Cable-Less, Magnetically Driven Forceps for Minimally Invasive Surgery

Cable-Less, Magnetically Driven Forceps for Minimally Invasive Surgery

In this letter, a novel end-effector for surgical applications is presented that uses magnetic actuation in lieu of a more traditional cable-driven tool with the goal of providing high dexterity in hard-to-reach locations by decoupling the tool actuation from the rest of the surgical system. The gri...

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Bibliographic Details
Published in:IEEE robotics and automation letters Vol. 4; no. 2; pp. 1202 - 1207
Main Authors: Forbrigger, Cameron, Lim, Andrew, Onaizah, Onaizah, Salmanipour, Sajad, Looi, Thomas, Drake, James, Diller, Eric D.
Format: Journal Article
Language:English
Published: Piscataway IEEE 01-04-2019
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects:
Actuation
Coils
Control systems design
Decoupling
Degrees of freedom
End effectors
Grippers
Grippers and other end-effectors
Magnetic flux
Magnetic moments
Magnets
Medical instruments
micro/nano robots
Minimally invasive surgery
Nickel titanides
Robot arms
Shape memory alloys
surgical robotics: laparoscopy
Wrist
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Summary:In this letter, a novel end-effector for surgical applications is presented that uses magnetic actuation in lieu of a more traditional cable-driven tool with the goal of providing high dexterity in hard-to-reach locations by decoupling the tool actuation from the rest of the surgical system. The gripper and wrist device consists of several magnets connected with compliant Nitinol joints that allow two rotational degrees of freedom and one gripping degree of freedom. As an end-effector for an existing surgical robot arm, this device could augment existing minimally invasive surgical robots by allowing high distal dexterity in surgical sites with narrow and restricted access. A static deflection model of the device is used to design an open-loop controller. The current prototype is capable of exerting pushing/pulling forces of 9 mN and gripping forces of 6 mN when magnetic flux densities of 20 mT are applied by a laboratory-scale electromagnetic coil system. These forces could be greatly amplified in a clinical-scale system to make brain tissue resection feasible. Under open-loop control, the wrist of the device can maneuver from <inline-formula><tex-math notation="LaTeX">{+\pi /4}</tex-math></inline-formula> to <inline-formula><tex-math notation="LaTeX">{-\pi /4}</tex-math></inline-formula> rad in less than 1 s with a maximum error of 0.12 rad.
ISSN:2377-3766
2377-3766
DOI:10.1109/LRA.2019.2894504