A consensus protocol for the Basophil Activation Test for multicenter collaboration and External Quality AssuranceAuthors: Pascal, M# 1, Edelman SM#2, Nopp, A#3, Möbs, C4, Geilenkeuser, WJ5, Knol, EF6, Ebo, DG7, Mertens C7, Shamji, MH8, Santos, AF9,10, Patil, S11, Eberlein, B*12, Mayorga, C*13, Hoffmann HJ14*Affiliations1 Immunology Department, Centre de Diagnòstic Biomèdic, Hospital Clínic de Barcelona, Barcelona, Spain; Institut d’Investigacions Biomèdiques August Pi i Sunyer (IDIBAPS), Universitat de Barcelona, Spain.2 Skin and Allergy Hospital, Helsinki University Central Hospital, Helsinki, Finland, present address Aimmune Therapeutics, Finland3 Department of Clinical Science and Education, Karolinska Institutet, Södersjukhuset, and Sachs´ Children and Youth Hospital, Södersjukhuset, Stockholm, Sweden4 Department of Dermatology and Allergology, Philipps-Universität Marburg, Marburg, Germany5 Reference Institute for Bioanalytics, Bonn, Germany6 Center of Translational Immunology and Dermatology/Allergology, University Medical Center Utrecht, Utrecht, The Netherlands.7 Faculty of Medicine and Health Sciences, Department of Immunology-Allergology- Rheumatology, University of Antwerp, Antwerp, Belgium8 National Heart and Lung Institute, Imperial College London, UK and NIHR Imperial Biomedical Research Centre, UK9 Department of Women and Children’s Health (Pediatric Allergy) & Peter Gorer Department of Immunobiology, Faculty of Life Sciences and Medicine, King’s College London, London, United Kingdom10 Children’s Allergy Service, Evelina London Children’s Hospital, Guy’s and St Thomas’ Hospital, London, United Kingdom11 Division of Allergy and Immunology, Departments of Medicine and Pediatrics, Massachusetts General Hospital, Harvard Medical School, Boston, Massachusetts, United States12 Department of Dermatology and Allergy Biederstein, School of Medicine, Technical University Munich, Munich, Germany13 Allergy Clinical Unit, Hospital Regional Universitario de Málaga and Allergy Research Group, Instituto de Investigación Biomédica de Málaga-IBIMA-BIONAND, Malaga, Spain;14 Department of Clinical Medicine, Aarhus University, Department of Respiratory Diseases and Allergy, Aarhus University Hospital, Denmark# shared first authors, * shared senior authorsCOIM Pascal, SM Edelman, A Nopp, C Möbs, EF Knol, SU Patil and C Mayorga have no conflict of interest regarding this work. B Eberlein received methodological and technical support from the company BUEHLMANN Laboratories AG (Schönenbuch, Switzerland) outside the submitted work. Dr Hoffmann reports grant from the Innovation Fund of Denmark, outside the submitted work. Dr Shamji reports grants awarded to institution from the Immune Tolerance Network, UK Medical Research Council, Allergy Therapeuitics, LETI Laboratories, Revolo biotherapeutics and Angany Inc. He has received consulting fees from Bristol Meyers Squibb and lecture fees from Allergy Therapeutics and LETI laboratories, all outside the submitted work. Dr. Santos reports grants from Medical Research Council (MR/M008517/1; MC/PC/18052; MR/T032081/1), Food Allergy Research and Education (FARE), the NIH, Asthma UK (AUK-BC-2015-01), the Immune Tolerance Network/National Institute of Allergy and Infectious Diseases (NIAID, NIH) and the NIHR through the Biomedical Research Centre (BRC) award to Guy’s and St Thomas’ NHS Foundation Trust, during the conduct of the study; speaker or consultancy fees from Thermo Scientific, Nutricia, Infomed, Novartis, Allergy Therapeutics, IgGenix, Stallergenes, Buhlmann, as well as research support from Buhlmann and Thermo Fisher Scientific through a collaboration agreement with King’s College London, outside the submitted work. Dr Geilenkeuser is an employee of Referenizinstitut für Bioanalytik, DE that provided logistic assistance and reagent support for the study.To the editorThe basophil activation test (BAT) has significant potential as a diagnostic tool to better phenotype and manage patients with IgE-mediated allergies, so that only a small proportion of patients need to be challenged. Sample, reagent, laboratory procedure, analysis protocols, and population characteristics can influence BAT performance (1,2). Regulatory approval and clinical implementation require extensive standardization of laboratory protocols, cytometer settings, and results interpretation (3). European national authorities require External Quality Assurance (EQA) of the performance of modern diagnostic laboratories by agencies independent of test suppliers to meet ISO 15189:2012, 15189:2013 and 9001:2015.Based on an online survey among 59 responding European laboratories performing BAT in 2017 (4,5) (Online Supplement; Results of the online survey), a Task Force was launched in 2018 to create the basis for a BAT-EQA. Round Robins (RR) were organized with seven shipments of 2 donors each to 7-10 European centers with overnight courier service from Bonn, DE. To minimize variation, prior to shipment, blood basophils were activated with 1 ul FcεRI antibody/ml of blood and stabilized with 0.2 mL Transfix (Cytomark, UK) per mL of blood to stabilize activated basophils up to 48 hours for staining (6). Fresh blood was included for stimulation and staining at the participating laboratory sites.We met after the third shipment to reach consensus on a protocol for BAT (Online Supplement; Proposed SOP for in house BAT). The threshold set on an unstimulated control sample was determined empirically on an independent data set as equal or greater than 2.5% with ROC curves based on data from patients with hypersensitivity to amoxicillin and patients with peanut allergy, (Online supplement, tables S1 and S2). This proposal did not find universal consensus among the authors.Data analysis started with identification of the relevant region in a scatter plot, followed by identification of basophils with the relevant markers, for instance, using low SSC and CD193 only or CD193 and CD123. Finally, the threshold was set at 2.5% of CD63 expression on resting basophils (Figure 1A). >5% CD63+basophils above that threshold in an activated sample was considered a positive response. This setting was used to obtain the percentage of CD63+ cells in centrally preactivated and locally activated blood samples; however, it was not adopted in all labs. Data from participating labs analyzed with their proprietary and the above standardized analysis compared well (online supplement, figure S4).The first two RR were used to establish coherence between participating laboratories. Data from RR3–RR7 were comparable. The standard deviation of activation measured at all participating centers was 16.8% in preactivated blood (Figure 1B) compared with 49.2% for samples activated and analyzed locally, illustrating the utility of using preactivated blood for EQA. Shipment to Málaga took 48h, and local activation of blood basophils was consistently suboptimal, consistent with a preliminary round robin from 2012, where the clinical outcome was robust up to 24 h. Centrally activated basophils performed as well in Málaga as in other centers.EQA for BAT is critical to facilitate routine implementation of this assay in the field of in vitro allergy diagnostics. The variability of the responses to our survey highlighted the importance and need for multicenter validation. Full validation and standardization of the BAT protocol and analysis is essential and possible for setting the grounds for controlled multicenter research studies as well as EQA. The BAT-EQA Task Force provides a standard operating protocol (Online supplement; Proposed SOP for in house BAT) and reference materials for the test to standardize and enhance the accuracy of BAT for both clinical and research collaborations and EQA.

