INTRODUCTION- The usual interstitial pneumonia (UIP) pattern, hallmark of idiopathic pulmonary fibrosis (IPF), may induce harmful local overdistension during mechanical ventilation given the juxtaposition of different tissue elasticities. Mechanotransduction, linking mechanical stress and strain to molecular pro-fibrotic pathways, likely contributes to fibrosis progression. Understanding the mechanical forces and aeration patterns in the lungs of IPF patients is crucial for unraveling potential mechanisms of disease progression. Quantitative lung computed tomography (CT) can accurately assess the air content of lung regions, thus informing on zonal distension. This study aims to investigate radiological evidence of lung over aeration in spontaneously breathing UIP patients compared to healthy controls during maximal inspiration. METHODS- Patients with IPF diagnosis referred to the Center for Rare Lung Diseases of the University Hospital of Modena (Italy) in the period 2020-2023 who underwent High Resolution Computed Tomography (HRCT) scans at residual volume (RV) and total lung capacity (TLC) using standardized protocols were retrospectively considered eligible. Patients with no signs of lung disease at HRCT performed with the same image acquisition protocol nor at pulmonary function test (PFTs) served as controls. Lung segmentation and quantitative analysis were performed using 3D Slicer software. Lung volumes were measured, and specific density thresholds defined over aerated and fibrotic regions. Comparison between over aerated lung at RV and TLC in the two groups and according to lung lobes was sought. Further, the correlation between aerated lung and the extent of fibrosis was assessed and compared at RV and TLC. RESULTS- IPF patients (N=20) exhibited higher over aerated lung proportions than controls (N=15) both at RV and TLC (4.5% vs. 0.7%, p<0.0001 and 13.8% vs. 7%, p<0.0001 respectively). Over aeration increased significantly from RV to TLC in both groups, with no intergroup difference (p=0.67). Sensitivity analysis revealed significant variations in over aerated lung areas among lobes when passing from RV to TLC with no difference within lobes (p=0.28). Correlation between over aeration and fibrosis extent was moderate at RV (r=0.62, p<0.0001) and weak at TLC (r=0.27, p=0.01), being the two significantly different at interpolation analysis (p<0.0001). CONCLUSIONS-This study provides the first evidence of radiological signs of lung over aeration in patients with UIP-pattern patients when passing from RV to TLC. These findings offer new insights into the complex interplay between mechanical forces, lung structure, and fibrosis and warrant larger and longitudinal investigations.
Quantitative CT-analysis of over aerated lung tissue and correlation with fibrosis extent in patients with idiopathic pulmonary fibrosis / Tonelli, Roberto; Smit, Marry; Castaniere, Ivana; Della Casa, Giovanni; Andrisani, Dario; Gozzi, Filippo; Bruzzi, Giulia; Cerri, Stefania; Samarelli, ANNA VALERIA; Raineri, Giulia; Spagnolo, Paolo; Rizzoni, Raffella; Ball, Lorenzo; Paulus, Frederique; Bos, Lieuwe; Clini, Enrico; Marchioni, Alessandro. - In: RESPIRATORY RESEARCH. - ISSN 1465-993X. - 25:(2024), pp. 1-9. [10.1186/s12931-024-02970-4]
Quantitative CT-analysis of over aerated lung tissue and correlation with fibrosis extent in patients with idiopathic pulmonary fibrosis.
Roberto Tonelli;Filippo Gozzi;Giulia Bruzzi;Stefania Cerri;Anna Valeria Samarelli;Giulia Raineri;Enrico Clini;Alessandro Marchioni
2024
Abstract
INTRODUCTION- The usual interstitial pneumonia (UIP) pattern, hallmark of idiopathic pulmonary fibrosis (IPF), may induce harmful local overdistension during mechanical ventilation given the juxtaposition of different tissue elasticities. Mechanotransduction, linking mechanical stress and strain to molecular pro-fibrotic pathways, likely contributes to fibrosis progression. Understanding the mechanical forces and aeration patterns in the lungs of IPF patients is crucial for unraveling potential mechanisms of disease progression. Quantitative lung computed tomography (CT) can accurately assess the air content of lung regions, thus informing on zonal distension. This study aims to investigate radiological evidence of lung over aeration in spontaneously breathing UIP patients compared to healthy controls during maximal inspiration. METHODS- Patients with IPF diagnosis referred to the Center for Rare Lung Diseases of the University Hospital of Modena (Italy) in the period 2020-2023 who underwent High Resolution Computed Tomography (HRCT) scans at residual volume (RV) and total lung capacity (TLC) using standardized protocols were retrospectively considered eligible. Patients with no signs of lung disease at HRCT performed with the same image acquisition protocol nor at pulmonary function test (PFTs) served as controls. Lung segmentation and quantitative analysis were performed using 3D Slicer software. Lung volumes were measured, and specific density thresholds defined over aerated and fibrotic regions. Comparison between over aerated lung at RV and TLC in the two groups and according to lung lobes was sought. Further, the correlation between aerated lung and the extent of fibrosis was assessed and compared at RV and TLC. RESULTS- IPF patients (N=20) exhibited higher over aerated lung proportions than controls (N=15) both at RV and TLC (4.5% vs. 0.7%, p<0.0001 and 13.8% vs. 7%, p<0.0001 respectively). Over aeration increased significantly from RV to TLC in both groups, with no intergroup difference (p=0.67). Sensitivity analysis revealed significant variations in over aerated lung areas among lobes when passing from RV to TLC with no difference within lobes (p=0.28). Correlation between over aeration and fibrosis extent was moderate at RV (r=0.62, p<0.0001) and weak at TLC (r=0.27, p=0.01), being the two significantly different at interpolation analysis (p<0.0001). CONCLUSIONS-This study provides the first evidence of radiological signs of lung over aeration in patients with UIP-pattern patients when passing from RV to TLC. These findings offer new insights into the complex interplay between mechanical forces, lung structure, and fibrosis and warrant larger and longitudinal investigations.File | Dimensione | Formato | |
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