The cooling performance of a cryoprobe: Establishing guidelines for the safety margins in cryosurgery

Significance Statement

Research on the performance of newly developed cryoprobe, the Joule-Thomson cryoprobe, remains scarce with no data on its cooling power and growth rate of the ice ball formed. The perfect safety margin when utilizing this cryoprobe also needs to be provided for a successful cryosurgery.

In line with this, group of researchers led by Professor Hiroshi Takamatsu from Kyushu University in Japan published an article in International Journal of Refrigeration presenting experimental validation on cooling performances of Joule-Thomson cryoprobe coupled with improvement of pointers for setting the safety margin at the ice periphery.

Following the experimental setup, the authors observed the temperature variation and radial temperature distributions with the use of thermocouples. The authors further investigated the performance of three 1.5-mm dia. cryoprobes at three distinctive gas pressures and the results obtained from the experiments were compared with that of a two-dimensional numerical simulation developed by the authors.

Experimental results indicated that the temperature distribution did not reach a steady state until a period of 10 min. It became found that an increase in gas pressure led to a linear decrease of probe temperature with lowest temperature of -95°C observed at 27.4 MPa while the highest temperature at -75°C was observed at a gas pressure of 22.4 MPa. The probe temperature was considerably higher than that of 2-mm dia. cryoprobes. Although the diameter of the ice ball increased with respect to gas pressure, the diameter was much smaller than that obtained with larger cryoprobes: 21 mm at 22.4MPa and 27 mm at 27.2 MPa. The measured temperature and the size of ice ball correlated well with simulation results.

After a period of 10 min, isotherm of lethal temperatures for typical cancer cells, i.e. -20°C and -40°C, were approximately placed at 5 mm and 8 mm inside the ice front respectively which provides the safety margin wanted for the cryosurgical technique. The safety margin was also provided as a function of the radius of ice ball.

From numerical simulations, the authors were capable of deriving cooling power of the cryoprobe which couldn’t be decided experimentally. The maximum power increased with an increase in gas pressure with the least being 16 W and the highest at 24 W.

This study presents safety margins and guidelines for the usage of the Joule-Thomson cryoprobe for successful cryosurgery applications.  

https://youtube.com/watch?v=3rbqTIXI_8c%3Frel%3D0

The cooling performance of a cryoprobe: Establishing guidelines for the safety margins in cryosurgery. Advances in EngineeringThe cooling performance of a cryoprobe: Establishing guidelines for the safety margins in cryosurgery. Advances in EngineeringThe cooling performance of a cryoprobe: Establishing guidelines for the safety margins in cryosurgery. Advances in Engineering

About the author

Mohammed Shurrab is a Ph.D. candidate in the Department of Mechanical Engineering at Kyushu University, Japan. He received B.Sc. in medical engineering from Al-Ahliyyah Amman University in 2008 and M.Sc. in industrial engineering from University of Jordan in 2011. Before he was enrolled in the doctor course in Kyushu University, he worked as a lecturer in Islamic University of Gaza.

His research interests include bio-heat transfer, numerical modeling, simulation, optimization, ergonomics, business modelling, and Management. He has published 12 research papers in the areas of mechanical and industrial engineering. He received the Outstanding Graduation Project Award in 2008 from Jordan Engineers Association, and the Korpan Award from Japan Society for Low Temperature Medicine in 2015.  

About the author

Haidong Wang is an assistant professor of the Department of Mechanical Engineering at Kyushu University, Japan. After he received his Ph.D. in engineering mechanics from Tsinghua University, China in 2011, and spent two years as a postdoc in Tsinghua University, he joined the Heat and Mass Transfer Lab in Kyushu University in 2014.

His current research interests include cryosurgery, heat transfer at micro/nano scales, thermophysical properties of low-dimensional materials, development of MEMS sensors and fabrication techniques.  

About the author

Takanobu Fukunaga is a member of the technical staff in the Department of Mechanical Engineering at Kyushu University. He received Ph.D. from Kyushu Sangyo University in 2009. His research interests include cryosurgery, nanotechnology, MEMS sensors, bone cells, and bone remodeling. He has been involved in many experiments using biological cells. He has skills in the fabrication of microstructures and MEMS which is essential for the studies of micro- and nanoscale heat transfer.  

About the author

Kosaku Kurata is an associate professor of the department of Mechanical Engineering at Kyushu University, Japan. After he received his Ph.D. from Kyushu University in 2001, he performed postdoctoral research at University of Turku, Finland, for 2 years and worked as a lecturer at Kyushu Sangyo University, Japan.

His research interests include functional adaptation of biological tissue to mechanical stimulation, cell culture systems for tissue engineering, and tumor treatment using irreversible electroporation. He received the Award for Outstanding Research from Japanese Society for Bone morphometry in 1998 and 2009, the JBSE Papers of the Year Award in 2013, the Award for Outstanding Paper from the Heat Transfer Society of Japan in 2014, and the JSME Medal for Outstanding Paper from the Japan Society of Mechanical Engineers (JSME) in 2015. 

About the author

Hiroshi Takamatsu is a professor of thermal engineering in Kyushu University, Japan. He majored in mechanical engineering and received a doctor’s degree from Kyushu University in 1985. He has been a faculty of Kyushu University during his entire professional carrier at the Institute of Industrial Science and the Institute of Advanced Material Study prior to joining the Department of Mechanical Engineering as a full professor in 2004. He was involved in the study of boiling and condensation heat transfer associated with air conditioning, material processing and cooling of electronic devices for twenty years, but his current research interests include biothermal engineering, cryobiology and MEMS technologies.

His research involves irreversible electroporation, cryosurgery, biotransport, MEMS sensors and new methodologies for measuring thermal transport properties. He received the JSME Medal for Outstanding Paper from the Japan Society of Mechanical Engineers (JSME) in 2007 and 2015, the Award for Outstanding Paper from the Heat Transfer Society of Japan in 2001 and 2014, JBSE Papers of the Year Award in 2013, and an Achievement Award from Thermal Engineering Division of JSME in 2014.

Since 2015 he is the dean of the Faculty of Engineering, the School of Engineering and the Graduate School of Engineering in Kyushu University.

 

Journal Reference

Mohammed Shurrab, Haidong Wang, Noriaki Kubo, Takanobu Fukunaga, Kosaku Kurata, Hiroshi Takamatsu . The cooling performance of a cryoprobe: Establishing guidelines for the safety margins in cryosurgery, International Journal of Refrigeration 67 (2016) 308-318.

Department of Mechanical Engineering, Kyushu University, Japan.

 

 

Go To International Journal of Refrigeration

Check Also

Germano-Silicate Resonators for Ultralow-Loss Visible Integrated Photonics

Significance  Reference Chen HJ, Colburn K, Liu P, Yan H, Hou H, Ge J, Liu …

Advances in Engineering Copyright © 2010 - 2026 All Rights Reserved