[1] [1] C. J. Simon, D. E. Dupuy, W. W. Mayo-Smith, "Microwave ablation: Principles and applications," Radiographics 25, S69–S83 (2005).

[2] [2] G. Carrafiello, D. Lagana, M. Mangini, F. Fontana, G. Dionigi, L. Boni, F. Rovera, S. Cuffari, C. Fugazzola, Microwave tumors ablation: Principles, clinical applications and review of preliminary experiences," Int. J. Surg. 6, S65–S69 (2008).

[3] [3] C. Jones, S. A. Badger, G. Ellis, "The role of microwave ablation in the management of hepatic colorectal metastases," Surgeon 9, 33–37 (2011).

[4] [4] P. Liang, J. Yu, X. L. Yu, X. H. Wang, Q. Wei, S. Y. Yu, H. X. Li, H. T. Sun, Z. X. Zhang, H. C. Liu, Z. G. Cheng, Z. Y. Han, "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," Gut 61, 1100–1101 (2012).

[5] [5] S. Qiu-Jie, H. Zhi-Yu, N. Xiao-Xia, S. Wen-Yuan, S. Yuan-Yuan, H. Liu, L. Xin, L. Ping, "Feasible temperature of percutaneous microwave ablation of dog liver abutting the bowel," Int. J. Hyperthermia 27, 124–131 (2011).

[6] [6] W. He, X. D. Hu, D. F. Wu, L. Guo, L. Z. Zhang, D. Y. Xiang, B. Ning, "Ultrasonography-guided percutaneous microwave ablation of peripheral lung cancer," Clin. Imaging 30, 234–241 (2006).

[7] [7] P. Liang, Y. Wang, "Microwave ablation of hepatocellular carcinoma," Oncology 72, 124–131 (2007).

[8] [8] F. Liu, X. Yu, P. Liang, Z. Cheng, Z. Han, B. Dong, "Contrast-enhanced ultrasound-guided microwave ablation for hepatocellular carcinoma inconspicuous on conventional ultrasound," Int. J. Hyperthermia 27, 555–562 (2011).

[9] [9] X. Yu, F. Liu, P. Liang, A. D. Era, Z. Cheng, Z. Han, "Microwave ablation assisted by a computerised tomography-ultrasonography fusion imaging system for liver lesions: An ex vivo experimental study," Int. J. Hyperthermia 27, 172–179 (2011).

[10] [10] F. C. Henriques, Jr., "Studies of thermal injury; the predictability and the significance of thermally induced rate processes leading to irreversible epidermal injury," Arch. Pathol. (Chic.) 43, 489–502 (1947).

[11] [11] R. Agah, J. A. Pearce, A. J. Welch, M. Motamedi, "Rate process model for arterial tissue thermal damage: Implications on vessel photocoagulation," Lasers Surg. Med. 15, 176–184 (1994).

[12] [12] D. Zhu, Q. M. Luo, G. M. Zhu, W. Liu, "Kinetic thermal response and damage in laser coagulation of tissue," Laser Surg. Med. 31, 313–321 (2002).

[13] [13] C. T. Germer, A. Roggan, J. P. Ritz, C. Isbert, D. Albrecht, G. Muller, H. J. Buhr, "Optical properties of native and coagulated human liver tissue and liver metastases in the near infrared range," Lasers Surg. Med. 23, 194–203 (1998).

[14] [14] J. P. Ritz, A. Roggan, C. T. Germer, C. Isbert, G. Muller, H. J. Buhr, "Continuous changes in the optical properties of liver tissue during laser-induced interstitial thermotherapy," Lasers Surg. Med. 28, 307–312 (2001).

[15] [15] J. P. Ritz, A. Roggan, C. Isbert, G. Muller, H. J. Buhr, C. T. Germer, "Optical properties of native and coagulated porcine liver tissue between 400 and 2400 nm," Laser Surg. Med. 29, 205–212 (2001).

