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International Journal of Hyperthermia Volume 12, 1996 - Issue 3
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Original Article

Design of an ultrasonic therapy system for breast cancer treatment

X-Q. Lu Joint Center for Radiation Therapy, Department of Radiation Oncology, Harvard Medical School, Boston, MA, 02115, USA
,
E. C. Burdette Dornier Medical Systems Inc., Champaign, IL, 61820, USA
,
B. A. Bornstein Joint Center for Radiation Therapy, Department of Radiation Oncology, Harvard Medical School, Boston, MA, 02115, USA
,
J. L. Hansen Joint Center for Radiation Therapy, Department of Radiation Oncology, Harvard Medical School, Boston, MA, 02115, USA
&
G. K. Svensson Joint Center for Radiation Therapy, Department of Radiation Oncology, Harvard Medical School, Boston, MA, 02115, USA
Pages 375-399 | Received 25 Apr 1995, Accepted 17 Oct 1995, Published online: 09 Jul 2009

References

  • Ames W. F. Numerical Methods for Partial Differential Equations. New York Academic Press, New York 1977
  • Bowman H. F. Heat transfer and thermal dosimetry. Journal of Microwave Power 1981; 16(2)121–133
  • Bowman H. F. Themodynamics of tissue heating: modeling and measurements for temperature distributions. Physics Aspect of Hyperthermia, G. H. Nussbaum. American Institute of Physics, New York 1982; 511–548
  • Boyages J., Recht A., Connolly J., Schnitt S. J., Gelman R., Kooy H., Love S., Osteen R. T., Cady B., Silver B., Harris J. R. Early breast cancer: predictors of breast recurrence for patients treated with conservative surgery and radiation therapy. Radiationtherapy and Oncology 1990; 19: 29–41
  • Chen M. M. Microvascular Contributions in Tissue Heat Transfer. Annals of New York Academy of Sciences 1980; 335: 137–150
  • Cravalho E. G., Fox L. R., Kan J. C. The application of the bioheat equation to the design of thermal protocols for local hyperthermia. Annals of the New York Academy of Sciences 1980; 335: 86–97
  • Dewey W. C., Hopwood L. E., Sapareto S. A., Gerweck L. E. Cellular response to combinations of hyperthermia and radiation. Radiology 1977; 123: 463–474
  • Dickinson R. J. An Ultrasonic system for local hyperthermia using scanned focused transducers. IEEE Transactions Biomedical Engineering 1984; 31: 120–125
  • Dickinson R. J. Thermal conduction errors of manganin-constanian themocouple arrays. Phys. Med. Biol 1985; 30: 445–453
  • Duck F. A. Physical Properties of Tissue—A Comprehensive Reference Book. Academic Press Inc. 1990; 138
  • Ebbini E. S., Cain C. A. A spherical-section ultrasound phased array applicator for deep localized hyperthermia. IEEE Transactions on Biomedical Engineering 1991; 38: 634–644
  • Eberhart R. C., Shitzer A., Hernandez E. J. Thermal dilution methods 2; Estimation of tissue blood flow and metabolism. Annals NY Academy of Sciences 1980; 335: 107–132
  • Edmonds P. D., Mortensen C. L., Hill J. R., Holland S. K., Jensen J. F., Schattner P., Valders A. D., Lee R. H., Marzoni F. A. Ultrasound tissue characterization of breast biopsy specimens. Ultrasonic Imaging 1991; 13: 162–185
  • Fessenden P., Lee E. R., Andeson T. L., Strohbehn J. W., Meyer J. L., Samulski T. V., Marmor J. B. Experience with a multitransducer ultrasound system for localized hyperthermia of deep tissues. IEEE Transactions of Biomedical Engineering 1984; 31(1)126–134
  • Foster F. S., Hunt J. W. Transmission of ultrasound beams through human tissue—focusing and attenuation studies. Ultrasound in Medicine and Biology 1979; 5: 257–268
  • Hartov A., Colacchio T. A., Strohbehn J. W. Performance of an adaptive MIMO controller for a multiple-element ultrasound hyperthermia system. International Journal of Hyperthermia 1993; 9(4)563–579
  • Hansen J. L., Bornstein B. A., Svensson G. K., Newman W. H., Martin G. T., Sidney D. A., Frederick B. (1994) A quantitative, integrated, clinical focused ultrasound system for deep hyperthermia. Presented at the 1994 ASME International Mechanical Engineering Congress and Exhibition. 1994
  • Hynynen K., Roemer R., Anhalt D., Johnson C., Xu Z. X., Swindell W., Cetas T. A scanned, focused, multiple transducer ultrasonic system for localized hyperthermia treatments. International Journal of Hyperthermia 1987; 3(1)21–35
  • Hynynen K., Edwards D. K. Temperature Measurement During Ultrasound Hyperthermia. Medical Physics 1989; 16(4)618–626
