Invited review: Noninvasive microwave phased arrays for local hyperthermia: A review

References

• Abe M., Hiraoka M. Review: Localized hyperthermia and radiation in cancer therapy. International Journal of Radiation Biology 1985; 47: 347–359
   Web of Science ®Google Scholar
• Andersen J. B. Theoretical limitations on radiation into muscle tissue. International Journal of Hyperthermia 1985; 1: 45–55
   PubMedGoogle Scholar
• Andersen J. B., Baum A., Harmark K., Heinzl L., Rasmark P., Overgaard J. A hyperthermia system using a new inductive applicator. IEEE Transactions on Biomedical Engineering 1984; BME-31: 21–27
   Web of Science ®Google Scholar
• Antolini R., Cerri G., Cristoforetti L., De Leo R. Absorbed power distributions from single or multiple waveguide applicators during microwave hyperthermia. Physics in Medicine and Biology 1986; 31: 1005–1019
   PubMedGoogle Scholar
• Babbs C. F., Vaguine V. A., Jones J. T. A predictive-adaptive, multipoint feedback controller for local heat therapy of solid tumors. IEEE Transactions on Microwave Theory and Techniques 1986; MTT-34: 604–611
   Web of Science ®Google Scholar
• Bahl I. J., Stuchly S. S. Analysis of a microstrip covered with a lossy dielectric. IEEE Transactions on Microwave Theory and Techniques 1980; MTT-28: 104–109
   Google Scholar
• Bahl I. J., Stuchly S. S., Stuchly M. A. A new microstrip radiator for medical applications. IEEE Transactions on Microwave Theory and Techniques 1980a; MTT-28: 1464–1468
   Google Scholar
• Bahl I. J., Stuchly S. S., Stuchly M. A. New microstrip slot radiator for medical applications. Electronics Letters 1980b; 16: 731–732
   Web of Science ®Google Scholar
• Bahl I. J., Stuchly S. S., Lagenduk J. J. W., Stuchly M. A. Microstrip loop radiators for medical applications. IEEE Transactions on Microwave Theory and Techniques 1982; MTT-30: 1090–1093
   Google Scholar
• Bassen H. I., Coakley R. F. United States radiation safety and regulatory considerations for radiofrequency hyperthermia systems. Journal of Microwave Power 1981; 16: 215–226
   PubMedGoogle Scholar
• Beyne L., DeZutter D. Power deposition of a microstrip applicator radiating into a layered biological structure. IEEE Transactions on Microwave Theory and Techniques 1988; MTT-36: 126–131
   Web of Science ®Google Scholar
• Boesch R. D., Magin R. L., Franke S. J. Phase shifter for a 915 MHz phased array hyperthermia system. IEEE Transactions on Biomedical Engineering 1987; BME-34: 904–907
   Google Scholar
• Brady L. W. Hyperthermia: the development of management fees. Syllabus: A Categorical Course in Radiation Therapy: Hyperthermia, R. A. Steeves, B. R. Paliwal. Radiological Society of North America, Oak Brook, IL 1987; 179–182
   Google Scholar
• Cetas T. C., Roemer R. B. Status and future developments in the physical aspects of hyperthermia. Cancer Research (Suppl.) 1984; 44: 4894s–4901s
   PubMed Web of Science ®Google Scholar
• Cheever E., Leonard J. B., Foster K. R. Depth of penetration of fields from rectangular apertures into lossy media. IEEE Transactions on Microwave Theory and Techniques 1987; MTT-35: 865–867
   Google Scholar
• Cheung A. Y., Neyzari A. Deep local hyperthermia for cancer therapy: external electromagnetic and ultrasound techniques. Cancer Research (Suppl.) 1984; 44: 4736s–4744s
   PubMed Web of Science ®Google Scholar
• Cheung A. Y., Dao T., Robinson J. E. Dual-beam TEM applicator for direct-contact heating of dielectrically encapsulated malignant mouse tumor. Radio Science 1977; 12: 81–85
   Google Scholar
