Active Focal Zone Sharpening for High-precision Treatment Using Histotripsy

Overview

Journal IEEE Trans Ultrason Ferroelectr Freq Control

Specialties Biomedical Engineering
Nuclear Medicine

Date 2011 Feb 24

PMID 21342816

Citations 13

Authors

Tzu-Yin Wang

Zhen Xu

Timothy Hall

J Fowlkes

William Roberts

Charles Cain

Affiliations

Soon will be listed here.

Abstract

The goal of this study is to develop a focal zone sharpening strategy that produces more precise lesions for pulsed cavitational ultrasound therapy, or histotripsy. Precise and well-confined lesions were produced by locally suppressing cavitation in the periphery of the treatment focus without affecting cavitation in the center. The local suppression of cavitation was achieved using cavitation nuclei preconditioning pulses to actively control cavitation in the periphery of the focus. A 1-MHz 513-element therapeutic array was used to generate both the therapy and the nuclei preconditioning pulses. For therapy, 10-cycle bursts at 100-Hz pulse repetition frequency with P-/P+ pressure of 21/76 MPa were delivered to the geometric focus of the therapeutic array. For nuclei preconditioning, a different pulse was delivered to an annular region immediately surrounding the focus before each therapy pulse. A parametric study on the effective pressure, pulse duration, and delivery time of the preconditioning pulse was conducted in red blood cell-gel phantoms, where cavitational damage was indicated by the color change resulting from local cell lysis. Results showed that a short-duration (20 μs) preconditioning pulse at a medium pressure (P-/P+ pressure of 7.2/13.6 MPa) delivered shortly before (30 μs) the therapy pulse substantially suppressed the peripheral damage by 77 ± 13% while complete fractionation in the focal center was maintained. High-speed imaging of the bubble cloud showed a substantial decrease in the maximum width of the bubble cloud by 48 ± 24% using focal zone sharpening. Experiments in ex vivo livers confirmed that highly confined lesions were produced in real tissues as well as in the phantoms. This study demonstrated the feasibility of active focal zone sharpening using cavitation nuclei preconditioning, allowing for increased treatment precision compared with the natural focal width of the therapy transducer.

Citing Articles

Transcostal Histotripsy Ablation in an In Vivo Acute Hepatic Porcine Model.

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PMID: 34244841 DOI: 10.1007/s00270-021-02914-1.

Inertial Cavitation Behaviors Induced by Nonlinear Focused Ultrasound Pulses.

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Bubble Cloud Behavior and Ablation Capacity for Histotripsy Generated from Intrinsic or Artificial Cavitation Nuclei.

Edsall C, Khan Z, Mancia L, Hall S, Mustafa W, Johnsen E Ultrasound Med Biol. 2020; 47(3):620-639.

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Dependence of inertial cavitation induced by high intensity focused ultrasound on transducer -number and nonlinear waveform distortion.

Khokhlova T, Rosnitskiy P, Hunter C, Maxwell A, Kreider W, Ter Haar G J Acoust Soc Am. 2018; 144(3):1160.

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