Structural changes in the airways in asthma: observations and consequences

Structural changes reported in the airways of asthmatics include epithelial fragility, goblet cell hyperplasia, enlarged submucosal mucus glands, angiogenesis, increased matrix deposition in the airway wall, increased airway smooth muscle mass, wall thickening and abnormalities in elastin. Genetic influences, as well as fetal and early life exposures, may contribute to structural changes such as subepithelial fibrosis from an early age. Other structural alterations are related to duration of disease and/or long-term uncontrolled inflammation. The increase in smooth muscle mass in both large and small airways probably occurs via multiple mechanisms, and there are probably changes in the phenotype of smooth muscle cells, some showing enhanced synthetic capacity, others enhanced proliferation or contractility. Fixed airflow limitation is probably due to remodelling, whereas the importance of structural changes to the phenomenon of airways hyperresponsiveness may be dependent on the specific clinical phenotype of asthma evaluated. Reduced compliance of the airway wall secondary to enhanced matrix deposition may protect against airway narrowing. Conversely, in severe asthma, disruption of alveolar attachments and adventitial thickening may augment airway narrowing. The encroachment upon luminal area by submucosal thickening may be disadvantageous by increasing the risk of airway closure in the presence of the intraluminal cellular and mucus exudate associated with asthma exacerbations. Structural changes may increase airway narrowing by alteration of smooth muscle dynamics through limitation of the ability of the smooth muscle to periodically lengthen.     

The cytokine network in asthma and chronic obstructive pulmonary disease

Asthma and chronic obstructive pulmonary disease (COPD) are very common inflammatory diseases of the airways. They both cause airway narrowing and are increasing in incidence throughout the world, imposing enormous burdens on health care. Cytokines play a key role in orchestrating the chronic inflammation and structural changes of the respiratory tract in both asthma and COPD and have become important targets for the development of new therapeutic strategies in these diseases.     

Biological markers in diagnosing, monitoring, and treating asthma: a focus on noninvasive measurements

Asthma is a major concern for society, healthcare professionals, and individuals and families directly affected by asthma due to rising morbidity rates and costs associated with the disease. The pathological hallmark of asthma is airway inflammation that is considered to be a major cause of exacerbations and persistent structural alterations of the airways. Assessing airway inflammation is important for investigating the underlying mechanisms of the disease and possibly for following the progression and resolution of the disease. The presence and type of airway inflammation can be difficult to detect clinically, and may result in delays in initiating appropriate therapy. The purpose of this article is to review noninvasive methods for assessing biological markers of airway inflammation and their potential role in the future for diagnosing, monitoring, and treating asthma. The article reviews the noninvasive measurements of induced sputum and exhaled nitric oxide as indicators of airway inflammation.     

CHRONOBIOLOGY AND CHRONOPATHOPHYSIOLOGY OF NOCTURNAL ASTHMA

Asthma is increasing in prevalence and severity worldwide despite effective treatment and innovative research developments. Chronobiology is the study of biological rhythms and their mechanisms. Asthma is one of many diseases that exemplifies a circadian pattern in intensity, frequency of attacks and mortality. As many as 90% of asthmatics experience nocturnal symptoms severe enough to awaken them from sleep. Increased airway narrowing at night is thought to occur as a result of circadian variation in neurohormones and intensification of airway inflammation. Furthermore, vagal tone, neurogenic inflammation and airway hyperresponsiveness are increased at night. Many cells contribute to the nocturnal inflammatory process in the asthmatic airways, including mast cells, eosinophils, neutrophils and lymphocytes. These cells are capable of secreting innumerable inflammatory mediators, such as histamine, cytokines, leukotrienes, prostaglandins, neutral endopeptidase and superoxides, which are potent bronchoconstrictors and secretogogues. They also cause increased vascular permeability and airway oedema. All these chronobiological events promote nocturnal worsening of asthma and increased nocturnal deaths. Understanding the mechanisms of nocturnal asthma will help us learn more about asthma, and how to implement appropriate chronotherapeutic interventions.     