  • Kapp D. S., Cos R. S., Fessenden P., Meyer J. L., Prionas S. D., Lee E. R., Bargshaw M. A. Parameters predictive for complications of treatment with combined hyperthermia and radiation therapy. International Journal of Radiation Oncology, Biology and Physics 1992; 22(5)999–1008
  • Kapp K. S., Kapp D. S. Hyperthermia's emerging role in cancer herapy. Contemporary Oncology 1993; 21–30
  • Kaye G. W. C., Laby T. H. Tables of Physical and Chemical Constants. Longman, London 1973
  • Lele P. P. Physical aspects and clinical studies with ultrasound hyperthermia. Hyperthermia in Cancer Therapy, F. C. Storm. Hall Medical Publishers, Boston 1983; 333–367
  • Lu X-Q., Burdette E. C., Svensson G. K. Ultrasound Field Calculation In a Two-Layer Medium Submitted. International Journal of Hyperthermia 1995
  • Madsen E. L., Zagzebski J. A., Banjavie R. A., Jutila R. E. Tissue mimicking materials for ultrasound phantoms. Med. Phys 1978; 5(5)391–394
  • Mayr N. A., Staples J. J., Robinson R. A., Vanmetre J. E., Hussey D. H. Morphometric studies in intraductal breast carcinoma using computerized image analysis. Cancer 1991; 67: 2805–2812
  • Exposure Criteria for Medical Diagnostic Ultrasound: I. Criteria Based on the Thermal Mechanisms. 1992; 53–54, NCRP Report No. 113
  • Ocheltree K. B., Frizzell K. A. Determination of Power deposition patterns for localized hypthermia, a steady-state analysis. International Journal of Hyperthermia 1987; 3(3)269–279
  • Ocheltree K. B., Frizzell L. A. Sound field calculation for rectangular sources. IEEE Transactions on Ultrasonic, Ferroelectrics, and Frequency Control 1989; 36(2)242–247
  • Oleson J. R., Samulski T. V., Leopold K. A., Clegg S. T., Dewhirst M. W., Dodge R. K., George S. L. Sensitivity of hyperthermia trial outcomes to temperature and time: implications for thermal goals of treatment. International Journal of Radiation Oncology, Biology and Physics 1993; 25(2)289–97
  • Palcic B., Skarsgard L. D. Reduced oxygen enhancement ratio at low doses of ionizing radiation. Radiation Research 1984; 100: 328–339
  • Pennes H. H. Analysis of tissue and arterial blood temperatures in the resting human forearm. Journal of Applied Physiology 1948; 1: 93–122
  • Press W. H., Flannery B. P., Teukolsky S. A., Vetterling W. T. Numerical Recipes, The Art of Scientific Computing. Cambridge University Press, Cambridge 1985
  • Roemer R. B. Optimal power deposition in hyperthermia. I. The treatment goal: the ideal temperature distribution: the role of large blood vessel. International Journal of Hyperthermia 1991; 7(2)317–341
  • Roemer R. B., Swindell W., Clegg S. T., Kress R. L. Simulation of focused scanned ultrasonic heating of deep-seated tumours: the effect of blood perfusion. IEEE Transactions Sonics and Ultrasonics 1984; 31: 457–466
  • Roemer R. B. Heat transfer in hyperthermia treatment: Basic principles and applications. American Association of Physicists in Medicine 1988; 210–242, Medical Physics Monograph No. 16
  • Schesinger A. L., Belgam R. A., Carson P. L., et al. Assessment of ultrasonic computed tomography in symptomatic breast patients by discriminant analysis. Ultrasound in Medicine and Biology 1989; 15: 21–28
  • Sekins and Emery. Thermal science for physical medicine. Therapeutic Heat and Cold, J. F. Lehmann. Williams and Wilkins, Baltimore 1982
  • Strohbehn J. W., Roemer R. B. A survey of computer simulations of hyperthermia treatments. IEEE Transactions Biomedical Engineering 1984; 31: 136–149
  • Szajda K. S., Sodini C. G., Bowman H. F. The active needle for in-vivo temperature measurement. Program and Abstracts of Fourteenth Annual Meeting of the North Americam Hyperthermia Society. 1994; 111
  • Van Baren P., Ebbini E. S. Multi-Point temperature control during hyperthermia treatments: theory and simulation. IEEE Transactions on Biomedical Engineering. 1995, (in press)
  • Vernon C. C. Collaborative phase III superficial hyperthermia trial (MRC/ESHO/PMH). Program and Abstracts of Fourteenth Annual Meeting of the North American Hyperthermia Society. 1994; 87
  • Waterman E. M., Kramer D. B. Changes in human tumor blood flow during four weeks of hyperthermia. Program and Abstracts of Fourteenth Annual Meeting of the North American Hyperthermia Society. 1994; 125

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