Hynynen Kullervo, Jones Ryan M
Physical Sciences Platform, Sunnybrook Research Institute, Toronto, Canada. Department of Medical Biophysics, University of Toronto, Toronto, Canada. Institute of Biomaterials and Biomedical Engineering, University of Toronto, Toronto, Canada.
Phys Med Biol. 2016 Sep 7;61(17):R206-48. doi: 10.1088/0031-9155/61/17/R206. Epub 2016 Aug 5.
Focused ultrasound offers a non-invasive way of depositing acoustic energy deep into the body, which can be harnessed for a broad spectrum of therapeutic purposes, including tissue ablation, the targeting of therapeutic agents, and stem cell delivery. Phased array transducers enable electronic control over the beam geometry and direction, and can be tailored to provide optimal energy deposition patterns for a given therapeutic application. Their use in combination with modern medical imaging for therapy guidance allows precise targeting, online monitoring, and post-treatment evaluation of the ultrasound-mediated bioeffects. In the past there have been some technical obstacles hindering the construction of large aperture, high-power, densely-populated phased arrays and, as a result, they have not been fully exploited for therapy delivery to date. However, recent research has made the construction of such arrays feasible, and it is expected that their continued development will both greatly improve the safety and efficacy of existing ultrasound therapies as well as enable treatments that are not currently possible with existing technology. This review will summarize the basic principles, current statures, and future potential of image-guided ultrasound phased arrays for therapy.
聚焦超声提供了一种将声能无创地沉积到人体深部的方法,可用于广泛的治疗目的,包括组织消融、治疗剂靶向输送和干细胞递送。相控阵换能器能够对波束几何形状和方向进行电子控制,并可进行定制,以为特定治疗应用提供最佳的能量沉积模式。将其与现代医学成像结合用于治疗引导,可实现超声介导生物效应的精确靶向、在线监测和治疗后评估。过去,存在一些技术障碍阻碍了大孔径、高功率、密集排列相控阵的构建,因此,迄今为止它们尚未被充分用于治疗。然而,最近的研究已使此类阵列的构建成为可能,预计其持续发展将极大地提高现有超声治疗的安全性和有效性,并使现有技术目前无法实现的治疗成为可能。本综述将总结用于治疗的图像引导超声相控阵的基本原理、当前状况和未来潜力。