Accurate and rapid detection of B-lines— vertical hyperechoic artifacts in lung ultrasound (LUS) images—is essential for diagnosing and monitoring pulmonary diseases. We propose a novel algorithm based on Variational Mode Decomposition (VMD) for automatic segmentation and quantification of B-lines in LUS frames, marking the first application of VMD in this context. Each frame is treated as a two-dimensional signal and decomposed into intrinsic frequency modes, isolating characteristic vertical structures while suppressing noise and irrelevant anatomy. A block- wise projection strategy enhances structural consistency and robustness under low-contrast conditions. Evaluated on 116 annotated images from 42 patients using a portable convex probe, the method achieved a precision of 0.87, recall of 0.79, F1-score of 0.83, and Dice coefficient of 0.79. Although slightly below top deep learning models, its low computational complexity makes it suitable for real-time, point-of-care ultrasound systems. Future work may combine VMD with neural networks or beamforming to further improve performance.
Variational Mode Decomposition for B-Lines Segmentation in Lung Ultrasound Images: An Improved Approach / Bottino, A.; Botrugno, C.; Conversano, F.; Dell'Olio, F.; Koyazo, J. T.; Pisani, P.; Morello, R.; Lay-Ekuakille, A.; Casciaro, S.. - In: IEEE SENSORS LETTERS. - ISSN 2475-1472. - (2025). [10.1109/LSENS.2025.3617655]
Variational Mode Decomposition for B-Lines Segmentation in Lung Ultrasound Images: An Improved Approach
Botrugno C.;Dell'Olio F.;
2025
Abstract
Accurate and rapid detection of B-lines— vertical hyperechoic artifacts in lung ultrasound (LUS) images—is essential for diagnosing and monitoring pulmonary diseases. We propose a novel algorithm based on Variational Mode Decomposition (VMD) for automatic segmentation and quantification of B-lines in LUS frames, marking the first application of VMD in this context. Each frame is treated as a two-dimensional signal and decomposed into intrinsic frequency modes, isolating characteristic vertical structures while suppressing noise and irrelevant anatomy. A block- wise projection strategy enhances structural consistency and robustness under low-contrast conditions. Evaluated on 116 annotated images from 42 patients using a portable convex probe, the method achieved a precision of 0.87, recall of 0.79, F1-score of 0.83, and Dice coefficient of 0.79. Although slightly below top deep learning models, its low computational complexity makes it suitable for real-time, point-of-care ultrasound systems. Future work may combine VMD with neural networks or beamforming to further improve performance.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
