What does this research mean for the field?

Quantitative computed tomography identifies four distinct structural phenotypes in asthma patients that correlate with specific underlying molecular pathways, such as apoptosis in luminal dilation phenotypes and complement activation in airway wall thickening phenotypes. Novelty: ClaimNovelty.INCREMENTAL. Consensus alignment: ConsensusAlignment.NEUTRAL.

What question did this study set out to answer?

This research aims to identify distinct asthma phenotypes through clustering quantitative CT measurements and to explore the associated molecular pathways via sputum proteomics.

May 20, 2026

B22-07 Quantitative Computed Tomographic Clusters In C-biopred Asthma Cohort: Association With Sputum Proteomics

Key Points

This research aims to identify distinct asthma phenotypes through clustering quantitative CT measurements and to explore the associated molecular pathways via sputum proteomics.
Applied consensus clustering to qCT data from 239 asthma patients and 68 healthy controls in the Chinese C-BIOPRED cohort.
Clustered based on airway dimensions, lung volumes, and densitometry measurements.
Analyzed sputum proteomics to determine upregulated molecular pathways in identified clusters.
Four distinct qCT clusters were identified: Cluster 1 showed severe air trapping and luminal dilation; Cluster 2 exhibited thickened airway walls; Cluster 3 had preserved lung volumes; Cluster 4 presented with severe airflow obstruction.
Sputum eosinophilia was significantly elevated in Clusters 1 and 4.
Proteomic analysis revealed enhanced apoptosis and cornified envelope pathways in Cluster 1, while Clusters 2 and 4 showed increased complement activation and IGF transport regulation.

Abstract

Abstract Severe asthma exhibits heterogeneity in airflow obstruction, driven by airway remodeling and air trapping, which can be noninvasively assessed via quantitative computed tomography (qCT). This study aimed to identify asthma phenotypes by clustering qCT measurements of airway dimensions, lung volumes, and densitometry, and to elucidate the underlying molecular pathways through sputum proteomics. We applied consensus clustering to qCT data from 239 asthma patients (severe and mild/moderate) and 68 healthy controls from the Chinese C-BIOPRED cohort. Four distinct qCT clusters emerged: Cluster 1, characterized by luminal dilation, severe air trapping, and reduced lung density; Cluster 2, with thickened airway walls and luminal narrowing without air trapping; Cluster 3, showing mild luminal dilation, preserved lung volumes, and optimal spirometry; and Cluster 4, featuring airway wall thickening, luminal narrowing, severe air trapping, and profound airflow obstruction. Sputum eosinophilia was elevated in Clusters 1 and 4. Proteomics revealed upregulated pathways in apoptosis execution and cornified envelope formation in Cluster 1, while Cluster 2 and 4 exhibited enhanced complement activation, fibrin formation, plasma lipoprotein assembly, and insulin-like growth factor (IGF) transport regulation. These findings delineate qCT-derived phenotypes and their associated underlying mechanisms of airway remodeling and airflow obstruction in severe asthma. This abstract is funded by: None

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B22-07 Quantitative Computed Tomographic Clusters In C-biopred Asthma Cohort: Association With Sputum Proteomics

Key Points

Abstract

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