Deep-Learning-Based Compliant Motion Control of a Pneumatically-Driven Robotic Catheter

Journal article (2022)

Authors

D. Wu Katholieke Universiteit Leuven, Medical Instruments & Bio-Inspired Technology - Mechanical, Maritime and Materials Engineering
Xuan Thao Ha Katholieke Universiteit Leuven
Yao Zhang Katholieke Universiteit Leuven
Mouloud Ourak Katholieke Universiteit Leuven
Gianni Borghesan Katholieke Universiteit Leuven
Kenan Niu Katholieke Universiteit Leuven
F. Trauzettel Medical Instruments & Bio-Inspired Technology - Mechanical, Maritime and Materials Engineering , Katholieke Universiteit Leuven
J. Dankelman Medical Instruments & Bio-Inspired Technology - Mechanical, Maritime and Materials Engineering
Arianna Menciassi Scuola Superiore Sant’Anna
Emmanuel Vander Poorten Katholieke Universiteit Leuven
Research Group
Medical Instruments & Bio-Inspired Technology (Mechanical, Maritime and Materials Engineering) (TU Delft)
Copyright: © 2022 D. Wu, Xuan Thao Ha, Yao Zhang, Mouloud Ourak, Gianni Borghesan, Kenan Niu, F. Trauzettel, J. Dankelman, Arianna Menciassi, Emmanuel Vander Poorten
DOI
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https://doi.org/10.1109/LRA.2022.3186497
LSTM Robots Hysteresis Hysteresis Force Robotic catheter Motion control Robot sensing systems Robot kinematics Catheters Compliant motion control Pneumatic artificial muscle
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Published Date

2022

Language

English

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Faculty

Mechanical, Maritime and Materials Engineering

Department

Biomechanical Engineering

Research Group

Medical Instruments & Bio-Inspired Technology

Abstract

In cardiovascular interventions, when steering catheters and especially robotic catheters, great care should be paid to prevent applying too large forces on the vessel walls as this could dislodge calcifications, induce scars or even cause perforation. To address this challenge, this paper presents a novel compliant motion control algorithm that relies solely on position sensing of the catheter tip and knowledge of the catheter's behavior. The proposed algorithm features a data-driven tip position controller. The controller is trained based on a so-called control Long Short-Term Memory Network (control-LSTM). Trajectory following experiments are conducted to validate the quality of the proposed control-LSTM. Results demonstrated superior positioning capability with sub-degree precision of the new approach in the presence of severe rate-dependent hysteresis. Experiments both in a simplified setup as well as in an aortic phantom further show that the proposed approach allows reducing the interaction forces with the environment by around 70%. This work shows how deep learning can be exploited advantageously to avoid tedious modeling that would be needed to precisely steer continuum robots in constrained environments such as the patient's vasculature.