Manuscripts and Publications
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2016. Understanding the impact of second-hand smoke exposure on clinical outcomes in participants with COPD in the SPIROMICS cohort.. Thorax. 71:411-420.
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2018. Lower serum IgA is associated with COPD exacerbation risk in SPIROMICS.. PLoS One. 13(4):e0194924.
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2021. Airway mucin MUC5AC and MUC5B concentrations and the initiation and progression of chronic obstructive pulmonary disease: an analysis of the SPIROMICS cohort.. Lancet Respir Med. 9(11):1241-1254.
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2020. Comparison of Proteomic Assessment Methods in Multiple Cohort Studies.. Proteomics. 20(12):e1900278.
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2022. Forced Expiratory Flow at 25%-75% Links COPD Physiology to Emphysema and Disease Severity in the SPIROMICS Cohort.. Chronic Obstr Pulm Dis. 9(2):111-121.
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2023. Association of Occupational Exposures and Chronic Obstructive Pulmonary Disease Morbidity.. J Occup Environ Med. 65(7):e443-e452.
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2019. Genetic landscape of chronic obstructive pulmonary disease identifies heterogeneous cell-type and phenotype associations.. Nat Genet. 51(3):494-505.
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2019. New genetic signals for lung function highlight pathways and chronic obstructive pulmonary disease associations across multiple ancestries. Nat Genet. 51(3):481-493.
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2016. SPIROMICS Protocol for Multicenter Quantitative Computed Tomography to Phenotype the Lungs.. Am J Respir Crit Care Med. 194(7):794-806.
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2018. Human airway branch variation and chronic obstructive pulmonary disease.. Proc Natl Acad Sci U S A. 115(5):E974-E981.
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2014. Comparison of spatially matched airways reveals thinner airway walls in COPD. The Multi-Ethnic Study of Atherosclerosis (MESA) COPD Study and the Subpopulations and Intermediate Outcomes in COPD Study (SPIROMICS).. Thorax. 69(11):987-96.
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2020. Association of Dysanapsis With Chronic Obstructive Pulmonary Disease Among Older Adults.. JAMA. 323(22):2268-2280.
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2023. Ambient Air Pollution Exposure and Sleep Quality in COPD.. Chronic Obstr Pulm Dis. 10(1):102-111.
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2020. Defining Chronic Mucus Hypersecretion Using the CAT in the SPIROMICS Cohort.. Int J Chron Obstruct Pulmon Dis. 15:2467-2476.
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2020. A Risk Prediction Model for Mortality Among Smokers in the COPDGene® Study.. Chronic Obstr Pulm Dis. 7(4):346-361.
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2016. Common Genetic Polymorphisms Influence Blood Biomarker Measurements in COPD.. PLoS Genet. 12(8):e1006011.
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2022. Black carbon content in airway macrophages is associated with increased severe exacerbations and worse COPD morbidity in SPIROMICS.. Respir Res. 23(1):310.
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2021. The influence of social support on COPD outcomes mediated by depression.. PLoS One. 16(3):e0245478.
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2023. Genetic regulators of sputum mucin concentration and their associations with COPD phenotypes.. PLoS Genet. 19(6):e1010445.
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2023. Machine learning for screening of at-risk, mild and moderate COPD patients at risk of FEV decline: results from COPDGene and SPIROMICS.. Front Physiol. 14:1144192.
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2022. PLOSL: Population learning followed by one shot learning pulmonary image registration using tissue volume preserving and vesselness constraints.. Med Image Anal. 79:102434.
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2023. Association Among Chronic Obstructive Pulmonary Disease Severity, Exacerbation Risk, and Anxiety and Depression Symptoms in the SPIROMICS Cohort.. J Acad Consult Liaison Psychiatry. 64(1):45-57.
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2019. The matrikine acetyl-proline-glycine-proline and clinical features of COPD: findings from SPIROMICS.. Respir Res. 20(1):254.
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2018. Elevated circulating MMP-9 is linked to increased COPD exacerbation risk in SPIROMICS and COPDGene.. JCI Insight. 3(22)
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2019. Safety and Tolerability of Comprehensive Research Bronchoscopy in Chronic Obstructive Pulmonary Disease. Results from the SPIROMICS Bronchoscopy Substudy.. Ann Am Thorac Soc. 16(4):439-446.