Matrix Metalloproteinases in the Pathogenesis of Asthma and COPD

While asthma is an inflammatory disorder of the airways involving mediators released from mast cells and eosinophils, inflammation alone is insufficient to explain the chronic nature of the disease. Recent progress in the understanding of disease pathogenesis has revealed that airway remodeling, which is at least in part due to an excess of extracellular matrix (ECM) deposition in the airway wall, plays a significant role in airflow obstruction. Matrix metalloproteinases (MMPs) have been suggested to be the major proteolytic enzymes to induce airway remodeling in asthma and COPD. It has been widely accepted that different inflammatory processes are involved in asthma and COPD with different inflammatory cells, mediators, and responses to treatments. Despite these different processes, airflow obstruction and airway remodeling characterize these two diseases. MMP-2 and -9 have been reported to be involved in the pathogenesis of airway remodeling in both diseases and MMP-12, in addition to these MMPs, in the pathogenesis of COPD. In this review, we discuss the current views on the role of MMPs in the pathogenesis of bronchial asthma and COPD. Anti-MMP therapy could theoretically be useful to prevent airway remodeling in asthma and COPD. However, to date no clinical data are available regarding the efficacy of anti-MMP therapies in the treatment of patients with asthma and COPD.     

Airway Dimensions in Fatal Asthma and Fatal COPD: Overlap in Older Patients

Abstract

In some patients with chronic asthma clinical and physiological similarities with COPD may exist, such as partial reversibility to bronchodilators and persistent expiratory airflow obstruction. However, pathological data comparing both diseases in patients of similar age and disease severity are scarce. We compared large and small airway dimensions in 12 younger (mean age 32 yrs) and 15 older (mean age 65 yrs) non-smoker adult fatal asthma patients with 14 chronic smokers with severe, fatal COPD (mean age 71 yrs). Using H&E, Movat pentachrome staining and image analysis, we quantified large airway basement membrane (BM) thickness (μm), submucosal gland area and large and small airway inner wall, smooth muscle and outer wall areas. Areas were normalized by BM perimeter (μm²/μm).

Younger adult fatal asthma patients had thicker BM, smooth muscle, and outer wall areas in both small and large airways when compared to COPD patients. In older asthmatics there was an overlap in BM thickness and airway structure in small airways. Inner wall layer in large and small airway level and submucosal gland areas were similar among groups. In conclusion, there are airway histological structural similarities between fatal asthma and fatal COPD. Older fatal asthmatics present overlapping airway structural features with younger adult fatal asthmatics and severe COPD patients. Our data contributes to a better understanding of asthma pathology in the elderly.     

Future treatment to lessen exacerbations of chronic obstructive pulmonary disease

Therapies currently used to reduce exacerbations of chronic obstructive pulmonary disease (COPD) are compounds used almost entirely for asthma therapy. A notable exception is tiotropium, a long-acting parasympatholytic agent. This compound and its precursor, iprotropium, are only occasionally used for asthma therapy. Likewise, leukotriene-modifying drugs are used occasionally for the treatment of COPD. In neither circumstance is there agency-approved indication for these particular cross-over therapies, but the use of long-acting beta(2)-adrenergic compounds and high-solubility inhaled steroids is a mainstay for therapy in both asthma and COPD. Similarly, theophylline, although less often used for either process, is therapeutically applicable to both asthma and COPD. Although overlap syndromes point to the occurrence of a common pathway in some cases, the inflammatory process for asthma and chronic obstructive pulmonary disease (COPD) differs substantially in most cases. Hence, the application of therapies designed to relax airway smooth muscle and ameliorate asthmatic inflammation lacks a therapeutic rationale for a disease characterized by predominant neutrophilic inflammation occurring in the small airways and alveoli. By definition, COPD is poorly reversible airflow obstruction; hence, the use of drugs designed to relax airway smooth muscle is somewhat counterintuitive and does not address the pathophysiological process of the disease.     

Chronic obstructive pulmonary disease: histopathology, inflammation and potential therapies

Chronic obstructive pulmonary disease (COPD) is a major worldwide health burden with increasing morbidity, mortality and health care cost. It is a slowly progressive chronic inflammatory condition that affects the conducting airways (both large and small) and lung parenchyma. In COPD, inflammation is evident early on even in mild disease and increases with disease severity. Recent advances in our knowledge demonstrate, by comparison with asthma, the distinctive, "abnormal" or exaggerated inflammatory processes involved in the pathogenesis of COPD and thus identify novel therapeutic targets that could potentially impact on disease progression. The present review will focus on what is known of the abnormal inflammatory response of COPD in different regions of the conducting airways and lung. Novel, potentially promising approaches to therapy are presented.     

