Abstract
Boiling histotripsy employs a number of millisecond-long High Intensity Focused Ultrasound (HIFU) pulses with high acoustic peak pressures at the HIFU focus to mechanically fractionate soft tissue. Studies have shown the mechanisms underpinning this tissue fractionation process; however, the question of how HIFU exposure conditions affect lesion formation still remains unclear. In the present work, a high-speed camera and a passive cavitation detection (PCD) system were used to investigate the dynamics of bubbles induced and the corresponding mechanical damage generated in optically transparent tissue-mimicking phantoms with two different boiling histotripsy exposure conditions (1. P+ = 85.4 MPa, P- = – 15.6 MPa; 2. P+ = 71.5 MPa, P- = – 13.4 MPa at focus). Our results clearly showed that there is a positive relationship between the size of a boiling bubble and the lesion dimension. At P+ = 85.4 MPa and P- = – 15.6 MPa, a relatively larger boiling bubble was, for instance, produced at the focus in the gel phantom followed by the presence of a wider cavitation cluster progressing toward the HIFU transducer, resulting in the formation of a larger lesion compared to that with P+ = 71.5 MPa and P- = – 13.4 MPa.
Highlights
Boiling histotripsy is a High Intensity Focused Ultrasound (HIFU) technique which uses shock wave heating and millisecond boiling to mechanically break down soft tissue without causing significant thermal damage [1]
A high-speed camera and a passive cavitation detection (PCD) system were used to investigate the dynamics of bubbles induced and the corresponding mechanical damage generated in optically transparent tissue-mimicking phantoms with two different boiling histotripsy exposure conditions
Broadband emissions appear in the spectrogram after 3.6 ms, which is an indication of the presence of cavitation clouds during the course of boiling histotripsy exposure [11]
Summary
Boiling histotripsy is a High Intensity Focused Ultrasound (HIFU) technique which uses shock wave heating and millisecond boiling to mechanically break down soft tissue without causing significant thermal damage [1]. A millisecond long shockwave with acoustic peak positive (P+) and negative (P-) pressures at the focus of P+ > 40 MPa and P- < 10 – 15 MPa can raise tissue temperature to 100oC, resulting in the creation of a boiling vapour bubble at the focus [8]. This is possible because enhanced tissue heating caused by shockwaves which contain tens of higher harmonics of the fundamental frequency can lead to a significant temperature rise.
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