A panel of multiple markers associated with chronic systemic inflammation and the risk of atherogenesis is detectable in asthma and chronic obstructive pulmonary disease

Asthma and chronic obstructive pulmonary disease (COPD) are both lung diseases involving chronic inflammation of the airway. The injury is reversible in asthma whereas it is mostly irreversible in COPD. Both patients of asthma and COPD are known at risk for cardiovascular disease (CVD) and type 2 diabetes (T2DM), nephropathy, and cancer. We measured multiple risk markers for atherogenesis in 55 patients with asthma and 62 patients with COPD. We wanted to know whether risk markers for atherogenesis corresponding to sequence of events of chronic inflammation were also detectable in the airway inflammatory diseases. Elevation of almost all markers involving inflammation of the endothelial cells in the coronary artery were detectable in asthma and COPD involving the inflammation of the epithelial cell lining of the airway. Both the level and % elevation of all markers were found mostly higher in COPD, the more severe form of the lung disease. We believe that these markers are useful for predicting risk of developing clinical complications such as CVD.     

Eosinophilic bronchitis: an imortant cause of prolonged cough

The recent development of noninvasive techniques to measure airway inflammation has led to the recognition of eosinophilic bronchitis, a condition characterized by a sputum eosinophilia identical to that seen in asthma, but without any of the functional abnormalities associated with asthma. The condition is interesting for a number of reasons. Firstly, eosinophilic bronchitis is a common cause of chronic cough, which is important to recognize as it responds well to corticosteroids. However, recognition is not straightforward because it requires assessment of airway inflammation. Secondly, the natural history of eosinophilic bronchitis is uncertain. Some patients with chronic obstructive pulmonary disease without a history of previous asthma have sputum eosinophilia, thus one possibility is that eosinophilic bronchitis may develop into fixed airflow obstruction. Finally, the difference in the association of eosinophilic airway inflammation to airway dysfunction between eosinophilic bronchitis and asthma is of interest as it is possible that it reflects important differences in the nature or site of the airway inflammation. Further study of this interesting condition may shed light on the relationship between airway inflammation and airway responsiveness, leading to a greater understanding of both eosinophilic bronchitis and asthma.     

Eosinophilic bronchitis: an important cause of prolonged cough

The recent development of noninvasive techniques to measure airway inflammation has led to the recognition of eosinophilic bronchitis, a condition characterized by a sputum eosinophilia identical to that seen in asthma, but without any of the functional abnormalities associated with asthma. The condition is interesting for a number of reasons. Firstly, eosinophilic bronchitis is a common cause of chronic cough, which is important to recognize as it responds well to corticosteroids. However, recognition is not straightforward because it requires assessment of airway inflammation. Secondly, the natural history of eosinophilic bronchitis is uncertain. Some patients with chronic obstructive pulmonary disease without a history of previous asthma have sputum eosinophilia, thus one possibility is that eosinophilic bronchitis may develop into fixed airflow obstruction. Finally, the difference in the association of eosinophilic airway inflammation to airway dysfunction between eosinophilic bronchitis and asthma is of interest as it is possible that it reflects important differences in the nature or site of the airway inflammation. Further study of this interesting condition may shed light on the relationship between airway inflammation and airway responsiveness, leading to a greater understanding of both eosinophilic bronchitis and asthma.     

Asthma: 2015 and beyond

Asthma is a multifactorial, chronic inflammatory disease of the airways. The knowledge that asthma is an inflammatory disorder has become a core fundamental in the definition of asthma. Asthma's chief features include a variable degree of air-flow obstruction and bronchial hyper-responsiveness, in addition to the underlying chronic airways inflammation. This underlying chronic airway inflammation substantially contributes to airway hyper-responsiveness, air-flow limitation, respiratory symptoms, and disease chronicity. However, this underlying chronic airway inflammation has implications for the diagnosis, management, and potential prevention of the disease. This review for the respiratory therapy community summarizes these developments as well as providing an update on asthma epidemiology, natural history, cause, and pathogenesis. This paper also provides an overview on appropriate diagnostic and monitoring strategies for asthma, pharmacology, and newer therapies for the future as well as relevant management of acute and ambulatory asthma, and a brief review of educational approaches.     

The inflammatory response in asthma.

Asthma is remarkably underdiagnosed and undertreated. While the clinical hallmark of asthma is reversible airflow obstruction, airway inflammation is the major pathologic feature. Studies have linked airway hyperresponsiveness, the basic physiologic defect in asthma, with airway inflammation, even in patients who have mild asthma. Management is directed toward treating the underlying disease process with anti-inflammatory therapy and alleviating breakthrough symptoms with bronchodilators.     

