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Hypersensitivity

Hypersensitivity refers to an exaggerated or inappropriate that causes tissue damage or dysfunction upon exposure to an , often harmless in nature. These reactions represent a of , leading to clinical manifestations ranging from mild discomfort to life-threatening conditions. In 1963, immunologists Philip G. H. Gell and Robin R. A. Coombs proposed a foundational system that divides hypersensitivity into four types based on the primary immune mechanisms involved: Type I (immediate, IgE-mediated), Type II (antibody-mediated cytotoxic), Type III (immune complex-mediated), and Type IV (delayed, T-cell-mediated). This framework remains the cornerstone for understanding and diagnosing such reactions, with ongoing refinements including expansions to such as type V (epithelial barrier dysfunction) and pharmacological (p-i) mechanisms, as per recent EAACI guidelines (2025). The four main types encompass a range of disorders: Type I includes atopic conditions like and ; Type II involves cytotoxic reactions such as ; Type III features immune complex diseases like ; and Type IV covers delayed reactions including . Type I accounts for the majority of atopic disorders, affecting nearly half the population in and due to environmental and genetic factors. Hypersensitivity reactions collectively pose significant challenges, contributing to widespread allergic diseases and complicating treatments like therapies or vaccinations. Advances in continue to elucidate overlaps between types and novel subtypes, informing targeted diagnostics and therapies such as monoclonal antibodies against IgE.

Overview

Definition and

Hypersensitivity is defined as an exaggerated or inappropriate to an that causes tissue damage or discomfort, in contrast to the protective and controlled responses characteristic of normal . This response occurs when the reacts excessively to harmless foreign substances, leading to pathological or . The term "allergy" is frequently used interchangeably with hypersensitivity but more precisely refers to reactions mediated by (IgE) antibodies, encompassing type I hypersensitivity.30180-2/fulltext) "," on the other hand, denotes a hereditary predisposition to produce IgE antibodies against common environmental allergens, resulting in heightened susceptibility to allergic diseases. Hypersensitivity differs from autoimmunity, which involves aberrant immune attacks on the body's own self-antigens, whereas hypersensitivity primarily targets exogenous antigens. It also contrasts with immunodeficiency, a condition marked by deficient or absent immune responses that increase infection risk, as opposed to the hyperactive state in hypersensitivity. Central to hypersensitivity are antigens, including allergens—typically proteins capable of directly stimulating IgE production—and haptens, low-molecular-weight compounds that elicit responses only after binding to larger carrier proteins to form complete antigens. Effector mechanisms in these reactions can be antibody-mediated (humoral, involving IgE, IgG, or IgM) or cell-mediated (cellular, primarily T lymphocytes). These reactions are broadly categorized into four types according to the Gell and Coombs , based on the predominant immune effectors involved.

Historical Background

The concept of hypersensitivity emerged from early 20th-century experiments investigating immune responses to toxins and . In 1902, French physiologist and his colleague Paul Portier conducted studies on venom during a scientific expedition, aiming to induce immunity in dogs through small doses. Instead, they observed severe, fatal reactions upon subsequent exposure, which Richet termed "anaphylaxis" to describe this paradoxical loss of protection rather than immunity. This discovery highlighted how prior could lead to heightened immune reactivity, laying the groundwork for understanding allergic phenomena. In 1906, Austrian pediatrician Clemens von Pirquet introduced the term "" (from Greek "allos" meaning other and "ergon" meaning reaction) to broadly describe altered biological reactivity following exposure to foreign substances, encompassing both protective immunity and harmful states. Observing reactions like from horse serum vaccinations, von Pirquet emphasized that antibodies could mediate both beneficial and pathological responses, shifting focus from infection alone to immune dysregulation. This framework integrated into a wider spectrum of immune alterations. A key experimental advance came in 1921 with the Prausnitz-Küstner (P-K) reaction, developed by German physicians Carl Prausnitz and Heinz Küstner. Using Küstner's serum (which contained skin-sensitizing antibodies to fish proteins) injected into Prausnitz's , followed by fish challenge, they demonstrated passive transfer of hypersensitivity, proving the existence of circulating reaginic antibodies responsible for immediate allergic responses.01742-7/fulltext) This test provided direct evidence of humoral factors in human allergy, influencing later serological studies. The systematic classification of hypersensitivity reactions was formalized in 1963 by British immunologists Philip G.H. Gell and Robin R.A. Coombs in their book Clinical Aspects of Immunology. Building on prior observations of antibody- and cell-mediated mechanisms, they categorized reactions into four types based on immune effector pathways, providing a foundational schema for distinguishing anaphylactic, cytotoxic, immune complex, and delayed-type responses. Molecular insights advanced in 1966 when Kimishige and Teruko Ishizaka identified (IgE) as the reaginic antibody mediating . Through fractionation of allergic sera and characterization of its unique properties, including heat stability and skin-sensitizing activity, they linked IgE to and atopic disorders, revolutionizing research.30165-8/fulltext)