• Cheung A. Y., Golding W. M., Samaran G. M. Direct contact applicators for microwave hyperthermia. Journal of Microwave Power 1981; 16: 151–159
   PubMedGoogle Scholar
• Christenson D. A., Durney C. H. Hyperthermia production for cancer therapy: a review of fundamentals and methods. Journal of Microwave Power 1981; 16: 89–105
   PubMedGoogle Scholar
• Collin R. E. Foundations for Microwave Engineering. McGraw-Hill, New York 1966
   Google Scholar
• Cudd P. A., Anderson A. P., Hawley M. S., Conway J. Phased array design considerations for deep hyperthermia through layered tissue. IEEE Transactions on Microwave Theory and Techniques 1986; MTT-34: 526–531
   Google Scholar
• Franconi C., Tiberio C. A., Roganella L., Begnozzi L. Low-frequency RF twin-dipole applicator for intermediate depth hyperthermia. IEEE Transactions on Microwave Theory and Techniques 1986; MTT-34: 612–619
   Web of Science ®Google Scholar
• Gee W., Lee S. W., Bong N. K., Cain C. A., Mittra R., Magin R. L. Focused array hyperthermia applicator: theory and experiment. IEEE Transactions on Microwave Theory and Techniques 1984; BME-31: 38–46
   Google Scholar
• Gibbs F. A. Clinical evaluation of a microwave/radiofrequency system (BSD Corporation) for induction of local and regional hyperthermia. Journal of Microwave Power 1981; 16: 185–192
   PubMedGoogle Scholar
• Gu Y., Ghandhi O. P. Phased-dipole applicators for torso heating in electromagnetic hyperthermia. IEEE Transactions on Microwave Theory and Techniques 1984; MTT-32: 645–647
   Google Scholar
• Guerquin-Kern J. L., Palas L., Priou A., Gautheric M. Local hyperthermia using microwaves for therapeutic purposes—experimental studies of various applicators. Journal of Microwave Power 1981; 16: 305–311
   PubMed Web of Science ®Google Scholar
• Guo T. C., Guo W. W., Larsen L. E. A local field study of a water-immersed microwave antenna array for medical imagery and therapy. IEEE Transactions on Microwave Theory and Techniques 1984; MTT-32: 844–853
   Web of Science ®Google Scholar
• Guy A. W., Chou C. Physical aspects of localized heating by radiowaves and microwaves. Hyperthermia in Cancer Therapy, F. K. Storm. G. K. Hall, Boston 1983
   Google Scholar
• Guy A. W., Lehmann J. F., Stonebridge J. B. Therapeutic applications of electromagnetic power. Proceedings of the IEEE 1974; 62: 55–75
   Web of Science ®Google Scholar
• Guy A. W., Lehmann J. F., Stonebridge J. E., Sorensen C. C. Development of a 915 MHz direct-contact applicator for therapeutic heating of tissues. IEEE Transactions on Microwave Theory and Techniques 1978; MTT-26: 550–556
   Web of Science ®Google Scholar
• Guy A. W., Chou C., Luk K. H. 915 MHz phased array system for treating tumors in cylindrical structures. IEEE Transactions on Microwave Theory and Techniques 1986; MTT-34: 502–507
   Google Scholar
• Hahn G. M. Hyperthermia and Cancer. Plenum Press, New York 1982
   Google Scholar
• Hand J. W. Heat delivery and thermometry in clinical hyperthermia. Recent Results in Cancer Research, vol. 104: Hyperthermia and the Therapy of Malignant Tumors, C. Streffer. Springer-Verlag, New York 1987; 1–23
   Google Scholar
• Hand J. W., Cheetham J. L., Hind A. J. Absorbed power distributions from coherent microwave arrays for localized hyperthermia. IEEE Transactions on Microwave Theory and Techniques 1986; MTT-34: 484–488
   Web of Science ®Google Scholar
• Iskander M. F. Physical aspects and methods of hyperthermia production by RF currents and microwaves. Physical Aspects of Hyperthermia, G. H. Nussbaum. Medical Physics Monograph No. 8, American Institute of Physics, New York 1982; 151–191
