Magnetic compression based anastomoses use magnetic force to necrose tissue between two magnets to create an anastomosis. Nickel-plated neodymium–iron–boron magnets are used in our study. The compression pressure between the magnets depends on the distance between the magnets, which is determined by the thickness of the compressed tissue and depends on bowel wall thickness and elasticity. It is critical to know the distance between the magnets once the tissue is compressed because the magnets must be within a critical distance of each other in order to create enough compressive force to necrose the tissue. We have developed an inductance sensor to detect the distance (tissue thickness) between the two magnets after the surgeon has deployed them. Inductance sensing is a contact-less sensing method that enables precise short-range detection of conducting surfaces. The inductor coil mounted on one magnet detects the second magnet by measuring the change in inductance due to eddy current induced on the nickel-plated surface of the second magnet. The change in the inductance is proportional to the change in distance between the magnets. The sensor was first calibrated by using polycarbonate sheets to simulate the intestine tissue. We are able to detect up to 6 mm of spacing between the magnets. Pig intestine from Yorkshire pigs was used to characterize the sensor. We are able to distinguish up to five distinct layers of the intestine from the large intestine. This sensing mechanism can indicate the operating surgeon the exact thickness of the tissue compressed between the two magnets. The surgeon can thus be sure of formation of a clean anastomosis and avoid the likelihood of the magnets sliding away or uncoupling.
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March 2016
Research-Article
Inductive Sensing to Detect Tissue Thickness Between Magnets for Potential Application in Magnetic Compression Based Anastomosis
Anupama Arun,
Anupama Arun
Department of Surgery,
University of California San Francisco,
San Francisco, CA 94143;
University of California San Francisco,
San Francisco, CA 94143;
Department of Bioengineering and
Therapeutic Sciences,
University of California San Francisco,
San Francisco, CA 94143
e-mail: anupama.arun@ucsf.edu
Therapeutic Sciences,
University of California San Francisco,
San Francisco, CA 94143
e-mail: anupama.arun@ucsf.edu
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Brandon Gaston,
Brandon Gaston
Department of Surgery,
University of California San Francisco,
San Francisco, CA 94143
University of California San Francisco,
San Francisco, CA 94143
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Dillon Kwiat,
Dillon Kwiat
Department of Surgery,
University of California San Francisco,
San Francisco, CA 94143
University of California San Francisco,
San Francisco, CA 94143
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Jill Imamura-Ching,
Jill Imamura-Ching
Department of Surgery,
University of California San Francisco,
San Francisco, CA 94143
University of California San Francisco,
San Francisco, CA 94143
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Richard Fechter,
Richard Fechter
Department of Surgery,
University of California San Francisco,
San Francisco, CA 94143
University of California San Francisco,
San Francisco, CA 94143
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Shijie Chen,
Shijie Chen
School of Electrical Engineering,
San Francisco State University,
San Francisco, CA 94132
San Francisco State University,
San Francisco, CA 94132
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Hao Jiang,
Hao Jiang
School of Electrical Engineering,
San Francisco State University,
San Francisco, CA 94132
San Francisco State University,
San Francisco, CA 94132
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Michael Harrison,
Michael Harrison
Department of Surgery,
University of California San Francisco,
San Francisco, CA 94143
University of California San Francisco,
San Francisco, CA 94143
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Shuvo Roy
Shuvo Roy
Department of Bioengineering and
Therapeutic Sciences,
University of California San Francisco,
San Francisco, CA 94143
Therapeutic Sciences,
University of California San Francisco,
San Francisco, CA 94143
Search for other works by this author on:
Anupama Arun
Department of Surgery,
University of California San Francisco,
San Francisco, CA 94143;
University of California San Francisco,
San Francisco, CA 94143;
Department of Bioengineering and
Therapeutic Sciences,
University of California San Francisco,
San Francisco, CA 94143
e-mail: anupama.arun@ucsf.edu
Therapeutic Sciences,
University of California San Francisco,
San Francisco, CA 94143
e-mail: anupama.arun@ucsf.edu
Brandon Gaston
Department of Surgery,
University of California San Francisco,
San Francisco, CA 94143
University of California San Francisco,
San Francisco, CA 94143
Dillon Kwiat
Department of Surgery,
University of California San Francisco,
San Francisco, CA 94143
University of California San Francisco,
San Francisco, CA 94143
Jill Imamura-Ching
Department of Surgery,
University of California San Francisco,
San Francisco, CA 94143
University of California San Francisco,
San Francisco, CA 94143
Richard Fechter
Department of Surgery,
University of California San Francisco,
San Francisco, CA 94143
University of California San Francisco,
San Francisco, CA 94143
Shijie Chen
School of Electrical Engineering,
San Francisco State University,
San Francisco, CA 94132
San Francisco State University,
San Francisco, CA 94132
Hao Jiang
School of Electrical Engineering,
San Francisco State University,
San Francisco, CA 94132
San Francisco State University,
San Francisco, CA 94132
Michael Harrison
Department of Surgery,
University of California San Francisco,
San Francisco, CA 94143
University of California San Francisco,
San Francisco, CA 94143
Shuvo Roy
Department of Bioengineering and
Therapeutic Sciences,
University of California San Francisco,
San Francisco, CA 94143
Therapeutic Sciences,
University of California San Francisco,
San Francisco, CA 94143
Manuscript received June 20, 2015; final manuscript received December 22, 2015; published online February 17, 2016. Assoc. Editor: Rosaire Mongrain.
J. Med. Devices. Mar 2016, 10(1): 011008 (7 pages)
Published Online: February 17, 2016
Article history
Received:
June 20, 2015
Revised:
December 22, 2015
Citation
Arun, A., Gaston, B., Kwiat, D., Imamura-Ching, J., Fechter, R., Chen, S., Jiang, H., Harrison, M., and Roy, S. (February 17, 2016). "Inductive Sensing to Detect Tissue Thickness Between Magnets for Potential Application in Magnetic Compression Based Anastomosis." ASME. J. Med. Devices. March 2016; 10(1): 011008. https://doi.org/10.1115/1.4032615
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