Relapsing polychondritis: reversible airway obstruction is not always asthma

Relapsing polychondritis (RP) is a rare disease characterized by recurrent inflammation of cartilaginous and other proteoglycan-rich tissues. Respiratory tract involvement is a common cause of morbidity and mortality in RP. We describe a patient whose clinical features at onset of disease were typical of asthma. Later, the patient developed symptoms and signs characteristic of RP. Tracheobronchomalacia necessitated airway support by stenting. The possibility that airway obstruction in the initial stages of RP is due to airway inflammation and that early, aggressive immunosuppressive treatment of RP may delay or prevent irreversible cartilaginous destruction and airway collapse are discussed.     

New insights into the relationship between airway inflammation and asthma

Asthma is a condition characterized by variable airflow obstruction, airway hyper-responsiveness (AHR) and airway inflammation which is usually, but not invariably, eosinophilic. Current thoughts on the pathogenesis of asthma are focused on the idea that it is caused by an inappropriate response of the specific immune system to harmless antigens, particularly allergens such as cat dander and house dust mite, that result in Th2-mediated chronic inflammation. However, the relationship between inflammation and asthma is complex, with no good correlation between the severity of inflammation, at least as measured by the number of eosinophils, and the severity of asthma. In addition, there are a number of conditions, such as eosinophilic bronchitis and allergic rhinitis, in which there is a Th2-mediated inflammatory response, but no asthma, as measured by variable airflow obstruction or AHR. Bronchoconstriction can also occur without obvious airway inflammation, and neutrophilic inflammation can in some cases be associated with asthma. When we compared the immunopathology of eosinophilic bronchitis and asthma, the only difference we observed was that, in asthma, the airway smooth muscle (ASM) was infiltrated by mast cells, suggesting that airway obstruction and AHR are due to an ASM mast cell myositis. This observation emphasizes that the features that characterize asthma, as opposed to bronchitis, are due to abnormalities in smooth muscle responsiveness, which could be intrinsic or acquired, and that inflammation is only relevant in that it leads to these abnormalities. It also emphasizes the importance of micro-localization as an organizing principle in physiological responses to airway inflammation. Thus, if inflammation is localized to the epithelium and lamina propria, then the symptoms of bronchitis (cough and mucus hypersecretion) result, and it is only if the ASM is involved -- for reasons that remain to be established -- that asthma occurs.     

Is mild asthma really ‘mild’?

Current evidence suggests that patients with mild asthma are often under-recognised, and those that are diagnosed can remain with this initial classification and be treated accordingly, despite worsening of their condition. There is considerable overlap between mild and more severe asthma in terms of the underlying pathophysiology and poorly reversible airway changes, such as subepithelial fibrosis and airway wall remodelling, which are present very early in the progression of asthma in patients with normal lung function. Life-threatening exacerbations can also occur in patients with mild asthma. In view of these factors and given that asthma is a two-component disease (airway inflammation and smooth muscle dysfunction), recent studies have examined the effects of both early intervention with steroids and combination therapy comprising an inhaled steroid and a long acting beta(2)-agonist. These studies suggest that early intervention is likely to provide better asthma control and possibly prevent or delay the worsening of disease and fatalities in patients considered to be mild asthmatics.     

Approaches to acute asthma and status asthmaticus in children

Asthma is the most common chronic disease in pediatric patients and is the leading cause of childhood disability. The functional abnormalities of this disease--namely, airway obstruction and hyperresponsiveness--are consequences primarily of airway inflammation. Outpatient therapy for acute asthma, as well as therapy for status asthmaticus (episodes of asthma unresponsive to usually effective outpatient therapy and necessitating hospitalization), primarily addresses treatment of airway inflammation. The goal of office and emergency room management of acute asthma is reversal of airway obstruction by the administration of inhaled beta-adrenergic medications. The therapy for status asthmaticus consists of intravenously administered aminophylline, corticosteroids, nebulized beta-adrenergic agents, and oxygen. Respiratory failure, the inability to maintain adequate elimination of CO2, may be effectively treated by adding continuous nebulization of albuterol. Mechanical ventilation will still be necessary in the rare patient who does not respond to pharmacologic therapy. Acute exacerbations of asthma, as well as status asthmaticus, can best be prevented by establishing effective maintenance programs individualized for each patient.     

