Abstract
The aim of this study is to clarify whether the combined evaluation of resting hyperinflation and emphysema confers any additional advantages in terms of predicting clinical outcomes in chronic obstructive pulmonary disease (COPD) patients. We included COPD patients from the Korean Obstructive Lung Disease (KOLD) cohort. Patients with a residual volume/total lung capacity (RV/TLC) over the upper limit of normal were defined as having resting hyperinflation, and those with an emphysema index >10% were defined as having emphysema. We investigated the impacts of resting hyperinflation and emphysema on exacerbations and mortality. A total of 310 COPD patients were analyzed over a mean of 61.1 months. After adjustment for covariates, resting hyperinflation was an independent predictor of earlier exacerbation (HR = 1.66, CI = 1.24–2.22), more frequent exacerbation (IRR = 1.35, CI = 1.01–1.81), and higher mortality (HR = 2.45, CI = 1.16–5.17) risk. Emphysema was also significantly associated with earlier exacerbation (HR = 1.64, CI = 1.15–2.35), and higher mortality (HR = 3.13, CI = 1.06–9.27) risk. Participants with both resting hyperinflation and emphysema had an additively higher risk of earlier exacerbations (HR = 1.71, 95% CI = 1.26–2.33) and mortality (HR = 3.75, 95% CI = 1.81–7.73) compared with those in other groups. In conclusion, resting hyperinflation and emphysema had additional worse impacts on exacerbations and mortality in COPD patients.
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Discover the latest articles, news and stories from top researchers in related subjects.Introduction
Chronic obstructive pulmonary disease (COPD), which is characterized by persistent and progressive airflow limitation, is a major cause of morbidity and mortality worldwide1,2. Furthermore, the disease is associated with increasing socioeconomic burdens3. The main pathophysiology of the disease involves inflammatory responses in the small airways and parenchymal destruction of the lung. However, the contribution of each of these individual factors varies from person to person, and as a result, COPD has various phenotypes4,5. The current diagnosis and classification of COPD is based mainly on the degree of expiratory flow limitation, which is represented by the forced expiratory volume in one second (FEV1). However, studies have shown that FEV1 alone cannot explain the inherent complexity of the various COPD phenotypes6.
In addition to expiratory airflow limitation, resting hyperinflation is another major manifestation of COPD caused by injury of the small airways and parenchymal destruction, which is known to be closely related to symptoms and exercise performance7,8,9. Indeed, the residual volume/total lung capacity ratio (RV/TLC), which is one of the most commonly used index reflecting the degree of resting hyperinflation with equations for reference values available10,11, is a potential prognostic marker associated with mortality in COPD12,13,14. However, small airway dysfunction occurs as a result of normal aging; such dysfunction can also lead to hyperinflation. For this reason, evaluation of the RV/TLC alone can lead to misrepresentations of the true status of COPD15. In addition, data remain scarce regarding the relationship between RV/TLC and outcomes other than mortality; in particular, few well-designed prospective studies have addressed this issue.
Another important pathological manifestation of COPD—emphysema—reflects the parenchymal destruction of the lung16. The presence and degree of emphysema can be quantified using computed tomography (CT), and the condition is also known to be associated with the various outcomes of COPD17,18,19. However, a significant proportion of patients with emphysema—even those with severe emphysema—show preserved lung function and exercise capacity, with only mild symptoms. Thus, the evaluation of emphysema alone as a prognostic marker also has shortcomings5,20,21.
Resting hyperinflation and emphysema are closely related, and they represent the “emphysema-hyperinflated” phenotype of COPD. However, most previous studies have evaluated the relationship of only one of these features with disease outcome22. Accordingly, we hypothesized that the evaluation of resting hyperinflation and emphysema in combination would provide additional information regarding the relationship of both features with the clinical course of COPD.
