A Systematic Investigation of Thermal Effects of High-Intensity Focused Ultrasound Therapy for Ultrasound Neuromodulation
Ben Fu, Dan-Dan Shan, Cong Pu, Le‐Hang Guo, Huixiong Xu, Chang Peng
Abstract
Ultrasound neuromodulation has demonstrated potentials for non-invasively activating ion channels within cell membranes and regulating neuronal activities in animal models and humans. The thermal effects of focused ultrasound play a significant role in activating the thermosensitive ion channels. However, until now the effects of various focused ultrasound parameters on the resultant temperature distribution for activating thermosensitive ion channels have not yet been sufficiently elucidated. In this study, <italic xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink">in-vitro</i> experiments are conducted by using high-intensity focused ultrasound transducers in three different types of porcine tissues including pork, liver and brain tissues. The influences of different ultrasound parameters on thermal effects are systematically analyzed. Our results show that elevating the ultrasound parameters including ultrasound frequency, acoustic power, and duty cycle can directly increase temperature rising rates and peak temperature values, while varying the pulse cycle number from 10 to 20 has nearly no impact. Furthermore, higher-frequency ultrasound stimulation such as 1.59 MHz and 2 MHz exhibits a larger temperature difference in the vicinity of the focal region. Our results also reveal that the temperature rising rate varies in that three types of tissues, which is dominant by the distinct acoustic attenuation coefficients. The findings in this study provide valuable insights for designing an effective ultrasound thermal neuromodulation sequence for clinical applications.