Epidemiology

Global Prevalence

Hypersensitivity reactions, particularly Type I (immediate, IgE-mediated), affect an estimated 20-30% of the global population, driven primarily by allergic conditions such as and . As of 2025, impacts more than 250 million people worldwide, representing a significant chronic respiratory burden. , another key manifestation, affects 400-500 million individuals globally, with prevalence rates ranging from 10-30% in adults and exceeding 40% in children in many regions. Food allergies, also under Type I, have seen notable increases, with pediatric prevalence rising substantially since 2000—nearly doubling in some populations from around 3-4% to 6-8%. Type IV hypersensitivity, such as , affects an estimated 15-20% of the general population in patch-tested studies, with varying by region and exposure to allergens like metals or fragrances. Types II and III hypersensitivities, often linked to autoimmune processes, collectively impact 5-10% of individuals in industrialized nations, with rising trends observed globally at an annual increase of about 12.5%. , a prototypical Type III condition, exemplifies this with a worldwide of 0.24-1%, affecting approximately 18 million people as of recent estimates. These figures underscore the substantial scale of hypersensitivity disorders, though underdiagnosis remains common, particularly in low-resource settings. Regional variations highlight higher rates of atopic (Type I) hypersensitivities in industrialized countries, where prevalence can reach 30-40% compared to 10-20% in developing regions, largely explained by the —reduced early microbial exposure leading to dysregulated immune responses. This pattern is evident in studies, where individuals moving from low- to high-prevalence areas show increased risk. Autoimmune hypersensitivities (Types /III) also vary geographically, with higher incidences in northern latitudes and urbanized areas. Demographically, Type I reactions peak in youth, with the highest prevalence among children and young adults, reflecting early to environmental triggers. In contrast, Types II and III exhibit a marked female predominance, affecting women 2-3 times more often than men, potentially due to hormonal and X-chromosome influences. Genetic factors, including HLA associations (e.g., in ), further modulate risk across all types, with familial aggregation observed in hypersensitivity reactions.

Risk Factors and Triggers

Hypersensitivity reactions are influenced by a combination of genetic predispositions that increase susceptibility to specific types. Polymorphisms in the IL-4 gene, such as the -590C/T variant, have been associated with enhanced production of interleukin-4, a key in Th2 immune responses, thereby elevating the risk of atopic conditions like and . Similarly, certain alleles, including , are linked to disorders such as , where they facilitate production against self-antigens. Environmental factors play a significant role in triggering and exacerbating hypersensitivity. Exposure to air pollutants, such as and , has been shown to heighten the incidence of allergic and asthma exacerbations by promoting epithelial barrier dysfunction and release. Dietary factors, particularly , contribute to increased risk, as low levels impair regulatory T-cell function and skew immune responses toward . The posits that reduced early-life exposure to diverse microbes alters the gut and , leading to dysregulated immune development and higher rates of disorders like eczema and food allergies. Lifestyle elements further modulate hypersensitivity risks across types. Smoking has been identified as a risk factor for Type III hypersensitivity reactions, such as those seen in systemic lupus erythematosus, where it promotes immune complex formation and disease flares through oxidative stress and autoantibody induction. For Type IV hypersensitivity, infections serve as common triggers for conditions like contact dermatitis; for instance, viral infections such as herpes simplex can induce or worsen delayed-type reactions to haptens by activating resident T cells. These factors collectively contribute to observed global prevalence trends, with rising urbanization and lifestyle changes correlating with increased hypersensitivity incidence in developed regions.

Classification Systems

Gell and Coombs Classification

The Gell and Coombs classification, introduced in by immunologists Philip G. H. Gell and Robin R. A. Coombs, establishes a systematic framework for categorizing hypersensitivity reactions into four distinct types based on the predominant immune mechanisms involved. This system serves as the cornerstone for understanding allergic and immune-mediated disorders by linking clinical manifestations to specific immunological pathways. The four types are defined as follows: Type I represents immediate hypersensitivity, primarily mediated by (IgE) antibodies that trigger rapid release of inflammatory mediators upon antigen exposure. Type II encompasses cytotoxic reactions, where (IgG) or (IgM) antibodies bind to antigens on cell surfaces, activating destructive processes such as complement fixation or . Type III involves immune complex deposition, in which soluble -antibody complexes form and precipitate in tissues, inciting inflammatory responses through complement activation. Type IV denotes delayed-type hypersensitivity, driven by T-lymphocyte activation without direct antibody involvement, resulting in cytokine-mediated inflammation. The rationale for this classification hinges on two key dimensions: the nature of the immune effectors—humoral (antibody-based for Types I-III) versus cellular (T-cell-based for Type IV)—and the temporal course of the reaction, contrasting immediate onset (within minutes to hours for Type I) with delayed progression (typically 24 to 72 hours for Type IV). This approach facilitates diagnostic and therapeutic distinctions by emphasizing the pathophysiological underpinnings over mere symptomatic overlap. Despite its enduring influence, the Gell and Coombs system has recognized limitations, as it does not encompass all hypersensitivity reactions; for instance, many drug-induced hypersensitivities exhibit mixed or atypical mechanisms that transcend these categories, prompting calls for refinements in complex clinical scenarios.