Lebrikizumab in the treatment of asthma

ABSTRACT

Introduction: Severe asthma continues to be a major clinical problem despite the availability of effective asthma medications such as inhaled corticosteroids. Several targeted biologic therapies are emerging to treat patients with severe asthma.

Areas covered: This review provides an update of information on lebrikizumab, a novel monoclonal antibody that targets IL-13 and is currently in advanced stages of development. It describes the role of IL-13, a key effector cytokine in Type 2 (T2) airway inflammation in asthma and discusses the results of recent phase 2 trials investigating lebrikizumab’s efficacy and safety in patients with severe asthma. Furthermore, it provides insight into the current ongoing trials with lebrikizumab and outlines future research needs.

Expert opinion: Several emerging therapeutic targets have been identified for patients with severe asthma. By specifically targeting IL-13, lebrikizumab has the potential to block several downstream signals that play a role in disease progression including airway inflammation, mucus hypersecretion and airway remodeling. The effects of lebrikizumab have been more marked in individuals with high serum periostin levels which reflect underlying IL-13 activity and T2 airway inflammation. Ongoing trials with lebrikizumab aim to further examine its long-term safety and efficacy in a larger population and explore its effects on airway inflammation and function.     

Pathogenesis of asthma

There is now strong evidence that airway inflammation is a predominant underlying problem in patients with asthma, and it has been suggested that ongoing inflammation may lead to airway injury and remodeling. There is also recent evidence that longstanding asthma could be associated with loss of elastic recoil, which can enhance airway obstruction and worsen asthma control [82,83]. Therefore, the use of anti-inflammatory therapy has been advocated in all guidelines, including the National Asthma Education and Prevention Program (NAEPP) Expert Panel Report [84] and its recent update [85] that recommended inhaled steroids as a first mode of therapy for patients with mild, moderate, or severe, persistent asthma. There is preliminary evidence that early institution of anti-inflammatory therapy might lead to disease modification and limit the progression of subepithelial fibrosis and airway remodeling. The pathogenesis of asthma clearly involves many cells and mediators, although the contribution of each individual factor is probably different from patient to patient depending on the setting and stimulus. Although currently available therapies are highly effective in controlling asthma symptoms and limiting exacerbations in the majority of patients, there is still a subset of patients that proceed to develop severe asthma with decreased lung function, lack of responsiveness to therapy, or frequent exacerbations. It is hoped that rapid progress in the area of asthma genetics and pharmacogenetics will yield a more precise and patient-specific understanding of asthma pathogenesis and allow practitioners to prescribe therapies that are designed for a particular patient or exacerbation. That will undoubtedly help to improve the care of asthma, limit its morbidity, and reduce the side effect of medications.     

What is the best pulmonary diagnostic approach for wheezing patients with normal spirometry?

Asthma is characterized by airway inflammation, airway hyper-responsiveness (AHR) and variable air flow obstruction. The diagnosis of asthma, however, is often based upon nonspecific clinical symptoms of cough, wheeze, and shortness of breath. Furthermore, the physical examination and measurements of pulmonary function are often unremarkable in patients with asthma, thereby complicating the diagnosis of the disease. The following discussion will review approaches to the diagnosis of asthma when lung functions are normal, and will largely focus on the use of bronchial provocation tests to detect underlying AHR.     

Moving towards a new generation of animal models for asthma and COPD with improved clinical relevance

Asthma and chronic obstructive pulmonary disease (COPD) are complex inflammatory airway diseases characterised by airflow obstruction that remain leading causes of hospitalization and death worldwide. Animal modelling systems that accurately reflect disease pathophysiology continue to be essential to the development of new therapies for both conditions. In this review, we describe preclinical in vivo models that recapitulate many of the features of asthma and COPD. Specifically, we discuss the pro's and con's of the standard models and highlight recently developed systems designed to more accurately reflect the complexity of both diseases. For instance, clinically relevant allergens (i.e. house dust mite) are now being used to mimic the inflammatory changes and airway remodelling that result after chronic allergen exposures. Additionally, systems are being developed to mimic steroid-resistant and viral exacerbations of allergic inflammation - aspects of asthma where there is an acute need for new therapies. Similarly, COPD models have evolved to align with the improved clinical understanding of the factors contributing to disease progression. This includes using cigarette smoke to model not only airway inflammation and remodelling, but some systemic changes (e.g. hypertension and skeletal muscle alterations) that are thought to influence disease. Further, mouse genetics are being exploited to gain insights into the genetics of COPD susceptibility. The new models of asthma and COPD described herein demonstrate that improved clinical understanding of the diseases and better preclinical models is an iterative process that will hopefully lead to therapies that can effectively manage severe asthma and COPD.     

