A Dual-Frequency Intravascular Ultrasound Transducer for Amplified Nanodroplet Vaporization Effects in Cavitation-Enhanced Sonothrombolysis

2022 IEEE International Ultrasonics Symposium (IUS) Pub Date : 2022-10-10 DOI:10.1109/IUS54386.2022.9958578

Sunho Moon, Huaiyu Wu, Bohua Zhang, Jinwook Kim, P. Dayton, Zhen Xu, Xiaoning Jiang

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Abstract

Thromboembolism often leads to stroke, myocardial infarction, and other severe complications. There remains a need for new technologies for clinical thrombosis treatment. Sonothrombolysis mediated with cavitation-enhancing agents has shown promise in the treatment of thromboembolism in preclinical studies and clinical trials. Recent works have emphasized specifically efficient sonothrombolysis using phase-change nanodroplets, likely due to their generation of cavitation within the clot matrix. Yet, it has also been reported that nanodroplets might vaporize more effectively under high-frequency excitation and generate more cavitation with low-frequency excitation. Therefore, in this work, a dual-frequency (10 MHz/500 kHz) intravascular transducer intended for nanodroplet-specific sonothrombolysis was developed to improve clot mass reduction rate while retaining lower acoustic pressures than the typical nanodroplet vaporization threshold at sub-megahertz excitation (> 5 MPa). It results in a 34 % improvement of thrombolysis efficiency compared to a single low-frequency excitation.

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一种用于空化增强超声溶栓中放大纳米液滴汽化效应的双频血管内超声换能器

血栓栓塞常导致中风、心肌梗死和其他严重并发症。临床血栓治疗仍然需要新的技术。超声溶栓介导的空化增强剂在治疗血栓栓塞的临床前研究和临床试验中显示出前景。最近的研究强调了使用相变纳米液滴的特别有效的超声溶栓，可能是由于它们在凝块基质中产生空化。然而，也有报道称，在高频激励下，纳米液滴可能会更有效地蒸发，而在低频激励下，纳米液滴会产生更多的空化。因此，在这项工作中，研究人员开发了一种用于纳米液滴特异性超声溶栓的双频(10 MHz/500 kHz)血管内换能器，以提高凝块质量减少率，同时保持比亚兆赫激励(> 5 MPa)下典型纳米液滴汽化阈值更低的声压。与单一低频激发相比，它可使溶栓效率提高34%。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2022 IEEE International Ultrasonics Symposium (IUS)

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