Effects of corticosteroids on noninvasive biomarkers of inflammation in asthma and chronic obstructive pulmonary disease

Exhaled breath analysis may be used to quantify inflammation and oxidative stress in the respiratory tract, in the differential diagnosis of airway diseases, and in the monitoring of therapy. The greatest progress has been made with standardized measurement of exhaled nitric oxide (NO). Bronchial NO is increased in asthma, correlated with other markers of inflammation, and reduced by treatment with corticosteroids and antileukotrienes. Alveolar NO is increased in chronic obstructive pulmonary disease (COPD), reflecting disease severity and progression. Exhaled carbon monoxide and ethane are increased in both asthma and COPD. Increased concentrations of 8-isoprostane, hydrogen peroxide, nitrite, and nitrotyrosine are found in exhaled breath condensate from patients with inflammatory lung diseases. Increased levels of lipid mediators are also found, and the pattern depends on the nature of the disease process. Additional biomarkers are exhaled breath temperature, which is elevated in asthma and reduced in COPD, and bronchial blood flow. It is likely that smaller and more sensitive analyzers will extend the discriminatory value of exhaled breath analysis and that new techniques will become available to diagnose and monitor respiratory diseases in the family practice and home settings.     

Small airway disease in asthma and COPD: clinical implications

Asthma and COPD have a high personal, societal, and economic impact. Both diseases are characterized by airway obstruction and an inflammatory process. The inflammatory process affects the whole respiratory tract, from central to peripheral airways that are <2 mm in internal diameter, the so-called small airways. There is an increased interest in small airway disease, and some new insights have been gained about the contribution of these small airways to the clinical expression of asthma and COPD, as reviewed in this article. Newly developed devices enable drugs to target the small airways, and this may have implications for treatment of patients with asthma, particularly those not responding to large-particle inhaled corticosteroids or those with uncontrollable asthma. The first studies in COPD are promising, and results from new studies are eagerly awaited.     

Airway remodelling assessed by sputum and high-resolution computed tomography in asthma and COPD.

It is not known whether sputum elastase, metalloproteinase (MMP)-9 and tissue-inhibitor metalloproteinase (TIMP)-1 are related to structural changes of the airways, as assessed by high-resolution computed tomography (HRCT) scan. The relationships between these markers and the magnitude of structural changes of the airways in asthma and chronic obstructive pulmonary disease (COPD) were assessed. Induced sputum and HRCT scan were performed in 30 asthmatics (14 mild and 16 severe) and in 12 patients with COPD. A greater extent of HRCT scan abnormalities was found in COPD than in severe and mild asthmatics. HRCT scan abnormalities correlated with the degree of airway obstruction in COPD and in severe asthma. HRCT scan abnormalities also correlated with the levels of sputum elastase both in COPD and in severe asthma. HRCT scan abnormalities were associated with sputum MMP-9/TIMP-1 ratio in mild asthma, severe asthma and COPD. In conclusion, this study demonstrates that sputum elastase and the metalloproteinase-9/tissue-inhibitor metalloproteinase-1 ratio are associated with the magnitude of high-resolution computed tomography scan abnormalities of the airways in asthma and chronic obstructive pulmonary disease, and suggests that the levels of these markers reflect the extent of structural changes of the airways.     

Bronchial hyper-responsiveness and exhaled nitric oxide in chronic obstructive pulmonary disease

