Noninvasive Measurement of Local Thermal Diffusivity Using Backscattered Ultrasound and Focused Ultrasound Heating

• Published in: Ultrasound in medicine & biology Vol. 34; no. 9; pp. 1449 - 1464
• Main Authors: Anand, Ajay, Kaczkowski, Peter J
• Format: Journal Article
• Language: English
• Published: England Elsevier Inc 01.09.2008
• Subjects: Algorithms; Computer Simulation; Humans; Models, Theoretical; Phantoms, Imaging; Radiology; Scattering, Radiation; Temperature; Thermal ablation; Tissue characterization; Transducers; Ultrasonic signal processing; Ultrasonic Therapy - instrumentation; Ultrasonic Therapy - methods; Ultrasound thermometry; Ultrasound treatment monitoring; Thermal ablation; Ultrasonic signal processing; Tissue characterization; Ultrasound treatment monitoring; Ultrasound thermometry
• ISSN: 0301-5629; 1879-291X
• DOI: 10.1016/j.ultrasmedbio.2008.02.004

Abstract Previously, noninvasive methods of estimating local tissue thermal and acoustic properties using backscattered ultrasound have been proposed in the literature. In this article, a noninvasive method of estimating local thermal diffusivity in situ during focused ultrasound heating using beamformed acoustic backscatter data and applying novel signal processing techniques is developed. A high intensity focused ultrasound (HIFU) transducer operating at subablative intensities is employed to create a brief local temperature rise of no more than 10°C. Beamformed radio-frequency (RF) data are collected during heating and cooling using a clinical ultrasound scanner. Measurements of the time-varying “acoustic strain”, that is, spatiotemporal variations in the RF echo shifts induced by the temperature related sound speed changes, are related to a solution of the heat transfer equation to estimate the thermal diffusivity in the heated zone. Numerical simulations and experiments performed in vitro in tissue mimicking phantoms and excised turkey breast muscle tissue demonstrate agreement between the ultrasound derived thermal diffusivity estimates and independent estimates made by a traditional hot-wire technique. The new noninvasive ultrasonic method has potential applications in thermal therapy planning and monitoring, physiological monitoring and as a means of noninvasive tissue characterization. (E-mail: ajay.anand@philips.com )