   Google Scholar
• Jacobi J. H., Larsen L. E., Hast C. T. Water-immersed microwave antennas and their application to microwave interrogation of biological targets. IEEE Transactions on Microwave Theory and Techniques 1979; MTT-27: 70–78
   Google Scholar
• Johnson R. H., James J. R., Hand J. W., Hopewell J. W., Dunlop P. R. C., Dickinson R. J. New low-profile applicators for local heating of tissues. IEEE Transactions on Microwave Theory and Techniques 1984; BME-32: 28–37
   Google Scholar
• Johnson R. H., Andrasic G., Smith D. L., James J. R. Field penetration of arrays of compact applicators in localized hyperthermia. International Journal of Hyperthermia 1985; 1: 321–336
   PubMedGoogle Scholar
• Johnson R. H., Preece A. W., Hand J. W., James J. R. A new type of lightweight low-frequency electromagnetic hyperthermia applicator. IEEE Transactions on Microwave Theory and Techniques 1987; MTT-3S: 1317–1321
   Google Scholar
• Kantor G. Evaluation and survey of microwave and radiofrequency applicators. Journal of Microwave Power 1981; 16: 135–150
   PubMedGoogle Scholar
• Kantor G., Cetas T. C. A comparative heating pattern study of direct-contact applicators in microwave diathermy. Radio Science 1977; 12: 111–119
   Web of Science ®Google Scholar
• Kantor G., Witters D. M., Jr. A 2450-MHz slab-loaded direct contact applicator with choke. IEEE Transactions on Microwave Theory and Techniques 1980; MTT-28: 1418–1422
   Web of Science ®Google Scholar
• Kantor G., Witters D. M., Jr, Greiser J. W. The performance of a new direct contact applicator for microwave diathermy. IEEE Transactions on Microwave Theory and Techniques 1978; MTT-26: 563–568
   Google Scholar
• Kapp D. S. Clinical indications for hyperthermia. Syllabus: A Categorical Course in Radiation Therapy: Hyperthermia, R. A. Steeves, B. R. Paliwal. Radiological Society of North America, Oak Brook, IL 1987; 77–91
   Google Scholar
• Kashyap S., Wyslouzil W. New inductive applicators for electromagnetic hyperthermia. Journal of Microwave Power 1987; 22: 13–18
   Google Scholar
• Ledee R., Chive M., Plancot M. Microstrip microslot antennas for biomedical applications: frequency analysis of different parameters of this type of applicator. Electronics Letters 1985; 21: 304–305
   Google Scholar
• Lehmann J. F., Guy A. W., Stonebridge J. B., Warren C. G., DeLateur B. J. Temperature distribution produced in models by three microwave applicators at 433.92 megahertz. Archives of Physical Medicine and Rehabilitation 1975; 56: 145–151
   PubMedGoogle Scholar
• Lehmann J. F., Guy A. W., Stonebridge J. B., DeLateur B. J. Evaluation of a therapeutic direct-contact 915 MHz microwave applicator for effective deep-tissue heating in humans. IEEE Transactions on Microwave Theory and Techniques 1978; MTT-26: 556–563
   Web of Science ®Google Scholar
• Lehmann J. F., Stonebridge J. B., Guy A. W. A comparison of patterns of stray radiation from therapeutic microwave applicators measured near tissue-substitute models and human subjects. Radio Science 1979; 14: 271–283
   Google Scholar
• Lin J. C. Special issue on phased arrays for hyperthermia treatment of cancer. IEEE Transactions on Microwave Theory and Techniques 1986; MTT-34: 481–648
   Google Scholar
• Ling H., Lee S. W., Gee W. Frequency optimization of focused microwave hyperthermia applicators. Proceedings of the IEEE 1984; 72: 224–225
   Google Scholar
