Investigation of Micro-motion Kinematics of Continuum Robots for Volumetric OCT and OCT-guided Visual Servoing

Overview

Journal IEEE ASME Trans Mechatron

Date 2021 Oct 18

PMID 34658616

Citations 3

Authors

Giuseppe Del Giudice

Andrew L Orekhov

Jin-Hui Shen

Karen Joos

Nabil Simaan

Affiliations

Soon will be listed here.

Abstract

Continuum robots (CR) have been recently shown capable of micron-scale motion resolutions. Such motions are achieved through equilibrium modulation using for altering either internal preload forces or changing the cross-sectional stiffness along the length of a continuum robot. Previously reported, but unexplained, turning point behavior is modeled using two approaches. An energy minimization approach is first used to explain the source of this behavior. Subsequently, a kinematic model using internal constraints in multi-backbone CRs is used to replicate this turning point behavior. An approach for modeling the micro-motion differential kinematics is presented using experimental data based on the solution of a system of linear matrix equations. This approach provides a closed-form approximation of the empirical micro-motion kinematics and could be easily used for real-time control. A motivating application of image-based biopsy using 3D optical coherence tomography (OCT) is envisioned and demonstrated in this paper. A system integration for generating OCT volumes by sweeping a custom B-mode OCT probe is presented. Results showing high accuracy in obtaining 3D OCT measurements are shown using a commercial OCT probe. Qualitative results using a miniature probe integrated within the robot are also shown. Finally, closed-loop visual servoing using OCT data is demonstrated for guiding a needle into an agar channel. Results of this paper present what we believe is the first embodiment of a continuum robot capable of micro and macro motion control for 3D OCT imaging. This approach can support the development of new technologies for CRs capable of surgical intervention and micro-motion for ultra-precision tasks.

Citing Articles

Robotics and optical coherence tomography: current works and future perspectives [Invited].

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OCT-guided Robotic Subretinal Needle Injections: A Deep Learning-Based Registration Approach.

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Robotic Assistance for Intraocular Microsurgery: Challenges and Perspectives.

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A Review of Robotic and OCT-Aided Systems for Vitreoretinal Surgery.

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