Bubble Cloud Characteristics and Ablation Efficiency in Dual-Frequency Intrinsic Threshold Histotripsy

TL;DR

This study explores how dual-frequency pulsing schemes influence bubble cloud behavior and improve ablation efficiency in intrinsic threshold histotripsy, enabling more precise tissue destruction.

Contribution

It demonstrates that dual-frequency histotripsy can modulate bubble dynamics and enhance ablation efficiency beyond single-frequency methods.

Findings

Dual-frequency pulses produce intermediate bubble cloud sizes.

Early pulse arrival improves cloud uniformity.

Dual-frequency ablation yields smaller, more precise lesions.

Abstract

Histotripsy is a non-thermal focused ultrasound ablation method that destroys tissue through the generation and activity of acoustic cavitation. Intrinsic threshold histotripsy generates bubble clouds when the dominant negative pressure phase of a single-cycle pulse exceeds an intrinsic threshold of ~25-30 MPa. The ablation efficiency is dependent upon the size and density of bubbles within the bubble cloud. This work investigates the effects of dual-frequency pulsing schemes on the bubble cloud behavior and ablation efficiency in intrinsic threshold histotripsy. A modular histotripsy transducer applied dual-frequency histotripsy pulses to tissue phantoms with a 1:1 pressure ratio from 500 kHz and 3 MHz frequency elements and varying the 3 MHz pulse arrival relative to the arrival of the 500 kHz pulse (-100 ns, 0 ns, and +100 ns). High-speed optical imaging captured cavitation effects to characterize bubble cloud and individual bubble dynamics. Lesion formation and ablation efficiency were also investigated in red blood cell (RBC) phantoms. Results showed that the single bubble and bubble cloud size for dual-frequency cases were intermediate to published results for the component single frequencies of 500 kHz and 3 MHz. Bubble cloud size and dynamics were also shown to be altered by the arrival time of the 3 MHz pulse relative to the 500 kHz pulse, with more uniform cloud expansion and collapse observed for early (-100 ns) arrival. Finally, RBC phantom experiments showed that dual-frequency exposures were capable of generating precise lesions with smaller areas and higher ablation efficiencies than previously published results for 500 kHz or 3 MHz. Overall, results demonstrate dual-frequency histotripsy's ability to modulate bubble cloud size and dynamics can be leveraged to produce precise lesions at higher ablation efficiencies than previously observed for single-frequency pulsing.