Ultrasound-cavitation-enhanced drug delivery via microbubble clustering induced by acoustic vortex tweezers

IF 8.7 1区化学 Q1 ACOUSTICS

Ultrasonics Sonochemistry Pub Date : 2025-03-01 DOI:10.1016/j.ultsonch.2025.107273

Ching-Hsiang Fan , Elaine Huang , Wei-Chen Lo , Chih-Kuang Yeh

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引用次数: 0

Abstract

The application of acoustic vortex tweezers (AVT) in conjunction with ultrasound (US) cavitation pulses presents a promising noninvasive approach for the delivery of high concentrations of therapeutic agents. This methodology facilitates the aggregation of drug-loaded microbubbles (MBs) into clusters, which are subsequently destroyed to release their contents. Nevertheless, prior investigations have not thoroughly examined the resonance frequency and cavitation activity of MB clusters, critical factors that could enhance the efficiency of payload release. Theoretically, the resonance frequency of an MB cluster is expected to approximate that of a single large bubble of comparable size, thus being significantly lower than that of the individual MBs constituting the cluster. Accordingly, this study aims to optimize the release of payloads from AVT-trapped MB clusters, which measure 15 to 40 μm (mean radius: 24.7 μm) in size, by employing US at their resonance frequency of 100 kHz, henceforth referred to as “on-resonance US.” In this investigation, MBs were loaded with the model drug DiI, resulting in the formation of DiI-MBs, which were then clustered utilizing AVT. On-resonance US excitation was subsequently applied to enhance the release of the drug payload. The dimensional characteristics of the DiI-MB clusters formed via 3-MHz AVT were measured to determine the range of resonance frequencies. Concurrent optical and acoustic analyses were conducted to evaluate the size, oscillation dynamics, and cavitation activity of the DiI-MB clusters in response to on-resonance US excitation. Additionally, the payload release from these clusters was quantitatively assessed. Our results indicate that significant oscillations of individual DiI-MB clusters commenced at a pressure of 44 kPa during 100 kHz US excitation. Further quantitative experiments demonstrated that the synergistic combination of AVT and 100-kHz US at 65 kPa significantly enhanced the payload release efficiency to 93 %. This efficiency surpassed that achieved with either method independently, with increases of 1.8-fold relative to AVT alone and 2.3-fold compared to 100-kHz US alone. The acoustic analyses revealed the onset of inertial cavitation at 44 kPa, which strongly correlated with payload release efficiency (R² = 0.78). These findings underscore the potential of our proposed methodology in monitoring and enhancing the efficiency of drug release.

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超声空化增强超声涡旋镊子诱导微泡聚类给药。

声学涡旋镊子（AVT）与超声空化脉冲（US）相结合的应用为高浓度治疗剂的输送提供了一种有前途的无创方法。这种方法有助于将载药微泡（mb）聚集成簇，随后将其破坏以释放其内容物。然而，先前的研究并没有彻底研究MB簇的共振频率和空化活性，这是提高有效载荷释放效率的关键因素。理论上，MB集群的共振频率预计接近于大小相当的单个大气泡的共振频率，因此明显低于构成集群的单个MB集群的共振频率。因此，本研究旨在优化avt捕获的MB簇的有效载荷释放，其尺寸为15至40 μm（平均半径：24.7 μm），通过在其共振频率为100 kHz时使用US，因此称为“非共振US”。在本研究中，MBs被加载模型药物DiI，形成DiI-MBs，然后利用AVT聚类。随后应用共振US激发来增强药物有效载荷的释放。测量了通过3mhz AVT形成的DiI-MB簇的尺寸特性，确定了共振频率范围。同时进行了光学和声学分析，以评估DiI-MB簇在非共振US激励下的尺寸、振荡动力学和空化活性。此外，对这些集群的有效载荷释放进行了定量评估。我们的研究结果表明，在100khz US激励下，单个DiI-MB簇在44kpa的压力下开始显著振荡。进一步的定量实验表明，AVT和100 khz US在65 kPa下的协同组合显著提高了有效载荷释放效率，达到93%。这种效率超过了单独使用任何一种方法所达到的效率，相对于单独使用AVT提高了1.8倍，与单独使用100 khz US相比提高了2.3倍。声学分析表明，惯性空化在44 kPa时发生，与载荷释放效率密切相关（R2 = 0.78）。这些发现强调了我们提出的方法在监测和提高药物释放效率方面的潜力。

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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来源期刊

Ultrasonics Sonochemistry 化学-化学综合

CiteScore

15.80

自引率

11.90%

发文量

361

审稿时长

59 days

期刊介绍： Ultrasonics Sonochemistry stands as a premier international journal dedicated to the publication of high-quality research articles primarily focusing on chemical reactions and reactors induced by ultrasonic waves, known as sonochemistry. Beyond chemical reactions, the journal also welcomes contributions related to cavitation-induced events and processing, including sonoluminescence, and the transformation of materials on chemical, physical, and biological levels. Since its inception in 1994, Ultrasonics Sonochemistry has consistently maintained a top ranking in the "Acoustics" category, reflecting its esteemed reputation in the field. The journal publishes exceptional papers covering various areas of ultrasonics and sonochemistry. Its contributions are highly regarded by both academia and industry stakeholders, demonstrating its relevance and impact in advancing research and innovation.