微波消融有效消融体积模型实验研究

doi:10.3969/j.issn.0258-8021.2014. 01.08

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摘要针对微波消融治疗需要监测消融区域的温度变化状态和获取有效消融体积的问题，通过离体猪肝实验，分析了消融区域的温升规律并建立了微波消融有效消融体积的数学模型。共进行了112例离体猪肝实验，采用40~70 W的不同微波功率和300~600 s的不同作用时间进行微波消融。实验在70 W微波功率作用下，实时采集了距离微波消融针5、10、15、20 mm处的毁损区域温度，对采用不同微波功率和作用时间得到的有效消融区域的短径、长径及体积数据进行了分析，并利用1stopt软件进行拟合。结果显示，消融区域不同位置的升温速度不同，距离微波针5 mm位置的升温速度为20 mm处的10倍左右；得到了有效消融区域的短径、长径和体积有关微波功率和作用时间的离体组织数学模型。消融区域的温升状态监测和有效消融体积模型的建立，有助于优化微波消融的术前治疗计划和进行实时消融治疗的效果评估。

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	赵金哲¹钱志余^1*刘珈^{2 &nb}

关键词 ：微波消融, 毁损区域, 体积模型, 手术计划

Abstract：Temperature variation in ablated area and effective ablation volume are very important parameters for microwave ablation treatment. In order to provide reference for realtime assessment of ablation efficacy, in vitro porcine liver experiments were carried out to monitor tissue temperature and build effective microwave ablation volume models in this work. Microwave power of 40~70 W and ablation time of 300~600 s were chosen to perform total 112 microwave ablations. The microwave power of 70 W was used in the first group of experiments and temperature changes at sites 5, 10, 15 and 20 mm away from microwave antenna were recorded in realtime during ablation. In the second group of experiments, different combinations of power and time produced a series of data of short axis, long axis and volume. Results showed that the increase of temperature near the microwave antenna was more rapid. Temperature rise at 5 mm away from the antenna was 10 times faster than that at 20 mm away. Volume data of the ablation area was analyzed using 1stopt to build experimental models for the short axis, long axis and volume of the ablation zone. Consequently, the monitoring of temperature and utilization of effective volume models will contribute to the microwave ablation surgical planning and realtime ablation efficacy assessment.

Key words： microwave ablation ablation zone volume model surgical planning

基金资助:国家自然科学基金（61275199）；江苏省普通高校研究生科研创新计划资助项目（CXLX13_147）

引用本文:

赵金哲¹钱志余^1*刘珈^{2 &nb. 微波消融有效消融体积模型实验研究[J]. 中国生物医学工程学报, 2014, 33(1): 51-56.

ZHAO Jin Zhe¹QIAN Zhi Yu^1* LIU Jia²WU Jia Li¹WANG . Experimental Study on Effective Microwave Ablation Volume Model. journal1, 2014, 33(1): 51-56.}

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http://cjbme.csbme.org/CN/10.3969/j.issn.0258-8021.2014. 01.08 或 http://cjbme.csbme.org/CN/Y2014/V33/I1/51

