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Function decline with longitudinal spirometric data will be required to confirm this hypothesis. Assessment of comorbidities was based on physiciandiagnosed comorbidities and not on a systematic diagnostic workup. Because high rates of underdiagnosed cardiovascular comorbidities have been previously reported in COPD patients [20], we cannot exclude that such comorbidities contributed to death in some patients without any diagnosed concomitant disease. Finally, our MedChemExpress CP21 methodology lead to the exclusion of 122 COPD patients who had missing data for mMRC and CCQ scores (see Methods). A careful investigation of this group of patients revealed that 107/ 122 patients were included at the very beginning of the LEUVEN outpatient cohort and belonged to a group of patients with severe airflow limitation (median [IQR] FEV1 24 [19?1]) at a median [IQR] age of 57 [54?2] yrs. who had few comorbidities and were evaluated for lung transplantation (Table S8). Although we were unable to include the patients in our analysis, these findings further reinforce our conclusions, as the excluded patients could correspond to subjects in Phenotype 2. Although some therapies (e.g., smoking cessation, pulmonary rehabilitation, bronchodilators) may be beneficial in all COPD subjects, differential characteristics of subjects in Phenotype 2 and Phenotype 3 suggest that different strategies may be developed for improving outcome, eventually resulting in better survival. Subjects in Phenotype 2 may preferentially benefit from lung transplantation as they are younger and have little co-morbidities. Early detection of subjects in Phenotype 2 would allow for early intervention, with the goal of developing disease-modifying therapy. Thus, future treatment targeting airway and parenchymal disease progression (e.g., growth factor receptor antagonists, protease inhibitors) may be of particular interest in these subjects with severe and early onset respiratory disease. We also speculate that interventions (e.g., aspirin, statins, beta-blockers) shown to reduce mortality in subjects with cardiovascular DprE1-IN-2 diseases may show optimal survival benefit in older subjects with cardiovascular comorbidities (Phenotype 3). In summary, this study identified two very different phenotypes of subjects at high risk of mortality: younger subjects with severe respiratory disease and emphysema, and older subjects with less severe respiratory disease and marked cardiovascular and metabolic comorbidities. Pathophysiological studies should take these phenotypes into account to determine whether they relate tospecific mechanisms and/or are differentially associated with specific genotypic signature or biomarkers. Further, potential therapeutic implication of these phenotypes can now be examined in prospective trials. Future studies should also focus on establishing simple algorithms based on the most discriminant factors for assigning patients to specific phenotypes. Such algorithms will have to be tested in validation cohorts 1379592 before they can be utilized in clinical practice.Supporting InformationText S1 Additional information on statistical analyses.(DOC)Table S1 Cluster analysis showing the relationships between continuous variables in 519 COPD subjects. (DOC) Table S2 Main characteristics of the 527 COPD subjectsincluded in the cluster analysis, according to their cohort of recruitment (Leuven outpatient clinic and NELSON study). (DOC)Table SCorrelation matrix between variables used in the cluster analys.Function decline with longitudinal spirometric data will be required to confirm this hypothesis. Assessment of comorbidities was based on physiciandiagnosed comorbidities and not on a systematic diagnostic workup. Because high rates of underdiagnosed cardiovascular comorbidities have been previously reported in COPD patients [20], we cannot exclude that such comorbidities contributed to death in some patients without any diagnosed concomitant disease. Finally, our methodology lead to the exclusion of 122 COPD patients who had missing data for mMRC and CCQ scores (see Methods). A careful investigation of this group of patients revealed that 107/ 122 patients were included at the very beginning of the LEUVEN outpatient cohort and belonged to a group of patients with severe airflow limitation (median [IQR] FEV1 24 [19?1]) at a median [IQR] age of 57 [54?2] yrs. who had few comorbidities and were evaluated for lung transplantation (Table S8). Although we were unable to include the patients in our analysis, these findings further reinforce our conclusions, as the excluded patients could correspond to subjects in Phenotype 2. Although some therapies (e.g., smoking cessation, pulmonary rehabilitation, bronchodilators) may be beneficial in all COPD subjects, differential characteristics of subjects in Phenotype 2 and Phenotype 3 suggest that different strategies may be developed for improving outcome, eventually resulting in better survival. Subjects in Phenotype 2 may preferentially benefit from lung transplantation as they are younger and have little co-morbidities. Early detection of subjects in Phenotype 2 would allow for early intervention, with the goal of developing disease-modifying therapy. Thus, future treatment targeting airway and parenchymal disease progression (e.g., growth factor receptor antagonists, protease inhibitors) may be of particular interest in these subjects with severe and early onset respiratory disease. We also speculate that interventions (e.g., aspirin, statins, beta-blockers) shown to reduce mortality in subjects with cardiovascular diseases may show optimal survival benefit in older subjects with cardiovascular comorbidities (Phenotype 3). In summary, this study identified two very different phenotypes of subjects at high risk of mortality: younger subjects with severe respiratory disease and emphysema, and older subjects with less severe respiratory disease and marked cardiovascular and metabolic comorbidities. Pathophysiological studies should take these phenotypes into account to determine whether they relate tospecific mechanisms and/or are differentially associated with specific genotypic signature or biomarkers. Further, potential therapeutic implication of these phenotypes can now be examined in prospective trials. Future studies should also focus on establishing simple algorithms based on the most discriminant factors for assigning patients to specific phenotypes. Such algorithms will have to be tested in validation cohorts 1379592 before they can be utilized in clinical practice.Supporting InformationText S1 Additional information on statistical analyses.(DOC)Table S1 Cluster analysis showing the relationships between continuous variables in 519 COPD subjects. (DOC) Table S2 Main characteristics of the 527 COPD subjectsincluded in the cluster analysis, according to their cohort of recruitment (Leuven outpatient clinic and NELSON study). (DOC)Table SCorrelation matrix between variables used in the cluster analys.

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Author: Ubiquitin Ligase- ubiquitin-ligase