Conditional Graph Neural Network for Predicting Soft Tissue Deformation and Forces

TL;DR

This paper introduces a conditional graph neural network that accurately predicts soft tissue deformation and forces in virtual environments, enhancing medical simulation realism and haptic feedback integration.

Contribution

The paper presents a novel data-driven cGNN model trained with transfer learning to improve soft tissue deformation and force prediction accuracy in virtual simulations.

Findings

Deformation prediction error of 0.35 mm

Force prediction error of 0.37 N

Effective transfer learning from simulations to experimental data

Abstract

Soft tissue simulation in virtual environments is becoming increasingly important for medical applications. However, the high deformability of soft tissue poses significant challenges. Existing methods rely on segmentation, meshing and estimation of stiffness properties of tissues. In addition, the integration of haptic feedback requires precise force estimation to enable a more immersive experience. We introduce a novel data-driven model, a conditional graph neural network (cGNN) to tackle this complexity. Our model takes surface points and the location of applied forces, and is specifically designed to predict the deformation of the points and the forces exerted on them. We trained our model on experimentally collected surface tracking data of a soft tissue phantom and used transfer learning to overcome the data scarcity by initially training it with mass-spring simulations and fine-tuning it with the experimental data. This approach improves the generalisation capability of the model and enables accurate predictions of tissue deformations and corresponding interaction forces. The results demonstrate that the model can predict deformations with a distance error of 0.35$\pm$0.03 mm for deformations up to 30 mm and the force with an absolute error of 0.37$\pm$0.05 N for forces up to 7.5 N. Our data-driven approach presents a promising solution to the intricate challenge of simulating soft tissues within virtual environments. Beyond its applicability in medical simulations, this approach holds the potential to benefit various fields where realistic soft tissue simulations are required.