Asthma in the 21st Century New Research Advances Asthma in the 21st Century New Research Advances Edited by Rachel Nadif Université Paris-Saclay, UVSQ, Univ. Paris-Sud, Inserm, Equipe d’Epidémiologie Respiratoire Intégrative, CESP, Villejuif, France Academic Press is an imprint of Elsevier 125 London Wall, London EC2Y 5AS, United Kingdom 525 B Street, Suite 1650, San Diego, CA 92101, United States 50 Hampshire Street, 5th Floor, Cambridge, MA 02139, United States The Boulevard, Langford Lane, Kidlington, Oxford OX5 1GB, United Kingdom Copyright © 2023 Elsevier Inc. All rights reserved. No part of this publication may be reproduced or transmitted in any form or by any means, electronic or mechanical, including photocopying, recording, or any information storage and retrieval system, without permission in writing from the publisher. 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To the fullest extent of the law, neither the Publisher nor the authors, contributors, or editors, assume any liability for any injury and/or damage to persons or property as a matter of products liability, negligence or otherwise, or from any use or operation of any methods, products, instructions, or ideas contained in the material herein. ISBN: 978-0-323-85419-1 For Information on all Academic Press publications visit our website at https://www.elsevier.com/books-and-journals Publisher: Stacy Masucci Acquisitions Editor: Ana Claudia A. Garcia Editorial Project Manager: Susan E. Ikeda Production Project Manager: Omer Mukthar Cover Designer: Matthew Limbert Typeset by Aptara, New Delhi, India Contents Contributors ix 2.2.3 Mechanisms through which eosinophils Foreword xiii contribute to disease 34 Acknowledgments xv 2.2 Noneosinophilic asthma 36 2.2.1 Defining noneosinophilic asthma 36 1. Asthma: From one disease 2.2.2 Clinical characteristics of to endotypes noneosinophilic asthma 36 2.2.3 Mechanisms of noneosinophilic asthma 37 Rachel Nadif, Marine Savouré 2.3 Implications for treatment of asthma 40 2.4 Conclusion 40 1.1 Introduction 1 References 40 1.2 History of “asthma” 1 1.2.1 From antiquity to the 19th century 1 3. Airway microbiome and asthma 1.2.2 The modern ERA: From the 20th century to the present time 2 Orianne Dumas, Laura Toivonen, Zhen Li, 1.3 Clinical and epidemiological aspects Kohei Hasegawa, Carlos A. Camargo, Jr. of asthma 2 3.1 Introduction 47 1.3.1 Clinical aspects of asthma 2 3.2 Sampling and characterization of airway 1.3.2 Epidemiological aspects of asthma 4 microbiome 47 1.3.3 From one disease to phenotypes 7 1.4 Asthma phenotypes 7 3.2.1 Sampling 47 1.4.1 Phenotypes according to the age of 3.2.2 Marker gene analysis 48 onset of asthma 7 3.2.3 Metagenomic shotgun sequencing 48 1.4.2 From phenotypes to endotypes 9 3.2.4 Statistical analysis 49 1.5 Asthma endotypes 9 3.3 Airway microbiota and asthma in adults 49 1.5.1 Endotypes from inflammatory and 3.3.1 Airway microbiota in patients with severe asthma phenotypes 10 asthma versus healthy subjects 49 1.5.2 Endotypes including omics-based 3.3.2 Airway microbiota and asthma approaches 11 phenotypes 49 1.5.2 Endotypes identified by data-driven 3.3.3 Conclusion and discussion on airway methods 11 microbiota in adults 52 1.6 Conclusion 24 3.4 Airway microbiota, wheezing and asthma References 24 in children 53 3.4.1 Wheezing illnesses 53 2. Eosinophilic and noneosinophilic 3.4.2 Asthma 53 3.4.3 Conclusion and discussion on airway asthma: Beyond severe asthma microbiota in children 54 Tara F. Carr, Sanjay B. Patel 3.5 Early life environment and airway microbiota 55 2.1 Introduction 31 3.6 Gut microbiota, airway microbiota and the 2.2 Eosinophilic asthma 31 gut–lung axis in asthma 56 2.2.1 Defining eosinophilic asthma 31 3.7 Conclusion and future directions 57 2.2.2 Clinical characteristics of eosinophilic References 58 asthma 32 v vi Contents 4. Gender differences and sex-related 5.3 Windows of exposure and expression, and