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Original Article

Microwave thermal imaging: initial in vivo experience with a single heating zone

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Pages 617-641 | Received 07 Dec 2002, Accepted 28 Apr 2003, Published online: 09 Jul 2009

References

  • Paulsen KD. Noninvasive monitoring and assessment of hyperthermia treatments: trends in current technology. In: Moriarty M, Mothersill C, Seymour C, Edington M, Ward JF, Fry RJM, eds. Proceedings of the 11th International Congress of Radiation Research 2000, Dublin, 18–23 July 1999, Lawrence, KS: Allen Press; 841–4.
  • Overgaard J, Gonzalez-Gonzales D, Hulshof MCCM, Arcangeli G, Dahl 0, Mella 0, Bentzen SM. Randomized trial of hyperthermia as adjuvant to radiotherapy for recurrent or metastatic malignant melanoma. Lancet 1995; 345: 540–3.
  • Van der Zee J, Gonzalez DG, van Rhoon GC, van Dijk JDP, van Putten WLJ, Hart AAM. Comparison of radiotherapy alone with radiotherapy plus hyperthermia in locally advanced pelvic tumors: a prospective, randomised multicentre trial. Lancet 2000; 355: 1119–25.
  • Fenn AJ. An adaptive microwave phased array for targeted heating of deep tumors in intact breast: animal study results. Int J Hypertherrnia 1999; 15: 45–61.
  • Gardner RA, Vargas HI, Block JB, Vogel CL, Fenn AJ, Kuehl GV, Doval M. Focused microwave phased array thermotherapy for primary breast cancer. Ann Surg Oncol 2002; 9: 326–32.
  • Carter DL, MacFall JR, Clegg ST, Wan X, Prescott DM, Charles HC, Samulski TV. Magnetic resonance thermometry during hyperthermia for human high-grade sarcoma. Int J Radiat Oncol Biol Phys 1998; 40: 815–22.
  • Wust P, Konstanczak P, Sander B, Knappe V, Schrunder S, Wlodarczyk W, Frenzel T, Muller G, Felix R. Non-invasive thermometry performed by measuring the chemical shift of a lanthanide complex. In: Franconi C, Arcangeli G, Cavaliere R, eds. Proceedings of the 7th International Congress of Hyperthennic Oncology 1996, Rome, 9–13 April, Rome: Tor Vergatta Post Graduate School of Medical Physics; 11: 436–8.
  • MacFall J, Prescott DM, Fullar E, Samulski TV. Temperature dependence of canine brain tissue diffusion coefficient measured in vivo with magnetic resonance echo-planar imaging. Int J Hyperthermia 1995; 11: 73–86.
  • Webb AG, Wong M, Niesman M, Kolbeck KJ, Wilmes LJ, Magin RL, Suslick KS. In-vivo NMR thermometry with liposomes containing Co complexes. Int J Hypertherrnia 1995; 11: 821–7.
  • DePorter J, De Wagter C, De Deene Y, Thomsen C, Stahlberg TF, Achten E. The proton-resonance-frequency-shift method compared with molecular diffusion for quantitative measurement of two-dimensional time dependent temperature distributions in a phantom. J Magn Reson Series B 1994; 103: 2340–1.
  • McDannold N, King RL, Jolesz FA, Hynynen K. The use of quantitative temperature images to predict the optimal power for focused ultrasound surgery: in vivo verification in rabbit muscle and brain. Med Phys 2002; 29: 356–65.
  • Daum DR, Hynynen K. A 256-element ultrasonic phased array system for the treatment of large volumes of deep-seated tissue. IEEE Trans Ultrason Ferroelec Freq Cont 2001; 46: 1254–68.
  • Siep R, Ebbini ES. Noninvasive estimation of tissue temperature response of heating fields using diagnostic ultrasound. IEEE Trans Biorned Eng 1995; 42: 828–39.
  • Siep R, VanBaren P, Cain CA, Ebbini ES. Noninvasive real-time multipoint temperature control for ultrasound phased array treatments. IEEE Trans Ultrason Ferroelec Freq Cont 1996; 43: 1063–73.