Alternative Classifications

While the Gell and Coombs classification remains foundational for understanding hypersensitivity reactions, modern schemas have evolved to incorporate non-immune mechanisms, mixed pathways, and endotype-specific distinctions to better reflect contemporary immunological insights. The European Academy of Allergy and Clinical Immunology (EAACI) on , published in 2023, expands the classic four-type system into nine categories to address complexities such as pseudo-allergic and mixed reactions. This framework retains antibody-mediated types I-III and refines cell-mediated type IV into subtypes IVa-c based on T-cell profiles (e.g., Th1 for IVa, Th2 for IVb), while introducing type V (epithelial barrier defects), type VI (metabolic-induced responses), and type VII (direct chemical or non-immune activations, including MRGPRX2-mediated pseudo-allergic reactions like those to certain drugs or opioids). Mixed reactions are accommodated by allowing overlaps, such as combined type I and IVb in conditions involving both IgE and eosinophilic pathways. This adaptation supports precision medicine by integrating biomarkers and endotypes, facilitating targeted therapies. For drug hypersensitivity specifically, Werner Pichler's 2003 classification, later updated, provides a targeted emphasizing T-cell mediated reactions beyond the broad type IV umbrella. It subdivides type IV into alpha (Th1 cytokine-driven, e.g., maculopapular exanthema via interferon-gamma), beta (eosinophil-recruiting via IL-5, e.g., drug reaction with and systemic symptoms or ), gamma (cytotoxic T-cell mediated keratinocyte , common in maculopapular eruptions), and delta (neutrophil-attracting, e.g., ). These subtypes highlight pharmacological interaction (p-i) mechanisms where s directly stimulate T-cells without prior , distinguishing them from true allergic responses. The 2016 update further categorizes reactions as allergic (immune-mediated), p-i (direct T-cell activation), or pseudo-allergic (non-immunologic ). Other schemes, such as the World Health Organization's (WHO) (ICD-11), organize allergic and hypersensitivity conditions into clinical entities rather than immune mechanisms, grouping them under a proposed "Hypersensitivity and Allergic Disorders" chapter with categories for respiratory (e.g., , ), dermatologic (e.g., urticaria, ), ocular (e.g., ), and multisystem reactions (e.g., , drug/food hypersensitivity). This structure, developed through and alignment with ontologies like , addresses gaps in prior ICD versions by enabling better epidemiological tracking and clinical coding without mechanistic overlap. Contemporary classifications increasingly integrate endotypes—distinct molecular pathways underlying phenotypes—to refine hypersensitivity understanding, as seen in where IL-5-driven endotypes (Type 2 high) respond to biologics like , contrasting with non- variants. This endotype approach, embedded in the EAACI , bridges mechanistic and clinical schemas for personalized management across allergic diseases.

Type I Hypersensitivity

Pathophysiology

Type I hypersensitivity, also known as immediate or IgE-mediated hypersensitivity, is an exaggerated to typically harmless environmental antigens called . It begins with a sensitization phase during initial exposure: antigen-presenting cells (e.g., dendritic cells) process the and present it via () class II to naive CD4+ T cells, which differentiate into T helper 2 (Th2) cells. Th2 cells release cytokines such as interleukin-4 (IL-4) and IL-13, promoting class switching to produce -specific (). These antibodies bind to high-affinity FcεRI receptors on the surface of mast cells and , sensitizing them for future encounters. Upon re-exposure, the cross-links adjacent IgE molecules on sensitized mast cells and , triggering via Lyn and Syk kinases, leading to rapid within 5–30 minutes (immediate phase). This releases preformed mediators including (causing and permeability), , and , as well as de novo synthesized lipid mediators like leukotrienes (LTC4, LTD4) and prostaglandins (PGD2), and cytokines (e.g., IL-4, IL-5, IL-13). and leukotrienes induce contraction, mucus secretion, and vascular changes. The late-phase response, occurring 2–8 hours later, involves recruitment of , , neutrophils, and Th2 cells via and IL-5, resulting in sustained and tissue damage. This biphasic mechanism underlies atopic diseases and is influenced by (e.g., atopy-related genes) and environmental factors, distinguishing it from non-IgE-mediated reactions. No quantitative claims present.