靶向Th17细胞免疫治疗中重度哮喘的作用

支气管哮喘（简称哮喘）是多种炎症细胞和炎性介质参与的慢性气道炎症性疾病。Thl/Th2免疫反应失衡是哮喘主要的发病机制,而嗜酸粒细胞性气道炎症和气道高反应性为哮喘的显著临床特征。Th17细胞通过活化和募集中性粒细胞,促进气道炎症发生发展,尤其与中重度哮喘密切相关。Th17细胞为中重度哮喘提供了潜在的治疗靶点。深入研究Th17细胞分化调控机制,有望为治疗中性粒细胞性哮喘带来新的愿景。     

Inflammatory mechanisms and treatment of obstructive airway diseases with neutrophilic bronchitis

Obstructive airway diseases such as asthma and chronic obstructive pulmonary disease (COPD) are major global health issues. Although considered as distinct diseases, airway inflammation is a key underlying pathophysiological process in asthma, COPD and bronchiectasis. Persistent neutrophilic airway inflammation (neutrophilic bronchitis) occurs with innate immune activation and is a feature of each of these airway diseases. Little is known about the mechanisms leading to neutrophilic bronchitis and few treatments are effective in reducing neutrophil accumulation in the airways.There is a similar pattern of inflammatory mediator release and toll like receptor 2 expression in asthma, COPD and bronchiectasis. We propose the existence of an active amplification mechanism, an effector arm of the innate immune system, involving toll like receptor 2, operating in persistent neutrophilic bronchitis.Neutrophil persistence in the airways can occur through a number of mechanisms such as impaired apoptosis, efferocytosis and mucus hypersecretion, all of which are impaired in airways disease. Impairment of neutrophil clearance results in a reduced ability to respond to bacterial infection. Persistent activation of airway neutrophils may result in the persistent activation of the innate immune system resulting in further airway insult.Current therapies are limited for the treatment of neutrophilic bronchitis; possible treatments being investigated include theophylline, statins, antagonists of pro-inflammatory cytokines and macrolide antibiotics. Macrolides have shown great promise in their ability to reduce airway inflammation, and can reduce airway neutrophils, levels of CXCL8 and neutrophil proteases in the airways. Studies also show improvements in quality of life and exacerbation rates in airways diseases.     

The αvβ6 integrin modulates airway hyperresponsiveness in mice by regulating intraepithelial mast cells

Allergic asthma is the most common form of asthma, affecting more than 10 million Americans. Although it is clear that mast cells have a key role in the pathogenesis of allergic asthma, the mechanisms by which they regulate airway narrowing in vivo remain to be elucidated. Here we report that mice lacking αvβ6 integrin are protected from exaggerated airway narrowing in a model of allergic asthma. Expression microarrays of the airway epithelium revealed mast cell proteases among the most prominent differentially expressed genes, with expression of mouse mast cell protease 1 (mMCP-1) induced by allergen challenge in WT mice and expression of mMCP-4, -5, and -6 increased at baseline in β6-deficient mice. These findings were most likely explained by loss of TGF-β activation, since the epithelial integrin αvβ6 is a critical activator of latent TGF-β, and in vitro-differentiated mast cells showed TGF-β-dependent expression of mMCP-1 and suppression of mMCP-4 and -6. In vitro, mMCP-1 increased contractility of murine tracheal rings, an effect that depended on intact airway epithelium, whereas mMCP-4 inhibited IL-13-induced epithelial-independent enhancement of contractility. These results suggest that intraepithelial activation of TGF-β by the αvβ6 integrin regulates airway responsiveness by modulating mast cell protease expression and that these proteases and their proteolytic substrates could be novel targets for improved treatment of allergic asthma.