Controlled Helical Propulsion Against the Flow of a Physiological Fluid

Chuang Li; Frank R. Halfwerk; Jutta Arens; Sarthak Misra; Michiel Warle; Islam S.M. Khalil

doi:10.1109/MARSS55884.2022.9870248

Controlled Helical Propulsion Against the Flow of a Physiological Fluid

Chuang Li, Frank R. Halfwerk, Jutta Arens, Sarthak Misra, Michiel Warle, Islam S.M. Khalil

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › Academic › peer-review

1 Citation (Scopus)

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Abstract

Untethered helical magnetic devices (UHMDs) have the potential to navigate bodily fluids using permanent-magnet robotic systems for minimally invasive diagnostic and surgical procedures. These devices can be actuated by robotically moving rotating permanent magnets (RPMs) to achieve controllable steering and propulsion simultaneously in a wireless manner. To date, the vast majority of motion control systems using UHMDs are constrained to operate in the absence of a dynamic flow field and prior work did not rigorously address the fundamental roles of rheological, magnetic, and geometric characteristics of the UHMD and its surroundings on the resulting stability. In this work, we show how to construct the region of attraction of a UHMD driven by two synchronized RPMs inside fluid-filled lumen around an equilibrium point. We first present the governing hydrodynamic model of a magnetically-driven UHMD to describe its behavior against the flow of blood serum. Then we validate the model using 1-D frequency response characterization and show that it captures the measured linear relationship between the actuation frequency and propulsive thrust at various flow fields. We find that a region of asymptotic stability can be achieved around an equilibrium point allowing a 6-mm-long UHMD to overcome maximum volumetric flow field of 1.2 l/hr (i.e., 2.65 cm/s).

Original language	English
Title of host publication	Proceedings of MARSS 2022 - 5th International Conference on Manipulation, Automation, and Robotics at Small Scales
Editors	Sinan Haliyo, Mokrane Boudaoud, Eric Diller, Xinyu Liu, Yu Sun, Sergej Fatikow
Publisher	Institute of Electrical and Electronics Engineers Inc.
Number of pages	6
ISBN (Electronic)	9781665459730
DOIs	https://doi.org/10.1109/MARSS55884.2022.9870248
Publication status	Published - Sept-2022
Event	5th International Conference on Manipulation, Automation, and Robotics at Small Scales, MARSS 2022 - Toronto, Canada Duration: 25-Jul-2022 → 29-Jul-2022

Conference

Conference	5th International Conference on Manipulation, Automation, and Robotics at Small Scales, MARSS 2022
Country/Territory	Canada
City	Toronto
Period	25/07/2022 → 29/07/2022

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10.1109/MARSS55884.2022.9870248

Controlled Helical Propulsion Against the Flow of a Physiological FluidFinal publisher's version, 4.15 MBLicence: Taverne

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Li, C., Halfwerk, F. R., Arens, J., Misra, S., Warle, M., & Khalil, I. S. M. (2022). Controlled Helical Propulsion Against the Flow of a Physiological Fluid. In S. Haliyo, M. Boudaoud, E. Diller, X. Liu, Y. Sun, & S. Fatikow (Eds.), Proceedings of MARSS 2022 - 5th International Conference on Manipulation, Automation, and Robotics at Small Scales Institute of Electrical and Electronics Engineers Inc.. https://doi.org/10.1109/MARSS55884.2022.9870248

Li, Chuang ; Halfwerk, Frank R. ; Arens, Jutta et al. / Controlled Helical Propulsion Against the Flow of a Physiological Fluid. Proceedings of MARSS 2022 - 5th International Conference on Manipulation, Automation, and Robotics at Small Scales. editor / Sinan Haliyo ; Mokrane Boudaoud ; Eric Diller ; Xinyu Liu ; Yu Sun ; Sergej Fatikow. Institute of Electrical and Electronics Engineers Inc., 2022.

