This paper details the design, analysis, fabrication, and validation of a deployable, atraumatic grasper intended for retraction and manipulation tasks in manual and robotic minimally invasive surgical (MIS) procedures. Fabricated using a combination of shape deposition manufacturing (SDM) and 3D printing, the device (which acts as a deployable end-effector for robotic platforms) has the potential to reduce the risk of intraoperative hemorrhage by providing a soft, compliant interface between delicate tissue structures and the metal laparoscopic forceps and graspers that are currently used to manipulate and retract these structures on an ad hoc basis. This paper introduces a general analytical framework for designing SDM fingers where the desire is to predict the shape and the transmission ratio, and this framework was used to design a multijointed grasper that relies on geometric trapping to manipulate tissue, rather than friction or pinching, to provide a safe, stable, adaptive, and conformable means for manipulation. Passive structural compliance, coupled with active grip force monitoring enabled by embedded pressure sensors, helps to reduce the cognitive load on the surgeon. Initial manipulation tasks in a simulated environment have demonstrated that the device can be deployed though a 15 mm trocar and develop a stable grasp using Intuitive Surgical's daVinci robotic platform to deftly manipulate a tissue analog.
Skip Nav Destination
Article navigation
Research-Article
Shape Deposition Manufacturing of a Soft, Atraumatic, and Deployable Surgical Grasper
Joshua Gafford,
Joshua Gafford
School of Engineering and Applied Sciences,
Harvard University
,Cambridge, MA 02138
Search for other works by this author on:
Ye Ding,
Ye Ding
School of Engineering and Applied Sciences,
Harvard University
,Cambridge, MA 02138
Search for other works by this author on:
Andrew Harris,
Andrew Harris
School of Engineering and Applied Sciences,
Harvard University
,Cambridge, MA 02138
Search for other works by this author on:
Terrence McKenna,
Terrence McKenna
School of Engineering and Applied Sciences,
Harvard University
,Cambridge, MA 02138
Search for other works by this author on:
Panagiotis Polygerinos,
Panagiotis Polygerinos
School of Engineering and Applied Sciences,
Harvard University
,Cambridge, MA 02138
Search for other works by this author on:
Dónal Holland,
Dónal Holland
School of Engineering and Applied Sciences,
Harvard University
,Cambridge, MA 02138
Search for other works by this author on:
Conor Walsh,
Conor Walsh
1
School of Engineering and Applied Sciences,
Harvard University
,Cambridge, MA 02138
;Wyss Institute for Biologically Inspired Engineering,
e-mail: walsh@seas.harvard.edu
Harvard University
,Cambridge, MA 02138
e-mail: walsh@seas.harvard.edu
1Corresponding author.
Search for other works by this author on:
Arthur Moser
Arthur Moser
Department of Surgery,
Boston, MA 02215
Beth Israel Deaconess Medical Center
,330 Brookline Avenue
,Boston, MA 02215
Search for other works by this author on:
Joshua Gafford
School of Engineering and Applied Sciences,
Harvard University
,Cambridge, MA 02138
Ye Ding
School of Engineering and Applied Sciences,
Harvard University
,Cambridge, MA 02138
Andrew Harris
School of Engineering and Applied Sciences,
Harvard University
,Cambridge, MA 02138
Terrence McKenna
School of Engineering and Applied Sciences,
Harvard University
,Cambridge, MA 02138
Panagiotis Polygerinos
School of Engineering and Applied Sciences,
Harvard University
,Cambridge, MA 02138
Dónal Holland
School of Engineering and Applied Sciences,
Harvard University
,Cambridge, MA 02138
Conor Walsh
School of Engineering and Applied Sciences,
Harvard University
,Cambridge, MA 02138
;Wyss Institute for Biologically Inspired Engineering,
e-mail: walsh@seas.harvard.edu
Harvard University
,Cambridge, MA 02138
e-mail: walsh@seas.harvard.edu
Arthur Moser
Department of Surgery,
Boston, MA 02215
Beth Israel Deaconess Medical Center
,330 Brookline Avenue
,Boston, MA 02215
1Corresponding author.
Manuscript received August 15, 2014; final manuscript received December 23, 2014; published online February 27, 2015. Assoc. Editor: Aaron M. Dollar.
J. Mechanisms Robotics. May 2015, 7(2): 021006 (11 pages)
Published Online: May 1, 2015
Article history
Received:
August 15, 2014
Revision Received:
December 23, 2014
Online:
February 27, 2015
Citation
Gafford, J., Ding, Y., Harris, A., McKenna, T., Polygerinos, P., Holland, D., Walsh, C., and Moser, A. (May 1, 2015). "Shape Deposition Manufacturing of a Soft, Atraumatic, and Deployable Surgical Grasper." ASME. J. Mechanisms Robotics. May 2015; 7(2): 021006. https://doi.org/10.1115/1.4029493
Download citation file:
Get Email Alerts
An Ultrasound-Guided Miniature Hand-Eye Integrated Robot for Percutaneous Needle Placement
J. Mechanisms Robotics (June 2025)
Force-Motion Coupled Mechanism Synthesis Method of Heavy Load Parallel Kinematic Mechanism for Multi-DoF Forming Process
J. Mechanisms Robotics (May 2025)
Design and Analysis of a Bimanual Parallel Dexterous Hand With Cooperative Manipulation Capability
J. Mechanisms Robotics (June 2025)
Design and Analysis of a Mobile Robot With Transformable Wheel-Legged Mechanism
J. Mechanisms Robotics (June 2025)
Related Articles
Design and Fabrication of a Soft Robotic Hand With Embedded Actuators and Sensors
J. Mechanisms Robotics (May,2015)
A Compact and Modular Laparoscopic Grasper With Tridirectional Force Measurement Capability
J. Med. Devices (September,2008)
Estimating Tool–Tissue Forces Using a 3-Degree-of-Freedom Robotic Surgical Tool
J. Mechanisms Robotics (October,2016)
Design of a Contact-Aided Compliant Notched-Tube Joint for Surgical Manipulation in Confined Workspaces
J. Mechanisms Robotics (February,2018)
Related Proceedings Papers
Related Chapters
Openings
Guidebook for the Design of ASME Section VIII Pressure Vessels
GD&T as a Language
Geometric Dimensioning and Tolerancing Handbook: Applications, Analysis & Measurement
GD&T as a Language
Geometric Dimensioning and Tolerancing: Applications, Analysis, Gauging and Measurement [per ASME Y14.5-2018]