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. Author manuscript; available in PMC: 2011 Aug 1.
Published in final edited form as: Clin Exp Allergy. 2010 Jun 7;40(8):1155–1162. doi: 10.1111/j.1365-2222.2010.03550.x

Pro/Con Debate: Is Occupational Asthma Induced by Isocyanates an IgE-Mediated Disease?

Adam V Wisnewski *, Meinir Jones **
PMCID: PMC3121887  NIHMSID: NIHMS301015  PMID: 20545707

Abstract

Isocyanates, low-molecular weight chemicals essential to polyurethane production, are one of the most common causes of occupational asthma, yet the mechanisms by which exposure leads to disease remain unclear. While isocyanate asthma closely mirrors other Type I Immune Hypersensitivity (“Allergic”) disorders, one important characteristic of hypersensitivity (“allergen”-specific IgE) is reportedly absent in a large portion of affected individuals. This variation from common environmental asthma (which typically is induced by high molecular weight allergens) is important for two reasons. (1) Allergen-specific IgE is an important mediator of many of the symptoms of bronchial hyper-reactivity in “allergic asthma”. Lack of allergen-specific IgE in isocyanate hypersensitive individuals suggests differences in pathogenic mechanisms, with potentially unique targets for prevention and therapy. (2) Allergen-specific IgE forms the basis of the most commonly used diagnostic tests for hypersensitivity (skin prick and RAST). Without allergen-specific IgE, isocyanates may go unrecognized as the cause of asthma. In hypersensitive individuals, chronic exposure can lead to bronchial hyperreactivity that persists years after exposure ceases. Thus, the question, of whether or not isocyanate asthma is an IgE mediated disease, has important implications for disease screening/surveillance, diagnosis, treatment and prevention. The present Pro/Con Debate, addresses contemporary, controversial issues regarding IgE in isocyanate asthma.

BACKGROUND

Isocyanate, Asthma, and IgE

Isocyanate-induced asthma is an occupational lung disease with striking similarities to “allergic” asthma, a condition that typifies Type I Immune Hypersensitivity, as defined by Gell and Coombs.1 A cardinal feature of Type I Immune Hypersensitivity is the presence of allergen specific immunoglobulins that have undergone isotype class switching to the epsilon constant region (i.e. IgE.).2 Allergen-induced cross-linking of IgE on the surface of mast cells is a “trigger” for asthma, via the release of histamine and other mediators that cause immediate reactions and incite a cascade of ongoing inflammation (including delayed-phase responses).36 Production of IgE (isotype swithching) is largely dependent upon IL-4, a cytokine produced by subset of T cells (Th2-type), whose “helper” activity is critical in orchestrating the inflammatory responses of Type I Immune hypersensitivity.710

Absence of Allergen-specific IgE in Isocyanate Asthma?

It has been reported that the majority of individuals with isocyanate-induced asthma do not have allergen-specific IgE (see Table 1)1124 findings challenging to reconcile with Gell and Coombs’ classic definition of Type I immune hypersensitivity. Without allergen-specific IgE, what mechanisms account for the airway inflammation observed following isocyanate exposure, especially immediate responses? Furthermore, since as described above, isotype switching to IgE generally requires T cell derived IL-4, does the lack of IgE in isocyanate hypersensitive individuals imply fundamental differences in the underlying cellular response to isocyanate compared with common environmental allergens? These same questions extend to asthma caused by certain other low molecular weight compounds (e.g. plicatic acid, persulfates), and other types of idiopathic or “intrinsic” asthma, where “allergen-specific”-IgE is not detectable.

Table 1.

