Recent advances in medical robotics have initiated a transition from rigid serial manipulators to flexible or continuum robots capable of navigating to confined anatomy within the body. A desire for further procedure minimization is a key accelerator for the development of these flexible systems where the end goal is to provide access to the previously inaccessible anatomical workspaces and enable new minimally invasive surgical (MIS) procedures. While sophisticated navigation and control capabilities have been demonstrated for such systems, existing manufacturing approaches have limited the capabilities of millimeter-scale end-effectors for these flexible systems to date and, to achieve next generation highly functional end-effectors for surgical robots, advanced manufacturing approaches are required. We address this challenge by utilizing a disruptive 2D layer-by-layer precision fabrication process (inspired by printed circuit board manufacturing) that can create functional 3D mechanisms by folding 2D layers of materials which may be structural, flexible, adhesive, or conductive. Such an approach enables actuation, sensing, and circuitry to be directly integrated with the articulating features by selecting the appropriate materials during the layer-by-layer manufacturing process. To demonstrate the efficacy of this technology, we use it to fabricate three modular robotic components at the millimeter-scale: (1) sensors, (2) mechanisms, and (3) actuators. These modules could potentially be implemented into transendoscopic systems, enabling bilateral grasping, retraction and cutting, and could potentially mitigate challenging MIS interventions performed via endoscopy or flexible means. This research lays the ground work for new mechanism, sensor and actuation technologies that can be readily integrated via new millimeter-scale layer-by-layer manufacturing approaches.
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March 2017
Research-Article
Toward Medical Devices With Integrated Mechanisms, Sensors, and Actuators Via Printed-Circuit MEMS
Joshua Gafford,
Joshua Gafford
John A. Paulson School of Engineering
and Applied Sciences,
Harvard University,
Cambridge, MA 02138
e-mail: jgafford@seas.harvard.edu
and Applied Sciences,
Harvard University,
Cambridge, MA 02138
e-mail: jgafford@seas.harvard.edu
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Tommaso Ranzani,
Tommaso Ranzani
Wyss Institute for
Biologically-Inspired Engineering,
Boston, MA 02115
Biologically-Inspired Engineering,
Boston, MA 02115
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Sheila Russo,
Sheila Russo
Wyss Institute for
Biologically-Inspired Engineering,
Boston, MA 02115
Biologically-Inspired Engineering,
Boston, MA 02115
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Alperen Degirmenci,
Alperen Degirmenci
John A. Paulson School of
Engineering and Applied Sciences,
Harvard University,
Cambridge, MA 02138
Engineering and Applied Sciences,
Harvard University,
Cambridge, MA 02138
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Samuel Kesner,
Samuel Kesner
Wyss Institute for
Biologically-Inspired Engineering,
Boston, MA 02115
Biologically-Inspired Engineering,
Boston, MA 02115
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Robert Howe,
Robert Howe
John A. Paulson School of
Engineering and Applied Sciences,
Harvard University,
Cambridge, MA 02138;
Engineering and Applied Sciences,
Harvard University,
Cambridge, MA 02138;
Wyss Institute for
Biologically-Inspired Engineering,
Boston, MA 02115
Biologically-Inspired Engineering,
Boston, MA 02115
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Robert Wood,
Robert Wood
John A. Paulson School of
Engineering and Applied Sciences,
Harvard University,
Cambridge, MA 02138;
Engineering and Applied Sciences,
Harvard University,
Cambridge, MA 02138;
Wyss Institute for
Biologically-Inspired Engineering,
Boston, MA 02115
Biologically-Inspired Engineering,
Boston, MA 02115
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Conor Walsh
Conor Walsh
John A. Paulson School of
Engineering and Applied Sciences,
Harvard University,
Cambridge, MA 02138;
Engineering and Applied Sciences,
Harvard University,
Cambridge, MA 02138;
Wyss Institute for
Biologically-Inspired Engineering,
Boston, MA 02115
Biologically-Inspired Engineering,
Boston, MA 02115
Search for other works by this author on:
Joshua Gafford
John A. Paulson School of Engineering
and Applied Sciences,
Harvard University,
Cambridge, MA 02138
e-mail: jgafford@seas.harvard.edu
and Applied Sciences,
Harvard University,
Cambridge, MA 02138
e-mail: jgafford@seas.harvard.edu
Tommaso Ranzani
Wyss Institute for
Biologically-Inspired Engineering,
Boston, MA 02115
Biologically-Inspired Engineering,
Boston, MA 02115
Sheila Russo
Wyss Institute for
Biologically-Inspired Engineering,
Boston, MA 02115
Biologically-Inspired Engineering,
Boston, MA 02115
Alperen Degirmenci
John A. Paulson School of
Engineering and Applied Sciences,
Harvard University,
Cambridge, MA 02138
Engineering and Applied Sciences,
Harvard University,
Cambridge, MA 02138
Samuel Kesner
Wyss Institute for
Biologically-Inspired Engineering,
Boston, MA 02115
Biologically-Inspired Engineering,
Boston, MA 02115
Robert Howe
John A. Paulson School of
Engineering and Applied Sciences,
Harvard University,
Cambridge, MA 02138;
Engineering and Applied Sciences,
Harvard University,
Cambridge, MA 02138;
Wyss Institute for
Biologically-Inspired Engineering,
Boston, MA 02115
Biologically-Inspired Engineering,
Boston, MA 02115
Robert Wood
John A. Paulson School of
Engineering and Applied Sciences,
Harvard University,
Cambridge, MA 02138;
Engineering and Applied Sciences,
Harvard University,
Cambridge, MA 02138;
Wyss Institute for
Biologically-Inspired Engineering,
Boston, MA 02115
Biologically-Inspired Engineering,
Boston, MA 02115
Conor Walsh
John A. Paulson School of
Engineering and Applied Sciences,
Harvard University,
Cambridge, MA 02138;
Engineering and Applied Sciences,
Harvard University,
Cambridge, MA 02138;
Wyss Institute for
Biologically-Inspired Engineering,
Boston, MA 02115
Biologically-Inspired Engineering,
Boston, MA 02115
1Corresponding author.
Manuscript received July 31, 2016; final manuscript received November 9, 2016; published online January 11, 2017. Assoc. Editor: Rita M. Patterson.
J. Med. Devices. Mar 2017, 11(1): 011007 (12 pages)
Published Online: January 11, 2017
Article history
Received:
July 31, 2016
Revised:
November 9, 2016
Citation
Gafford, J., Ranzani, T., Russo, S., Degirmenci, A., Kesner, S., Howe, R., Wood, R., and Walsh, C. (January 11, 2017). "Toward Medical Devices With Integrated Mechanisms, Sensors, and Actuators Via Printed-Circuit MEMS." ASME. J. Med. Devices. March 2017; 11(1): 011007. https://doi.org/10.1115/1.4035375
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