further support symptom control. Installing air purifiers in living spaces filters out airborne allergens, while avoiding carpets and opting for hard flooring reduces dust accumulation. In cases of GPC, switching to daily disposable lenses or limiting wear time to fewer hours per day can minimize mechanical irritation and protein buildup on lenses. Behavioral strategies emphasize non-irritating relief methods. Patients should avoid rubbing their eyes, which can worsen through mechanical release of mediators; instead, applying cool compresses for 10-15 minutes several times daily soothes itching and reduces swelling. Using preservative-free frequently dilutes allergens and inflammatory mediators on the ocular surface, providing immediate symptomatic relief. These non-pharmacological measures have demonstrated efficacy, particularly in mild cases. A showed that combining with cold compresses significantly reduced ocular hyperemia and surface temperature compared to either alone (P < 0.05), with effects persisting beyond baseline levels in seasonal allergic conjunctivitis models. Overall, allergen avoidance and supportive practices can reduce symptom severity in mild presentations, serving as a first-line approach before considering pharmacological options.

Pharmacological Treatments

Pharmacological treatments for allergic conjunctivitis aim to alleviate symptoms by targeting the release and effects of and other inflammatory mediators in the ocular surface. These therapies are typically topical to minimize systemic side effects, with systemic options reserved for cases involving widespread or severe disease. First-line agents include antihistamines, stabilizers, and dual-action drugs, while corticosteroids and nonsteroidal anti-inflammatory drugs (NSAIDs) are used for more refractory or acute presentations. Topical antihistamines block H1 receptors to rapidly reduce itching, redness, and associated with seasonal () and perennial allergic conjunctivitis (). Examples include emedastine (0.05%, dosed 1 drop four times daily), (0.05%, 1 drop twice daily), and (0.05%, 1 drop four times daily), which provide onset of action within minutes and last up to 12 hours. These agents are particularly effective for mild to moderate symptoms and are well-tolerated, though they may cause mild stinging upon instillation. Oral antihistamines, such as loratadine (10 mg daily) or fexofenadine (180 mg daily), offer systemic relief for patients with concomitant but are less targeted for ocular symptoms alone. Mast cell stabilizers inhibit and mediator release, making them suitable for prophylactic use in patients with predictable exposure. Cromolyn sodium (4%, 1 drop four to six times daily) and lodoxamide (0.1%, 1 drop four times daily) require regular application for 1-2 weeks to achieve maximal effect, after which they can prevent symptoms during seasons. These agents are safe for long-term use with minimal side effects, though their slower onset limits utility in acute flares. Dual-action agents combine and stabilizing properties, serving as first-line for SAC and PAC due to their broad efficacy and convenience. (0.1% or 0.2%, 1 drop twice daily) and (0.025%, 1 drop twice daily) provide rapid symptom relief within 30 minutes and sustained control for up to 12 hours, outperforming single-action agents in clinical trials. Newer formulations, such as preservative-free , reduce ocular surface irritation, and alcaftadine (0.25%, 1 drop once daily) offers similar benefits with once-daily dosing. These drugs are recommended by guidelines for their favorable safety profile and efficacy in reducing itching and hyperemia. NSAIDs inhibit enzymes to block prostaglandin-mediated inflammation, providing adjunctive relief in refractory cases unresponsive to antihistamines. (0.5%, 1 drop four times daily) is the most commonly used, with short-term application (up to one week) effective for reducing conjunctival hyperemia and discomfort, though it may cause transient burning. Other options like (0.1%) show similar efficacy but are not routinely recommended as monotherapy due to potential corneal irritation. Topical corticosteroids potently suppress the allergic inflammatory cascade but are reserved for severe flares or vernal/atopic keratoconjunctivitis (VKC/AKC) due to risks like elevated and . Fluorometholone (0.1%, 1 drop four times daily, tapered over 1-2 weeks) and (0.2% or 0.5%, 1 drop four times daily initially) are preferred for their lower risk of adverse effects compared to prednisolone. Use should be limited to short courses under ophthalmologic monitoring, with intraocular pressure checks recommended after one week. For patients with systemic or inadequate response to topical therapies, systemic options include second-generation oral antihistamines like loratadine for broad symptom control. In severe AKC, emerging biologics such as (subcutaneous, dosed every 2-4 weeks based on IgE levels and weight) and have shown promise in case series and clinical studies by reducing ocular inflammation and steroid dependence, though not yet specifically approved for this indication. typically begins with monotherapy, escalating as needed, and corticosteroids are tapered promptly to avoid complications.