Studies of Isocyanate-Specific IgE in Isocyanate Asthma

% IgE+ # Subjects Patient source Diagnosis Isocyanate Antigen Preparation & Characterization “Substitution”*** Assay Ref.
0% 11 Manufacturing Plant Symptoms TDI Liquid phase, Guttman Assay 13:1 RAST 11
3% 34 Various Industries SIC* TDI Liquid phase, UV spectroscopy 34:1 RAST 12
14% 247 Multiple Isocyanate Industries/Clinics Physician TDI, TMI*, MDI, MMI* Liquid phase, Derivatization w/Azo dye 26:1, 13:1, 15:1, 10:1 RAST 13
19% 26 Cotton Seed Processing Industry SIC TMI Liquid phase, UV spectroscopy 16:1 RAST 14
20% 35 Finland Health Registry SIC TDI, MDI, HDI - - RAST 15
21% 19 Pulmonary Disease Clinics Montreal/Quebec SIC TDI, MDI, HDI Liquid phase, Mass spectrometry 3:1 to 10:1 ELISA 16
22% 23 Pulmonary Disease Clinics Montreal/Quebec SIC HDI and oligomer Vapor & Liquid phases, Mass Spectrometry 6:1, 23:1
2:1
RAST 17
23% 26 Hôpital du Sacré Coeur, Montreal, Canada SIC TDI, MDI, HDI Liquid phase, chemical (TNBS) 10:1, 7:1, 24:1 ELISA 18
31% 29 Hôpital du Sacré Coeur, Montreal, Canada SIC TDI, MDI, HDI Liquid phase, chemical (TNBS) and immunoelectrophoresis - ELISA 19
34% 58 Royal Brompton Hospital United Kingdom SIC or Physician TDI, MDI, HDI - - RAST 20
38% 8 Musical Instrument and Motor Vehicle Industries Expiratory (Peak) Flow TDI, MDI, HDI Liquid phase, UV spectroscopy - RAST 21
44% 66 Furniture/Musical Instrument Industries SIC TDI Vapor phase, Chemical (TNBS) and MALDI-MS 12:1 ELISA 22
55% 11 Hôpital du Sacré Coeur & Yale Medical Clinic SIC HDI Vapor phase, Chemical (TNBS) and MALDI-MS 3:1 RAST 23
**91% 12 Multiple Worsites Physician Records TDI Liquid Phase UV spectroscopy 30:1 RAST 24
*

Specific inhalation challenge (SIC)

**

Selection criteria was physician-verified work-related immediate-type asthma attack

***

Substitution = molar ratio of isocyanate to albumin (isocyanate:albumin)

- Not reported

Diagnosis, Surveillance. and Screening

The absence of allergen (isocyanate)-specific IgE in isocyanate asthma creates substantial challenges when evaluating isocyanate-exposed individuals with asthma. Without allergen-specific IgE as a definitive diagnostic, isocyanates may be overlooked or mistakenly exonerated as the cause of disease, and exposure-induced bronchial hyper-reactivity may instead be attributed to other environmental triggers, especially delayed responses, which may occur after the worker leaves the job-site. The lack of allergen-specific IgE also limits pro-active disease screening/surveillance (e.g. routine blood testing/RAST), which might otherwise identify affected workers, including those early in the course of disease, where prompt removal from exposure provides the greatest protection against long-lasting (isocyanate-exposure induced) lung function decline. Thus, uncertainty over the presence and role of (allergen-specific) IgE in isocyanate asthma has a huge impact on efforts towards disease diagnosis, screening and surveillance.

PRO/CON DEBATE

Twelve topics, that support (1–6) or refute (7–12) the role of IgE in isocyanate asthma, were chosen for debate by the authors. The Pro viewpoint supports the hypothesis that isocyanate asthma is an IgE mediated disease, while the Con viewpoint supports the hypothesis that isocyanate asthma is not an IgE mediated disease.

  1. Clinical presentation of isocyanate asthma is typical of an allergic process.

    Pro: Isocyanate asthmatics generally do not experience asthma symptoms the first time they are exposed to isocyanates, the disease typically takes months to years to develop, and becomes more severe with repeated exposure.25 A “latent phase” between exposure and the development of asthma is well-described for common environmental asthma and known to reflect the time period during which systemic immune sensitization occurs.26 The reported immediate and dual phase reactions to isocyanate exposure are typical of “allergic” responses.27

    Con: The spectrum of isocyanate asthma is diverse. While some subjects develop clear-cut immediate responses, delayed responses to isocyanate occur more frequently than with high molecular weight allergens.28 The “latent” phase of isocyanate asthma remains poorly understood and may represent the time necessary for non-immunologic processes, such as repetitive injury-repair cycles or permanent structural changes.29

  2. Isocyanate-specific IgE may not be detected if the wrong form of “isocyanate antigen” is used in the immunoassay (false negative test).