• Loane J., Ling H., Wang B. F., Lee S. W. Experimental investigation of a retro-focusing microwave hyperthermia applicator: conjugate-field matching scheme. IEEE Transactions on Microwave Theory and Techniques 1986; MTT-34: 490–493
   Google Scholar
• Lovisolo G. A., Adami M., Archangeli G., Borrani A., Calamai G., Cividalli A., Mauro F. A multi-frequency water-filled waveguide applicator: thermal dosimetry in vivo. IEEE Transactions on Microwave Theory and Techniques 1984; MTT-32: 893–896
   Web of Science ®Google Scholar
• Magin R. L., Kantor G. Comparison of the heating patterns of small microwave (2450 MHz) applicators. Journal of Bioengineering 1977; 1: 493–509
   Google Scholar
• Mendecki J., Friedenthal E., Botstein C., Sterzer F., Paglione R. Therapeutic potential of conformal applicators for induction of hyperthermia. Journal of Microwave Power 1979; 14: 139–144
   PubMedGoogle Scholar
• Physical Aspects of Hyperthermia, G. H. Nussbaum. Medical Physics Monograph No. 8, American Institute of Physics, New York 1982
   Google Scholar
• Paglione R., Sterzer F., Mendecki J., Friedenthal E., Botstein C. 27 MHz ridged waveguide applicator for localized hyperthermia treatment of deep-seated malignant tumors. Microwave Journal 1981; 24: 71–80
   Web of Science ®Google Scholar
• Paliwal B. R. Basic physics parameters and instrumentation of hyperthermia. Syllabus: A Categorical Course in Radiation Therapy: Hyperthermia, R. A. Steeves, B. R. Paliwal. Radiological Society of North America, Oak Brook, IL 1987; 57–70
   Google Scholar
• Perez C. A. Rationale for clinical application of hyperthermia alone or combined with irradiation or cytotoxic drugs in cancer therapy. Physical Aspects of Hyperthermia, G. H. Nussbaum. Medical Physics Monograph No. 8, American Institute of Physics, New York 1982; 63–89
   Google Scholar
• Pilepich M. V., Myerson R. J., Emami B. N., Perez C. A., Leybovich L., Von Gerichten D. Regional hyperthermia: a feasibility analysis. International Journal of Hyperthermia 1987; 3: 347–351
   PubMed Web of Science ®Google Scholar
• Samulski T. V. Noninvasive microwave hyperthermia. Syllabus: A Categorized Course in Radiation Therapy: Hyperthermia, R. A. Steeves, B. R. Paliwal. Radiological Society of North America, Oak Brook, IL 1987; 71–76
   Google Scholar
• Sandhu T. S. Clinical hyperthermia with microwaves. Physical Aspects of Hyperthermia, G. H. Nussbaum. Medical Physics Monograph No. 8, American Institute of Physics, New York 1982; 329–356
   Google Scholar
• Sathiaseelan V., Iskander M. F., Howard G. C., Bleehen N. M. Theoretical analysis and clinical demonstration of the effect of power pattern control using the annular phased-array hyperthermia system. IEEE Transactions on Microwave Theory and Techniques 1986; MTT-34: 514–519
   Web of Science ®Google Scholar
• Sato G., Shibata C., Sekimukai S., Wakabayashi H., Mitsuka K., Giga K. Phase-controlled circular array heating equipment for deep-seated tumors: preliminary experiments. IEEE Transactions on Microwave Theory and Techniques 1986; MTT-34: 520–524
   Google Scholar
• Short J. G., Turner P. F. Physical hyperthermia and cancer therapy. Proceedings of the IEEE 1980; 68: 133–142
   Web of Science ®Google Scholar
• Sterzer F., Paglione R. W., Beck Nowogrodzki E., Mendecki J., Friedenthal E., Botstein C. Microwave apparatus for the treatment of cancer. Microwave Journal 1980a; 23: 39–44
   Google Scholar
• Sterzer F., Paglione R. W., Mondecki J., Friedenthal E., Botstein C. RF therapy for malignancy. IEEE Spectrum 1980b; 32–37
   Web of Science ®Google Scholar