Clinical Manifestations and Examples

Type I hypersensitivity reactions range from mild, localized symptoms to severe, systemic , typically occurring minutes after exposure and affecting , respiratory, gastrointestinal, or cardiovascular systems. Common triggers include airborne allergens (, mites), foods (nuts, ), drugs (penicillin), and venoms. Allergic rhinitis (hay fever) manifests as nasal itching, sneezing, rhinorrhea, and congestion, often with , triggered by seasonal pollens. presents with wheezing, dyspnea, cough, and reversible airflow obstruction due to , exacerbated by allergens or exercise. (eczema) involves chronic pruritic skin lesions with erythema, vesicles, and scaling, commonly linked to food or aeroallergens in atopics. (hives) and feature transient, pruritic wheals or deeper swelling, respectively, from release. Anaphylaxis is the most severe form, involving multi-organ activation with symptoms like , , laryngeal , urticaria, , and diarrhea; it can be fatal without epinephrine intervention and is often triggered by , stings, or drugs. Food allergies may cause oral itching, gastrointestinal cramps, or . These conditions contribute to the atopic , where early manifestations like eczema precede or . As of 2025, prevalence of atopic disorders affects approximately 20–30% of children globally, with rising trends in urban areas.

Type II Hypersensitivity

Pathophysiology

Type II hypersensitivity reactions are antibody-mediated cytotoxic responses in which IgG or IgM antibodies bind to antigens on the surface of cells or the , leading to target cell destruction or dysfunction. This process involves several mechanisms: opsonization, where antibody-coated cells are marked for by macrophages and neutrophils via Fc receptors; complement activation, which generates the membrane attack complex () to lyse cells and releases anaphylatoxins (C3a, C5a) that promote and recruit additional immune cells; and antibody-dependent cellular cytotoxicity (), where natural killer (NK) cells or other effectors bind to antibody regions to release perforin and granzymes, inducing . Additionally, antibodies can disrupt cellular function without direct lysis, such as by blocking or stimulating receptors (e.g., in or ). The reaction typically develops over hours to days, distinguishing it from the rapid onset of Type I.

Clinical Manifestations and Examples

Type II hypersensitivity reactions primarily manifest as cytotoxic damage to cells or tissues, resulting in symptoms such as , which presents with , , dark urine, and fatigue; , characterized by easy bruising, petechiae, , and bleeding tendencies; and tissue necrosis, leading to organ-specific dysfunction like renal failure or . A key example is [autoimmune hemolytic anemia](/page/Autoimmune_hemic anemia) (AIHA), particularly the warm antibody form (warm AIHA), where IgG target red blood cells, causing extravascular and symptoms including , weakness, , and . In neonates, Rh incompatibility exemplifies acute type II reactions, with maternal anti-Rh IgG crossing the to destroy fetal erythrocytes, resulting in severe , , , and potentially . Goodpasture syndrome represents a tissue-specific manifestation, involving anti-glomerular antibodies that induce and , with clinical features such as , dyspnea, cough, , and . Drug-induced cases, such as those triggered by penicillin, often lead to or through hapten-mediated antibody binding, presenting with fever, chills, , and cytopenias shortly after exposure. These reactions typically progress acutely, as seen in transfusion mismatches or neonatal , but can become chronic in autoimmune conditions like warm AIHA or certain drug sensitivities, with relapsing or persistent cytopenias requiring ongoing monitoring.

Type III Hypersensitivity

Pathophysiology

Type III hypersensitivity reactions occur when antigen-antibody immune complexes form in the circulation and are not adequately cleared by the , leading to their deposition in various tissues such as walls, glomeruli, synovia, or alveoli. These complexes, typically involving IgG or IgM antibodies, activate the upon deposition. This activation generates anaphylatoxins C3a and C5a, which promote degranulation and recruit neutrophils and monocytes to the site. The recruited inflammatory cells release lysosomal enzymes, , and proinflammatory cytokines, causing local tissue damage, , and inflammation. Additionally, platelet aggregation may contribute to microthrombi formation, exacerbating vascular injury. The reaction typically develops 3 to 10 hours after exposure in previously sensitized individuals, though it may take 7 to 10 days for initial production following primary encounter. Persistent or recurrent exposure sustains complex formation, particularly in chronic conditions. This mechanism underlies acute reactions like the and chronic diseases such as (SLE) or post-streptococcal .

