Anomaly detection-inspired few-shot medical image segmentation through self-supervision with supervoxels
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https://hdl.handle.net/10037/26143Date
2022-02-11Type
Journal articleTidsskriftartikkel
Peer reviewed
Abstract
Recent work has shown that label-efficient few-shot learning through self-supervision can achieve
promising medical image segmentation results. However, few-shot segmentation models typically rely on
prototype representations of the semantic classes, resulting in a loss of local information that can degrade
performance. This is particularly problematic for the typically large and highly heterogeneous background
class in medical image segmentation problems. Previous works have attempted to address this issue by
learning additional prototypes for each class, but since the prototypes are based on a limited number of
slices, we argue that this ad-hoc solution is insufficient to capture the background properties. Motivated
by this, and the observation that the foreground class (e.g., one organ) is relatively homogeneous, we
propose a novel anomaly detection-inspired approach to few-shot medical image segmentation in which
we refrain from modeling the background explicitly. Instead, we rely solely on a single foreground prototype to compute anomaly scores for all query pixels. The segmentation is then performed by thresholding
these anomaly scores using a learned threshold. Assisted by a novel self-supervision task that exploits the
3D structure of medical images through supervoxels, our proposed anomaly detection-inspired few-shot
medical image segmentation model outperforms previous state-of-the-art approaches on two representative MRI datasets for the tasks of abdominal organ segmentation and cardiac segmentation
Is part of
Hansen, S. (2022). Leveraging Supervoxels for Medical Image Volume Segmentation With Limited Supervision. (Doctoral thesis). https://hdl.handle.net/10037/27613.Publisher
ElsevierCitation
Hansen, Gautam, Jenssen, Kampffmeyer. Anomaly detection-inspired few-shot medical image segmentation through self-supervision with supervoxels. Medical Image Analysis. 2022;78:1-12Metadata
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