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引用次数: 3
摘要
聚焦超声手术(FUS)通常基于5兆赫以下的频率,通常在1兆赫左右。虽然这可以很好地渗透到组织中,但它限制了可以达到的最小病变尺寸。在这里报道的研究中,我们研究了允许更高频率的FUS的设备,因此原则上减小了最小病变尺寸。我们解释了我们使用Y-36°切割铌酸锂构建高频高强度换能器的方法。选择这种材料是因为它的低损耗使它能够在基本工作频率的谐波下进行高频操作。建立了中心频率在6.6 ~ 20.0 MHz范围内的单元件换能器,并测量了换能器的效率和声功率输出。一个聚焦的6.6 mhz换能器由多个元件一起操作组成,并使用超声模体和MRI扫描进行测试。结果显示,在MRI扫描平面上2.5 mm × 3.4 mm的局部区域内,幻相温度升高32°C。因此,这项研究表明,使用铌酸锂生产能够进行高分辨率聚焦超声手术的高频换能器是可行的。
Lithium niobate ultrasound transducers for high-resolution focused ultrasound surgery
Focused ultrasound surgery (FUS) is usually based on frequencies below 5 MHz, typically around 1 MHz. Whilst this allows good penetration into tissue, it limits the minimum lesion dimensions that can be achieved. In the study reported here, we investigated devices to allow FUS at much higher frequencies, therefore in principle reducing the minimum lesion dimensions. We explain the methodology we have used to build high-frequency high-intensity transducers using Y-36° cut lithium niobate. This material was chosen as its low losses give it the potential to allow very high-frequency operation at harmonics of the fundamental operating frequency. A range of single element transducers with a centre frequency between 6.6 MHz and 20.0 MHz was built and the transducers' efficiency and acoustic power output were measured. A focussed 6.6-MHz transducer was built with multiple elements operated together and tested using an ultrasound phantom and MRI scans. It was shown to increase phantom temperature by 32°C in a localised area of 2.5 mm × 3.4 mm in the plane of the MRI scan. This study therefore demonstrates that it is feasible to produce high-frequency transducers capable of high-resolution focused ultrasound surgery using lithium niobate.
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