measurement error 92 hormonal factors in asthma 5.4 Diet and asthma: State of the art 93 Bénédicte Leynaert, Francisco Gómez Real, 5.4.1 Dietary antioxidant intake 93 N. Sabrina Idrose, Shyamali C. Dharmage 5.4.2 Dietary polyunsaturated fatty acid intake 99 4.1 Introduction 63 5.4.3 Vitamin D 102 4.2 Gender differences in asthma, findings 5.4.4 Folates 104 from epidemiologic studies 64 5.4.5 Fiber 104 4.2.1 Asthma prevalence 64 5.4.6 Specific food or food groups 107 4.2.2 Incidence and remission 64 5.4.7 Dietary patterns 112 4.2.3 Diagnosis 67 5.5 Complex interrelations between diet, 4.2.4 Severity and phenotypes 67 obesity, and physical activity in asthma 4.3 Hormonal factors: Events associated with prevention and management 116 changes in sex hormones among women 69 5.5.1 State of the art 116 4.3.1 Changes in respiratory outcomes 5.5.2 The issue of mediation by obesity with puberty and menarche 69 in the diet-asthma association 117 4.3.2 Changes in respiratory outcomes 5.5.3 The issue of time-dependent with menstrual cycle 70 confounding in the interrelations 4.3.3 Changes in respiratory outcomes between nutritional factors with oral contraceptive use 71 and asthma 118 4.3.4 Changes in respiratory outcomes 5.5.4 Epiphenomenon 118 with pregnancy 72 5.6 Conclusion and future directions 119 4.3.5 Changes in respiratory outcomes References 119 with menopause 73 4.3.6 Changes in respiratory outcomes 6. Indoor air and respiratory health: with hormonal treatment for the Volatile organic compounds and menopause 74 4.4 Hormones and respiratory health 76 cleaning products 4.4.1 Overview of findings from Lidia Casas, Orianne Dumas, Nicole Le Moual experimental studies 76 4.4.2 Lung physiology, sex hormones, sex 6.1 Introduction 135 hormone-binding globulin and asthma: 6.2 Exposure assessment of indoor chemicals: Findings from Epidemiologic studies VOCs, SVOCs, and cleaning products 136 and clinical trials 78 6.2.1 Exposure assessment of volatile 4.5 Gender specific determinants of asthma, organic compounds 136 beyond sex hormones 80 6.2.2 Exposure assessment of semivolatile 4.5.1 Obesity 80 organic compounds 136 4.5.2 Environment 80 6.2.3 Cleaning products 137 4.5.3 Gender and sex hormones 81 6.3 Respiratory health effects of residential 4.6 Conclusion 81 exposure to VOCs, SVOCs, and cleaning References 81 products: Results from epidemiological studies 138 5. Diet and asthma 6.3.1 Respiratory effects of volatile organic compounds 138 Raphaëlle Varraso, Zhen Li, Annabelle Bedard, 6.3.2 Respiratory effects of semivolatile Carlos A. Camargo, Jr. organic compounds 140 5.1 Introduction 87 6.3.3 Cleaning products 141 5.2 Assessment of diet in epidemiological 6.4 Conclusions on respiratory health effects of studies 87 cleaning products 145 5.2.1 Tools to assess dietary intakes 87 6.5 Conclusion and future directions 145 5.2.2 Approaches to analyzing dietary data 88 References 146 Contents vii 7. Outdoor air pollution and asthma 8.4.2 Overview of DNAm studies in asthma 184 8.4.3 Take-home messages from DNAm in a changing climate studies in asthma 189 Bénédicte Jacquemin, Emilie Burte, Marine Savouré, 8.5 Conclusions and future directions 189 Joachim Heinrich References 190 7.1 General introduction 151 9. Asthma and COPD: distinct diseases 7.2 Air pollution and asthma 152 or components of a continuum? 