Health and Medical Research Institute, National Institute of Advanced Industrial Science and Technology (AIST), Tsukuba, Japan.
J Med Ultrason (2001). 2021 Apr;48(2):123-135. doi: 10.1007/s10396-021-01083-5. Epub 2021 Apr 1.
In this study, the robustness and feasibility of a noise elimination method using continuous wave response of therapeutic ultrasound signals were investigated when tissue samples were moved to simulate the respiration-induced movements of the different organs during actual high-intensity focused ultrasound (HIFU) treatment. In addition to that, the failure conditions of the proposed algorithm were also investigated.
The proposed method was applied to cases where tissue samples were moved along both the lateral and axial directions of the HIFU transducer to simulate respiration-induced motions during HIFU treatment, and the noise reduction level was investigated. In this experiment, the speed of movement was increased from 10 to 40 mm/s to simulate the actual movement of the tissue during HIFU exposure, with the intensity and driving frequency of HIFU set to 1.0-5.0 kW/cm and 1.67 MHz, respectively. To investigate the failure conditions of the proposed algorithm, the proposed method was applied with the HIFU focus located at the boundary between the phantom and water to easily cause cavitation bubbles. The intensity of HIFU was set to 10 kW/cm.
Almost all HIFU noise was constantly able to be eliminated using the proposed method when the phantom was moved along the lateral and axial directions during HIFU exposure. The noise reduction level (PRL in this study) at an intensity of 1.0, 3.0, and 5.0 kW/cm was in the range of 28-32, 38-40, and 42-45 dB, respectively. On the other hand, HIFU noise was not basically eliminated during HIFU exposure after applying the proposed method in the case of cavitation generation at the HIFU focus.
The proposed method can be applicable even if homogeneous tissues or organs move axially or laterally to the direction of HIFU exposure because of breathing. A condition under which the proposed algorithm failed was when instantaneous tissue changes such as cavitation bubble generation occurred in the tissue, at which time the reflected continuous wave response became less steady.
本研究旨在探讨一种利用治疗超声信号连续波响应消除噪声的方法的稳健性和可行性,当组织样本移动以模拟实际高强度聚焦超声(HIFU)治疗过程中不同器官呼吸引起的运动时。此外,还研究了所提出算法的失效条件。
将所提出的方法应用于组织样本沿 HIFU 换能器的侧向和轴向移动的情况,以模拟 HIFU 治疗过程中的呼吸运动,并研究降噪水平。在该实验中,将运动速度从 10 增加到 40mm/s,以模拟 HIFU 照射过程中组织的实际运动,HIFU 的强度和驱动频率分别设置为 1.0-5.0kW/cm 和 1.67MHz。为了研究所提出算法的失效条件,将所提出的方法应用于 HIFU 焦点位于体模和水之间的边界处,以便于产生空化气泡。HIFU 的强度设置为 10kW/cm。
当组织样本在 HIFU 照射过程中沿侧向和轴向移动时,几乎可以始终使用所提出的方法消除所有 HIFU 噪声。在 1.0、3.0 和 5.0kW/cm 的强度下,降噪水平(本研究中的 PRL)分别在 28-32dB、38-40dB 和 42-45dB 范围内。另一方面,在 HIFU 焦点处产生空化的情况下,应用所提出的方法后,在 HIFU 照射期间,HIFU 噪声基本上没有被消除。
即使由于呼吸导致均匀组织或器官沿 HIFU 照射方向轴向或侧向移动,所提出的方法也可以适用。当组织中发生瞬时变化,例如空化气泡生成时,所提出的算法会失效,此时反射连续波响应变得不太稳定。