Background: Nonimmediate (delayed) allergic reactions to penicillins are common and some of them can be life-threatening. The genetic factors influencing these reactions are unknown/poorly known/poorly understood. We assessed the genetic predictors of a delayed penicillin allergy that cover the HLA loci. Methods: Using next-generation sequencing (NGS), we genotyped the MHC region in 24 patients with delayed hypersensitivity compared with 20 patients with documented immediate hypersensitivity to penicillins recruited in Italy. Subsequently, we analyzed in silico Illumina Immunochip genotyping data that covered the HLA loci in 98 Spanish patients with delayed hypersensitivity and 315 with immediate hypersensitivity compared to 1,308 controls. Results: The two alleles DRB3*02:02:01:02 and DRB3*02:02:01:01 were reported in twenty cases with delayed reactions (83%) and ten cases with immediate reactions (50%), but not in the Allele Frequency Net Database. Bearing at least one of the two alleles increased the risk of delayed reactions compared to immediate reactions, with an OR of 8.88 (95% CI, 3.37–23.32; P <0.0001). The haplotype (ACAA) from rs9268835, rs6923504, rs6903608, and rs9268838 genetic variants of the HLA-DRB3 genomic region was significantly associated with an increased risk of delayed hypersensitivity to penicillins (OR, 1.7; 95% CI: 1.06–1.92; P=0.001), but not immediate hypersensitivity. Conclusion: We showed that the HLA-DRB3 locus is strongly associated with an increased risk of delayed penicillin hypersensitivity, at least in Southwestern Europe. The determination of HLA-DRB3*02:02 alleles in the risk management of severe delayed hypersensitivity to penicillins should be evaluated further in larger population samples of different origins.