［1］Liang Ping, Dong Baowei, Yu Xiaoling, et al. Prognostic factors for percutaneous microwave coagulation therapy of hepatic metastases ［J］. Am J Roentgenol, 2003, 181(5): 1319-1325.
［2］Simon CJ, Dupuy DE, MayoSmith WW. Microwave ablation: principles and applications ［J］. Radiographics, 2005, 25(Suppl 1): S69-S83.
［3］刘静, 邓中山. 肿瘤热疗物理学［M］. 北京：科学出版社, 2008: 8-9
［4］唐劲天. 肿瘤热疗生物学［M］. 北京：人民卫生出版社, 2010: 115-122
［5］Liang Ping, Yu Jie, Yu Xiaoling, et al. Percutaneous cooledtip microwave ablation under ultrasound guidance for primary liver cancer: a multicentre analysis of 1363 treatmentnaive lesions in 1007 patients in China ［J］. Gut, 2012, 61(7): 1100-1101.
［6］Liang Ping, Wang Yang, Yu XiaoLing, et al. Malignant liver tumors: treatment with percutaneous microwave ablationcomplications among cohort of 1136 patients ［J］. Radiology, 2009, 251(3): 933-940.
［7］Bhardwaj N, Strickland AD, Ahmad F, et al. Microwave ablation for unresectable hepatic tumours: clinical results using a novel microwave probe and generator ［J］. European Journal of Surgical Oncology(EJSO), 2010, 36(3): 264-268. 
［8］Wolf FJ, Grand DJ, Machan JT, et al. Microwave ablation of lung malignancies: effectiveness, CT findings, and safety in 50 patients ［J］. Radiology, 2008, 247(3): 871-879.［9］Castle SM, Salas N, Leveillee RJ. Initial experience using microwave ablation therapy for renal tumor treatment: 18-month followup ［J］. Urology, 2011, 〖STHZ〗77〖STBZ〗(4): 792-797.
［10］Yu Jie, Liang Ping, Yu Xiaoling, et al. Ultrasoundguided percutaneous microwave ablation of splenic metastasis: report of four cases and literature review ［J］. International Journal of Hyperthermia, 2011, 27(5): 517-22.
［11］李欣. 超声引导下微波消融治疗肝癌的研究进展［J］. 肿瘤学杂志, 2010,16(7): 523-526.
［12］Brace CL, Laeseke PF, van der Weide DW, et al. Microwave ablation with a triaxial antenna: results in ex vivo bovine liver ［J］. IEEE Transactions on Microwave Theory and Techniques, 2005, 53(1): 215-220.
［13］曹兵生, 董宝玮, 黎晓林, 等. 扩大微波凝固范围和改善凝固形状的实验研究［J］. 中华超声影像学杂志, 2006, 15(8): 621-623.
［14］孙媛媛, 梁萍, 董宝玮, 等. 水冷915 MHz与2450 MHz微波凝固离体猪肝的比较［J］. 中国医学影像技术, 2007, 23(2): 177-180.
［15］Brace CL, Laeseke PF, Sampson LA, et al. Microwave ablation with multiple simultaneously powered smallgauge triaxial antennas: Results from an in vivo swine liver model1 ［J］. Radiology, 2007, 244(1): 151-156.
［16］Yang Deshan, Converse MC, Mahvi DM, et al. Measurement and analysis of tissue temperature during microwave liver ablation ［J］. IEEE Transactions on Biomedical Engineering, 2007, 54(1): 150-155.
［17］Shi Wenyuan, Liang Ping, Zhu Qiang, et al. Microwave ablation: results with double 915 MHz antennae in ex vivo bovine Livers ［J］. European journal of radiology, 2011, 79(2): 214-217.
［18］Jones C, Badger S A, Ellis G. The role of microwave ablation in the management of hepatic colorectal metastases ［J］. The Surgeon, 2011, 9(1): 33-37.
［19］Kuang Ming, Lu Ming D, Xie Xiao Y, et al. Liver Cancer: Increased microwave delivery to ablation zone with cooledshaft antennaexperimental and clinical studies ［J］. Radiology, 2007, 242(3): 914-924.
［20］Wang Yang, Sun Yuanyuan, Feng Lei, et al. Internally cooled antenna for microwave ablation: results in ex vivo and in vivo porcine livers ［J］. European Journal of Radiology, 2008, 67(2): 357-361.
［21］Cheng Zhigang, Xiao Qiujin, Wang Yang, et al. 915MHz microwave ablation with implanted internal cooledshaft antenna: Initial experimental study in in vivo porcine livers ［J］. European Journal of Radiology, 2011, 79(1): 131-135.
［22］Liang Ping Wang Yang. Microwave ablation of hepatocellular carcinoma ［J］. Oncology, 2007, 72(Suppl 1): 124-131.
［23］Keangin P, Wessapan T, Rattanadecho P. Analysis of heat transfer in deformed liver cancer modeling treated using a microwave coaxial antenna ［J］. Applied Thermal Engineering, 2011, 31(16): 3243-3254.
［24］张烨，钱志余，郭金涛，等. 肿瘤微波热消融有效毁损区域温度场分布的仿真研究［J］. 生物物理学报, 2012, 28(9): 763-770.