Immunotherapy

Immunotherapy, also known as allergen-specific (AIT), represents a for allergic conjunctivitis by inducing to specific allergens, thereby reducing long-term symptom severity and medication dependence. It is particularly indicated for patients with moderate-to-severe seasonal or perennial allergic conjunctivitis who have not achieved adequate control with , including those sensitized to or house dust mites. Treatment typically spans 3 to 5 years to achieve durable effects, with evaluation for continuation based on response. Subcutaneous immunotherapy (SCIT) involves administering escalating doses of extracts via injections, starting with build-up phases and progressing to maintenance doses every 4 weeks. It is effective for pollen-related seasonal allergic conjunctivitis (), with studies demonstrating approximately 50% improvement in visual analog scale (VAS) scores for symptoms after 3 years of . SCIT reduces conjunctival symptom scores and use, offering superior efficacy compared to sublingual options in some analyses. Sublingual immunotherapy (SLIT) delivers allergens through tablets or drops placed under the , providing a safer, home-administered alternative to SCIT with fewer systemic risks. FDA-approved SLIT options, such as Odactra for house dust mite-induced with or without , were expanded in 2025 to include children aged 5 through 11 years. SLIT significantly improves ocular symptoms in perennial cases, with moderate evidence from meta-analyses showing reduced scores and decreased rescue medication needs. The mechanism of AIT involves shifting the immune response from a Th2-dominant profile, which promotes IgE-mediated inflammation, to a Th1 response with increased production of regulatory T-cells (Tregs) that suppress allergen-specific reactions. This tolerance induction leads to decreased mast cell degranulation and eosinophil recruitment in the conjunctiva, providing long-term protection. Outcomes of AIT include sustained clinical benefits post-treatment, with many patients experiencing prolonged remission of symptoms and reduced allergen sensitivity for years after completion. Common side effects are local reactions, such as oral itching with SLIT or injection-site swelling with SCIT, though systemic anaphylaxis is rare (less than 0.1% for SCIT). Recent advances include ocular-specific SLIT trials demonstrating promise for severe forms like vernal keratoconjunctivitis (VKC), with 2024 reviews highlighting significant reductions in ocular symptom scores through targeted allergen desensitization.

Complications and Prognosis

Complications

Allergic conjunctivitis, particularly in its severe forms such as (VKC) and atopic keratoconjunctivitis (AKC), can lead to significant ocular complications if untreated or inadequately managed. Corneal erosions and ulcerations are prominent risks, with shield ulcers occurring in approximately 3-11% of VKC cases, often resulting from the accumulation of and plaques that disrupt the epithelial surface. These ulcers, typically oval-shaped and located centrally or paracentrally, can progress to stromal opacification and increase susceptibility to secondary bacterial infections, especially in AKC where persistent epithelial defects heighten the risk of bacterial, fungal, or herpetic . Untreated erosions and infections may further cause corneal scarring, which can induce irregular and impair . Chronic inflammation in severe cases contributes to long-term structural changes, including and , particularly in AKC, where adhesions form between the palpebral and bulbar , potentially leading to fornix shortening and restricted ocular . Prolonged use of topical corticosteroids for exacerbates these risks, with an elevated incidence of cataracts—often anterior subcapsular or posterior types—observed in AKC patients requiring extended . Additionally, chronic eye rubbing associated with atopic conditions increases the risk of vision-threatening , with up to a 37% higher in those with allergic conjunctivitis. Severe allergen exposures can uncommonly lead to systemic allergic reactions, including rare instances of manifesting with ocular swelling alongside broader responses. Chronic symptoms also impose quality-of-life burdens, such as anxiety and reduced productivity due to persistent discomfort and visual interference. Overall, complications arise in fewer than 5% of mild seasonal cases but affect up to 30% of severe VKC or AKC presentations, with corneal ulcers reported in about 9.7% of VKC patients.

Prognosis

Allergic conjunctivitis generally carries a favorable , particularly with timely and , as most cases are self-limiting and do not result in permanent loss. Symptoms in seasonal allergic conjunctivitis (SAC) and perennial allergic conjunctivitis (PAC), the most common forms, typically resolve completely between exposures, with rare corneal involvement or long-term sequelae when treated appropriately. Recurrences are common upon re-exposure to allergens, but these do not usually progress to chronic damage, emphasizing the importance of avoidance strategies for sustained symptom control. In more severe variants like (VKC), the condition is often self-limited, with occurring in approximately 95% of patients by late or around age 20. However, up to 6% of VKC cases may lead to vision-threatening complications, including corneal scarring, shield ulcers, or , particularly if giant tarsal papillae are present or is inadequate. Recent studies as of 2024 indicate that even patients receiving s or immunomodulators continue to have an elevated prevalence of complications such as corneal scars. Atopic keratoconjunctivitis (AKC), associated with systemic , follows a more chronic course without reliable remission rates, increasing the risk of persistent inflammation and secondary issues like cataracts or from prolonged corticosteroid use. Overall outcomes improve significantly with multidisciplinary care, including monitoring for treatment-related risks such as steroid-induced , which can cause irreversible if unaddressed. Early intervention remains key to minimizing recurrences and preventing rare but serious complications across all subtypes.