Therefore, we carried out a multicenter, prospective, longitudinal study involving detailed assessment of patients with COPD. The participants were observed for up to 10 years under appropriate treatment23. The aim of this study was to assess the associations of resting hyperinflation and emphysema with the clinical course of COPD. Hyperinflation was evaluated using RV/TLC, while emphysema was determined using CT. In addition, this study aimed to explore whether the evaluation of these two features in combination confers additional information along with phenotypical classification for the prediction of exacerbations and mortality in COPD patients.
Methods
Study design and participants
The KOLD study prospectively recruited patients with obstructive lung disease from the pulmonary clinics of 14 referral hospitals in South Korea from June 2005 to October 2012. The details of this cohort have been reported previously23. The present study included patients from the cohort who (1) were aged ≥40 years; (2) had a post-bronchodilator FEV1/forced vital capacity (FVC) below the lower limits of normal (LLN) according to the prediction equation suggested by the Global Lung Initiative (GLI)24; (3) were current or ex-smokers, with a smoking history of more than 10 pack-years; and (4) had the results of both chest CT and body plethysmography available at baseline. Patients with an RV/TLC over the upper limits of normal (ULN) as calculated by prediction equations adjusting for sex and age bias were defined as having resting hyperinflation10, and those with an emphysema index (volume fraction of the lung ≤ −950 Hounsfield Units [HU]) >10% were defined as having emphysema17. To evaluate whether combined evaluation of the two features would inform better prediction of the clinical outcomes of COPD, subjects were classified into four groups: Group 1 had an RV/TLC ≤ ULN and an emphysema index ≤ 10%; Group 2 had an RV/TLC ≤ ULN and an emphysema index >10%; Group 3 had an RV/TLC > ULN and an emphysema index ≤ 10%; and Group 4 had an RV/TLC > ULN and an emphysema index >10%. First, we independently evaluated the association between each feature—hyperinflation and emphysema—as well as emphysema index and RV/TLC as a continuous variable, and the clinical course of COPD. We then performed multiple comparisons of long-term outcomes among the groups.
The design of this study was approved by the ethics committee of the Seoul National University Hospital Institutional Review Board (IRB no. 1611–013–804). The study was conducted in accordance with the Declaration of Helsinki. Written, informed consent was obtained from all included subjects.
Procedures and measurements
Baseline clinical data from all participants, including demographic information and smoking status, were collected. To establish symptom scores, St. George’s respiratory questionnaire (SGRQ) and the modified Medical Research Council (mMRC) dyspnea-scale were used. Chronic bronchitis was defined as the presence of phlegm for periods of three months or more for at least two years. Each patient’s history of acute exacerbations in the year prior enrollment was also collected. In addition to regular follow-ups at three-month intervals, reports were taken when patients experienced exacerbations or mortality. Participants visited the clinics every 3 months for assessments of the experience of acute exacerbations. If a participant did not visit the attending clinic, research coordinators called him or her to obtain information. The definition of acute exacerbation used in this study was any event that required an unplanned visit to a clinic or emergency room with or without admission due to acute aggravation of respiratory symptoms. Acute exacerbations were assessed based on both self-reports to questionnaires and the medical records including prescription papers. When loss-to-follow-up occurred, the investigators made reasonable efforts to contact the participants and ascertain the cause. The reasons for loss-to-follow-up were properly recorded.
Pulmonary function tests were performed according to the American Thoracic Society guidelines using the Vmax 22 (Sensor Medics, Yorba Linda, CA, USA) and PFDX (Medgraphics, St Paul, MN, USA)25. Post-bronchodilator FEV1 and FVC, indices of lung volume, as well as the diffusing capacity of carbon monoxide (DLCO), were measured at baseline and at each annual visit. All post-bronchodilator spirometry values were measured 15 min after the administration of 400 µg of salbutamol. Bronchodilator reversibility was identified when the FEV1 increased by 12% and at least 200 mL above the baseline value after salbutamol administration11. Static lung volumes, total lung capacity (TLC), and residual volume (RV) were measured using body plethysmography with a V6200 (CareFusion, San Diego, CA, USA), Vmax 22, or PFDX26.