Molecular Mechanisms

In type III hypersensitivity, immune complexes trigger the classical complement pathway through the binding of C1q to the Fc regions of antibodies within the complex, initiating a proteolytic cascade that cleaves C4 and C2 to form the C3 convertase C4b2a. This activation generates anaphylatoxins C3a and C5a, which promote inflammation, and proceeds to the formation of the membrane attack complex (MAC) via C5b-9 assembly on nearby cell surfaces, potentially leading to localized tissue damage if deposition occurs in vessel walls. The efficiency of C1q binding depends on the size and IgG subclass of the immune complex, with IgM-containing complexes exhibiting higher avidity due to their pentameric structure. Aberrant glycosylation of IgG in immune complexes significantly influences their pro-inflammatory potential by altering Fcγ receptor (FcγR) interactions on effector cells such as macrophages and neutrophils. Specifically, reduced galactosylation or sialylation in the Fc region—often observed in chronic inflammatory states—exposes fucose-linked structures that enhance binding to activating FcγRIIa and FcγRIIIa, thereby amplifying release and independent of complement. In contrast, fully galactosylated or sialylated IgG promotes inhibitory signaling through FcγRIIb, dampening ; however, in type III reactions like systemic , disease-associated IgG shows increased agalactosylated forms (G0 s), correlating with heightened FcγR-mediated effector functions and immune complex persistence. This glycan modulation thus serves as a regulatory checkpoint, where pro-inflammatory variants exacerbate vascular deposition and neutrophil . The pathogenicity of immune complexes is highly size-dependent, governed by the antigen-to-antibody (Ag:Ab) ratio during formation, with and clearance favored at the zone but tissue deposition occurring with smaller complexes in excess zones. In antigen excess (high Ag:Ab ratio, e.g., Ag:Ab >> 1:1), soluble complexes form that evade reticuloendothelial clearance, facilitating their circulation and subsequent trapping in glomerular or synovial tissues; this contrasts with the lattice-like structures at (roughly 1:1 effective valency) that rapidly and are phagocytosed efficiently. (CRP) modulates this process by binding moieties on altered self-s within complexes, promoting their opsonization via FcγR and complement activation to enhance clearance, thereby mitigating pathogenic accumulation in acute phases of type III reactions. In chronic settings, however, dysregulated CRP levels may fail to prevent persistent small-complex deposition, perpetuating inflammation.

Type IV Hypersensitivity

Pathophysiology

Type IV hypersensitivity, classified by Gell and Coombs as a delayed-type reaction, is mediated by T lymphocytes without involvement of antibodies, distinguishing it from immediate hypersensitivity responses. The reaction typically manifests 48 to 72 hours after exposure, lacking an immediate phase due to the time required for T-cell and . This delayed onset allows for the recruitment and amplification of cellular immune components at the site of challenge. The process begins with antigen-presenting cells, such as dendritic cells or macrophages, processing and presenting antigens via (MHC) class II molecules to naive + T cells in lymphoid tissues. Upon recognition, these + T cells differentiate into effector subsets, primarily Th1 and Th17 cells, depending on the milieu—such as IL-12 for Th1 and IL-6/TGF-β for Th17. Activated Th1 cells release interferon-gamma (IFN-γ), while Th17 cells produce interleukin-17 (IL-17), both of which orchestrate downstream inflammatory events. These s amplify the response by promoting further T-cell recruitment and effector function. Macrophages are key responders, activated by IFN-γ and IL-17 to enhance , produce , and secrete additional proinflammatory mediators, leading to tissue inflammation and potential formation in chronic cases. IL-17 specifically drives macrophage and infiltration, while IFN-γ upregulates inducible (iNOS) for oxidative burst. In certain contexts, CD8+ cytotoxic T cells contribute by recognizing antigens presented on molecules, releasing perforin and granzymes to induce target cell . This cell-mediated supports the overall delayed reaction without antibody dependence.

Subtypes and Clinical Examples

Type IV hypersensitivity reactions are subdivided into four subtypes (IVa through IVd) based on the dominant T-cell subsets, cytokines, and effector cells involved, a classification originally proposed by Werner Pichler to better delineate their immunological and clinical heterogeneity, particularly in drug reactions. This framework has been refined in recent nomenclature updates, such as the 2023 EAACI position paper, which aligns the subtypes with T helper profiles (T1 for IVa, T2 for IVb, T3 for IVc) and includes roles for . This framework integrates T-cell activation patterns with specific inflammatory profiles, aiding in the distinction of delayed-type responses from other hypersensitivity mechanisms. Subtype IVa involves Th1 cells producing interferon-gamma (IFN-γ), leading to macrophage activation and granulomatous inflammation. A representative clinical example is the tuberculin skin test (Mantoux reaction), where intradermal injection of purified protein derivative from Mycobacterium tuberculosis elicits induration at 48-72 hours in sensitized individuals, indicating prior exposure. Subtype IVb is driven by Th2 cells secreting interleukin-4 (IL-4), IL-5, and IL-13, promoting recruitment and B-cell IgE production, often overlapping with type I features in settings. , particularly the T2-high endotype, exemplifies this subtype, where persistent exposure triggers airway and . Subtype IVc features cytotoxic CD8+ T cells that release perforin and granzymes to induce in target cells. Acute allograft rejection, such as in , demonstrates this mechanism, with donor antigen-specific T cells attacking graft tissues, leading to cellular infiltration and dysfunction. Stevens-Johnson syndrome/toxic epidermal necrolysis (SJS/TEN), severe cutaneous reactions often drug-induced, also align with IVc due to keratinocyte death mediated by cytotoxic T cells. Subtype IVd entails T-cell production of IL-8 and other that recruit neutrophils, resulting in pustular or neutrophilic dermatoses. While SJS/TEN primarily reflects IVc , certain drug eruptions with neutrophilic components can exhibit IVd features; a classic example is (AGEP), characterized by widespread sterile pustules. Beyond these subtype-specific cases, broader clinical examples of type IV hypersensitivity illustrate its diverse manifestations. Allergic contact dermatitis to , the most common metal allergen, arises from hapten-specific T-cell responses in , causing eczematous lesions at sites of like jewelry or coins, confirmed by patch testing. Drug eruptions, such as drug reaction with eosinophilia and systemic symptoms (DRESS) triggered by , represent a systemic type IVb response involving , , and organ involvement like , with genetic factors like HLA-B*58:01 increasing risk in susceptible populations. Celiac disease exemplifies a chronic gastrointestinal type IV reaction, where peptides activate intraepithelial + T cells and lamina propria Th1 cells, causing villous and . Pichler's classification has been instrumental in integrating these drug-related examples, emphasizing pharmacological interaction (p-i) concepts where drugs directly stimulate T cells without , facilitating subtype-specific diagnostics like lymphocyte transformation tests for maculopapular exanthema (IVa) or severe reactions like (IVb).