@inproceedings{067f99c53fd245bfad5341e5b16c0d90,

title = "Controlled Helical Propulsion Against the Flow of a Physiological Fluid",

abstract = "Untethered helical magnetic devices (UHMDs) have the potential to navigate bodily fluids using permanent-magnet robotic systems for minimally invasive diagnostic and surgical procedures. These devices can be actuated by robotically moving rotating permanent magnets (RPMs) to achieve controllable steering and propulsion simultaneously in a wireless manner. To date, the vast majority of motion control systems using UHMDs are constrained to operate in the absence of a dynamic flow field and prior work did not rigorously address the fundamental roles of rheological, magnetic, and geometric characteristics of the UHMD and its surroundings on the resulting stability. In this work, we show how to construct the region of attraction of a UHMD driven by two synchronized RPMs inside fluid-filled lumen around an equilibrium point. We first present the governing hydrodynamic model of a magnetically-driven UHMD to describe its behavior against the flow of blood serum. Then we validate the model using 1-D frequency response characterization and show that it captures the measured linear relationship between the actuation frequency and propulsive thrust at various flow fields. We find that a region of asymptotic stability can be achieved around an equilibrium point allowing a 6-mm-long UHMD to overcome maximum volumetric flow field of 1.2 l/hr (i.e., 2.65 cm/s). ",

author = "Chuang Li and Halfwerk, {Frank R.} and Jutta Arens and Sarthak Misra and Michiel Warle and Khalil, {Islam S.M.}",

note = "Funding Information: This work is supported by the European Research Council (ERC) under the European Unions Horizon 2020 Research and Innovation programme under Grant 866494 project-MAESTRO, and financial support from the China Scholarship Council (CSC). Publisher Copyright: {\textcopyright} 2022 IEEE.; 5th International Conference on Manipulation, Automation, and Robotics at Small Scales, MARSS 2022 ; Conference date: 25-07-2022 Through 29-07-2022",

year = "2022",

month = sep,

doi = "10.1109/MARSS55884.2022.9870248",

language = "English",

editor = "Sinan Haliyo and Mokrane Boudaoud and Eric Diller and Xinyu Liu and Yu Sun and Sergej Fatikow",

booktitle = "Proceedings of MARSS 2022 - 5th International Conference on Manipulation, Automation, and Robotics at Small Scales",

publisher = "Institute of Electrical and Electronics Engineers Inc.",

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Li, C, Halfwerk, FR, Arens, J, Misra, S, Warle, M & Khalil, ISM 2022, Controlled Helical Propulsion Against the Flow of a Physiological Fluid. in S Haliyo, M Boudaoud, E Diller, X Liu, Y Sun & S Fatikow (eds), Proceedings of MARSS 2022 - 5th International Conference on Manipulation, Automation, and Robotics at Small Scales. Institute of Electrical and Electronics Engineers Inc., 5th International Conference on Manipulation, Automation, and Robotics at Small Scales, MARSS 2022, Toronto, Canada, 25/07/2022. https://doi.org/10.1109/MARSS55884.2022.9870248

Controlled Helical Propulsion Against the Flow of a Physiological Fluid. / Li, Chuang; Halfwerk, Frank R.; Arens, Jutta et al.
Proceedings of MARSS 2022 - 5th International Conference on Manipulation, Automation, and Robotics at Small Scales. ed. / Sinan Haliyo; Mokrane Boudaoud; Eric Diller; Xinyu Liu; Yu Sun; Sergej Fatikow. Institute of Electrical and Electronics Engineers Inc., 2022.

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › Academic › peer-review

TY - GEN

T1 - Controlled Helical Propulsion Against the Flow of a Physiological Fluid

AU - Li, Chuang

AU - Halfwerk, Frank R.

AU - Arens, Jutta

AU - Misra, Sarthak

AU - Warle, Michiel

AU - Khalil, Islam S.M.