7.2.1 Main air pollutants 152 7.2.2 Short-term effect on asthma 153 Clémence Martin, Guillaume Chassagnon, Sven 7.2.3 Long-term air pollution and asthma 153 Günther, Stéfanie Habib, Jean Pastré, Pierre-Régis 7.2.4 Susceptibility factors 160 Burgel, Nicolas Roche 7.2.5 Burden of air pollution exposure on asthma 161 9.1 Introduction 195 7.2.6 Possible mechanisms 161 9.2 Asthma, COPD, overlap: definitions and 7.2.7 Causality 162 basic epidemiology 196 7.3 Asthma and air pollution in the context 9.2.1 Definitions 196 of climate change 163 9.2.2 Burden 196 7.3.1 Air pollution and climate change 164 9.3 Natural history of and risk factors for 7.3.2 Climate change and asthma 165 obstructive airways diseases, from childhood 7.3.3 Interaction between climate change, to advanced age 197 air pollution, and asthma 166 9.3.1 From early life and childhood to adult 7.4 General conclusion 167 asthma and COPD 198 References 168 9.3.2 Common and specific risk factors 199 9.3.3 Asthma and COPD in adults 200 9.3.4 Asthma and COPD in the elderly 201 8. Genetic and epigenetic links 9.4 Shared and distinct underlying to asthma risk mechanisms 201 9.4.1 Small airways obstruction 201 Andréanne Morin, Carole Ober, Nathan Schoettler 9.4.2 Microbial environment 201 8.1 Introduction 173 9.4.3 Inflammatory pathways and their 8.2 Asthma gene discovery through genome- biomarkers 202 wide association studies 173 9.5 Clinical presentations and diagnostic 8.2.1 Beyond SNP associations 174 challenges 203 8.2.2 Genetic associations of asthma 9.5.1 Major clinical phenotypes 204 subphenotypes 176 9.5.2 Asthma-COPD overlap (ACO) 204 8.2.3 Take-home messages from GWASs 9.6 Physiological similarities and differences of asthma 177 between asthma and COPD 204 8.3 The role of rare and loss-of-function 9.7 The role of imaging in the assessment of variants in asthma 177 chronic airways diseases 205 8.3.1 Rare LOF variants in the ADRB2 gene 9.7.1 Computed tomography (CT) signs of are associated with severe asthma 178 bronchial involvement 205 8.3.2 A rare LOF variant in the IL33 gene 9.7.2 Specific features of COPD 206 is associated with eosinophilia 9.7.3 Particular features of ACO 206 and asthma 181 9.7.4 Indications of imaging in clinical 8.3.3 Nonsense mutations in the FLG gene routine and research settings 206 are associated with asthma 182 9.8 Therapeutic implications 206 8.3.4 A common LOF variant in GSDMB 9.8.1 Inhaled corticosteroids and inhaled confers protection from asthma 182 bronchodilators 206 8.3.5 Take-home messages from rare variant 9.8.2 Biologics targeting type 2 inflammation 207 and loss-of-function mutation studies 183 9.8.3 Add-on, nonbiologic therapies 207 8.4 Epigenomic studies of asthma 183 9.9 Conclusions 208 8.4.1 Methods for studying DNAm 184 References 208 viii Contents 10. Asthma in an aging world 10.7 Conclusion 226 References 226 Hiroyuki Nagase, Maho Suzukawa 11. Asthma in the digital world 10.1 Introduction 217 10.2 Epidemiology of asthma in the elderly 217 Jean Bousquet, Bernardo Sousa-Pinto, Francesca 10.2.1 Epidemiology of elderly persons 217 Puggioni, Aram Anto, Fabio Balli, Thomas Casale, 10.2.2 Epidemiology of asthma in Wienczyslawa Czarlewski, Anna Bedbrook, the elderly 217 Luisa Brussino, Mina Gaga, Bilun Gemicioglu, 10.2.3 Death from asthma in the elderly 217 Ludger Klimek, Violeta Kvedariene, Renaud Louis, 10.3 Physiological change in the airways Joaquin Sastre, Nicola Scichilone, Arunas Valiulis, due to aging 218 Eleptherios Zervas, Arzu Yorgancioglu, Torsten 10.3.1 Structural changes 218 Zuberbier, Josep M Anto, G Walter Canonica, 10.3.2 Changes in pulmonary function Joao A Fonseca due to aging 218 10.3.3 Immunosenescence 219 11.1 Introduction 231 10.4 Phenotype of asthma in the elderly 219 11.2 Regulatory framework for data 10.5 Problems in diagnosing asthma in protection 232 the elderly 221 11.3 Electronic health records 233 10.5.1 Airflow limitation 222 11.4 Registries in severe asthma 233 10.5.2 Bronchial hyper-responsiveness 222 11.5 Telehealth in asthma 234 10.5.3 Fraction of exhaled nitric oxide 11.6 mHealth apps 234 (FeNO) 222 11.7 mHealth sensors 235 10.5.4 Underperception of dyspnea 222 11.8 Platforms 236 10.5.5 Problems in spirometry 223 11.9 Serious games 236 10.5.6 Comorbidities 223 11.10 Impact of digital health on asthma 237 10.6 Treatment of asthma in the elderly 223 11.10.1 Phenotype discovery using 10.6.1 Low peak inspiratory flow and digital health 237 difficulty in synchronization 223 11.10.2 Diagnosis 237 10.6.2 Inhaled