Several lung diseases including asthma and chronic obstructive pulmonary disease (COPD) involve chronic inflammation of the airways. Therefore, there is great interest in non-invasive methods assessing airway inflammation. Measurement of bronchial hyper-responsiveness (BHR) and exhaled nitric oxide (NO) are such indirect markers of airway inflammation. Additional information about severity of disease, prognosis and possible response to anti-inflammatory treatment with inhaled corticosteroids can be gained by these methods. However, they are not yet established in assessing patients with COPD in clinical routine. BHR has long been recognised as a hallmark of asthma. Less is known about prevalence and clinical relevance of BHR in the general population and in COPD patients. Longitudinal studies have shown that BHR in healthy persons is a risk factor for development of respiratory symptoms, asthma and COPD. BHR has also been shown to increase the detrimental effect of cigarette smoke and is associated with a decline in lung function. Furthermore, studies indicate that the presence of BHR is a prognostic factor in COPD. Increased BHR to histamine has been shown to be a predictor for mortality in COPD patients. Based on current guidelines, treatment of patients with severe COPD (GOLD stage III and IV) and regular exacerbations includes therapy with inhaled corticosteroids. Inhaled corticosteroids have been shown to reduce frequency of exacerbations but they have not been shown to modify long-term decline in FEV1. However, one small study found that BHR to inhaled mannitol could possibly predict responsiveness to inhaled corticosteroids in patients with moderately severe COPD and identify a subgroup of patients that is likely to benefit from this treatment. Exhaled NO has been shown to correlate with other inflammatory markers and to be elevated in asthma. In COPD patients, data is inconsistent. However, measuring exhaled NO may have a role in the identification of patients with severe, unstable COPD who were shown to have higher NO levels compared to patients with stable COPD. This suggests that exhaled NO might be a method to assess and monitor disease activity in COPD. Possible explanations for the contradictory results are different measurement techniques of exhaled NO and different smoking histories of patients in various studies. Smoking has been found to be a confounding factor by reducing NO levels significantly, an effect which might counteract the potentially increased exhaled NO due to airway inflammation. In conclusion, measuring BHR and exhaled NO in patients with COPD might provide additional information about disease severity, prognosis and possible response to anti-inflammatory medical treatment. However, to establish these methods in clinical routine in COPD patients, more data is clearly needed.     

The role of small airways in lung disease

The small airways constitute one of the least understood areas of the lungs. They play a role in many lung diseases, and small airway pathology results in significant morbidity New approaches to their evaluation may provide insights into this major area of lung disease. Asthma is well recognized as a disease of both large and small airways. Physiological and pathological evidence, from techniques such as post-mortem tissue histological analysis, induced sputum and transbronchial biopsies, has reinforced the concept of the involvement of the entire bronchial tree n the inflammatory process in asthma, In addition to describing the airway pathology in asthma, th s review focuses on the pathogenesis and role of small airway obstruction n other diseases, including chronic obstructive pulmonary disease (COPD), idiopathic pulmonary fibrosis (IPF), sarcoidosis and obliterative bronchiolitis (OB). COPD is characterized by the presence of airflow obstruction resulting from lesions in the small airways. In addition, features compatible with small airways disease are common in IPF, sarcoidosis and OB. Recent advances in pulmonary imaging, such as high-resolution computed tomography (HRCT) and magnetic resonance imaging (MRI) with hyperpolarized 3He, have allowed non-invasive reproducible measurements of structure-function relationships to be made for the small airways.These techniques have great potential for diagnosing changes in small airway function and for assessing responses to treatment. New insights into the contribution of small airways to a range of lung diseases may lead to the development of therapies targeted at this part of the bronchial anatomy.     

Increased nitrosothiols in exhaled breath condensate in inflammatory airway diseases

Nitrosothiols (RS-NOs) are formed by interaction of nitric oxide (NO) with glutathione and may limit the detrimental effect of NO. Because NO generation is increased in airway inflammation, we have measured RS-NOs in exhaled breath condensate in patients with asthma, cystic fibrosis, or chronic obstructive pulmonary disease (COPD). We also measured exhaled NO and nitrite (NO(2-)) in the same subjects. RS-NOs were detectable in exhaled breath condensate of all subjects. RS-NOs were higher in subjects with severe asthma (0.81 +/- 0.06 microM) when compared with normal control subjects (0.11 +/- 0.02 microM, p < 0.01) and with subjects with mild asthma (0.08 +/- 0.01 microM, p < 0.01). Elevated RS-NOs values were also found in patients with cystic fibrosis (0.35 +/- 0.07 microM, p < 0.01), in those with COPD (0.24 +/- 0.04 microM, p < 0.01) and in smokers (0.46 +/- 0.09 microM, p < 0.01). In current smokers there was a correlation (r = 0.8, p < 0.05) between RS-NOs values and smoking history (pack/year). We also found elevated concentrations of NO(2-) in patients with severe asthma, cystic fibrosis, or COPD, but not in smokers or patients with mild asthma. This suggests that exhaled NO(2-) is less sensitive than exhaled RS-NOs. This study has shown that RS-NOs are detectable in exhaled breath condensate of healthy subjects and are increased in patients with inflammatory airway diseases. As RS-NOs concentrations in exhaled breath condensate vary in the different airway diseases and increase with the severity of asthma, their measurement may have clinical relevance as a noninvasive biomarker of nitrosative stress.     