Volumetric CT scans were taken at the time of enrollment, after 1 year, and then at intervals of 3 years. The scans were taken at full inspiration and expiration using 16-multidetector CT scanners (Somatom Sensation 16; Siemens Medical Systems, Bonn, Germany; GE Lightspeed Ultra; General Electric Healthcare, Milwaukee, WI, USA; Philips Brilliance 16; Philips Medical Systems, Best, Netherlands). Whole lung images were extracted automatically, and the attenuation coefficient of each pixel was calculated. The emphysema index was determined by calculation of the volume fraction of the lungs below −950 HU at full inspiration27.
Statistical analyses
Characteristics were compared among groups using analysis of variance (for continuous variables) and chi-square tests, as appropriate. To additionally evaluate the difference in values between groups with further adjustments for possible confounding factors, analysis of covariance was used. When evaluating RV/TLC and emphysema index as continuous variables, the distributions of these data were assessed first. While RV/TLC showed normal distribution, emphysema index showed right-skewness. Accordingly, emphysema index was analyzed with log transformation. Cox-proportional hazard modeling was used to assess the relationship between groups in terms of the first event of acute exacerbation and mortality, with statistical adjustments for the following factors: age, sex, body mass index, pack-years smoked, smoking status, SGRQ score, exacerbation history at baseline, and use of long-acting β-agonists (ICS/LABA) or inhaled long-acting muscarinic antagonists (LAMA). In this way, we made more extensive adjustments for potential factors which may affect the clinical course of COPD compared to other major studies that assessed similar outcomes28,29. FEV1 was not included in the multivariate analyses because it was mutually correlated with both emphysema and RV/TLC. The proportional hazard assumptions of Cox regression models were assessed based on Schoenfeld residuals tests (Stata syntax “estat phtest”)30. All cox models did not show non-proportionality. Binomial negative regression analysis was used to assess the relationship between each group and annual exacerbation rates—defined in terms of incidence rate ratio (IRR)—with adjustments for the same covariates listed above. The 95% CIs were calculated, and p-values < 0.05 were considered statistically significant. All analyses were performed using IBM SPSS Statistics 20.0 (IBM Corp., Armonk, NY, US) and Stata, version 14.2 (StataCorp., College Station, TX, US).
Results
Patient characteristics
A total of 310 subjects with COPD were eligible for analyses (Fig. 1). The mean (standard deviation) follow-up period was 61.1 (37.0) months. Table 1 shows a comparison of baseline demographic data and clinical characteristics among the groups. Compared to other groups, patients who had both resting hyperinflation and emphysema (Group 4) had the lowest BMI, FEV1 (in both the percentage of predicted value and z-score), and FEV1/FVC ratio, as well as the highest SGRQ score and mMRC grade.
Patients with resting hyperinflation had worse symptom grades than those without (mean SGRQ score: 29.9 ± 16.6 in Groups 1 and 2 vs. 41.0 ± 17.7 in Groups 3 and 4, p < 0.001; mean mMRC grade: 1.4 ± 1.0 in Groups 1 and 2 vs. 2.0 ± 1.0 in Groups 3 and 4, p < 0.001). This difference in symptom grades remained statistically significant after adjustment for following factors: age, sex, body mass index, pack-years smoked, smoking status, exacerbation history at baseline. Conversely, the relationship between emphysema and symptoms was relatively weak regardless of adjustments. Similarly, patients with resting hyperinflation had more severe airflow limitation, as measured by FEV1, regardless of whether they had emphysema.
