Li Tong, Chen Hong, Khokhlova Tatiana, Wang Yak-Nam, Kreider Wayne, He Xuemei, Hwang Joo Ha
Center for Industrial and Medical Ultrasound, Applied Physics Laboratory, University of Washington, Seattle, WA, USA.
Center for Industrial and Medical Ultrasound, Applied Physics Laboratory, University of Washington, Seattle, WA, USA.
Ultrasound Med Biol. 2014 Jul;40(7):1523-34. doi: 10.1016/j.ultrasmedbio.2014.01.007. Epub 2014 Mar 6.
Pulsed high-intensity focused ultrasound (pHIFU) has been shown to enhance vascular permeability, disrupt tumor barriers and enhance drug penetration into tumor tissue through acoustic cavitation. Monitoring of cavitation activity during pHIFU treatments and knowing the ultrasound pressure levels sufficient to reliably induce cavitation in a given tissue are therefore very important. Here, three metrics of cavitation activity induced by pHIFU and evaluated by confocal passive cavitation detection were introduced: cavitation probability, cavitation persistence and the level of the broadband acoustic emissions. These metrics were used to characterize cavitation activity in several ex vivo tissue types (bovine tongue and liver and porcine adipose tissue and kidney) and gel phantoms (polyacrylamide and agarose) at varying peak-rare factional focal pressures (1-12 MPa) during the following pHIFU protocol: frequency 1.1 MHz, pulse duration 1 ms and pulse repetition frequency 1 Hz. To evaluate the relevance of the measurements in ex vivo tissue, cavitation metrics were also investigated and compared in the ex vivo and in vivo murine pancreatic tumors that develop spontaneously in transgenic KrasLSL.G12 D/+; p53 R172 H/+; PdxCretg/+ (KPC) mice and closely re-capitulate human disease in their morphology. The cavitation threshold, defined at 50% cavitation probability, was found to vary broadly among the investigated tissues (within 2.5-10 MPa), depending mostly on the water-lipid ratio that characterizes the tissue composition. Cavitation persistence and the intensity of broadband emissions depended both on tissue structure and lipid concentration. Both the cavitation threshold and broadband noise emission level were similar between ex vivo and in vivo pancreatic tumor tissue. The largest difference between in vivo and ex vivo settings was found in the pattern of cavitation occurrence throughout pHIFU exposure: it was sporadic in vivo, but it decreased rapidly and stopped over the first few pulses ex vivo. Cavitation activity depended on the interplay between the destruction and circulation of cavitation nuclei, which are not only used up by HIFU treatment but also replenished or carried away by circulation in vivo. These findings are important for treatment planning and optimization in pHIFU-induced drug delivery, in particular for pancreatic tumors.
脉冲高强度聚焦超声(pHIFU)已被证明可增强血管通透性、破坏肿瘤屏障并通过声空化作用增强药物向肿瘤组织的渗透。因此,在pHIFU治疗期间监测空化活动并了解足以在给定组织中可靠诱导空化的超声压力水平非常重要。在此,介绍了由pHIFU诱导并通过共聚焦被动空化检测评估的三种空化活动指标:空化概率、空化持续性和宽带声发射水平。在以下pHIFU方案期间,这些指标用于表征几种离体组织类型(牛舌、肝脏、猪脂肪组织和肾脏)以及凝胶体模(聚丙烯酰胺和琼脂糖)在不同峰值-稀疏聚焦压力(1-12MPa)下的空化活动:频率1.1MHz、脉冲持续时间1ms和脉冲重复频率1Hz。为了评估离体组织测量的相关性,还对在转基因KrasLSL.G12D/+;p53R172H/+;PdxCretg/+(KPC)小鼠中自发形成且在形态上与人类疾病高度相似的离体和体内小鼠胰腺肿瘤中的空化指标进行了研究和比较。发现以50%空化概率定义的空化阈值在所研究的组织中差异很大(在2.5-10MPa范围内),这主要取决于表征组织组成的水脂比。空化持续性和宽带发射强度均取决于组织结构和脂质浓度。离体和体内胰腺肿瘤组织之间的空化阈值和宽带噪声发射水平相似。在体内和离体环境之间发现的最大差异在于整个pHIFU暴露过程中的空化发生模式:在体内是空散的,但在离体时在最初几个脉冲期间迅速下降并停止。空化活动取决于空化核的破坏与循环之间的相互作用,空化核不仅会被HIFU治疗消耗,还会在体内通过循环进行补充或带走。这些发现对于pHIFU诱导的药物递送中的治疗计划和优化很重要,特别是对于胰腺肿瘤。