Increased exhaled nitric oxide in chronic bronchitis: comparison with asthma and COPD

STUDY OBJECTIVES: To test the hypothesis that exhaled nitric oxide (NO) is increased in patients with chronic bronchitis, and to compare the results with exhaled NO in patients with asthma and COPD. STUDY DESIGN: Cross-sectional survey. SETTING AND PATIENTS: Veterans Administration pulmonary function laboratory. Patients (n = 179) were recruited from 234 consecutive patients. Two nonsmoking control groups of similar age, with normal spirometry measurements and no lung disease, were used (18 patient control subjects and 20 volunteers). MEASUREMENTS: Participants completed questionnaires and spirometry testing. Exhaled NO was measured by chemiluminescence using a single-breath exhalation technique. RESULTS: Current smoking status was associated with reduced levels of exhaled NO (smokers, 9. 2 +/- 0.9 parts per billion [ppb]; never and ex-smokers, 14.3 +/- 0. 6 ppb; p < 0.0001). Current smokers (n = 57) were excluded from further analysis. Among nonsmokers, the levels of exhaled NO were significantly higher in patients with chronic bronchitis (17.0 +/- 1. 1 ppb; p = 0.035) and asthma (16.4 +/- 1.3 ppb; p = 0.05) but not in those with COPD (14.7 +/- 1.0 ppb; p = 0.17) when compared with either control group (patient control subjects, 11.1 +/- 1.6 ppb; outside control subjects, 11.5 +/- 1.5 ppb). The highest mean exhaled NO concentration occurred in patients with both chronic bronchitis and asthma (20.2 +/- 1.6 ppb; p = 0.005 vs control subjects). CONCLUSIONS: Exhaled NO is increased in patients with chronic bronchitis. The increase of exhaled NO in patients with chronic bronchitis was similar to that seen in patients with asthma. The highest mean exhaled NO occurred in patients with both chronic bronchitis and asthma. Exhaled NO was not increased in patients with COPD. Although chronic bronchitis and asthma have distinct histopathologic features, increased exhaled NO in patients with both diseases suggests common features of inflammation.     

支气管哮喘-慢性阻塞性肺疾病重叠综合征的分型诊疗进展及新的研究方向

支气管哮喘(简称哮喘)和COPD均是气流阻塞性疾病,两者发病机制和临床特点表现不同.近年来临床发现部分患者既有哮喘特点又有COPD的特点,这类患者目前命名为哮喘-慢性阻塞性肺疾病重叠综合征(asthma-COPD overlap syndrome,ACOS).目前所定义的ACOS在临床中表现异质性,根据其不同临床表现而划分为不同的表型,根据各个表型特点进行药物治疗.ACOS作为新的疾病分类,可以考虑从气道、合并症及生活方式等各个方面开展新的研究方向.     

Genetic Backgrounds of Asthma and COPD

Asthma and COPD are complex diseases with strong genetic and environmental components. These common pulmonary diseases have both different and similar clinical features. Molecular genetic techniques are being used to improve understanding of these common late onset disorders. Recently, several genes and genetic loci associated with increased susceptibility to asthma and COPD have been described. Many of these genes are expressed in the lung tissues, indicating that events in lung tissues might drive disease processes. Lung tissues are rich sources of innate danger signals, and an increased understanding of how the lung tissues communicate with the immune system to maintain healthy tissue might provide new insights into the pathogenesis of chronic inflammatory lung diseases in which injury and repair are in disequilibrium. Given that the innate immune system is at the interface between the airways and environmental insults, genetic polymorphisms in genes related to the innate immune system are likely to affect susceptibility to both asthma and CopD. In addition, some findings from genetic studies provide molecular support for the point of view proposed in the Dutch hypothesis regarding the relationship between asthma and COPD, which highlights the complexity of the pathways that can induce small airway disease and suggests that there is a continuum between asthma and COPD.     

