JIGGLE: An Active Sensing Framework for Boundary Parameters Estimation in Deformable Surgical Environments


Nikhil Uday Shinde, Xiao Liang, Fei Liu, Yutong Zhang, Florian Richter, Sylvia Lee Herbert, Michael C. Yip
Paper Website

Paper ID 7

Session 1. Control

Poster Session day 1 (Tuesday, July 16)

Abstract: Surgical automation can improve the accessibility and consistency of life-saving procedures. Most surgeries require separating layers of tissue to access the surgical site, and suturing to re-attach incisions. These tasks involve deformable manipula- tion to safely identify and alter tissue attachment (boundary) topology. Due to poor visual acuity and frequent occlusions, surgeons tend to carefully manipulate the tissue in ways that enable inference of the tissue’s attachment points without causing unsafe tearing. In a similar fashion, we propose JIGGLE, a framework for estimation and interactive sensing of unknown boundary parameters in deformable surgical environments. This framework has two key components: (1) a probabilistic estimation to identify the current attachment points, achieved by integrating a differentiable soft-body simulator with an extended Kalman filter (EKF), and (2) an optimization-based active control pipeline that generates actions to maximize information gain of the tissue attachments, while simultaneously minimizing safety costs. The robustness of our estimation approach is demonstrated through experiments with real animal tissue, where we infer sutured attachment points using stereo endoscope observations. We also demonstrate the capabilities of our method in handling complex topological changes such as cutting and suturing.