第 42 卷 第 6 期         陈燕华等： 高强度聚焦超声治疗子宫肌瘤中水囊耦合的影响评估                                         1199


                 该评估体系可为进一步实验研究最佳的水囊                               35(1): 419–434.
             耦合方式奠定基础。基于当前研究，作者下一步研                             [14] Arkin H, Xu L X, Holmes K R. Recent developments in
                                                                   modeling heat transfer in blood perfused tissues[J]. IEEE
             究工作将设计离体组织和活体实验来分析评估真
                                                                   Transactions on Biomedical Engineering, 1994, 41(2):
             实情况下水囊对治疗效率和成像质量的影响。                                  97–107.
                                                                [15] Papadacci C, Pernot M, Couade M, et al. High-contrast
                                                                   ultrafast imaging of the heart[J]. IEEE Transactions on
                            参 考     文   献                          Ultrasonics, Ferroelectrics, and Frequency Control, 2014,
                                                                   61(2): 288–301.
              [1] Quinn S D, Gedroyc W M. Thermal ablative treatment of  [16] Correia M, Provost J, Chatelin S, et al. Ultrafast har-
                 uterine fibroids[J]. International Journal of Hyperthermia,  monic coherent compound (UHCC) imaging for high
                 2015, 31(3): 272–279.                             frame rate echocardiography and shear-wave elastogra-
                                                                   phy[J]. IEEE transactions on Ultrasonics, Ferroelectrics,
              [2] Donnez J, Dolmans M M. Uterine fibroid management:
                 from the present to the future[J]. Human Reproduction  and Frequency Control, 2016, 63(3): 420–431.
                 Update, 2016, 22(6): 665–686.                  [17] Montaldo G, Tanter M, Bercoff J, et al. Coherent plane-
              [3] Elhelf I A S, Albahar H, Shah U, et al.  High inten-  wave compounding for very high frame rate ultrasonogra-
                 sity focused ultrasound: the fundamentals, clinical appli-  phy and transient elastography[J]. IEEE Transactions on
                 cations and research trends[J]. Diagnostic and Interven-  Ultrasonics, Ferroelectrics, and Frequency Control, 2009,
                 tional Imaging, 2018, 99(6): 349–359.             56(3): 489–506.
              [4] Izadifar Z, Izadifar Z, Chapman D, et al. An introduction  [18] Matrone G, Savoia A S, Caliano G, et al. The delay mul-
                 to high intensity focused ultrasound: systematic review on  tiply and sum beamforming algorithm in ultrasound B-
                 principles, devices, and clinical applications[J]. Journal of  mode medical imaging[J]. IEEE Transactions on Medical
                 Clinical Medicine, 2020, 9(2): 460.               Imaging, 2014, 34(4): 940–949.
              [5] Shehata I A. High intensity focused ultrasound: Imag-  [19] 王浩, 徐祥, 贺庆, 等. 基于平均短阶相干系数的平面波复合
                 ing is the key![J]. Diagnostic and Interventional Imaging,  成像算法 [J]. 生物医学工程研究, 2019, 38(4): 403–409.
                 2014, 95(6): 569–572.                             Wang Hao, Xu Xiang, He Qing, et al. Coherent plane-
              [6] Casarotto R A, Adamowski J C, Fallopa F, et al. Coupling  wave compounding weighted by average short-lag coher-
                 agents in therapeutic ultrasound: acoustic and thermal  ence factor[J]. Journal of Biomedical Engineering Re-
                 behavior[J]. Archives of Physical Medicine and Rehabili-  search, 2019, 38(4): 403–409.
                 tation, 2004, 85(1): 162–165.                  [20] Yuan X, Borup D, Wiskin J W, et al. Formulation and
              [7] ter Haar G, Coussios C. High intensity focused ultrasound:  validation of Berenger’s PML absorbing boundary for the
                 physical principles and devices[J]. International Journal of  FDTD simulation of acoustic scattering[J]. IEEE Trans-
                 Hyperthermia, 2007, 23(2): 89–104.                actions on Ultrasonics, Ferroelectrics, and Frequency Con-
              [8] Reeve D M. Diagnostic ultrasound: physics and equip-  trol, 1997, 44(4): 816–822.
                 ment[J]. Journal of Nuclear Medicine, 2012, 53(6): 1004.  [21] Berenger J P. A perfectly matched layer for the absorp-
              [9] 杜功焕. 声学基础 [M]. 南京: 南京大学出版社, 2001.                tion of electromagnetic waves[J]. Journal of Computa-
             [10] Nowicki A. Safety of ultrasonic examinations:  ther-  tional Physics, 1994, 114(2): 185–200.
                 mal and mechanical indices[J]. Medical Ultrasonography,  [22] Yuan X, Borup D, Wiskin J, et al. Simulation of acous-
                 2020, 22(2): 203–210.                             tic wave propagation in dispersive media with relax-
             [11] Westervelt P J. Parametric acoustic array[J]. The Journal  ation losses by using FDTD method with PML absorbing
                 of the acoustical society of America, 1963, 35(4): 535–537.  boundary condition[J]. IEEE Transactions on Ultrasonics,
             [12] Roohi R, Baroumand S, Hosseinie R, et al. Numerical  Ferroelectrics, and Frequency Control, 1999, 46(1): 14–23.
                 simulation of HIFU with dual transducers: the implemen-  [23] 桂逢烯, 郑昊, 李雁浩, 等. 高强度聚焦超声间歇式治疗中焦
                 tation of dual-phase lag bioheat and non-linear Westervelt  域温度分布的仿真研究 [J]. 应用声学, 2021, 40(3): 383–390.
                 equations[J]. International Communications in Heat and  Gui Fengxi, Zheng Hao, Li Yanhao, et al.  Simula-
                 Mass Transfer, 2021, 120: 105002.                 tion research on temperature distribution in focal re-
             [13] Gupta P, Srivastava A. Numerical analysis of thermal re-  gion during high intensity focused ultrasound intermittent
                 sponse of tissues subjected to high intensity focused ul-  treatment[J]. Journal of Applied Acoustics, 2021, 40(3):
                 trasound[J]. International Journal of Hyperthermia, 2018,  383–390.