Antonio Lopez-Marin, Verya Daeichin, Andres Hunt, Geert Springeling, Robert Beurskens, Antonius F W Van der Steen, Gijs Van Soest
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引用次数: 0
Abstract
Multimodal intravascular ultrasound and photoacoustic (IVUS/PA) imaging is a promising diagnostic tool for cardiovascular diseases like atherosclerosis. IVUS/PA catheters typically require two independent transducers due to different frequency requirements, potentially increasing the catheter size. To facilitate multimodal imaging within conventional catheter dimensions, we designed, fabricated, and characterized a dual-transducer acoustic stack where a low-frequency (LF) PA receiver sits as a matching layer for the high-frequency (HF) US transducer. While the HF transducer operates around 50 MHz, the LF receiver targets frequencies below 15 MHz to capture most of the PA energy from atherosclerotic plaque lipids. Simulation results reveal that this configuration could increase the sensitivity of the HF transducer by 3.54 dB while maintaining bandwidth. Phantom experiments with fabricated stacks showed improved performance for the US transducer, validating the enhanced sensitivity and bandwidth. Following improvements in stack fabrication, the proposed acoustic stack is a viable design that can significantly enhance diagnostic accuracy for atherosclerosis, providing high-resolution, multifrequency imaging within a compact catheter form factor.
多模态血管内超声和光声(IVUS/PA)成像是治疗动脉粥样硬化等心血管疾病的一种前景广阔的诊断工具。由于频率要求不同,IVUS/PA 导管通常需要两个独立的传感器,这可能会增加导管的尺寸。为了在传统导管尺寸内实现多模态成像,我们设计、制造并鉴定了一种双换能器声学叠层,其中低频 PA 接收器作为高频 US 换能器的匹配层。高频换能器的工作频率约为 50 兆赫,而低频接收器的目标频率低于 15 兆赫,以捕获动脉粥样硬化斑块脂质的大部分 PA 能量。模拟结果表明,这种配置可将高频换能器的灵敏度提高 3.54 dB,同时保持带宽不变。使用制作好的堆栈进行的模拟实验显示,US 传感器的性能得到了改善,验证了灵敏度和带宽的提高。在改进堆栈制造之后,所提出的声学堆栈是一种可行的设计,可显著提高动脉粥样硬化的诊断准确性,在紧凑的导管外形中提供高分辨率、多频成像。
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.