Diagnosis

General Diagnostic Approaches

The of hypersensitivity reactions begins with a thorough clinical and , which are foundational for identifying potential triggers and classifying the reaction type based on temporal patterns. A detailed should elicit information on recent exposures to antigens such as drugs, foods, insect stings, or environmental allergens, along with the onset and progression of symptoms—immediate reactions (minutes to hours) suggesting type I mechanisms, while delayed onset (hours to days) may indicate types II, III, or IV. Symptom patterns, including recurrent episodes, family of atopy, and associated comorbidities like asthma or eczema, further guide the evaluation. The assesses for characteristic signs such as urticaria, angioedema, respiratory distress, or organ-specific involvement (e.g., joint swelling in arthralgias), helping to differentiate hypersensitivity from mimics like infections or autoimmune disorders. Basic laboratory tests provide supportive evidence of allergic predisposition and inflammation. Measurement of total serum immunoglobulin E (IgE) levels is useful in evaluating atopic individuals, as elevated concentrations (>100 IU/mL) are associated with type I hypersensitivity and increased risk of allergic diseases. Peripheral blood eosinophil counts, often elevated (>500 cells/μL) in type I reactions and some type III processes, indicate eosinophil-mediated tissue damage and correlate with clinical severity in hypersensitivity syndromes. Skin prick testing serves as a first-line in vivo assessment for IgE-mediated atopy, involving application of allergen extracts to the skin followed by pricking; a positive wheal-and-flare response (>3 mm induration) within 15-20 minutes confirms sensitization, though it does not prove clinical relevance without history correlation. In cases of suspected organ involvement, imaging and biopsy offer targeted insights into tissue pathology. Radiographic imaging, such as chest X-rays or computed tomography, evaluates pulmonary or systemic manifestations like interstitial infiltrates in . Biopsy of affected tissues, for instance, or in immune complex-mediated reactions like , can reveal diagnostic features such as leukocytoclastic or immune complex deposition, confirming hypersensitivity when clinical suspicion is high. These procedures are reserved for atypical or severe presentations to rule out alternative etiologies.

Type-Specific Testing

Diagnostic testing for hypersensitivity reactions is tailored to the distinct immunological pathways of each type, enabling precise confirmation of the underlying mechanism following initial clinical evaluation and general approaches such as history-taking. For , which involves IgE-mediated immediate reactions, skin prick testing serves as a primary method to detect by introducing allergens into the and observing wheal-and-flare responses after 15-20 minutes; a positive result is typically defined as a wheal at least 3 mm larger than the negative control, with sensitivity ranging from 70-97% for aeroallergens and >85% for foods. Serum-specific IgE testing complements this by quantifying allergen-specific IgE antibodies through immunoassays like ImmunoCAP, offering high sensitivity (>85%) and variable specificity (40-80%) particularly when skin testing is contraindicated, such as in patients with extensive or recent . The double-blind placebo-controlled food challenge (DBPCFC) remains the gold standard for confirming IgE-mediated food allergies when and skin tests are equivocal, involving supervised administration of the suspected versus to observe clinical reactions while minimizing bias. Emerging methods like the basophil activation test () provide additional specificity (up to 95%) for confirming clinical reactivity. In , characterized by antibody-mediated cytotoxicity, the direct detects IgG or complement bound to the surface of target cells like erythrocytes, confirming immune-mediated in conditions such as by agglutination upon addition of anti-human globulin. The indirect identifies circulating antibodies in that can bind to cells, aiding of hemolytic transfusion reactions or drug-induced anemias by mixing with cells and observing indirect . For anti-glomerular (anti-GBM) disease, a subtype of Type II, enzyme-linked immunosorbent assay () quantifies IgG antibodies against the alpha-3 chain of , with high sensitivity (95-100%) supporting of through linear deposition patterns confirmed on . Type III hypersensitivity, driven by immune complex deposition, is assessed via measurement of complement levels, where reduced serum C3 and C4 indicate classical pathway activation and consumption in diseases like systemic lupus erythematosus (SLE) or post-streptococcal , often accompanied by low CH50 as a marker of overall complement activity. Immune complex assays, such as the C1q binding test, detect circulating complexes by quantifying C1q precipitation equivalents, with elevated levels (e.g., >3.9 μg Eq/mL) supporting diagnoses like or hypocomplementemic urticarial , where complexes trigger inflammation upon tissue deposition. For , a T-cell-mediated delayed reaction, patch testing is the established approach, applying standardized epicutaneously under occlusion and reading reactions at 48-96 hours to identify like , with positivity indicated by , induration, or vesicles corresponding to the site. The lymphocyte transformation test (LTT) provides an alternative by culturing patient peripheral blood lymphocytes with the suspected and measuring via tritiated incorporation or , yielding a stimulation index above 2-3 to indicate , with sensitivity around 70% for drug and metal allergies though limited by availability and standardization.

