Concetti Chiave
Skeleton Recall Loss is a novel loss function that effectively preserves the connectivity of thin tubular structures in segmentation tasks, while being computationally efficient and compatible with multi-class problems.
Sintesi
The paper proposes a novel loss function called Skeleton Recall Loss for segmentation of thin tubular structures, such as vessels, nerves, roads, or concrete cracks.
Key highlights:
- Existing deep learning-based segmentation losses like Dice or Cross-Entropy often struggle to preserve the structural connectivity or topology of thin structures, which is crucial for downstream tasks.
- While current topology-focused losses like centerlineDice (clDice) address this, they introduce significant computational and memory overheads, especially for 3D data and multi-class problems.
- Skeleton Recall Loss overcomes these challenges by using a computationally inexpensive CPU-based "tubed skeleton" instead of a differentiable skeleton, while still effectively preserving connectivity.
- Skeleton Recall Loss demonstrates superior performance to clDice Loss on 5 public datasets, while reducing computational overhead by more than 90%.
- It is the first multi-class capable loss function for thin structure segmentation, excelling in both efficiency and efficacy for topology-preservation.
Statistiche
"Accurately segmenting thin tubular structures, such as vessels, nerves, roads or concrete cracks, is a crucial task in computer vision."
"Standard deep learning-based segmentation loss functions, such as Dice or Cross-Entropy, focus on volumetric overlap, often at the expense of preserving structural connectivity or topology."
"Differentiable skeleton based methods require a GPU-based skeleton computation [31] or prediction [28], leading to approximately 88% additional training time and 52% more VRAM consumption compared to the plain nnUNet backbone when averaged across our 5 datasets (excluding multi-class TopCoW)."
"Remarkably, our method Skeleton Recall Loss does the same at only an additional 8% training time and 2% higher VRAM consumption."
Citazioni
"Skeleton Recall Loss yields overall superior results to a baseline network without topological losses, as well as against clDice Loss as a state-of-the-art topological loss."
"Notably, our loss function inherently feasibly supports multi-class segmentation problems and thus can be considered a new state-of-the-art for delineating thin curvilinear structures in natural as well as medical images."