corticosteroids 224 11.10.3 Management 237 10.6.3 Bronchodilators 224 11.10.4 Adherence to treatment 237 10.6.4 Combination agents comprising 11.11 Conclusion 238 ICS, LABA, and LAMA 225 References 239 10.6.5 Biologics 225 10.6.6 Other agents 226 Index 245 Contributors Aram Anto MASK-air, Montpellier, France IRCCS, Rozzano, Italy; Department of Biomedical Sciences, Humanitas University, Pieve Emanuele, Italy Josep M Anto ISGlobAL, Barcelona Institute for Global Health, Barcelona, Spain; IMIM (Hospital del Tara F. Carr Department of Medicine, University of Mar Medical Research Institute), Barcelona, Spain; Arizona, Tucson, AZ, United States Universitat Pompeu Fabra (UPF), Barcelona, Spain; Thomas Casale Division of Allergy/immunology, CIBER Epidemiología y Salud Pública (CIBERESP), University of South Florida, Tampa, FL, United States Barcelona, Spain Lidia Casas Social Epidemiology and Health Policy Fabio Balli Breathing Games Association, Geneva, (SEHPO), Department of Family Medicine and Switzerland; Concordia University, Montreal, Canada Population Health (FAMPOP), University of Antwerp, Annabelle Bedard Paris-Saclay University, UVSQ, Wilrijk, Belgium Paris-Sud University, Inserm, Integrative Respiratory Guillaume Chassagnon Université Paris Cité, Paris, Epidemiology team, CESP, Villejuif, France France; Service de Radiologie, Hôpital Cochin, APHP. Anna Bedbrook MASK-air, Montpellier, France Centre, Paris, France Jean Bousquet Institute of Allergology, Charité – Wienczyslawa Czarlewski Medical Consulting Universitätsmedizin Berlin, Corporate Member of Freie Czarlewski, Levallois, France Universität Berlin and Humboldt-Universität zu Berlin, Shyamali C. Dharmage Centre for Food and Allergy Berlin, Germany; Fraunhofer Institute for Translational Research, Murdoch Children’s Research Institute, Medicine and Pharmacology ITMP, Allergology and Victoria, Australia; Allergy and Lung Health Unit, Immunology, Berlin, Germany; University Hospital School of Population and Global Health, University of Montpellier, Montpellier, France Melbourne, Victoria, Australia Luisa Brussino Department of Medical Sciences, Allergy Orianne Dumas Université Paris-Saclay, UVSQ, Univ. and Clinical Immunology Unit, University of Torino & Paris-Sud, Inserm, Équipe d’Épidémiologie respiratoire Mauriziano Hospital, Torino, Italy intégrative, CESP, Villejuif, France Pierre-Régis Burgel Service de Pneumologie, Hôpital Joao A Fonseca MEDCIDS - Department of Community Cochin, APHP. Centre, Paris, France; Université Paris Medicine, Information and Health Decision Sciences, Cité, Paris, France; Institut Cochin, UMR 1016, Paris, Faculty of Medicine, University of Porto, Porto, France Portugal; CINTESIS – Center for Health Technology and Services Research, University of Porto, Porto, Emilie Burte Univ. Rennes, Inserm, EHESP, Irset Portugal; RISE – Health Research Network, University (Institut de recherche en santé, envir onnement et travail) of Porto, Porto, Portugal - UMR_S 1085, Rennes, France Mina Gaga ERS President 2017-2018, Athens Chest Carlos A. Camargo, Jr. Department of Emergency Hospital, 7th Resp Med Department and Asthma Center, Medicine, Massachusetts General Hospital, Harvard Athens, Greece Medical School, Boston, Massachusetts, United States; Channing Division of Network Medicine, Department Bilun Gemicioglu Department of Pulmonary Diseases, of Medicine, Brigham and Women’s Hospital, Harvard Istanbul University-Cerrahpasa, Cerrahpasa Faculty of Medical School, Boston, Massachusetts, United States; Medicine, Istanbul, Turkey Department of Epidemiology, Harvard T.H. Chan School Sven Günther Université Paris Cité, Paris, France; of Public Health, Boston, Massachusetts, United States Unité d’Explorations Fonctionnelles Respiratoires et G Walter Canonica Personalized Medicine, Asthma Sommeil, Hôpital Européen George Pompidou, Paris, and Allergy, Humanitas Clinical and Research Center France ix