  • Simon C, VanBaren P, Ebbini ES. Motion compensation algorithm for two-dimensional temperature estimation using diagnostic pulse-echo ultrasound. In: Surgical Applications of Energy, Proceedings of SPIE 1998; 3249: 182–92.
  • Chive M. Use of microwave radiometry for hyperthermia monitoring and as a basis for thermal dosimetry. In: Gautherie M, ed. Methods of Hypertherrnia Control, Clinical Therrnology Series (Therrnotherapy), New York: Springer-Verlag, 1990; 113–28.
  • Dubois L, Pribetich J, Fabre J, Chive M, Moschetto Y. Non-invasive microwave multi-frequency radiometry used in microwave hyperthermia for bi-dimensional reconstruction of temperature patterns. Int J Hypertherrnia 1993; 9: 415–43.
  • Mizushina S, Ohba H, Abe K, Sugiura T, Kondoh K, Nakamura Y, Mamouni A, Leroy A. Temperature profiling using multifrequency microwave radiometry. In: Franconi C, Arcangeli G, Cavaliere R, eds. Proceedings of the 7th International Congress of Hypertherrnic Oncology 1996, II: 416–8.
  • Stauffer PR, Jacobsen S, Neuman D, Rossetto F. Progress toward radiometry controlled conformal microwave array hyperthermia applicator. 22nd Annual EMBS International Conference, Chicago, IL, 2000; 1613–6.
  • Stauffer PR, Neuman D, Jacobsen S, Rossetto F. Conformal microwave array applicator for heating and radiometric thermometry of large area superficial disease. Progress in Electromagnetic Research Symposium, Cambridge, MA, 2002; 866.
  • Jacobsen S, Stauffer PR, Neuman DG. Dual-mode antenna design for microwave heating and noninvasive thermometry of superficial tissue disease. IEEE Trans Biorned Eng 2000; 47: 1500–9.
  • Jacobsen S, Stauffer PR. Non-parametric 1-D temperature restoration in lossy media using Tikhonov regularization on sparse radiometry data. IEEE Trans Biorned Eng 2003; 50: 178–88.
  • Duck FA. Physical properties of tissues: a comprehensive reference book, London: Academic Press; 1990.
  • Hasted JB. Aqueous Dielectrics, London: Chapman and Hall; 1972.
  • Von Hippel AR, ed. Dielectric Materials and Applications, New York: The Technology Press of MIT and Wiley & Sons, Inc.; 1954.
  • Stogryn A. Equations for Calculating the Dielectric Constant of Saline Water. IEEE Trans Microwave Theo Tech 1971; 19: 733–6.
  • Bolomey J, Hawley M. Non-invasive control of hyperthermia. In: Gautherie M, ed. Methods of Hypertherrnia Control, Clinical Therrnology Series (Therrnotherapy), New York: Springer-Verlag, 1990; 35–111.
  • Blad B, Persson B, Lindstrom K. Quantitative assessment of impedance tomography for temperature measurements in hyperthermia. Int J Hypertherrnia 1992; 8: 33–43.
  • Hawley MS, Conway J, Amasha H, Mangnall YF, Van Rhoon GC. Electrical impedance tomography: prospects for non-invasive control of deep hyperthermia treatments. Frontiers Med Biol Eng 1992; 4: 119–28.
  • Paulsen KD, Moskowitz MJ, Ryan TP, Mitchell SE, Hoopes PJ. Initial in-vivo experience with EIT as a thermal estimator during hyperthermia. Int J Hypertherrnia 1996; 12: 573–91.
  • Moskowitz MJ, Paulsen KD, Ryan TP, Pang D. Temperature field estimation using electrical impedance profiling methods: II experimental system description and phantom results. Int J Hypertherrnia 1994; 10: 229–45.
  • Moskowitz MJ, Ryan TP, Paulsen KD, Mitchell SE. Clinical implementation of electrical impedance tomography with hyperthermia. Int J Hypertherrnia 1995; 11: 141–9.
  • Chang JT, Paulsen KD, Meaney PM, Fanning M. Noninvasive thermal assessment of tissue phantoms using an active near field microwave imaging technique. Int J Hypertherrnia 1998; 14: 513–34.
  • Mallorqui .1.1, Broquetas A, Jofre L, Cardama A. Noninvasive active microwave thermo-metry with a microwave tomographic scanner in hyperthermia treatments. ACES J 1992; 7: 121–7.