Clinical study of multiple breath biomarkers of asthma and COPD (NO, CO(2), CO and N(2)O) by infrared laser spectroscopy

Breath analysis is a powerful non-invasive technique for the diagnosis and monitoring of respiratory diseases, including asthma and chronic obstructive pulmonary disease (COPD). Exhaled nitric oxide (NO) and carbon monoxide (CO) are markers of airway inflammation and can indicate the extent of respiratory diseases. We have developed a compact fast response quantum cascade laser system for analysis of multiple gases by tunable infrared absorption spectroscopy. The ARI breath analysis instrument has been deployed in a study of exhaled breath from patients with asthma or COPD. A total of 173 subjects participated, including both adult and pediatric patients. Patients in asthma or COPD exacerbations were evaluated twice-during the exacerbation and at a follow-up visit-to compare variations in breath biomarkers during these events. The change in exhaled NO levels between exacerbation and 'well' visits is consistent with spirometry data collected. Respiratory models are important for understanding the exchange dynamics of nitric oxide and other species in the lungs and airways. At each patient's visit, tests were conducted at four expiratory flow rates. We have applied a trumpet model with axial diffusion to the multi-flow exhaled nitric oxide data, obtaining NO alveolar concentrations and airway fluxes. We found higher airway fluxes for those with more severe asthma and during exacerbation events. The alveolar concentrations from the model were higher in adults with asthma and COPD, but this trend was less clear among the pediatric subjects.     

Clinical phenotypes of obstructive airway diseases in an outpatient population

Background and Objectives: Historically, obstructive airway diseases such as asthma and COPD are classified as different diseases. Although the definitions are clearly described, classification of patients into these traditional, clinical disease entity can be difficult. Recent evidence that there are complex, overlapping phenotypes of obstructive lung disease. Our aim was to capture clinical phenotypes of obstructive diseases through the use of cluster analysis in a representative patient population at a common Dutch pulmonary outpatient clinic. Clinical physiological and cellular/ molecular markers were used in the analysis. Methods: To carry out the cluster analysis, an imputed dataset was created from a random sample of 191 adult patients chosen from a pulmonary outpatient clinic. The selection criteria from the sample included patients with a doctor's diagnosis for asthma or COPD. Detailed assessment of patient pulmonary function, blood eosinophil counts, allergic sensitisation and smoking history was collected. Results: We observed four distinct clusters with different clinical characteristics of obstructive lung diseases. Cluster 1: patients with a history of extensive cigarette smoking, airway obstruction without signs of emphysema; cluster 2: patients with features of the emphysematous type of COPD; cluster 3: patients with characteristics of allergic asthma; cluster 4: patients with features suggesting an overlap syndrome of atopic asthma and COPD. Conclusion: Four phenotypes of obstructive lung disease were identified amongst patients clinically labelled as asthma or COPD. These findings emphasize the concept that there are different phenotypes of obstructive lung diseases, including overlapping and complementary disease entities. These phenotypes of chronic airways disease can serve to tailor disease management.     

Sequentially induced sputum in patients with asthma or chronic obstructive pulmonary disease.

It has been demonstrated that consecutive samples of induced sputum may differ with respect to cellular composition. The aim of this study was to compare two sequential sputum samples in patients with chronic obstructive pulmonary disease (COPD) and asthma with different severity. Two sputum inductions were performed 30 min apart and processed separately in healthy subjects (n=11), patients with moderate to severe COPD (n=10), asthmatics treated with beta2-agonists alone (group 1, n=11), inhaled steroids (group 2, n=12) or systemic steroids (group 3, n=7). In healthy subjects and asthma group 2, percentages of neutrophils decreased significantly between the two sputum inductions but did not change in COPD and asthma group 3. Percentages of eosinophils did not change significantly in any group of patients. Concentrations of interleukin (IL)-8 decreased significantly in the control group and asthma groups 1 and 2 but not in asthma group 3 and the COPD group. These data demonstrate differences in sputum composition between two consecutive samples which were most pronounced in healthy subjects. Therefore, pooling of sputum samples may affect the results, particularly in healthy subjects, in contrast to subjects with more severe asthma or chronic obstructive pulmonary disease. These findings may be suggestive of differences in the distribution of inflammation along the airways between distinct airway diseases.     

