Background: Approximately 10% of the global population identify themselves as penicillin allergic, yet 90% are not truly allergic and could safely tolerate penicillin. There is no simple way to identify these people. Current in vitro diagnostics include specific immunoglobulin E, sIgE (with a sensitivity of 19% and specificity of 97%) and basophil activation testing (BAT) with undefined sensitivity and specificity. Objective: To define the sensitivity and specificity of BAT in the diagnosis of penicillin allergyMethods: PubMed and EMBASE searched from inception to 04/02/2023 for original studies evaluating the performance characteristics of basophil activation test for penicillin allergy in adults. Study selection, data extraction, risk of bias, assessment with QUADAS-2 tool, certainty assessment with GRADE methodology were performed independently, in duplicate. Meta-analysis was performed using Reitsma methodology.Results: Twenty-two studies fulfilled the inclusion criteria. Twelve used the same positive threshold giving a summary point sensitivity 51% (95% CI, 46%-56%) and specificity 89% (95% CI, 85%-93%). Significant risk of bias was identified due to patient selection. GRADE certainty of evidence rated sensitivity “very low” due to imprecision and specificity as “low”. There was great heterogeneity in methods used. Use of 1000 basophils per test did not improve performance above 500 basophils. Conclusion: BAT sensitivity is highly variable across studies and remains too low to be considered as a routine element of clinical practice. BAT specificity is not as good as sIgE in penicillin allergy diagnosis. Significant further work is required in this field before clinical application of BAT in routine practice.

While the number and types of indoor air pollutants is rising, much is suspected but little is known about the impact of their potentially synergistic interactions, upon human health. Gases, particulate matter, organic compounds, but also allergens and viruses, fall within the ‘pollutant’ definition. Distinct populations, such as children and allergy and asthma sufferers are highly susceptible, while a low socioeconomic background is a further susceptibility factor; however, no specific guidance is available. We spend most of our time indoors; for children, the school environment is of paramount importance and potentially amenable to intervention. The interactions between some pollutant classes have been studied; for example, respiratory viral infection induces hyperresponsiveness to allergens, as well as irritants. However, a lot is missing in respect to understanding interactions between specific pollutants of different classes in terms of concentrations, timing, and sequence, to improve targeting and upgrade standards. SynAir-G is a European Commission-funded project aiming to reveal and quantify synergistic interactions between different pollutants affecting health, from mechanisms to real-life, focusing on the school setting. It will develop a comprehensive and responsive multipollutant monitoring system, advance environmentally friendly interventions, and disseminate the generated knowledge to relevant stakeholders in accessible and actionable formats.

Amoxicillin induced mast cell degranulation mediated by FcεRI specific IgG: a new insight to beta-lactam allergy To the editor,Immediate drug hypersensitivity reactions (IDHR) to beta-lactams (BL), referred to here as beta-lactam allergy (BLA), is defined as the development of symptoms such as urticaria and bronchospasm within one hour of beta-lactam exposure (1). Classical Type 1 immunoglobulin E (IgE)-mediated allergy describes a response which occurs within minutes of allergen exposure in a previously sensitised person. It has therefore been widely accepted that BLA is mediated by beta-lactam specific IgE (BL-sIgE) (1). In other Type 1 IgE driven allergies, such as food allergy, sIgE to major allergen components can be shown to be highly specific (2, 3). However, for BLA, BL-sIgE has poor specificity, suggesting alternative mechanisms might be involved (4).Type 1 IgE mediated reactions are mainly mediated by basophils and mast cells (MCs). Previous studies have demonstrated the use of the basophil activation test (BAT) in predicting BLA, with European allergy guidance stating that BAT can aid BLA diagnosis (5). However, BAT requires fresh whole blood which is not ideal for in depth mechanistic exploration.In an in vitro BLA model using human progenitor derived MCs, we have shown that MCs sensitised with serum from a patient with confirmed BLA, demonstrated amoxicillin (AMX) induced degranulation (CD63+ positivity) after 30 minutes of stimulation with AMX (Figure 1B). In contrast, sensitisation with serum from a non-BLA control demonstrated no response (Figure 1C).The mechanism of degranulation from the BLA model is very different from the classical IgE-mediated Type 1 degranulation such as that seen in food and inhalant allergy (6). In our in vitro model of classical IgE-mediated Type 1 degranulation, sIgE binds to FcɛRI with high affinity which is not disturbed by pipetting and washing (6). In our BLA model, BLA serum sensitized MCs have a much weaker degranulation and can easily lose their response to beta-lactam stimulation under physical disturbance (Figure 1A).We hypothesised that FcɛRI was involved in the degranulation process in BLA, not through the high affinity binding of IgE, but instead through IgG binding. We produced a recombinant fragment representing the extracellular portion of the FcɛRI receptor alpha chain, which is mainly responsible for antibody binding. When added to the serum, this fragment binds and neutralizes FcɛRI-specific antibody—IgE and IgG, by preventing them binding to the cells. BLA serum was treated with increasing concentrations of the FcɛRI fragments and then added to the MCs for sensitization. After stimulating the sensitized MCs using AMX, we observed a dosage-dependent decrease of MCs degranulation, indicating direct involvement of the FcɛRI in the degranulation process of BLA (Figure 2A).To investigate whether degranulation was mediated by IgE, we neutralized serum IgE by adding omalizumab before MC sensitisation. This showed no impact on the AMX induced degranulation (Figure 2A). In contrast, omalizumab inhibited MC degranulation in a classical IgE model, using pooled serum from cat allergic patients stimulated with cat allergen (Figure 2B).To determine whether FcεRI-specific IgG is functionally responsible for the AMX induced MCs degranulation, we isolated IgG from BLA serum using IgG-depletion spin columns. MCs sensitized with the IgG-only fraction showed no response to anti-IgE, but retained a strong response to AMX (Figure 2B). In comparison, in the IgG-depleted serum fraction (~60% IgG removed), we observed a strong degranulation to anti-IgE stimulation but a weakened response to AMX (Figure 2C).A limitation of this preliminary work is it used serum from only one BLA patient.In summary, we developed a cell model for BLA using in vitrodifferentiated human MCs. This BLA model has demonstrated the involvement of FcεRI-specific IgG in mediating AMX-induced MCs degranulation. The results are worthy of further investigation in a larger patient cohort.Word Count 599Figure legend ( Word count 98 and 98 respectively, max 100)Figure 1. Demonstration of in vitro BLA model using MCs derived from human progenitor cells. A) After washing the sensitized MCs with phosphate buffered saline (PBS), different cells responsiveness to AMX and anti-IgE. B) When adding the AMX in the presence of BL IDHR serum, cell degranulation was observed. C) No degranulation was observed from AMX stimulation when serum from a non-BL IDHR subject was used. D) Treatment of AMX in the absence of serum showed a mild increase of CD63 compared to cells without stimulation, Percentage CD63+ cells is shown in the box. Representative figures from three independent experiments.Figure 2. Investigating the role of FcεRI-specific IgG in BLAin vitro model A) the BLA in vitro model, B) classical type I IgE cat allergy model. AMX or cat allergen induced degranulation was quantified on MCs sensitized with single BLA or pooled cat allergic subject serum pre-treated with recombinant FcεRI alpha chain fragment or omalizumab. C) BLA in vitro model; MCs sensitized with either IgG-depleted serum fraction or IgG-only fraction. Sensitised MCs were stimulated with anti-IgE, AMX or media control. Histogram demonstrating fluorescence intensity of CD63 expression on MCs surface. Mean ±SD. *=p<0.05 from three independent experiments, NS=not significant.