Respective associations of resting hyperinflation and emphysema with outcomes of COPD
Table 2 shows the respective associations of resting hyperinflation and emphysema with exacerbations over time; these were estimated by the hazard ratio (HR) for time to first exacerbation, and the incidence rate ratio (IRR) for exacerbation incidences. After adjustment for potential confounding factors, elevated RV/TLC as a continuous variable was significantly associated with (1) a higher risk of an earlier exacerbation event (HR = 1.02, 95% CI = 1.01–1.03) and (2) a higher incidence rate of exacerbation (IRR = 1.01, 95% CI = 1.002–1.03). As a categorical variable, patients with resting hyperinflation had a significantly higher risk of an earlier exacerbation event (HR = 1.66, 95% CI = 1.24–2.22) and a higher incidence rate of exacerbation (HR = 1.35, 95% CI = 1.01–1.81). The emphysema index showed trends that were similar to those of the RV/TLC. Elevated emphysema index (in log scale) as a continuous variable was significantly associated with a higher risk of an earlier exacerbation event (HR = 1.45, 95% CI = 1.01–2.09). Patients with emphysema had a significantly higher risk of an earlier exacerbation event (HR = 1.64, 95% CI = 1.15–2.35). The associations with mortality are shown in Table 3. Resting hyperinflation and emphysema were significantly associated with higher mortality risk, respectively.
Combined associations of resting hyperinflation and emphysema with outcomes of COPD
Figure 2a (time to first exacerbation) and 2b (exacerbation rates) show the comparison of exacerbation risk among the groups. Patients who had both resting hyperinflation and emphysema (Group 4) had a significantly higher risk of exacerbations than those with neither (Group 1; HR = 2.51, 95% CI = 1.58–3.98; IRR = 1.78, 95% CI = 1.15–2.75). In addition, patients with both resting hyperinflation and emphysema (Group 4) showed a significantly higher risk of exacerbations than all other groups (Groups 1–3; HR = 1.71, 95% CI = 1.26–2.33). The trend of increasing risk from group 1 (no feature) to group 2 or 3 (1 feature) to group 4 (2 features) was statistically significant for both time to first exacerbation (HR = 1.56, 95% CI = 1.26–1.94) and exacerbation rate (IRR = 1.29, 95% CI = 1.04–1.60). Figure 3 shows the comparison of mortality risk among the groups. Patients who had both resting hyperinflation and emphysema (Group 4) had a significantly higher risk of mortality than other groups (Groups 1–3; HR = 3.75, 95% CI = 1.81–7.73).
Discussion
The present study explored the independent and combined associations of resting hyperinflation and emphysema with the clinical characteristics and outcomes of COPD. The results revealed that clinical symptoms, as measured by SGRQ and mMRC scores, are more closely related to resting hyperinflation than to emphysema. Both resting hyperinflation and emphysema were independent predictors of exacerbation risk and mortality. In addition, patients with both resting hyperinflation and emphysema had a significantly higher risk of exacerbation and mortality than those with only one or neither of the conditions. To our knowledge, this was the first study to identify the combined association of resting hyperinflation and emphysema with the clinical outcomes of COPD. Our results add novel information to the field and indicate that careful inspection of both features in combination could provide additional information that is useful for predicting the disease course of COPD in clinical practice.
It is widely accepted that small airway disease and emphysema are the two main components of COPD pathology, and that various severities and combinations of these components constitute the spectrum of disease phenotypes. It follows that proper classification of the underlying COPD phenotypes would improve prognostic predictions and enable individualized treatment6. Specifically, resting hyperinflation is caused by increased compliance and loss of elastic recoil in the lung; these effects are in turn a result of injury to the small airways and parenchymal destruction. Thus, resting hyperinflation is not necessarily equivalent to emphysema7. To date, the degree of resting hyperinflation is most commonly measured using indices from body plethysmography, elevated RV/TLC is a typical indicator22. The results of the present study concur with those of previous studies that have suggested a close relationship between resting hyperinflation and the clinical symptoms of COPD9,31. In addition, our results provide data indicating that an elevated RV/TLC is an independent risk factor for exacerbations and mortality even with extensive adjustments for potential factors that may also influence the clinical course. This supports and extends the knowledge regarding resting hyperinflation as a prognostic factor in COPD13,14.