[16] [16] D. Zhu, Q. M. Luo, J. S. Yu, S. Q. Zeng, Y. Ruan, "The coagulation process of biological tissue measured by light scattering," P. Soc. Photo-Opt. Ins. 3863, 407–411 (1999).

[17] [17] W. C. Lin, C. Buttemere, A. Mahadevan-Jansen, "Effect of thermal damage on the in vitro optical and fluorescence characteristics of liver tissues," IEEE J. Sel. Top. Quantum Electron. 9, 162–170 (2003).

[18] [18] C. D. Anderson, W. C. Lin, C. R. Buttemere, M. K. Washington, A. Mahadevan-Jansen, J. Pierce, I. B. Nicoud, C. W. Pinson, R. S. Chari, "Real-time spectroscopic assessment of thermal damage: Implications for radiofrequency ablation," J. Gastrointest Surg. 8, 660–669 (2004).

[19] [19] C. R. Buttemere, R. S. Chari, C. D. Anderson, M. K. Washington, A. Mahadevan-Jansen, W. C. Lin, "In vivo assessment of thermal damage in the liver using optical spectroscopy," J. Biomed. Opt. 9, 1018–1027 (2004).

[20] [20] L. Dai, Z. Qian, K. Li, T. Yang, H. Wang, "In vivo detection of reduced scattering coefficient of C6 glioma in rat brain tissue by near-infrared spectroscopy," J. Biomed. Opt. 13, 044003 (2008).

[21] [21] J. Xie, Z. Qian, T. Yang, W. Li, G. Hu, "Minimally invasive assessment of the effect of mannitol and hypertonic saline therapy on traumatic brain edema using measurements of reduced scattering coefficient (mus')," Appl. Opt. 49, 5407–5414 (2010).

[22] [22] Z. G. Cheng, Q. J. Xiao, Y. Wang, Y. Y. Sun, T. Lu, P. Liang, "915 MHz microwave ablation with implanted internal cooled-shaft antenna: Initial experimental study in in vivo porcine livers," Eur. J. Radiol. 79, 131–135 (2011).

[23] [23] F. Y. Liu, X. L. Yu, P. Liang, Y. Wang, P. Zhou, J. Yu, "Comparison of percutaneous 915 MHz microwave ablation and 2450 MHz microwave ablation in large hepatocellular carcinoma," Int. J. Hyperthermia 26, 448–455 (2010).

[24] [24] Y. Wang, Y. Sun, L. Feng, Y. Gao, X. Ni, P. Liang, "Internally cooled antenna for microwave ablation: Results in ex vivo and in vivo porcine livers," Eur. J. Radiol. 67, 357–361 (2008).

[25] [25] C. L. Brace, P. F. Laeseke, L. A. Sampson, T. M. Frey, D. W. van der Weide, F. T. Lee, Jr., "Microwave ablation with multiple simultaneously powered small-gauge triaxial antennas: Results from an in vivo swine liver model," Radiology. 244, 151– 156 (2007).

[26] [26] W. Shi, P. Liang, Q. Zhu, X. Yu, Q. Shao, T. Lu, Y. Wang, B. Dong, "Microwave ablation: Results with double 915 MHz antennae in ex vivo bovine livers," Eur. J. Radiol. 79, 214–217 (2011).

[27] [27] B. Dong, P. Liang, X. Yu, L. Su, D. Yu, Z. Cheng, J. Zhang, "Percutaneous sonographically guided microwave coagulation therapy for hepatocellular carcinoma: Results in 234 patients," AJR Am. J. Roentgenol. 180, 1547–1555 (2003).

[28] [28] P. Liang, B. Dong, X. Yu, D. Yu, Y. Wang, L. Feng, Q. Xiao, "Prognostic factors for survival in patients with hepatocellular carcinoma after percutaneous microwave ablation," Radiology 235, 299–307 (2005).