A 3-axis optical force/torque sensor for prostate needle placement in Magnetic resonance imaging environments | IEEE Conference Publication | IEEE Xplore
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A 3-axis optical force/torque sensor for prostate needle placement in Magnetic resonance imaging environments

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Hao Su; Gregory S. Fischer
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Abstract:

The work presented in this paper has been performed in furtherance of developing an MRI (Magnetic resonance imaging) compatible fiber optical force sensor. In this paper,...Show More

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Abstract:

The work presented in this paper has been performed in furtherance of developing an MRI (Magnetic resonance imaging) compatible fiber optical force sensor. In this paper, we discuss the design criteria and sensing principle of this optical sensor for monitoring forces in the 0-20 Newton range with an sub-Newton resolution. This instrumentation enables two degrees-of-freedom (DOF) torque measurement and one DOF force measurement. A novel flexure mechanism is designed and the finite element analysis is performed to aid the optimization of the design parameters. This 3 axis force/torque sensor with this range and resolution is an ideal tool for interventional procedures, e.g. needle biopsy and brachytherapy. The sensor is experimentally investigated and calibrated. Calibration results demonstrate that this sensor is a practical and accurate measurement apparatus.
Published in: 2009 IEEE International Conference on Technologies for Practical Robot Applications
Date of Conference: 09-10 November 2009
Date Added to IEEE Xplore: 20 November 2009
ISBN Information:

ISSN Information:

DOI: 10.1109/TEPRA.2009.5339654
Conference Location: Woburn, MA, USA
References is not available for this document.
Contents

I. Introduction

The MRI based medical diagnosis and treatment paradigm capitalizes on the novel benefits and capabilities created by the combination of high sensitivity for detecting tumors, high spatial resolution and high-fidelity soft tissue contrast. This makes it an ideal modality for guiding and monitoring medical procedures, such as needle biopsy and low-dose-rate permanent brachytherapy. Though with so many appealing merits, the magnetic and electrical fields in MRI environment presents significant challenges for mechatronic instrumentation design. Generally, the development of sensors for applications in MR environments requires careful consideration of safety and electromagnetic compatibility constraints. Fig. 1 illustrates a diagram of a traditional transrectal ultrasound guided (TRUS) brachytherapy needle placement procedure which is structurally similar to our application in [1]. Our previous work in [2] has developed an MRI-compatible actuation system, specifically targeting the neural intervention procedure, we intend to extend this work to sensor design to further our systematic approach to developing MR-compatible mechatronic systems. Specifically, for soft tissue needle placement, our basic measurement requirement is 3 axis hybrid sensing-one force and two torque measurements and the details would be explained in Section II.

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