The present study also indicated that resting hyperinflation is more important than emphysema for understanding the status and course of COPD. In terms of the relationships between emphysema and exacerbations, our study was consistent with previous studies, which have suggested that the presence of emphysema is a risk factor for exacerbations19,32. However, it is notable that, according to our results, the relationship between emphysema and clinical symptoms and its value in predicting exacerbations were relatively weak compared with those of resting hyperinflation. Specifically, our results showed that patients with resting hyperinflation had more severe airflow limitation, regardless of whether they had emphysema. The association with resting hyperinflation independent of emphysema could be explained by the contribution of small airway disease. This supports the concept that small airway injury precedes emphysema with increasing severity of COPD33,34.
In addition to small airway injury and parenchymal destruction due to COPD, resting hyperinflation can also result from normal aging35. Physiological studies have shown that, with advancing age, progressive enlargement of the alveolar ducts, as well as changes in the collagen and elastin content of the airways, lead to loss of elastic recoil and hyperinflation. The same changes are present in patients with COPD36,37. Indeed, a recent study by Martinez et al. showed that, in normal subjects without COPD, aging resulted in increased hyperinflation associated with small airway dysfunction. Conversely, emphysema was not associated with aging in non-smokers15. Aging can be a significant confounding factor during the evaluation of COPD status based the on degree of hyperinflation alone. Therefore, we can assume that the combined inspection of hyperinflation with emphysema, which is a distinct pathological process of COPD, provides additional information regarding the prediction of disease status and prognosis. Similarly, a recent study by Galban et al. reported that simultaneous evaluation of emphysema and hyperinflation, as determined by inspiratory and expiratory CT imaging, respectively, could more objectively characterize and classify the clinical phenotypes of COPD34. However, expiratory CT images are not yet widely obtained from all patients in real clinical practice, and they increase the amount of radiation exposure38. Therefore, RV/TLC from body plethysmography may be a reliable alternative for measuring resting hyperinflation. Our results support the hypothesis that evaluation of resting hyperinflation and emphysema in combination confers additional information for predicting exacerbations and mortality in the clinical course of COPD. They also indicate that, in routine practice, both RV/TLC and the emphysema index should be closely monitored and interpreted in combination.
The main strength of our study is the use of a well-designed, prospective cohort that included subjects with COPD at various stages of severity. The cohort was purely observational; thus, the events recorded were likely to represent disease-related changes in patients who were properly managed. Moreover, because longitudinal and accurate data on exacerbation and mortality were collected over a long observational period, the prognostic value of the analyzed indices could be evaluated adequately. In addition, our analyses, we performed extensive adjustments for factors that may also influence the clinical course of COPD, suggesting that our results have high validity.
Our study had several limitations. First, although the prediction equations used to evaluate the upper limit of normality of RV/TLC and the cutoff value for emphysema index used in the present study are generally accepted10,17,25, the accumulated evidence on the exact cutoff value for these indices remains weak, especially when regarding possible variation between races. Second, although the protocol of our study included evaluation of CT indices at expiration, no factors from expiratory CT exams were significantly associated with COPD outcomes (data not shown). Third, in the KOLD cohort study, the reproducibility or variability of CT density obtained from different clinics was not measured. However, all CT scans were performed with a prescribed protocol, and images were sent to a central lab to be checked for consistency23. Fourth, we did not apply random effects from institutions in the statistical analyses. Although major observational studies generally present results analyzed regardless of random effects from centers39,40, possible imprecisions may exist. Fifth, because the study was mainly focused on the association between baseline clinical values and subsequent outcomes, the longitudinal aspects of variables were not significantly considered. Moreover, possible residual confounding such as influence of age on mortality could also be a limitation of our study.
In conclusion, combined evaluation of resting hyperinflation and emphysema using body plethysmography and CT confers additional information and better prediction of the clinical course of COPD. It may also contribute to a more adequate phenotypical classification of COPD.
References
Vogelmeier, C. F. et al. Global Strategy for the Diagnosis, Management, and Prevention of Chronic Obstructive Lung Disease 2017 Report. GOLD Executive Summary. Am J Respir Crit Care Med. 195, 557–582 (2017).
Lozano, R. et al. Global and regional mortality from 235 causes of death for 20 age groups in 1990 and 2010: a systematic analysis for the Global Burden of Disease Study 2010. Lancet. 380, 2095–2128 (2012).
