Topology-Constrained Learning for Efficient Laparoscopic Liver Landmark Detection
This work addresses a critical problem for surgeons by improving anatomical guidance during laparoscopic liver surgery, though it appears incremental as it builds on existing methods with novel constraints.
The paper tackles the challenge of automatic landmark detection in laparoscopic liver surgery by introducing TopoNet, a topology-constrained learning framework that achieves outstanding accuracy and computational efficiency on L3D and P2ILF datasets.
Liver landmarks provide crucial anatomical guidance to the surgeon during laparoscopic liver surgery to minimize surgical risk. However, the tubular structural properties of landmarks and dynamic intraoperative deformations pose significant challenges for automatic landmark detection. In this study, we introduce TopoNet, a novel topology-constrained learning framework for laparoscopic liver landmark detection. Our framework adopts a snake-CNN dual-path encoder to simultaneously capture detailed RGB texture information and depth-informed topological structures. Meanwhile, we propose a boundary-aware topology fusion (BTF) module, which adaptively merges RGB-D features to enhance edge perception while preserving global topology. Additionally, a topological constraint loss function is embedded, which contains a center-line constraint loss and a topological persistence loss to ensure homotopy equivalence between predictions and labels. Extensive experiments on L3D and P2ILF datasets demonstrate that TopoNet achieves outstanding accuracy and computational complexity, highlighting the potential for clinical applications in laparoscopic liver surgery. Our code will be available at https://github.com/cuiruize/TopoNet.