Background: Chemokines are important mediators in immune cell recruitment, contributing to allergy development. However, extensive studies of chemokines in the circulation in relation to the presence and development of allergic diseases remain scarce. Our aim was to investigate associations of circulating allergy-related chemokines with development of asthma and sensitisation cross-sectionally and longitudinally in a population-based cohort. Methods: The chemokines CCL17, CCL22, CXCL10, CXCL11 and CCL18 were measured in plasma samples from children in the Manchester Asthma and Allergy Study. Samples were available from cord blood at birth (n=376), age 1 (n=195) and 8 years (n=334). Cross-sectional and longitudinal association analyses were performed in relation to asthma and allergic sensitisation, as well as allergic phenotype clusters previously derived using machine learning in the same study population. Results: In children with asthma and/or allergic sensitisation, CCL18 levels were consistently elevated at ages 1 and/or 8 years. In a longitudinal model including information on asthma from 4 time-points (ages 5, 8, 11 and 16 years), we observed a significant association between increasing CCL18 levels at age 1 and a higher risk of asthma from early school age to adolescence (OR=2.9, 95% CI 1.1-7.6, p=0.028). We observed similar associations in longitudinal models for allergic sensitisation. Asthma later in life was preceded by increased CXCL10 levels after birth, and decreased CXCL11 levels at birth. Conclusion: Elevated CCL18 levels throughout childhood precede the development of asthma and allergic sensitisation. The Th1-associated chemokines CXCL10 and CXCL11 also associated with development of both outcomes, with differential temporal effects.

Background: Effector cells assays provide an overall measure of responsiveness to allergen, but the lack of reliable, high-throughput assays limits the clinical utility of this approach. The aim of this study was to develop a high-throughput Basophil Activation Test (BAT), based on human progenitor cell-derived basophils (PCB), and to investigate the role of PCB activation test (PCBAT) in allergy diagnosis. Methods: PCBs were differentiated from CD34+ progenitor cells, and sensitized with sera from subjects sensitized to cat (n=35, 17 subjects clinical reactivity validated), peanut-allergic (n=30, 15 subjects clinical reactivity validated), peanut-sensitized but tolerant subjects (n=13). Sensitized PCBs were then stimulated with a range of concentrations of the corresponding allergens and degranulation was measured using CD63 expression on flow cytometry. Results: Following passive sensitisation of the mature PCB (2D7+/FcεRI+/CD117-/HLADR-) with serum and stimulation with allergen, we saw a dose-dependent increase in CD63 expression which was allergen specific. In subjects sensititsed to cat there was a positive correlation between PCBAT area under curve (AUC) versus specific IgE (sIgE) to cat (p=0.001) and versus airway responsiveness to inhaled cat allergen (p=0.026). There was a significant negative correlation between PCBAT AUC for peanut allergen and response to oral food challenge test to peanut - subjects with higher PCBAT AUC reacted to a lower dose on the oral food challenge to peanut (p=0.001), and had higher sIgE to Ara h 1 (p=0.007). All peanut tolerant subjects showed no reaction to peanut on PCBAT. Conclusion: PCBAT may confer a powerful alternative tool in allergy testing.