Lopez, A. D. et al. Chronic obstructive pulmonary disease: current burden and future projections. Eur Respir J. 27, 397–412 (2006).
Hogg, J. C. Pathophysiology of airflow limitation in chronic obstructive pulmonary disease. Lancet. 364, 709–721 (2004).
Makita, H. et al. Characterisation of phenotypes based on severity of emphysema in chronic obstructive pulmonary disease. Thorax. 62, 932–937 (2007).
Han, M. K. et al. Chronic obstructive pulmonary disease phenotypes: the future of COPD. Am J Respir Crit Care Med. 182, 598–604 (2010).
Gagnon, P. et al. Pathogenesis of hyperinflation in chronic obstructive pulmonary disease. Int J Chron Obstruct Pulmon Dis. 9, 187–201 (2014).
O’Donnell, D. E., Lam, M. & Webb, K. A. Spirometric correlates of improvement in exercise performance after anticholinergic therapy in chronic obstructive pulmonary disease. Am J Respir Crit Care Med. 160, 542–549 (1999).
O’Donnell, D. E., Guenette, J. A., Maltais, F. & Webb, K. A. Decline of resting inspiratory capacity in COPD: the impact on breathing pattern, dyspnea, and ventilatory capacity during exercise. Chest. 141, 753–762 (2012).
Stocks, J. & Quanjer, P. H. Reference values for residual volume, functional residual capacity and total lung capacity. ATS Workshop on Lung Volume Measurements. Official Statement of The European Respiratory Society. Eur Respir J. 8, 492–506 (1995).
Pellegrino, R. et al. Interpretative strategies for lung function tests. Eur Respir J. 26, 948–968 (2005).
Nishimura, K., Izumi, T., Tsukino, M. & Oga, T. Dyspnea is a better predictor of 5-year survival than airway obstruction in patients with COPD. Chest. 121, 1434–1440 (2002).
Budweiser, S., Harlacher, M., Pfeifer, M. & Jorres, R. A. Co-morbidities and hyperinflation are independent risk factors of all-cause mortality in very severe COPD. COPD. 11, 388–400 (2014).
Shin, T. R. et al. The Prognostic Value of Residual Volume/Total Lung Capacity in Patients with Chronic Obstructive Pulmonary Disease. J Korean Med Sci. 30, 1459–1465 (2015).
Martinez, C. H. et al. Age and Small Airway Imaging Abnormalities in Subjects With and Without Airflow Obstruction in SPIROMICS. Am J Respir Crit Care Med. 195, 464–472 (2017).
Snider, G., Kleinerman, J., Thurlbeck, W. & Bengally, Z. The definition of emphysema. Report of a National Heart, Lung, and Blood Institute, Division of Lung Diseases workshop. Am Rev Respir Dis. 132, 182–185 (1985).
Vestbo, J. et al. Changes in forced expiratory volume in 1 second over time in COPD. N Engl J Med. 365, 1184–1192 (2011).
Johannessen, A. et al. Mortality by level of emphysema and airway wall thickness. Am J Respir Crit Care Med. 187, 602–608 (2013).
Han, M. K. et al. Chronic obstructive pulmonary disease exacerbations in the COPDGene study: associated radiologic phenotypes. Radiology. 261, 274–282 (2011).
Gelb, A. F. et al. Limited contribution of emphysema in advanced chronic obstructive pulmonary disease. Am Rev Respir Dis. 147, 1157–1161 (1993).
Kirby, M. et al. COPD: Do Imaging Measurements of Emphysema and Airway Disease Explain Symptoms and Exercise Capacity? Radiology. 277, 872–880 (2015).
Dubé, B. P., Guerder, A., Morélot-Panzini, C. & Laveneziana, P. The clinical relevance of the emphysema-hyperinflated phenotype in COPD. COPD Research and Practice. 2, 1, https://doi.org/10.1186/s40749-015-0017-7 (2016).
