TY - GEN
T1 - Can Ultrasound Confidence Maps Predict Sonographers’ Labeling Variability?
AU - Duque, Vanessa Gonzalez
AU - Zirus, Leonhard
AU - Velikova, Yordanka
AU - Navab, Nassir
AU - Mateus, Diana
N1 - Publisher Copyright:
© 2023, The Author(s), under exclusive license to Springer Nature Switzerland AG.
PY - 2023
Y1 - 2023
N2 - Measuring cross-sectional areas in ultrasound images is a standard tool to evaluate disease progress or treatment response. Often addressed today with supervised deep-learning segmentation approaches, existing solutions highly depend upon the quality of experts’ annotations. However, the annotation quality in ultrasound is anisotropic and position-variant due to the inherent physical imaging principles, including attenuation, shadows, and missing boundaries, commonly exacerbated with depth. This work proposes a novel approach that guides ultrasound segmentation networks to account for sonographers’ uncertainties and generate predictions with variability similar to the experts. We claim that realistic variability can reduce overconfident predictions and improve physicians’ acceptance of deep-learning cross-sectional segmentation solutions. Toward that end, we rely on a simple and efficient method to estimate Confidence Maps (CM)s from ultrasound images. The method provides certainty for each pixel for minimal computational overhead as it can be precalculated directly from the image. We show that there is a correlation between low values in the confidence maps and expert’s label uncertainty. Therefore, we propose to give the confidence maps as additional information to the networks. We study the effect of the proposed use of ultrasound CMs in combination with four state-of-the-art neural networks and in two configurations: as a second input channel and as part of the loss. We evaluate our method on 3D ultrasound datasets of the thyroid and lower limb muscles. Our results show ultrasound CMs increase the Dice score, improve the Hausdorff and Average Surface Distances, and decrease the number of isolated pixel predictions. Furthermore, our findings suggest that ultrasound CMs improve the penalization of uncertain areas in the ground truth data, thereby improving problematic interpolations. Our code and example data will be made public at https://github.com/IFL-CAMP/Confidence-segmentation.
AB - Measuring cross-sectional areas in ultrasound images is a standard tool to evaluate disease progress or treatment response. Often addressed today with supervised deep-learning segmentation approaches, existing solutions highly depend upon the quality of experts’ annotations. However, the annotation quality in ultrasound is anisotropic and position-variant due to the inherent physical imaging principles, including attenuation, shadows, and missing boundaries, commonly exacerbated with depth. This work proposes a novel approach that guides ultrasound segmentation networks to account for sonographers’ uncertainties and generate predictions with variability similar to the experts. We claim that realistic variability can reduce overconfident predictions and improve physicians’ acceptance of deep-learning cross-sectional segmentation solutions. Toward that end, we rely on a simple and efficient method to estimate Confidence Maps (CM)s from ultrasound images. The method provides certainty for each pixel for minimal computational overhead as it can be precalculated directly from the image. We show that there is a correlation between low values in the confidence maps and expert’s label uncertainty. Therefore, we propose to give the confidence maps as additional information to the networks. We study the effect of the proposed use of ultrasound CMs in combination with four state-of-the-art neural networks and in two configurations: as a second input channel and as part of the loss. We evaluate our method on 3D ultrasound datasets of the thyroid and lower limb muscles. Our results show ultrasound CMs increase the Dice score, improve the Hausdorff and Average Surface Distances, and decrease the number of isolated pixel predictions. Furthermore, our findings suggest that ultrasound CMs improve the penalization of uncertain areas in the ground truth data, thereby improving problematic interpolations. Our code and example data will be made public at https://github.com/IFL-CAMP/Confidence-segmentation.
KW - 3D segmentation
KW - 3D ultrasound
KW - Confidence maps
KW - fully convolutional neural networks
UR - http://www.scopus.com/inward/record.url?scp=85174748067&partnerID=8YFLogxK
U2 - 10.1007/978-3-031-44521-7_17
DO - 10.1007/978-3-031-44521-7_17
M3 - Conference contribution
AN - SCOPUS:85174748067
SN - 9783031445200
T3 - Lecture Notes in Computer Science (including subseries Lecture Notes in Artificial Intelligence and Lecture Notes in Bioinformatics)
SP - 175
EP - 184
BT - Simplifying Medical Ultrasound - 4th International Workshop, ASMUS 2023, Held in Conjunction with MICCAI 2023, Proceedings
A2 - Kainz, Bernhard
A2 - Müller, Johanna Paula
A2 - Kainz, Bernhard
A2 - Noble, Alison
A2 - Schnabel, Julia
A2 - Khanal, Bishesh
A2 - Day, Thomas
PB - Springer Science and Business Media Deutschland GmbH
T2 - 4th International Workshop of Advances in Simplifying Medical Ultrasound, ASMUS 2023
Y2 - 8 October 2023 through 8 October 2023
ER -