    Pro: The structural form of isocyanates recognized by the human immune system (as an allergen) remains unclear, as isocyanates react rapidly with proteins and water.30, 31 Different oligomeric formulations, isomers, and phases (vapor/liquid), further impact antigencicity.17, 22, 23 Most studies of isocyanate-specific IgE to date, have used isocyanate-albumin conjugates, however, such conjugates can differ substantially depending upon the methods used for their production.22, 23, 30, 32, 33

    Con: Over the last 40 years, a wide-range of experimental methods have been employed to generate and characterize “isocyanate antigens”.17, 22, 23, 3235 The major carrier protein for isocyanate in vivo has been identified as albumin, and specific sites of conjugation have been identified by mass spectrometry.23, 36 Despite progress in understanding the antigenicity of isocyanate-albumin conjugates, the most advanced studies to date fall short of accounting for the substantial proportion of isocyanate asthmatics without detectable chemical-specific IgE.17, 22

  3. Isocyanate specific IgE may be “missed” due to assay detection limits.

    Pro: IgE is present at very low concentrations in serum and thus requires highly sensitive reagents for detection, such as radioisotopically labeled anti-human IgE.37 Many serology studies of isocyanate-specific IgE to date have relied upon enzyme-linked immunosorbant assays (ELISA), often without definition of detection limits.16, 18, 19, 38

    Con: While the detection limits of most IgE serology tests reported to date, remain unclear, many studies have made use of the same sensitive methods proven reliable for measuring other allergen-specific IgE, including radioisotope and/or fluorescent labels along with high (allergen) density solid phase platforms.15, 20, 39

  4. Isocyanate specific IgE serum levels may decrease (below detection limits) away from exposure.

    Pro: Experimental evidence has shown that isocyanate-specific serum IgE decreases away from exposure, and can become undetectable (by traditional RAST) as quickly as 30 days away exposure.20 Variable and sometimes long time intervals between an individuals’ last exposure and serology testing thus, may contribute to the apparent absence of specific-IgE is patients with the disease (see more below).

    Con: Studies that have longitudinally followed serum levels of isocyanate-specific IgE, suggest their 1/2 life is similar to that of IgE specific for common environmental allergens.20 Antigenic forms of isocyanate (albumin-conjugates) may persist for weeks in the blood stream of exposed individuals.40, 41

  5. The socio-economics of isocyanate asthma affects the detection of serum specific IgE.

    Pro: The socio-economics of isocyanate asthma (and other occupational diseases) may cause workers to postpone medical attention until their condition becomes severe enough to prevent them from working. In the case of isocyanate asthma, this delay could be sufficient time for specific-IgE levels to fall below detection limits, especially if the patient must travel to specialized testing centers for disease diagnosis.

    Con: Many occupations that use isocyanates are life-long careers for which workers have invested substantial time and money. Thus, there is self-incentive for workers to remain vigilant about the possibility of hypersensitivity to chemicals in their workplace, especially isocyanates, which are well-recognized as a cause of occupational asthma.

  6. HLA-linkage of isocyanate asthma supports a role for IgE.

    Pro: Genetic differences in human leukocyte antigen (HLA) class II alleles have been associated with isocyanate asthma in several different populations. Similar findings have been reported in common environmental asthma, and together with the known role of HLA-class II in antigen presentation to CD4 T-cells, support a role for prototypical TH2-driven/IgE responses.4246

    Con: The association between HLA class II and isocyanate asthma has been variable in different studies.47, 48 Furthermore, the link between HLA class II expression and IgE is indirect via Th2 cells. HLA class II genes are located in region of the genome (Chr 6) that likely contains numerous genes involved in allergic responses.

  7. Lack of IL-4 mRNA (a critical factor for epsilon class switching), in situ in the human airway argues against a role for IL-4 in isocyanate asthma.

    Pro: While recent studies have highlighted the conspicuous absence of IL-4 in human airway biopsies from isocyanate asthma patients, older studies reported the presence of florid Th2-type airway inflammation using immunohistochemical approaches.49, 50 The kinetics of IL-4 expression, in relationship to exposure may have contributed to conflicting results, as levels may diminish with increasing time intervals between disease diagnosis and biopsy.

    Con: A striking absence of epsilon constant region (Cε) and IL-4 mRNA has been observed locally within bronchial mucosa, in patients undergoing inhalation challenge with isocyanate, at a dose sufficient to provoke an asthmatic reaction.49 The lack of detectable IgE and IL-4 mRNA in patients with isocyanate–induced asthma, represents strong evidence that IgE is not produced in the bronchial mucosa level, following an active challenge with isocyanates. IL-4 is required for B cell switching in favor of IgE and is sufficient to initiate transcription through the heavy chain Cε locus.51 Thus the lack of both IL-4 and IgE transcripts in the bronchial mucosa, following an isocyanate challenge, suggest that IgE is not crucial to the induction of occupational asthma to isocyanates. Thus, it is likely that non-IgE mediated mechanisms are important, at least in a proportion of patients with isocyanate-induced asthma.