Park, T. S. et al. Study Design and Outcomes of Korean Obstructive Lung Disease (KOLD) Cohort Study. Tuberc Respir Dis (Seoul). 76, 169–174 (2014).
Quanjer, P. H. et al. Multi-ethnic reference values for spirometry for the 3–95-yr age range: the global lung function 2012 equations. Eur Respir J. 40, 1324–1343 (2012).
Miller, M. R. et al. Standardisation of spirometry. Eur Respir J. 26, 319–338 (2005).
Wanger, J. et al. Standardisation of the measurement of lung volumes. Eur Respir J. 26, 511–522 (2005).
Gevenois, P. A., de Maertelaer, V., De Vuyst, P., Zanen, J. & Yernault, J. C. Comparison of computed density and macroscopic morphometry in pulmonary emphysema. Am J Respir Crit Care Med. 152, 653–657 (1995).
Sin, D. D. et al. Serum PARC/CCL-18 concentrations and health outcomes in chronic obstructive pulmonary disease. Am J Respir Crit Care Med. 183, 1187–1192 (2011).
Park, H. Y. et al. Club cell protein 16 and disease progression in chronic obstructive pulmonary disease. Am J Respir Crit Care Med. 188, 1413–1419 (2013).
Grambsch, P. M. & Therneau, T. M. Proportional hazards tests and diagnostics based on weighted residuals. Biometrika. 81, 516–526 (1994).
O’Donnell, D. E. & Laveneziana, P. Dyspnea and activity limitation in COPD: mechanical factors. COPD. 4, 225–236 (2007).
Oh, Y. M. et al. Emphysematous phenotype is an independent predictor for frequent exacerbation of COPD. Int J Tuberc Lung Dis. 18, 1407–1414 (2014).
McDonough, J. E. et al. Small-airway obstruction and emphysema in chronic obstructive pulmonary disease. N Engl J Med. 365, 1567–1575 (2011).
Galban, C. J. et al. Computed tomography-based biomarker provides unique signature for diagnosis of COPD phenotypes and disease progression. Nat Med. 18, 1711–1715 (2012).
Lee, K. W. et al. Correlation of aging and smoking with air trapping at thin-section CT of the lung in asymptomatic subjects. Radiology. 214, 831–836 (2000).
Niewoehner, D. E., Kleinerman, J. & Liotta, L. Elastic behavior of postmortem human lungs: effects of aging and mild emphysema. J Appl Physiol. 39, 943–949 (1975).
Lang, M. R. et al. Collagen content of alveolar wall tissue in emphysematous and non-emphysematous lungs. Thorax. 49, 319–326 (1994).
Bankier, A. A. et al. Air trapping: comparison of standard-dose and simulated low-dose thin-section CT techniques. Radiology. 242, 898–906 (2007).
Nishimura, M. et al. Clinical features and determinants of COPD exacerbation in the Hokkaido COPD cohort study. Eur Respir J. 43, 1289–1297 (2014).
Couper, D. et al. Design of the Subpopulations and Intermediate Outcomes in COPD Study (SPIROMICS). Thorax. 69, 491–494 (2014).
Acknowledgements
The authors thank the members of the KOLD Study Group for providing KOLD cohort data which was built with the support of a grant from the Korea Healthcare Technology R&D Project, Ministry for Health and Welfare, Republic of Korea (A102065 & HI10C2020).
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Y.W.K. and C.H.L. contributed to the study design, data analysis, data interpretation, manuscript preparation, revision, and final approval of the manuscript. H.G.H., Y.I.K., D.K.K., Y.M.O., S.H.L., K.U.K. and S.D.L. contributed to the data collection, data analysis, revision, and final approval of the manuscript. All authors reviewed the manuscript.
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Kim, Y.W., Lee, CH., Hwang, HG. et al. Resting hyperinflation and emphysema on the clinical course of COPD. Sci Rep 9, 3764 (2019). https://doi.org/10.1038/s41598-019-40411-1
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DOI: https://doi.org/10.1038/s41598-019-40411-1
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