Background: Nonimmediate (delayed) allergic reactions to penicillins are common and some of them can be life-threatening. The genetic factors influencing these reactions are unknown/poorly known/poorly understood. We assessed the genetic predictors of a delayed penicillin allergy that cover the HLA loci. Methods: Using next-generation sequencing (NGS), we genotyped the MHC region in 24 patients with delayed hypersensitivity compared with 20 patients with documented immediate hypersensitivity to penicillins recruited in Italy. Subsequently, we analyzed in silico Illumina Immunochip genotyping data that covered the HLA loci in 98 Spanish patients with delayed hypersensitivity and 315 with immediate hypersensitivity compared to 1,308 controls. Results: The two alleles DRB3*02:02:01:02 and DRB3*02:02:01:01 were reported in twenty cases with delayed reactions (83%) and ten cases with immediate reactions (50%), but not in the Allele Frequency Net Database. Bearing at least one of the two alleles increased the risk of delayed reactions compared to immediate reactions, with an OR of 8.88 (95% CI, 3.37–23.32; P <0.0001). The haplotype (ACAA) from rs9268835, rs6923504, rs6903608, and rs9268838 genetic variants of the HLA-DRB3 genomic region was significantly associated with an increased risk of delayed hypersensitivity to penicillins (OR, 1.7; 95% CI: 1.06–1.92; P=0.001), but not immediate hypersensitivity. Conclusion: We showed that the HLA-DRB3 locus is strongly associated with an increased risk of delayed penicillin hypersensitivity, at least in Southwestern Europe. The determination of HLA-DRB3*02:02 alleles in the risk management of severe delayed hypersensitivity to penicillins should be evaluated further in larger population samples of different origins.

Nanotechnology is science, engineering, and technology conducted at the nanoscale, which is about 1 to 100 nanometers. It has led to the development of nanomaterials, which behave very differently compared with materials with larger scales and can be applied in a wide range of applications in biomedicine. The physical and chemical properties of materials of such small compounds depend mainly on the size, shape, composition, and functionalisation of the system. Nanoparticles, carbon nanotubes, liposomes, polymers, dendrimers, nanogels, among others, can be nanoengineeried for controlling all parameters, including their functionalisation with ligands, which provide the desired interaction with the immunological system. However, undesired issues related to their toxicity and hypersensitivity responses have impeded more rapid health applications. Through interactions with the immune system, some of these nanostructures show promising applications as vaccines and diagnostics tools. Dendrimeric Antigens, Nanoallergens, and nanoparticles are potential tools for the in vitro diagnosis of allergic reactions. Glycodendrimers, liposomes, polymers, and nanoparticles have shown interesting applications in immunotherapy. There are wide panels of structures accessible, and controlling their physico-chemical properties would allow the obtainment of safer and more efficient compounds for clinical applications goals, either in diagnosis or treatment.

Background. Lymphocyte transformation test (LTT) has been widely used to evaluate non-immediate drug hypersensitivity reactions (NIDHRs). However, the lack of standardisation and the low sensitivity have limited its routine diagnostic use. The drug presentation by dendritic cells (DCs) and the assessment of proliferation on effector cells have shown promising results. Flow-cytometry-based methods can help apply these improvements. We aimed to assess the added value of using drug-primed-DCs and the determination of the proliferative response of different lymphocyte subpopulations in NIDHRs. Methods. Patients with confirmed NIDHR were evaluated by both conventional (C-LTT) and with drug-primed-DCs LTT (dDC-LTT) analysing the proliferative response in T-cells and other effector cell subpopulations by using the fluorescent molecule, carboxyfluorescein diacetate succinimidyl ester. Results. The C-LTT showed a significantly lower sensitivity (33.3%) compared with dDC-LTT (65.2%), which was confirmed analysing each particular clinical entity: SJS-TEN (62.5% vs 87.5%), MPE (14.3% vs 41.7%), and AGEP (33% vs 80%). When including the effector cell subpopulations involved in each clinical entity, CD3++CD4+Th1 cells in SJS-TEN, CD3++CD4+Th1+NK cells in MPE, and CD3++NK cells in AGEP, we could significantly increase the sensitivity of the in vitro test to 100%, 66.6%, and 100%, respectively. With an overall sensitivity of 87% and 85% of specificity in NIDHR. Conclusions. The use of a flow-cytometry-based test, DCs as drug presenting cells, and focussing on effector cell subpopulations for each clinical entity significantly improved the drug-specific proliferative response in NIDHRs with a unique cellular in vitro test.

Coronavirus disease 2019 (COVID-19), a respiratory tract infection caused by a novel human coronavirus, the severe acute respiratory syndrome coronavirus 2, leads to a wide spectrum of clinical manifestations ranging from asymptomatic cases to patients with mild and severe symptoms, with or without pneumonia. Given the huge influence caused by the overwhelming COVID-19 pandemic affecting over three million people worldwide, a wide spectrum of drugs is considered for the treatment in the concept of repurposing and off-label use. There is no knowledge about the diagnosis and clinical management of the drug hypersensitivity reactions that can potentially occur during the disease. This review brings together all the published information about the diagnosis and management of drug hypersensitivity reactions due to current and candidate off-label drugs and highlights relevant recommendations. Furthermore, it gathers all the dermatologic manifestations reported during the disease for guiding the clinicians to establish a better differential diagnosis of drug hypersensitivity reactions in the course of the disease.