N1 - Funding Information: This work is supported by the European Research Council (ERC) under the European Unions Horizon 2020 Research and Innovation programme under Grant 866494 project-MAESTRO, and financial support from the China Scholarship Council (CSC). Publisher Copyright: © 2022 IEEE.

PY - 2022/9

Y1 - 2022/9

N2 - Untethered helical magnetic devices (UHMDs) have the potential to navigate bodily fluids using permanent-magnet robotic systems for minimally invasive diagnostic and surgical procedures. These devices can be actuated by robotically moving rotating permanent magnets (RPMs) to achieve controllable steering and propulsion simultaneously in a wireless manner. To date, the vast majority of motion control systems using UHMDs are constrained to operate in the absence of a dynamic flow field and prior work did not rigorously address the fundamental roles of rheological, magnetic, and geometric characteristics of the UHMD and its surroundings on the resulting stability. In this work, we show how to construct the region of attraction of a UHMD driven by two synchronized RPMs inside fluid-filled lumen around an equilibrium point. We first present the governing hydrodynamic model of a magnetically-driven UHMD to describe its behavior against the flow of blood serum. Then we validate the model using 1-D frequency response characterization and show that it captures the measured linear relationship between the actuation frequency and propulsive thrust at various flow fields. We find that a region of asymptotic stability can be achieved around an equilibrium point allowing a 6-mm-long UHMD to overcome maximum volumetric flow field of 1.2 l/hr (i.e., 2.65 cm/s).

AB - Untethered helical magnetic devices (UHMDs) have the potential to navigate bodily fluids using permanent-magnet robotic systems for minimally invasive diagnostic and surgical procedures. These devices can be actuated by robotically moving rotating permanent magnets (RPMs) to achieve controllable steering and propulsion simultaneously in a wireless manner. To date, the vast majority of motion control systems using UHMDs are constrained to operate in the absence of a dynamic flow field and prior work did not rigorously address the fundamental roles of rheological, magnetic, and geometric characteristics of the UHMD and its surroundings on the resulting stability. In this work, we show how to construct the region of attraction of a UHMD driven by two synchronized RPMs inside fluid-filled lumen around an equilibrium point. We first present the governing hydrodynamic model of a magnetically-driven UHMD to describe its behavior against the flow of blood serum. Then we validate the model using 1-D frequency response characterization and show that it captures the measured linear relationship between the actuation frequency and propulsive thrust at various flow fields. We find that a region of asymptotic stability can be achieved around an equilibrium point allowing a 6-mm-long UHMD to overcome maximum volumetric flow field of 1.2 l/hr (i.e., 2.65 cm/s).

U2 - 10.1109/MARSS55884.2022.9870248

DO - 10.1109/MARSS55884.2022.9870248

M3 - Conference contribution

AN - SCOPUS:85139086041

BT - Proceedings of MARSS 2022 - 5th International Conference on Manipulation, Automation, and Robotics at Small Scales

A2 - Haliyo, Sinan

A2 - Boudaoud, Mokrane

A2 - Diller, Eric

A2 - Liu, Xinyu

A2 - Sun, Yu

A2 - Fatikow, Sergej

PB - Institute of Electrical and Electronics Engineers Inc.

T2 - 5th International Conference on Manipulation, Automation, and Robotics at Small Scales, MARSS 2022

Y2 - 25 July 2022 through 29 July 2022

ER -

Li C, Halfwerk FR, Arens J, Misra S, Warle M, Khalil ISM. Controlled Helical Propulsion Against the Flow of a Physiological Fluid. In Haliyo S, Boudaoud M, Diller E, Liu X, Sun Y, Fatikow S, editors, Proceedings of MARSS 2022 - 5th International Conference on Manipulation, Automation, and Robotics at Small Scales. Institute of Electrical and Electronics Engineers Inc. 2022 doi: 10.1109/MARSS55884.2022.9870248

Controlled Helical Propulsion Against the Flow of a Physiological Fluid

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