DocumentCode
2470934
Title
Characterizing electroactive polymers for use in minimally invasive surgical instruments
Author
Cohen, A.L. ; Zhane, Q.M. ; Cheng, Z.Y. ; Runt, J.P. ; Snyder, A.J.
Author_Institution
Dept. of Bioeng., Pennsylvania State Univ., Hershey, PA, USA
fYear
2002
fDate
2002
Firstpage
111
Lastpage
112
Abstract
The popularity of minimally invasive surgical (MIS) procedures over traditional open procedures motivates us to develop new instruments that address the limits of existing technology and enable more widespread use of minimally invasive approaches. Robotic surgical instruments have the potential to provide improved dexterity and range of motion within the confines of the human body when compared with manually actuated instruments. The high strain response of electron-irradiated p(VDF-TrFE) copolymer makes it a candidate actuator material for robotic instruments that provide electronic mediation and multiple degrees of freedom of tip movement. We are currently studying both active and passive viscoelastic properties with the end goal of constructing a mathematical model to simulate the behavior of this material as an actuator. Studies have been conducted on 15 micron thick samples in rolled and rolled-flattened configurations. Active responses indicate approximately 2.5% strain in a 93 MV/m electric field under lightly loaded test conditions. Passive properties can be modeled by a 5 parameter viscoelastic model with two time constants of approximately 12 and 193 seconds. Current studies are examining means of combining active and passive properties in a simple model that can aid in design of a control system for the robotic actuators
Keywords
biocontrol; biomedical materials; dexterous manipulators; electrostriction; intelligent actuators; intelligent materials; medical robotics; polymer blends; polymer films; surgery; time series; viscoelasticity; Voigt elements; active viscoelastic properties; actuator material; control system design; electroactive polymers; electron-irradiated p(VDF-TrFE) copolymer; electronic mediation; electrostrictive copolymers; high strain response; improved dexterity; mathematical model; minimally invasive surgical instruments; multiple degrees of freedom; passive viscoelastic properties; robotic surgical instruments; semicrystalline ferroelectric polymer; solution cast films; spring-dashpot models; time series; tip movement; Actuators; Capacitive sensors; Conducting materials; Elasticity; Humans; Minimally invasive surgery; Polymers; Robots; Surgical instruments; Viscosity;
fLanguage
English
Publisher
ieee
Conference_Titel
Bioengineering Conference, 2002. Proceedings of the IEEE 28th Annual Northeast
Conference_Location
Philadelphia, PA
Print_ISBN
0-7803-7419-3
Type
conf
DOI
10.1109/NEBC.2002.999490
Filename
999490
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