3D ultrasound segmentation is a challenging task due to image artefacts, low signal-to-noise ratio and lack of contrast at anatomical boundaries. Current solutions usually rely on complex, anatomy-specific regularization methods to improve segmentation accuracy. In this work, we propose a highly adaptive learning-based method for fully automatic segmentation of ultrasound volumes. During training, anatomy-specific features are obtained through a sparse auto-encoder. The extracted features are employed in a Hough Forest based framework to retrieve the position of the target anatomy and its segmentation contour. The resulting method is fully automatic, i.e. it does not require any human interaction, and can robustly and automatically adapt to different anatomies yet enforcing appearance and shape constraints.We demonstrate the performance of the method for three different applications: segmentation of midbrain, left ventricle of the heart and prostate.
Milletari, F., Ahmadi, S., Kroll, C., Hennersperger, C., Tombari, F., Shah, A., et al. (2015). Robust segmentation of various anatomies in 3D ultrasound using hough forests and learned data representations. Cham : Springer Verlag [10.1007/978-3-319-24571-3_14].
Robust segmentation of various anatomies in 3D ultrasound using hough forests and learned data representations
TOMBARI, FEDERICO;
2015
Abstract
3D ultrasound segmentation is a challenging task due to image artefacts, low signal-to-noise ratio and lack of contrast at anatomical boundaries. Current solutions usually rely on complex, anatomy-specific regularization methods to improve segmentation accuracy. In this work, we propose a highly adaptive learning-based method for fully automatic segmentation of ultrasound volumes. During training, anatomy-specific features are obtained through a sparse auto-encoder. The extracted features are employed in a Hough Forest based framework to retrieve the position of the target anatomy and its segmentation contour. The resulting method is fully automatic, i.e. it does not require any human interaction, and can robustly and automatically adapt to different anatomies yet enforcing appearance and shape constraints.We demonstrate the performance of the method for three different applications: segmentation of midbrain, left ventricle of the heart and prostate.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.