Advanced SearchSearch Tips
Development of Pressure Sensor for Identifying Guinea Pig`s Large Intestinal Motility Caused by Drug
facebook(new window)  Pirnt(new window) E-mail(new window) Excel Download
 Title & Authors
Development of Pressure Sensor for Identifying Guinea Pig`s Large Intestinal Motility Caused by Drug
Park, Jae-Soon; Park, Jung-Ho; Kim, Eung-Bo; Cho, Sung-Hwan; Jang, Su-Jeong; Joung, Yeun-Ho;
  PDF(new window)
In this paper, in order to quantify the peristalsis occurrence in a guinea pig`s large intestine, a miniaturized air-gap capacitive pressure sensor was fabricated through micro-electro-mechanical system (MEMS). The proposed pressure sensor is a two-layered biocompatible polyimide substrate consisting of an air-gap capacitive plates between the substrates. The proposed pressure sensor was designed with a careful consideration of the structure and motility mechanism of the guinea pig`s large intestine. Artificial pellets were mounted on a prototype pressure sensor to provide some redundancies in the form of size and shape of the guinea pig feces. Capacitance of a prototype sensor was recorded to be 2.5 ~ 3 pF. This capacitance value was later converted to count value using a lab fabricated data conversion system. Sensitivity of the pressure sensor was recorded to be below 1 mmHg per atmospheric pressure. During in vivo testing, artificial peristalsis caused by drug injection was measured by inserting the prototype pressure sensor into the guinea pig`s large intestine and pressure data obtained due to artificial peristalsis was graphed using a labview program. The proposed pressure sensor could measure the pressure changes in the proximal, medial, and distal parts of the large intestine. The results of the experiment confirmed that pressure changes of guinea pig`s large intestine was proportional to the degree of drug injection.
Pressure sensor;MEMS;Polyimide;Artificial pellet;Intestinal motility;
 Cited by
S. J. Myung, T. H. Lee, K. C. Huh, S. C. Choi, and C. I. Sohn, The Korean Society of Gastroenterology, 55, 316 (2010). [DOI:] crossref(new window)

J. W. Cho, National Health Insurance Service, 3 (2014).

C. Y. Chen, J. R. Chen, M. D. Ke, C. H. Huang, Y. H. Hsueh, and C. D. Kuo, IEEE APCCAS, 450 (2010).

J. H. Lim, H. S. Kim, E. J. Choi, C. K. Shim, and H. J. Park, The Korean Society of Neurogastroenterology and Motility, 14, 7 (2008).

J. W. Arkwright, N. G. Blenman, I. D. Underhill, S. A. Maunder, N. J. Spencer, M. Costa, Simon J. Brookes, M. M. Szczesniak, and P. G. Dinning, IEEE Sensors Journal, 12, 113 (2012). [DOI:] crossref(new window)

H. S. Kim, E. J. Choi, and H. Park, Neurogastroenterol Motil, 20, 169 (2008). [DOI:]

M. Dokmeci and K. Najafi, Journal of Microelectromechanical Systems, 10, 197 (2001). [DOI:] crossref(new window)

J. T. Kim, S. I. Kim, and Y. H. Joung, J. Korean Inst. Electr. Electron. Mater. Eng., 26, 669 (2013).