• Hyperthermia in Cancer Therapy, F. K. Storm. G. K. Hall, Boston 1983
   Google Scholar
• Storm F. K., Elliott R. S., Harrison W. H., Morton D. L. Clinical RF hyperthermia by magnetic-loop induction: a new approach to human cancer therapy. IEEE Transactions on Microwave Theory and Techniques 1982; MTT-30: 1149–1157
   Google Scholar
• Streffer C. Recent Results in Cancer Research. Springer-Verlag, New York 1987
   Google Scholar
• Stuchly M. A., Stuchly S. S., Kantor G. Diathermy applicators with circular aperture and corrugated flange. IEEE Transactions on Microwave Theory and Techniques 1980; MTT-28.: 267–271
   Google Scholar
• Tanabe E., McEven A., Norris C. S., Fessenden P., Samulski T. V. A multielement microstrip antenna for local hyperthermia. Proceedings of the 1983 Microwave Theory and Techniques Symposium. 1983; 183–185
   Google Scholar
• Taylor L. Implantable radiators for cancer therapy by microwave hyperthermia. Proceedings of the IEEE 1980; 68: 142–149
   Web of Science ®Google Scholar
• Trembly B. S., Wilson A. H., Sullivan M. J., Stein A. D., Wong T. Z., Strohbehn J. W. Control of the SAR pattern within an interstitial microwave array through variation of antenna driving phase. IEEE Transactions on Microwave Theory and Techniques 1986; MTT-34: 568–571
   Google Scholar
• Turner P. F. Regional hyperthermia with an annular phased array. IEEE Transactions on Biomedical Engineering 1984; BME-31: 106–114
   Web of Science ®Google Scholar
• Turner P. F. Interstitial equal-phased arrays for EM hyperthermia. IEEE Transactions on Microwave Theory and Techniques 1986a; MTT-34: 572–577
   Web of Science ®Google Scholar
• Turner P. F. Mini-annular phased array for limb hyperthermia. IEEE Transactions on Microwave Theory and Techniques 1986b; MTT-34: 508–512
   Web of Science ®Google Scholar
• Underwood H. R., Franke S. J., Magin R. L. Thin multi-element microstrip applicator for focused superficial hyperthermia therapy. Proceedings of the 35th Annual RRS Meeting/7th Annual NAHG Meeting, Atlanta, GA, 1987a, 63, (abstract)
   Google Scholar
• Underwood H. R., Franke S. J., Peterson A. F., Magin R. L. A multi-element microstrip applicator for superficial hyperthermia therapy. Student-paper supplement to Proceedings of the 9th Annual Conference of the IEEE Engineering in Medicine and Biololgy Society, Boston, MA, 1987b; 28
   Google Scholar
• Uzunoglu N. K., Angelikas E. A., Cosmidis P. A. A 432-MHz local hyperthermia system using an indirectly cooled, water loaded waveguide applicator. IEEE Transactions on Microwave Theory and Techniques 1987; MTT-35: 106–111
   Google Scholar
• Wang Y. X. Slot-line coupler for medical applications. Electronics Letters 1984; 20: 931–940
   Google Scholar
• Wang Y. X. Coplanar waveguide short-gap resonator for medical applications. IEEE Transactions on Microwave Theory and Techniques 1985; MTT-33: 1310–1312
   Google Scholar
• Wait J. R. Focused heating in cylindrical targets: Part I. IEEE Transactions on Microwave Theory and Techniques 1985; MTT-33: 647–649
   Google Scholar
• Wait J. R., Lumori M. Focused heating on cylindrical targets: Part II. IEEE Transactions on Microwave Theory and Techniques 1986; MTT-34: 357–359
   Google Scholar
• Hyperthermia, D. J. Watmough, W. M. Ross. Blackie and Son, London 1986
   Google Scholar
• Wong T. Z., Strohbehn J. W., Jones K. M., Mechling J. A., Trembly B. S. SAR patterns from an interstitial microwave antenna-array hyperthermia system. IEEE Transactions on Microwave Theory and Techniques 1986; MTT-34: 560–567
   Google Scholar