Super-Resolution Ultrasound Imaging for Analysis of Microbubbles Cluster by Acoustic Vortex Tweezers.

Ching-Hsiang Fan, Wei-Chen Lo, Chung-Han Huang, Thi-Nhan Phan, Chih-Kuang Yeh
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Abstract

Using acoustic vortex tweezers (AVT) to spatially accumulate microbubbles (MBs) shows promise for enhancing drug delivery efficiency and reducing off-target effects. The strong echogenicity of accumulated MBs also improves diagnostics via conventional ultrasound (US) B-mode imaging. However, the annular high-pressure distribution of AVT inhibits MBs inflow at the inlet, reducing MBs collection. The spatial resolution of US B-mode imaging further limits theranostic applications of AVT-mediated MBs accumulation. To address these challenges, we integrated an AVT waveform with volumetric super-resolution imaging (VSRI) to monitor the dynamic growth of MBs cluster during accumulation. We used a 5-MHz 2D array transducer for VSRI, employing plane wave pulses interleaved with accumulating pulses to retain MBs at a flow rate of 0.023-0.047 mL/s in a 3-mm vessel phantom. An asymmetrical AVT waveform (AVT*) was produced by modulating the pressure at the MBs inlet compared to the outlet. The effectiveness was validated in rat cerebral vessels for real-time volumetric tracking of MBs clusters. Microscopy observations showed that AVT* could quickly gather flowing MBs into cluster without repelling them at a flow rate of 0.023 mL/s. Statistical results indicated that microscopic data correlated better with VSRI than with B-mode images, suggesting VSRI suffices to detect the dynamics of AVT*-actuated MBs accumulation in real-time. Additionally, VSRI detected a significant increase in MBs cluster size over time during AVT* in the superior sagittal sinus of the rat brain. These findings demonstrate that the proposed strategy can accumulate the flowing MBs at a desired location and simultaneously observe this phenomenon.

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利用超分辨率超声波成像技术分析声学涡流镊所产生的微气泡簇。
利用声学涡流镊(AVT)在空间积聚微气泡(MBs),有望提高给药效率并减少脱靶效应。积聚的微气泡具有很强的回声性,这也改善了传统超声(US)B 型成像的诊断效果。然而,AVT 的环形高压分布会抑制甲基溴在入口处的流入,从而减少甲基溴的收集。US B 型成像的空间分辨率进一步限制了 AVT 介导的 MBs 聚集的治疗应用。为了应对这些挑战,我们将 AVT 波形与容积超分辨率成像(VSRI)相结合,以监测 MBs 聚集过程中的动态生长。我们使用 5-MHz 二维阵列换能器进行 VSRI,在 3 毫米血管模型中使用平面波脉冲与累积脉冲交错,以 0.023-0.047 毫升/秒的流速保留 MBs。通过调节 MBs 入口与出口的压力,产生了不对称的 AVT 波形(AVT*)。在大鼠脑血管中验证了这种方法的有效性,可用于实时跟踪 MBs 簇的体积。显微镜观察结果表明,在流速为 0.023 毫升/秒的情况下,AVT* 能迅速将流动的甲基溴聚集成团,而不会将其排斥。统计结果表明,显微镜数据与 VSRI 的相关性优于 B 型图像,这表明 VSRI 足以实时检测 AVT* 驱动的 MBs 聚集动态。此外,VSRI 还能检测到大鼠大脑上矢状窦在 AVT* 期间 MBs 簇大小随时间的显著增加。这些研究结果表明,所提出的策略可以在所需位置聚集流动的 MBs,并同时观察这一现象。
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来源期刊
CiteScore
7.70
自引率
16.70%
发文量
583
审稿时长
4.5 months
期刊介绍: IEEE Transactions on Ultrasonics, Ferroelectrics and Frequency Control includes the theory, technology, materials, and applications relating to: (1) the generation, transmission, and detection of ultrasonic waves and related phenomena; (2) medical ultrasound, including hyperthermia, bioeffects, tissue characterization and imaging; (3) ferroelectric, piezoelectric, and piezomagnetic materials, including crystals, polycrystalline solids, films, polymers, and composites; (4) frequency control, timing and time distribution, including crystal oscillators and other means of classical frequency control, and atomic, molecular and laser frequency control standards. Areas of interest range from fundamental studies to the design and/or applications of devices and systems.
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