  • Miyakawa M. Tomographic measurement of temperature change in phantoms of the human body by chirp radar-type microwave computed tomography. Med Biol Eng Cornput 1993; 31: S31–6.
  • Bertero M, Miyakawa M, Boccacci P, Conte F, Orikasa K, Furutani M. Image restoration in chirp-pulse microwave CT (CP-MCT). IEEE Trans Biorned Eng 2000; 47: 690–9.
  • Meaney PM, Paulsen KD, Ryan TP. Two-dimensional hybrid element image reconstruc-tion for TM illumination. IEEE Trans Anten Propag 1995; 43: 239–47.
  • Meaney PM, Paulsen KD, Chang JT. Near-field microwave imaging of biologically-based materials using a monopole transceiver system. IEEE Trans Microwave Theo Tech 1998; 46: 31–45.
  • Meaney PM, Paulsen KD, Chang JT, Fanning M. Compensation for nonactive array element effects in a microwave imaging system: part IIimaging results. IEEE TransMed Irnag 1999; 18: 508–18.
  • Slaney M, Kak AC, Larsen LE. Limitations of imaging with first-order diffraction tomography. IEEE Trans Microwave Theo Tech 1984; 32: 860–74.
  • Meaney PM, Paulsen KD, Pogue BW, Miga MI. Microwave image reconstruction utilizing log-magnitude and unwrapped phase to improve high-contrast object recovery. IEEE Trans Med Irnag 2001; 20: 104–16.
  • Meaney PM, Paulsen KD, Fanning MW, Li D, Fang Q. Image accuracy improvements in microwave tomographic thermometry: phantom experience. Int .1 Hypertherrnia 2003; 19: 534–550.
  • Semenov SY, Svenson RH, Bulyshev AE, Souvorov AE, Nazarov AG, Sizov YE, et al. Three-dimensional microwave tomography: initial experimental imaging of animals. IEEE Trans Biorned Eng 2002; 49: 55–63.
  • Meaney PM, Fanning MW, Li D, Poplack SP, Paulsen KD. A clinical prototype for active microwave imaging of the breast. IEEE Trans Microwave Theo Tech 2000; 48: 1841–53.
  • Bolomey JC, Joisel A, Gaboriaud G. Applications of microwave active imaging in medicine: past and present. IEEE Colloq App Microwaves Med 1995; 3/1–3/5.
  • Joisel A, Bolomey JC, Gaboriaud G, Lagendijk J, van Dijk J. The impact of microwave imaging on the control of deep hyperthermia treatments. In: Gerner EW, ed. Proceedings of the 6th International Conference on Hypertherrnia Oncology, Arizona Board of Regents, 1992; 206.
  • Meaney PM, Paulsen KD, Hartov A, Crane RK. An active microwave imaging system for reconstruction of 2-D electrical property distributions. IEEE Trans Biorned Eng 1995; 42: 1017–26.
  • Paulsen KD, Meaney PM, Moskowitz MJ, Sullivan Jr JM. A dual mesh scheme for finite element based reconstruction algorithms. IEEE Trans Med Irnag 1996; 14: 504–14.
  • Fang Q, Meaney PM, Geimer SA, Paulsen KD. Microwave image reconstruction from 3D fields coupled to 2D parameter estimation. IEEE Trans Med Irnag 2002; in press.
  • Li D, Meaney PM, Paulsen KD. Conformal microwave imaging for breast cancer detection. IEEE Trans Microwave Theo Tech 2003; 51: 1179–1186.
  • Meaney PM, Paulsen KD, Geimer S, Haider S, Fanning MW. Quantification of 3D field effects during 2D microwave imaging. IEEE Trans Biorned Eng 2002; 49: 708–20.
  • Meaney PM, Demidenko E, Yagnamurthy NK, Li D, Fanning MW, Paulsen KD. A two-stage microwave image reconstruction procedure for improved internal feature extraction. Med Phys 2001; 28: 2358–69.
  • Bolomey JC, Pichot C, Gaboriaud G.. Planar microwave imaging camera for biomedical applications: critical and prospective analysis of reconstruction algorithms. Radio Sci 1991; 26: 541–50.
  • Meaney PM, Pendergrass SA, Fanning MW, Li D, Paulsen KD. Importance of using a reduced contrast coupling medium in 2D microwave imaging. JEMWA 2003; 17: 333–335.

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