Innate immunity to influenza in chronic airways diseases

Influenza presents a unique human infectious disease that has a substantial impact on the public health, in general, and especially for those with chronic airways diseases. People with asthma and chronic obstructive pulmonary disease (COPD) are particularly vulnerable to influenza infection and experience more severe symptoms with the worsening of their pre‐existing conditions. Recent advances in reverse genetics and innate immunity has revealed several influenza virulence factors and host factors involved in influenza pathogenesis and the immune responses to infection. Early innate immunity plays a critical role of limiting viral infection and spread; however, the underlying mechanisms that lead to enhanced susceptibility to influenza infection and severe symptoms in those with asthma and COPD to infection remain un‐investigated. This review will explore the importance of early innate antiviral responses to influenza infection and how these responses are altered by influenza virus and in those with chronic airways diseases.     

An official JRS statement: The principles of fractional exhaled nitric oxide (FeNO) measurement and interpretation of the results in clinical practice

Nitric oxide (NO) is produced in the body and has been shown to have diverse actions in the abundance of research that has been performed on it since the 1970s, leading to Furchgott, Murad, and Ignarro receiving the Nobel Prize in Physiology or Medicine in 1998. NO is produced by nitric oxide synthase (NOS). NOS is broadly distributed, being found in the nerves, blood vessels, airway epithelium, and inflammatory cells. In asthma, inflammatory cytokines induce NOS activity in the airway epithelium and inflammatory cells, producing large amounts of NO. Measurement of fractional exhaled nitric oxide (FeNO) is a simple, safe, and quantitative method of assessing airway inflammation. The FeNO measurement method has been standardized and, in recent years, this noninvasive test has been broadly used to support the diagnosis of asthma, monitor airway inflammation, and detect asthma overlap in chronic obstructive pulmonary disease (COPD) patients. Since the normal upper limit of FeNO for healthy Japanese adults is 37 ppb, values of 35 ppb or more are likely to be interpreted as a signature of inflammatory condition presenting features with asthma, and this value is used in clinical practice. Research is also underway for clinical application of these measurements in other respiratory diseases such as COPD and interstitial lung disease. Currently, there remains some confusion regarding the significance of these measurements and the interpretation of the results. This statement is designed to provide a simple explanation including the principles of FeNO measurements, the measurement methods, and the interpretation of the measurement results.     

Similarities and differences in asthma and chronic obstructive pulmonary disease exacerbations

There is no generally accepted definition of an exacerbation either for asthma or for chronic obstructive pulmonary disease. There is little consistency among the symptomatic or functional criteria used in different studies. The most consistent criterion is the introduction of systemic corticosteroids for the acute worsening of the disease. The time course of an exacerbation does not seem to differ very much between asthma and chronic obstructive pulmonary disease (COPD). The decrease in peak flow rate is more pronounced in asthma than in COPD. The frequency of exacerbations is linked to disease severity both in asthma and COPD. Common causes are viral infections and increased environmental air pollution, whereas allergen exposure and bacterial infections are more specific for asthma and COPD exacerbations, respectively. Few data are available about the airway pathology of asthma or COPD exacerbations. Eosinophilia and/or neutrophilia have been associated with exacerbations in both diseases. Avoidance of the causal factors decreases exacerbation rate in both diseases. Pharmacologic prevention of exacerbations in asthma has been shown for inhaled corticosteroids, combination therapy with long-acting inhaled beta(2)-agonists and inhaled corticosteroids, and monoclonal anti-IgE. Inhaled corticosteroids, long-acting inhaled beta(2)-agonists, combination therapy with both, and the long-acting inhaled anticholinergic tiotropium decrease the exacerbation rate in COPD.     

Pathology and pathophysiology of chronic obstructive pulmonary disease

A variety of pathological changes have been observed in the central airways, peripheral airways and lung parenchyma of patients with chronic obstructive pulmonary disease (COPD). The characteristic changes in the central airways include inflammatory cellular infiltration into the airway wall and mucous gland enlargement. In the peripheral airways, various morphological changes are observed, including mucous plugging, epithelial abnormalities, inflammatory cellular infiltrates, fibrosis and distortion; these changes lead to airway narrowing. In the lung parenchyma, emphysema defined as alveolar destruction and airspace enlargement is present. Although the major sites of airflow limitation in patients with COPD are most likely the peripheral airways, lesions in both the peripheral airways and the lung parenchyma contribute to chronic airflow limitations.