Ultrasound-Guided Wireless Tubular Robotic Anchoring System

Tianlu Wang; Wenqi Hu; Ziyu Ren; Metin Sitti

doi:10.1109/LRA.2020.3003868

Ultrasound-Guided Wireless Tubular Robotic Anchoring System

Tianlu Wang^*, Wenqi Hu^*, Ziyu Ren^*, Metin Sitti^*

^*Corresponding author for this work

Research output: Contribution to journal › Journal Article › peer-review

32 Citations (Scopus)

Abstract

Untethered miniature robots have significant potential and promise in diverse minimally invasive medical applications inside the human body. For drug delivery and physical contraception applications inside tubular structures, it is desirable to have a miniature anchoring robot with self-locking mechanism at a target tubular region. Moreover, the behavior of this robot should be tracked and feedback-controlled by a medical imaging-based system. While such a system is unavailable, we report a reversible untethered anchoring robot design based on remote magnetic actuation. The current robot prototype's dimension is 7.5 mm in diameter, 17.8 mm in length, and made of soft polyurethane elastomer, photopolymer, and two tiny permanent magnets. Its relaxation and anchoring states can be maintained in a stable manner without supplying any control and actuation input. To control the robot's locomotion, we implement a two-dimensional (2D) ultrasound imaging-based tracking and control system, which automatically sweeps locally and updates the robot's position. With such a system, we demonstrate that the robot can be controlled to follow a pre-defined 1D path with the maximal position error of 0.53 \boldsymbol{\pm } 0.05 mm inside a tubular phantom, where the reversible anchoring could be achieved under the monitoring of ultrasound imaging.

Original language	English
Article number	9121662
Pages (from-to)	4859-4866
Number of pages	8
Journal	IEEE Robotics and Automation Letters
Volume	5
Issue number	3
DOIs	https://doi.org/10.1109/LRA.2020.3003868
Publication status	Published - Jul 2020
Externally published	Yes

Bibliographical note

Publisher Copyright:
© 2016 IEEE.

Keywords

Medical robots and systems
computer vision for medical robotics
mechanism design
soft robotics
ultrasound imaging-based control

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1109/LRA.2020.3003868

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title = "Ultrasound-Guided Wireless Tubular Robotic Anchoring System",

abstract = "Untethered miniature robots have significant potential and promise in diverse minimally invasive medical applications inside the human body. For drug delivery and physical contraception applications inside tubular structures, it is desirable to have a miniature anchoring robot with self-locking mechanism at a target tubular region. Moreover, the behavior of this robot should be tracked and feedback-controlled by a medical imaging-based system. While such a system is unavailable, we report a reversible untethered anchoring robot design based on remote magnetic actuation. The current robot prototype's dimension is 7.5 mm in diameter, 17.8 mm in length, and made of soft polyurethane elastomer, photopolymer, and two tiny permanent magnets. Its relaxation and anchoring states can be maintained in a stable manner without supplying any control and actuation input. To control the robot's locomotion, we implement a two-dimensional (2D) ultrasound imaging-based tracking and control system, which automatically sweeps locally and updates the robot's position. With such a system, we demonstrate that the robot can be controlled to follow a pre-defined 1D path with the maximal position error of 0.53 \textbackslash{}boldsymbol\{\textbackslash{}pm \} 0.05 mm inside a tubular phantom, where the reversible anchoring could be achieved under the monitoring of ultrasound imaging.",

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author = "Tianlu Wang and Wenqi Hu and Ziyu Ren and Metin Sitti",

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AB - Untethered miniature robots have significant potential and promise in diverse minimally invasive medical applications inside the human body. For drug delivery and physical contraception applications inside tubular structures, it is desirable to have a miniature anchoring robot with self-locking mechanism at a target tubular region. Moreover, the behavior of this robot should be tracked and feedback-controlled by a medical imaging-based system. While such a system is unavailable, we report a reversible untethered anchoring robot design based on remote magnetic actuation. The current robot prototype's dimension is 7.5 mm in diameter, 17.8 mm in length, and made of soft polyurethane elastomer, photopolymer, and two tiny permanent magnets. Its relaxation and anchoring states can be maintained in a stable manner without supplying any control and actuation input. To control the robot's locomotion, we implement a two-dimensional (2D) ultrasound imaging-based tracking and control system, which automatically sweeps locally and updates the robot's position. With such a system, we demonstrate that the robot can be controlled to follow a pre-defined 1D path with the maximal position error of 0.53 \boldsymbol{\pm } 0.05 mm inside a tubular phantom, where the reversible anchoring could be achieved under the monitoring of ultrasound imaging.

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Ultrasound-Guided Wireless Tubular Robotic Anchoring System

Abstract

Bibliographical note

Keywords

UN SDGs

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