Treatment and Management

Pharmacological and Immunomodulatory Therapies

Pharmacological therapies for hypersensitivity reactions primarily target acute symptom relief and underlying immune dysregulation, with treatment selection guided by the hypersensitivity type and clinical manifestations. For acute type I reactions, such as , intramuscular epinephrine is the first-line intervention, rapidly reversing , , and other life-threatening symptoms by activating alpha- and beta-adrenergic receptors. Adjunctive therapies include H1-antihistamines like diphenhydramine to block histamine-mediated effects such as urticaria and pruritus, and systemic corticosteroids like to mitigate and prevent biphasic reactions, though these have slower onset compared to epinephrine. Biologic agents have revolutionized management of chronic or severe hypersensitivity by modulating key immune pathways. , a anti-IgE , binds free IgE to reduce and sensitization, significantly decreasing allergic reactions in disorders like allergic and food allergies; FDA approval in 2024 extended its use to reduce reactions from accidental multi-food exposure in adults and children aged 1 year and older. For type II and III hypersensitivity, rituximab, an anti-CD20 , depletes B cells to interrupt production and immune complex formation; it serves as an effective second-line therapy in steroid-refractory type II conditions like immune and , and shows promise in type III-mediated diseases such as systemic with renal involvement. Immunosuppressants are cornerstone for , which involves T-cell-mediated . Cyclosporine, a inhibitor, suppresses T-cell activation and release, proving effective in severe cases like and drug reaction with eosinophilia and systemic symptoms (DRESS), where it rapidly halts infiltration and cutaneous eruptions as a steroid-sparing . Recent advancements as of 2025 include IL-17 inhibitors like , which target Th17-driven in T-cell mediated autoimmune conditions, demonstrating improved control in clinical trials. In September 2025, Regeneron reported positive phase 3 trial results for first-in-class monoclonal antibodies blocking IgE responses to cat and pollen allergens, offering potential new options for type I environmental allergies.

Desensitization and Supportive Care

Desensitization therapies, particularly for reactions, aim to induce tolerance to s through controlled exposure, thereby reducing the severity of future reactions. Oral (OIT) involves gradual ingestion of increasing doses of the under medical supervision, often leading to desensitization where patients can tolerate higher amounts without immediate symptoms. For , a common type I trigger, recent clinical trials have demonstrated desensitization rates of approximately 70-80% in both children and adults after 1-2 years of treatment, with sustained unresponsiveness achieved in about 40% of participants following a period of avoidance. Sublingual (SLIT), administered as extracts placed under the , offers a less invasive alternative, reducing symptoms of and by at least 40% compared to standard treatments, with benefits persisting for up to two years after discontinuation. These approaches are most effective for IgE-mediated allergies and require ongoing monitoring to manage potential adverse reactions during the buildup phase. Updates as of September 2025 highlight advancements in aeroallergen , including improved subcutaneous and sublingual protocols for broader coverage. Avoidance remains a non-pharmacological strategy for managing hypersensitivity across types, focusing on minimizing with known triggers to prevent reactions. For type I allergies, such as or environmental allergens, elimination diets strictly exclude offending items like or pollen exposure, while environmental controls include using allergen-proof bedding covers, washing linens in hot water (at least 130°F), and keeping windows closed during high-pollen seasons. In type IV delayed hypersensitivity, like from or , protective measures such as wearing gloves, barrier creams, or clothing effectively reduce exposure and subsequent T-cell mediated inflammation. Patients are advised to carry identification of their allergens and, for severe cases, epinephrine auto-injectors to enable rapid response if avoidance fails. Supportive care emphasizes immediate symptom relief and stabilization during acute hypersensitivity episodes, complementing desensitization and avoidance efforts. Bronchodilators, such as nebulized albuterol, are administered to alleviate in or exacerbations associated with type I reactions, improving airflow and oxygenation. Intravenous fluids are provided rapidly to counteract and , particularly in severe anaphylactic , helping restore hemodynamic stability. In patients with underlying immunodeficiencies who experience hypersensitivity-like reactions due to antibody deficiencies, immunoglobulin (IgG) replacement therapy—delivered intravenously or subcutaneously—replenishes protective antibodies, reducing risk and modulating immune responses that may exacerbate hypersensitivity symptoms. At the 2025 American College of Allergy, & Immunology (ACAAI) meeting, emerging strategies for type IV delayed hypersensitivity included repurposed immunomodulators and T-cell-targeted therapies, alongside genetic screening to predict reactions.

