References
- Seebass M, Reck R, Gellermann J, Nadobny J, Wust P. Electromagnetic phased arrays for regional hyperthermia: Optimal frequency and antenna arrangement. Int J Hyperthermia 2001; 17: 321–336
- Nadobny J, Fahling H, Hagmann MJ, Turner PF, Wlodarczyk W, Gellermann JM, Wust P. Experimental and numerical investigation of feed-point parameters in a 3-D hyperthermia applicator using different FDTD models of feed networks. IEEE Trans Biomed Eng 2002; 49: 1348–1359
- Gellermann J, Wlodarczyk W, Hildebrandt B, Ganter H, Nicolau A, Rau B, Tilly W, Fahling H, Nadobny J, Felix R, et al. Noninvasive magnetic resonance thermography of recurrent rectal carcinoma in a 1.5 Tesla hybrid system. Cancer Res 2005; 65: 5872–5880
- Nadobny J, Wlodarczyk W, Westhoff L, Gellermann J, Felix R, Wust P. A clinical water-coated antenna applicator for MR-controlled deep-body hyperthermia: A comparison of calculated and measured 3-D temperature data sets. IEEE Trans Biomed Eng 2005; 52: 505–519
- Lynn JG, Zwemer RL, Chick AJ, Miller AE. A new method for the generation and use of focused ultrasound in experimental biology. J Gen Physiol 1942; 26: 179–193
- Hynynen K, Clement GT, McDannold N, Vykhodtseva N, King R, White PJ, Vitek S, Jolesz J. A 500-element ultrasound phased array system for noninvasive focal surgery of the brain: A preliminary rabbit study with ex vivo human skulls. Magn Reson Med 2004; 52: 100–107
- McDannold N, Tempany CM, Fennessy FM, So MM, Rybicki FJ, Stewart EA, Jolesz FA, Hynynen K. Uterine leiomyomas: MR imaging-based thermometry and thermal dosimetry during focused ultrasound thermal ablation. Radiology 2006; 240: 263–272
- Furusawa H, Namba K, Thomasen S, Akiyama F, Bendet A, Tanaka C, Yasuda Y, Nakahara H. Magnetic resonance-guided focused ultrasound surgery of breast cancer: Reliability and effectiveness. J Am Coll Surg 2006; 203: 54–63
- Fujisawa K. General treatment of klystron resonant cavities. IRE Trans Microwave Theory and Tech 1958; 6: 344–358
- Giordano M, Momo F, Sotgiu A. On the design of a re-entrant square cavity as resonator for low-frequency ESR spectroscopy. J Phys E: Sci Instrum 1983; 16: 774–779
- Matsuda J, Kato K, Saitoh Y. The application of a re-entrant type resonant cavity applicator to deep and concentrated hyperthermia. Japan J Hyperthermia Oncol 1988; 4: 111–118
- Kato K, Wadamori N, Matsuda J, Uzuka T, Takahashi H, Tanaka R. Improvement of the resonant cavity applicator for brain tumor hyperthermia. Proc IEEE EMBS 2003; 25: 3271–3274
- Wadamori N, Matsuda J, Takahashi H, Grinev I, Uzuka T, Tanaka R. Heating properties of a re-entrant cavity-type applicator for deep regional hyperthermia treatments. Proc 9th Int Congress Hyperthermic Oncol. 2004, 169
- Ishihara Y, Gotanda Y, Wadamori N, Matsuda J. Hyperthermia applicator based on reentrant cavity for localized head and neck tumors. Rev Sci Inst 2007; 72: 243011–243018
- Taguchi G, Chowdhury S, Wu Y, Taguchi S, Yano H. Taguchi's Quality Engineering Handbook. John Wiley & Sons, Inc., Hoboken, NJ 2004
- Ishihara Y, Minegishi Y, Wadamori N. A heating applicator based on a reentrant cavity with optimized local heating characteristics. STM/WCIO Joint Annual Meeting. Washington, DC 2007; 232–233
- Slater JC. Microwave electronics. Dover, New York 1969
- Pennes H. Analysis of tissue and arterial blood temperatures in the resting human forearm. J Appl Physiol 1948; 1: 93–122
- Leonard JB, Foster KR, Athey TW. Thermal properties of tissue equivalent phantom materials. IEEE Trans Biomed Eng 1984; 31: 533–536
- Ishihara Y, Endo Y, Wadamori N, Ohwada H. A noninvasive temperature measurement regarding the heating applicator based on a reentrant cavity. STM/WCIO Joint Annual Meeting. Washington, DC 2007; 230–231
- Ishihara Y, Endo Y, Ohwada H, Wadamori N. Noninvasive thermometry in a reentrant resonant cavity applicator. 29th IEEE EMBS Annual International Conference, Lyon, 2007, 1487–1490