  8. Isocyanates do not stimulate vigorous in vitro T-cell responses (Th2), which are associated common environmental asthma

    Pro: In vitro cellular responses are dependent upon the “antigen”, which as described above, remains unclear for isocyanate chemicals. The antigen presenting cells for isocyanates also remain unclear and may be absent from the in vitro assays reported to date, which commonly utilize peripheral blood mononuclear cells.

    Con: The prototypical Th2 responses stimulated by common environmental allergens, and known to induce asthma and IgE in vivo, are not observed when human T-cells from isocyanate asthmatics are cultured with isocyanate (albumin conjugates) in vitro.52 In contrast, isocyanates stimulate limited proliferation of γδ and CD8 T cells along with production of mainly monocytic cytokines/chemokines (see more below).5355 More recently, murine studies suggest that TH-17 cells may be a crucial effector population for isocyanate responsivness.56

  9. Isocyanate-albumin antigens stimulate predominately the monocytic population of human blood cells, rather than (TH2) cell types known to promote IgE production.

    Pro: Any cell-based immunoassay for isocyanates encounters issues with the chemicals cytotoxicity, in addition to uncertainty regarding the “antigenic” form (discussed above). Furthermore, it remains unclear if all of the cells necessary to respond to isocyanate are present in the peripheral blood. Notably limiting in the blood are dendritic cells, γδ T cells, and airway epithelial cell types, which have been shown to respond to isocyanate.5759

    Con: Increasing evidence points to an important role for monocytes, and possibly other innate immune cells in the development of isocyanate asthma.16, 54, 60, 61 In vitro studies from several independent laboratories describe the stimulation of human monocytes and monocyte-like human cell lines, by isocyanate-albumin conjugates, including the production of chemokines associated with asthma, such as MCP-1 and MIF. 16, 54, 60, 62

  10. Histamine releasing factors, such as MCP-1, substitute for IgE, in the asthmatic response triggered by isocyanates.

    Pro: While MCP-1 production in vitro (in response to isocyanate albumin antigen) has been shown to be greater by PBMCs from isocyanate asthmatics, vs. exposed controls, mechanisms by which MCP-1 and TH2-like inflammation is selectively induced, without IgE production remain unclear.16

    Con: Experimental evidence demonstrates high levels of isocyanate-antigen driven MCP-1 production by PBMCs from isocyanate asthmatics (but not controls).16, 54, 62 MCP-1 is a chemokine with potent histamine releasing activity, equal to or greater than that triggered by IgE receptor cross-linking.63 A major PBMC cell type that produces MCP-1 is the monocyte, which is innately activated by isocyanate-albumin conjugates.60, 64, 65 Thus, direct activation of innate immune cells may be a crucial underlying pathological response to isocyanate exposure.60, 66

  11. Oxidative stress, rather than antigen-driven (e.g. IgE) responses is the pathological mechanism that leads to isocyanate asthma.

    Pro: While isocyanates have been shown to induce oxidative stress, evidence that this process participates directly in isocyanate asthma pathogenesis is lacking.58, 59, 66 Oxidative stress occurs in response to numerous exposures, including many that do not cause asthma.67, 68

    Con: Isocyanates have been shown to disrupt oxidant homeostasis through several distinct analytic methodologies.58, 59, 61, 6972 Evidence linking oxidant stress and allergic responses highlight non-immunologic mechanisms that may modulate isocyanate responsiveness, including the development of asthma.7375

  12. Chemical-induced toxicity, rather than antigen-driven (e.g. IgE) responses is the pathological mechanism that leads to isocyanate asthma.

    Pro: While isocyanates are highly toxic, occupational exposure limits are set several orders of magnitude below the lowest observable effects dose measured in animal studies.76, 77

    Con: Repetitive cycles of injury and repair may represent the essential process underlying isocyanate asthma pathogenesis, with immune sensitization and the development of specific IgE as a common secondary phenomenon.29, 78 With the aid of contemporary molecular techniques, it has been shown that subcytotoxic (occupational) concentrations of isocyanate do have specific effects on airway cells, including oxidative stress as mentioned above.58, 71 Furthermore genetic studies have shown associations of isocyanate asthma with polymorphisms in specific enzymes thought to participate is isocyanate metabolism (N-acetyl, and Glutathione-S-Transferases).7982

SUMMARY

Controversy continues to exist over the role of IgE in isocyanate asthma, which has important implications for understanding disease pathogenesis as well as prevention and diagnosis. IgE that specifically binds isocyanate is challenging to define due to isocyanates reactivity with (self) proteins. A better understanding of isocyanates reactivity with self-molecules is essential to understanding their allergenicity, and answering the question, is isocyanate asthma an IgE mediated disease?

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