In the classic form, mediator release occurs when the antigen (allergen) binds to antigen-specific immunoglobulin E (IgE) attached to previously sensitized basophils and mast cells. The mediators are released almost immediately when the antigen binds. In an anaphylactoid reaction, exposure to an inciting substance causes direct release of mediators, a process that is not mediated by IgE. Increased mucous secretion and increased bronchial smooth muscle tone, as well as airway edema, contribute to the respiratory symptoms observed in anaphylaxis. Cardiovascular effects result from decreased vascular tone and capillary leakage. Histamine release in skin causes urticarial skin lesions.

The most common inciting agents in anaphylaxis are parenteral antibiotics (especially penicillins), IV contrast materials, Hymenoptera stings, and certain foods (most notably, peanuts). Oral medications and many other types of exposures also have been implicated. Anaphylaxis also may be idiopathic.

Approximately 1 in 5000 exposures to a parenteral dose of a penicillin or cephalosporin antibiotic causes anaphylaxis. More than 100 deaths per year are reported in the United States. Fewer than 100 fatal reactions to Hymenoptera stings are reported each year in the United States but this is considered to be an underestimate. One to 2% of people receiving IV radiocontrast experience some sort of reaction. The majority of these reactions are minor, and fatalities are rare. Low molecular weight contrast causes fewer and less severe reactions.

Eyes may itch and tearing may be noted. Conjunctival injection may occur.

Dyspnea is present when patients have bronchospasm or upper airway edema. Hypoxia and hypotension may cause weakness, dizziness, or syncope. Chest pain may occur due to bronchospasm or myocardial ischemia (secondary to hypotension and hypoxia). GI symptoms of cramplike abdominal pain with nausea, vomiting, or diarrhea also occur but are less common, except in the case of food allergy.

In a classic case of anaphylaxis, the patient or a bystander provides a history of possible exposures that may have caused the rapid onset of skin and other manifestations. This history often is partial; exposure may not be recalled, or it may not be considered significant by the patient or physician. For example, when queried about medications, a patient may not mention over-the-counter (OTC) products. The clinician may not realize that, while reactions are usually rapid in onset, they also may be delayed.

Frank cardiovascular collapse or respiratory arrest may occur in severe cases. Anxiety is common unless hypotension or hypoxia causes obtundation. Shock may occur without prominent skin manifestations or history of exposure; therefore, anaphylaxis is part of the differential diagnosis for patients who present with shock and no obvious cause.

The classic skin manifestation is urticaria (ie, hives). Lesions are red and raised, and they sometimes have central blanching. Intense pruritus occurs with the lesions. Lesion borders usually are irregular and sizes vary markedly. Only a few small or large lesions may become confluent, forming giant urticaria. At times, the entire dermis is involved with diffuse erythema and edema. Hives can occur anywhere on the skin

In a local reaction, lesions occur near the site of a cutaneous exposure (e.g.: insect bite). The involved area is erythematous, edematous, and pruritic. If only local skin reaction (as opposed to generalized urticaria) is present, systemic manifestations (e.g.: respiratory distress) are less likely. Local reactions, even if severe, are not predictive of systemic anaphylaxis on re-exposure. Lesions typical of angioedema also may manifest in anaphylaxis. The lesions involve mucosal surfaces and deeper skin layers. Angioedema usually is nonpruritic and associated lesions are nonpitting. Lesions most often appear on the lips, palms, soles, and genitalia.

Upper airway compromise may occur when the tongue or oropharynx is involved. When the upper airway is involved, stridor may be noted. The patient may have a hoarse or quiet voice and may lose speaking ability as the edema progresses. Complete airway obstruction is the most common cause of death in anaphylaxis. Wheezing is common when patients have lower airway compromise due to bronchospasm or mucosal edema. In angioedema, due to ACE inhibitors, marked edema of the tongue and lips may obstruct the airway.

Cardiovascular examination is normal in mild cases. In more severe cases, compensatory tachycardia occurs due to loss of vascular tone. Intravascular volume depletion may take place as a consequence of capillary leakage. These mechanisms also lead to development of hypotension. Relative bradycardia has been reported.

Parenteral exposures tend to result in faster and more severe reactions. Most severe reactions occur soon after exposure. The faster a reaction develops, the more severe it is likely to be. While most reactions occur within hours, symptoms may not occur for as long as 3-4 days after exposure.

Penicillin and cephalosporin antibiotics are the most commonly reported medical agents in anaphylaxis. This prevalence is a function of the immunogenicity and overuse of these agents. Because of their molecular and immunologic similarity, cross- sensitivity may exist. Reports often assert that 10% of patients allergic to a penicillin antibiotic are allergic to cephalosporins. A recent report suggests that actual incidence of cross-reactivity is lower (perhaps 1%), with most reactions considered mild. A more recent review indicated that patients with a history of allergy to penicillin seem to have a higher risk (by a factor of about 3) of subsequent reaction to any drug and that the risk of an allergic reaction to cephalosporins in patients with a history of penicillin allergy may be up to 8 times as high as the risk in those with no history of penicillin allergy (i.e.: at least part of the observed "cross reactivity" may represent a general state of immune hyperresponsiveness, rather than true cross-reactivity).

