Allergic Reactions



Fig. 19.1
Incidence of allergic reactions to agents used in the perioperative period





Pathophysiology


Hypersensitivity is an excessive and undesirable reaction produced by a normal immune system. This reaction can be damaging, discomfort producing, and sometimes fatal. Hypersensitivity reactions require a pre-sensitized (immune) state of the host. Based on the mechanisms involved and the time taken for the reaction, hypersensitivity reactions can be divided into four types (Table 19.1).


Table 19.1
Types of hypersensitivity reactions







































 
Type I

Type II

Type III

Type IV

Mechanism

Immediate

Cytotoxic

Immune complex mediated

Delayed cell mediated

Response time

15–30 min

Minutes to hours

3–10 h

48–72 h

Antibody

IgE

IgM, IgG

Mainly IgG, IgM,

None

Antigens

Exogenous

Surface of cells

Soluble (not attached), exogenous or endogenous

Organs and tissues


Type I Hypersensitivity


The first step in type I hypersensitivity reactions involves an antigen binding to an antibody, IgE, on the surface of mast cells and basophils, which is known as sensitization (Fig. 19.2). This results in very little if any type of reaction upon initial exposure. It is the subsequent exposure to the same or similar antigen that results in an allergic reaction. After being sensitized to a specific antigen, the host recognizes the offending antigen and forms a cross-linking of two IgE antibodies, which results in degranulation and release of mediators from both mast cells and basophils. These mediators include histamine, arachidonic acid metabolites (leukotrienes and prostaglandins), kinins, eosinophil chemotactic factor of anaphylaxis (ECF-A), and platelet-activating factor (PAF). For unknown reasons, nonallergic individuals exposed to antigens result in IgG antibody formation and lack the cross-linking of IgE antibodies.

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Fig. 19.2
Mechanism of type I hypersensitivity reactions

Histamine activates receptors directly by binding H1, H2, and H3 receptors. The receptors of primary concern in type I reactions are mainly the H1 and H2 receptors. H1 receptor activation results in flushing, tachycardia, and increase in mucous production, whereas H2 receptor activation increases gastric secretion and vascular permeability. Arachidonic acid metabolites, both leukotrienes and prostaglandins, are responsible for creating physiological changes in the host resulting in unwanted side effects. Leukotrienes are involved in bronchoconstriction via smooth muscle contraction, increased vascular permeability, and myocardial depression. Prostaglandins produce vasodilatation, bronchospasm, increased vascular permeability, and pulmonary hypertension.

Kinins are small peptides that produce vasodilatation, increase vascular permeability, and bronchoconstriction. They are also involved in stimulating the release of nitric oxide and prostacyclin. ECF-A is a small-molecular-weight peptide mediator involved in chemotaxis of eosinophils at the site of the allergic reaction and inflammation. PAF is involved in stimulating both platelets and leukocytes to release inflammatory products and is responsible for local and systemic anticoagulation.

Anaphylaxis is one example of a type I allergic reaction along with allergic rhinitis, extrinsic asthma, urticaria, and angioedema (lisinopril). Anaphylaxis is an exaggerated form of type I hypersensitivity and can be caused by food (peanuts), drugs (penicillin), latex, contrast dye, and shellfish. This reaction, as stated above, requires prior exposure to the specific offending antigen or a similar structured molecule to form cross-linked IgE antibodies. If not recognized early, anaphylaxis can become life threatening.


Type II Hypersensitivity


Type II hypersensitivity is cytotoxic, involving complement activation. An antigen is introduced into the host, which is attached to an antibody, IgG or IgM. This combination of antigen–antibody activates complement, which results in the lysis of the antigen. After lysis of the antigen, phagocytosis is initiated. Examples of type II hypersensitivity reactions include hemolytic transfusion reactions, autoimmune hemolytic anemia, drug-induced hemolytic anemia (quinine, penicillin, hydralazine), and heparin-induced thrombocytopenia.


Type III Hypersensitivity


Type III hypersensitivity reactions involve the formation of antigen–antibody complexes, which are then deposited in various tissues. This deposition initiates an inflammatory response involving complement and neutrophil activation, resulting in damage to the tissue for that given organ system. The antigen may be exogenous (bacterial, viral, parasitic) or endogenous (non-organ-specific autoimmunity such as systemic lupus erythematosus (SLE)). The antigen is soluble and not attached to the organ involved. Examples of type III hypersensitivity reactions include serum sickness, skin reactions (SLE, Arthus reaction), SLE (kidneys), polyarteritis (arteries), and rheumatoid arthritis (joints).


Type IV Hypersensitivity


Type IV hypersensitivity is also known as delayed type hypersensitivity due to the absence of immediate signs and symptoms. This reaction involves sensitized T-cell lymphocytes (helper T cells), which releases lymphokines. Lymphokines are involved in inflammation and activation of T lymphocytes (cytotoxic T cells). Cytotoxic T cells specifically attack and kill these antigens on subsequent exposure. This reaction results in tissue damage. Examples of type IV hypersensitivity reactions include graft-versus-host reactions, tuberculin immunity, and contact dermatitis (poison ivy, chemicals, heavy metals).


Nonimmunologic Release of Histamine


These reactions are similar to type I hypersensitivity reactions, in that they produce the same symptoms. However, they are not considered hypersensitivity reactions because they are mediated by agents without IgE–allergen interaction. Many pharmacologic agents (thiobarbiturates, hydralazine, carbamazepine, phenytoin, sulfonamides, vancomycin, atracurium, mivacurium, morphine, meperidine, codeine) and other stimuli (exercise, emotional stress, anaphylatoxins C4a, C3a, C5a) are capable of nonimmunologic histamine release.


Prevention of Allergic Reactions


Though not 100 % preventable, many steps can be taken to eliminate the chance of allergic reactions. These include red flags in a patient’s chart, patient wristbands, and a thorough history from the patient to differentiate true allergies from common side effects of certain medications. Knowing the most common pharmacologic and nonpharmacologic antigens that elicit allergic reactions can help the physician be more vigilant when administering such agents. Commonly used agents that can cause an allergic reaction during anesthesia are listed in Table 19.2. Pharmacological prophylaxis to prevent allergic reactions (histamine receptor blockers, corticosteroids) before a surgical procedure is not supported by current data.


Table 19.2
Agents commonly implicated in allergic reactions during anesthesia































• Anesthetic agents

Induction agents (barbiturates, etomidate, propofol)

Ester local anesthetics

Muscle relaxants (succinylcholine, nondepolarizing muscle relaxants)

Opioids (meperidine, morphine, fentanyl)

• Other agents

Blood products (whole blood, packed cells, fresh-frozen plasma, platelets, cryoprecipitate)

Bone cement (methyl methacrylate)

Colloid volume expanders (dextrans, protein fractions, albumin, hetastarch)

Latex

Vascular graft material

• Drugs

Antibiotics (cephalosporins, penicillin, sulfonamides, vancomycin)

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Sep 18, 2016 | Posted by in ANESTHESIA | Comments Off on Allergic Reactions

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