Prevention

Primary Prevention Strategies

Primary prevention strategies for hypersensitivity focus on interventions that mitigate the initial sensitization process in individuals at high risk, particularly those with genetic predispositions to , such as family history of allergic diseases. These approaches target modifiable environmental factors during critical developmental windows, like infancy, to promote and reduce the likelihood of aberrant immune responses to antigens. One key strategy involves the use of to modulate the gut , which influences maturation and Th2-skewed responses associated with . of randomized controlled trials has shown that probiotic supplementation during and early infancy reduces the risk of atopic eczema by approximately 22% (RR 0.78, 95% CI 0.68–0.90), with stronger effects observed in high-risk populations. This benefit is attributed to strains like and , which enhance regulatory T-cell function and barrier integrity in the gut. Applications of the hygiene hypothesis emphasize early environmental exposures to foster diverse microbial interactions and prevent dysregulated immunity leading to Type I reactions. For instance, exposure to pets during the first year of life has been linked to a dose-dependent reduction in risk, with studies indicating up to a 15–20% lower incidence of to common allergens in children from pet-owning households. Similarly, introducing a diverse in , including complementary foods by 4–6 months, promotes oral and diversity; infants with high dietary variety at 9 months exhibit a 61% lower risk of by 18 months compared to those with limited diversity. For , vaccination against infectious triggers plays a pivotal role in averting immune complex formation from uncontrolled pathogen replication. The , administered universally in infancy, prevents chronic HBV infection, which is a known etiology of immune complex-mediated diseases like , thereby substantially lowering associated hypersensitivity risks. For , primary prevention includes strategies to avoid exposure in susceptible individuals, such as Rh immunoglobulin administration to Rh-negative mothers during to prevent , and careful blood typing and cross-matching in transfusions to avert hemolytic reactions.

Secondary Prevention Measures

Secondary prevention measures for hypersensitivity reactions aim to mitigate recurrence, progression, or severity in individuals who have already experienced or a clinical episode, focusing on identification, reduction, and preparedness. These strategies are tailored to the hypersensitivity type and eliciting agent, emphasizing multidisciplinary care involving allergists for diagnostic confirmation via skin testing, serum IgE assays, or patch tests. For instance, in type I immediate hypersensitivity, such as , patients receive counseling on allergen avoidance, with evidence from registries showing that 98% of food-allergic patients are advised on evasion to prevent episodes. Similarly, for delayed type IV reactions like , secondary prevention relies on patch testing to identify specific haptens, followed by strict avoidance of confirmed allergens, which reduces recurrence rates in occupational settings. For , secondary prevention involves vigilant monitoring and avoidance of offending agents, such as or alternative therapies in drug-induced cases (e.g., switching in penicillin after confirmation), and prompt treatment of established conditions like to prevent complications. A cornerstone of secondary prevention across IgE-mediated hypersensitivities is the prescription and on self-injectable epinephrine, particularly for anaphylaxis-prone patients. Guidelines recommend prescribing two epinephrine autoinjectors (EAIs) to high-risk individuals, such as those with a history of severe reactions or biphasic responses, with training on immediate use upon symptom onset to avert fatal outcomes. In drug hypersensitivity, where re-exposure may be unavoidable (e.g., essential antibiotics or ), rapid desensitization protocols induce temporary by administering incremental doses over hours, achieving success rates of 60-80% in antituberculous drug reactions and enabling safe continuation in over 90% of cases without alternatives. with H1-antihistamines and corticosteroids is also employed for certain reactions, though it does not eliminate risk entirely and is reserved for confirmed non-IgE mechanisms. For select type I hypersensitivities, allergen-specific () serves as a disease-modifying secondary prevention tool, desensitizing patients to triggers like venom or aeroallergens. Venom (VIT) is indicated for grade 2-4 sting reactions, reducing subsequent risk by up to 90% upon completion, with indefinite continuation advised in cases to prevent relapse. In food allergy, oral under specialist supervision can promote in peanut-allergic children, though it requires ongoing adherence to avoid rebound . on emergency action plans, medical alert bracelets, and follow-up testing for recurrent idiopathic cases further enhances outcomes, with registry data indicating higher AAI prescription rates (84%) in specialized centers compared to general settings (37%). avoidance remains foundational, as demonstrated in mite-sensitized children where encasings and high-temperature washing reduced exacerbations, though long-term efficacy varies by age and adherence.