History of penicillin or cephalosporin allergy often is unreliable and is not predictive of future reactions. Up to 85% of patients reporting an allergic reaction to penicillin do not react on subsequent exposure. When a drug in either class is the drug of choice for a patient with a life-threatening emergency, a number of options exist. When the history is indefinite, the drug may be administered under close observation; however, when possible, obtain the patient's informed consent. Immediate treatment measures for anaphylaxis should be available. Alternatively, when the history is more convincing, a desensitization or prophylactic pretreatment protocol may be instituted or another agent selected.

Aspirin and nonsteroidal anti-inflammatory drugs (NSAIDs) commonly are implicated in allergic reactions and anaphylaxis. Bronchospasm is common in patients with reactive airway disease and nasal polyps. Cross- reactivity may occur between the various NSAIDs.

IV administered radiocontrast media causes an anaphylactoid reaction that is clinically identical to true anaphylaxis and is treated in the same way. The reaction is not related to prior exposure. Shellfish or "iodine allergy" is not a contraindication to use of IV contrast and does not mandate a pretreatment regimen. As with any "allergic" patient, give consideration to use of low molecular weight (LMW) contrast. The term iodine allergy is a misnomer. Iodine is an essential trace element present throughout the body. No one is allergic to iodine. Patients who report iodine allergy usually have had either a prior contrast reaction or a shellfish allergy. Manage these patients as indicated earlier.

Approximately 1-3% of patients who receive hyperosmolar IV contrast experience a reaction. Use of LMW contrast decreases incidence of reactions to approximately 0.5%. Personnel, medications, and equipment needed for treatment of allergic reactions always should be available when these agents are administered. Obtain consent before administration. Reactions to radiocontrast usually are mild (most commonly urticarial), with only rare fatalities reported. Risk of a fatal reaction has been estimated at 0.9 cases per 100,000 exposures. Pretreatment with antihistamines or corticosteroids and use of LMW agents lead to lower rates of anaphylactoid reactions to IV contrast. Consider these measures for patients who have prior history of reaction, since rate of recurrence is estimated at 17-60%. Patients who are atopic and/or asthmatic also are at increased risk of reaction. In addition, allergic reaction is more difficult to treat in those taking beta-blockers.

Hymenoptera (bee) stings are a common cause of allergic reaction and anaphylaxis. An uncertain but enormous number of exposures occur; accurate reaction rates are difficult to estimate. In the United States, Hymenoptera envenomations result in fewer than 100 reported deaths per year. Local reaction and urticaria without other manifestations of anaphylaxis are much more common than full-blown anaphylaxis. Generalized urticaria is a risk factor for subsequent anaphylaxis; but a local reaction, even if severe, is not a risk factor for anaphylaxis.

Caution patients treated and released from the ED after an episode of anaphylaxis or generalized urticaria from Hymenoptera envenomation to avoid future exposure when possible. Consider referral to an allergist for desensitization, particularly when further exposure is likely. Additionally, consider prescribing a treatment kit with an epinephrine auto- injector and oral antihistamine. Both are effective measures in preventing or ameliorating future reactions.

Food allergy is also common. Symptoms usually are mild and limited to the GI tract, but full-blown anaphylaxis can occur. Fatalities are rare compared to number of exposures; however, the number of exposures is so high that foods may be the commonest cause of anaphylaxis. Anaphylaxis due to foods may be an underrecognized cause of sudden death and an unappreciated cause of diagnosed anaphylaxis. Commonly implicated foods include nuts (especially peanuts), legumes, fish and shellfish, milk, and eggs.

Latex allergy is an increasingly recognized problem in medical settings, where use of gloves and other latex products is ubiquitous. Most reactions are cutaneous or involve the mucous membranes. Anaphylactic reactions occur and have been reported with seemingly benign procedures (e.g.: Foley catheter insertion, intraperitoneal exposure to gloves during surgery).

Testing for sensitivity to penicillin antibiotics may be useful when a penicillin or cephalosporin antibiotic is the drug of choice for a serious infection in a patient who has a history of severe allergic reaction. Obtain informed consent, and ensure that resuscitative equipment is immediately available. Protocols for acute testing for allergy to penicillin or cephalosporin antibiotics involve administration of increasing IV doses of the chosen antibiotic, while observing the patient for pruritus, flushing, urticaria, dyspnea, hypotension, or other manifestations of anaphylaxis. If no manifestations are observed, a full dose of the antibiotic may be administered safely.

