Medications for Allergy

The use of intranasal corticosteroids is increasingly becoming first-line therapy for many patients with allergic rhinitis, especially those with moderate to severe symptoms or those with perennial allergic rhinitis in which nasal symptoms predominate. Intranasal corticosteroids specifically inhibit the allergic inflammatory processes that contribute to the late-phase response of nasal congestion. When used prophylactically, they can also inhibit the early-phase response to allergens. Overall, they are effective in relieving sneezing, nasal itching, rhinorrhea, and congestion.

Table 3 lists available intranasal corticosteroids, along with dosing information and comparative costs. In general, these agents are considered more cost-effective for use as monotherapy than 2nd-generation antihistamines. A recent meta-analysis found intranasal corticosteroids to be more effective than oral antihistamines in reducing nasal blockage, nasal discharge, sneezing, nasal itch, postnasal drip, and total nasal symptoms. No significant difference was detected for nasal discomfort, nasal resistance, and eye symptoms. No particular product has demonstrated clinical superiority, selection of drug should be based on factors such as response, ease of administration, cost, and formulation.

Table 3 Intranasal corticosteroids

Application site irritation (e.g., nasal irritation, burning, or sneezing after administration) is the most commonly encountered side effect. Patients complaining of local irritation may be switched to various aqueous formulations. Although rare, mucosal erosion and septal perforations have been reported with long-term use. To minimize septal irritation, patients should be instructed to direct the spray upwards and toward the lateral portion of the nose. Periodic examination of the nasal septum should be performed.

Although systemic effects from intranasal corticosteroids at recommended doses are considered minimal, there are some concerns regarding long-term exposure. Reports of posterior subcapsular cataract formation have been linked with the use of intranasal or inhaled corticosteroids; however, more recent prospective trials did not reveal evidence of posterior subcapsular cataract formation or elevation in intraocular pressure.

In 1998, the FDA’s advisory committees on pulmonary and allergy drugs and on metabolic endocrine drugs convened to assess data suggesting that intranasal corticosteroids may have an effect on growth velocity in children. Consequently, a new class labeling for pediatric use of inhaled and intranasal corticosteroids was mandated. At this time, the long-term significance of growth velocity reduction on final adult height is unknown. The FDA recommends routine monitoring of growth in pediatric patients using intranasal corticosteroids and titration to the lowest effective dose to minimize systemic risks.

Patient education is essential in ensuring proper use and compliance to intranasal corticosteroid therapy. Patients should be instructed on instillation techniques and informed about the possible delay in symptomatic response. Assessment of maximal response may require a therapeutic trial of several weeks. The drug should be administered regularly on a daily basis, rather than as needed for rescue relief.

For patients with severe disease, the combined use of intranasal corticosteroids and antihistamines may be necessary to control symptoms. The use of oral corticosteroids should be reserved for patients with severe exacerbations or intractable disease due to high risk of systemic adverse effects.

Most intranasal corticosteroids (CS) take a few days to work with the exception of the newer, more potent agents fluticasone and mometasone. Regardless, the maximum effect requires 1-2 weeks and possibly up to 3 weeks. Patients should be encouraged to contact their healthcare provider if no benefit is seen in this time. Often anti-allergy therapy is prescribed on a presumptive basis. Patients may be on intranasal CS therapy and not be aware of which allergens they are sensitive to. Skin prick allergy testing can easily assess allergy status. Once specific allergens are identified, appropriate environmental controls can be instituted.

When a patient exhibits intolerance to a specific intranasal corticosteroids product, an excipient in the formulation may be the cause. A suggested intervention would be to switch to an alternative product. For example, an alcohol-free product could be recommended over a product containing alcohol. Additional reinforcement should target instructions on proper nasal CS administration, and nasal conditioning (moisturizing). Often overlooked are patient-specific nasal behaviors. For example, a patient may be reporting nosebleeds, and through further inquiry reveals he is a frequent nose-picker; another patient may irrigate the nose with hydrogen peroxide. If nosebleeds remain problematic for the patient, referral to an Ear, Nose and Throat Specialist may be warranted. To facilitate tailoring patient therapy, Table 8 compares various intranasal corticosteroids available in the U.S.

Conclusion

Allergic rhinitis is characterized by acute and late phase reactions. Inflammation plays a dominant role in maintaining the late phase and contributes to the increased risk of complications. Intranasal steroids have been proven effective treatment for allergic rhinitis and are superior to oral antihistamines. Therefore, first-line treatment of allergic rhinitis should be intranasal steroids in patients with allergic rhinitis of perennial or seasonal pattern with persistent or moderate symptoms. Environmental control measures should target allergens relevant to the individual. Pharmacists are in a unique position to provide balanced information and take patient-specific factors into consideration when evaluating an individual patient for specific therapy for allergic rhinitis.