A widely quoted protocol for prevention of reactions to IV contrast suggests the following: Use low osmolality contrast. Administer hydrocortisone (200 mg IV); wait 2 hours if clinically appropriate. Administer diphenhydramine (50 mg IM) immediately before the procedure.

Desensitization regimens for penicillin and cephalosporin antibiotic allergy have been shown effective. A typical desensitization regimen involves administering the antibiotic of choice in an initial dose of 0.01 mg. While observing the patient, double the dose every 10-15 minutes until a full dose has been administered. Desensitization regimens do not protect against non–IgE-mediated reactions that may be severe or even life threatening (e.g.: Stevens- Johnson syndrome).

Immediately assess airway patency due to the potential for compromise secondary to edema or bronchospasm. Active airway intervention may be difficult due to laryngeal or oropharyngeal edema. In this circumstance, it may be preferable to defer intubation attempts, and instead ventilate with a bag/ valve/mask apparatus while awaiting medications to take effect. In extreme circumstances, cricothyrotomy or catheter jet ventilation may be lifesaving. Inhaled beta-agonists are used to counteract bronchospasm and should be administered to patients who are wheezing.

The IV line should be of large caliber due to the potential requirement for large-volume IV fluid resuscitation. Isotonic crystalloid solutions (ie, normal saline, Ringer lactate) are preferred. A keep vein open (KVO) rate is appropriate for patients with stable vital signs and only cutaneous manifestations. If hypotension or tachycardia is present, administer a fluid bolus of 20 mg/kg for children and 1 L for adults. Further fluid therapy depends on patient response. Large volumes may be required in the profoundly hypotensive patient.

Administer epinephrine to patients with systemic manifestations of anaphylaxis. With mild cutaneous reactions, an antihistamine alone may be sufficient, thus the potential adverse effects of epinephrine can be avoided. Patients on beta-blocker medications may not respond to epinephrine. In these cases, glucagon may be useful. Antihistamines (e.g.: H1 blockers), such as diphenhydramine (Benadryl) are important and should be administered for all patients with anaphylaxis or generalized urticaria. Corticosteroids are used in anaphylaxis primarily to decrease the incidence and severity of delayed or biphasic reactions. Corticosteroids may not influence the acute course of the disease; therefore, they have a lower priority than epinephrine and antihistamines.

Hospital care begins with standard monitoring and treatment, including oxygen, cardiac monitoring, and a large-bore IV with isotonic crystalloid solution. Further intervention depends on severity of reaction and affected organ system(s). Rapidly assess airway patency in patients with systemic signs or symptoms. If required, intubation may be difficult to achieve because of upper airway or facial edema. Standard rapid sequence induction (RSI) techniques can be used but may cause loss of the airway in a patient whose airway anatomy is altered by edema. Epinephrine may rapidly reverse airway compromise, and bag/valve/mask ventilation may be effective in the interim when intubation is not possible. Surgical airway intervention using standard cricothyrotomy is an option when orotracheal intubation or bag/valve/ mask ventilation is not effective.

Wheezing or stridor indicates bronchospasm or mucosal edema. Treatment with epinephrine and inhaled beta-agonists is effective for these indications.

Recommendations to treat refractory bronchospasm with corticosteroids have been made because of their effectiveness in reactive airway disease. As in asthma therapy, onset of action is delayed for several hours. Aminophylline also has been recommended for bronchospasm in anaphylaxis and may be more rapidly effective than corticosteroids.

Hypotension in anaphylaxis usually is due to vasodilatation and capillary fluid leakage. Epinephrine is the primary pharmacologic treatment for these findings. H1-blocking antihistamines also may have a role in reversing hypotension. Some authors also recommend H2-blocking agents. Large volume fluid resuscitation with isotonic crystalloid often is needed to support the circulation in patients with cardiovascular manifestations of anaphylaxis.

Refractory hypotension first should be treated with large volumes of crystalloid and repeated doses of epinephrine or a continuous epinephrine infusion. If this is not effective, other pressors with alpha- adrenergic activity, such as levarterenol (Levophed) or dopamine, may be considered. Cases of effective use of military antishock trousers (MAST) for refractory hypotension have been reported.

Primary drug treatments for acute anaphylactic reactions are epinephrine and H1 antihistamines. These agents clearly are effective; do not delay or defer their use in favor of other treatments. Inhaled beta-agonists lack some of the adverse effects of epinephrine. Inhaled beta-agonists are useful for cases of bronchospasm, but they may not have additional effects when optimal doses of parenteral epinephrine are used. Corticosteroids mainly are effective in preventing biphasic (ie, delayed) reactions. Due to this delayed effect, corticosteroids are not first-line treatments. H2-blocking antihistamines theoretically are attractive agents, but evidence supporting their clinical effectiveness is less than for H1-blocking agents. Glucagon may be useful in treating refractory cardiovascular effects in patients taking beta-blockers.