Biomedical Engineering Reference
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[22] K. W. Chan et al., “Use of thermocouples in the intense fields of ferromagnetic
implant hyperthermia,”
Int. J. Hyperthermia
, Vol. 9, pp. 831-848, 1993.
[23] D. T. Tompkins et al., “Temperature-dependent versus, constant-rate blood perfu-
sion modeling in ferromagnetic thermoseed hyperthermia: Results with a model
of the human prostate,”
Int. J. Hyperthermia
, Vol. 10, pp. 517-536, 1994.
[24] B. P. Partington et al., “Temperature distributions, microangiographic and
histopathologic correlations in normal tissue heated by ferromagnetic needles,”
Int. J. Hyperthermia
, Vol. 5, pp. 319-327, 1989.
[25] M. A. Burton et al., “In vitro and in vivo responses of doxorubicin ion exchange
microspheres to hyperthermia,”
Int.
J.
Hyperthermia
,
Vol.
8,
pp.
485-494,
1992.
[26] H. Matsuno, I. Tohnai, K. Mitsudo, et al., “Interstitial hyperthermia using mag-
netite cationic liposomes inhibit to tumor growth of VX-7 transplanted tumor in
rabbit tongue,”
Jpn. J. Hyperthermic Oncol
., Vol. 17, pp. 141-150, 2001.
[27] S. Wada, K. Tazawa, I. Furuta, S. Takemori, T. Minamimura, H. Nagae, “Applica-
tion of hyperthermia using dextran magnetite complex (DM) for head and neck
cancer,”
Jpn. J. Hyperthermic Oncol.
, Vol. 14, pp. 197-205, 1998.
[28] M. Shinkai, M. Suzuki, N. Yokoi, M. Yanase, W. Shimizu, H. Honda, T. Kobayashi,
“Development of anticancer drugs—Encapsulated magnetoliposome and its com-
bination effect of hyperthermia and chemotherapy,”
Jpn. J. Hyperthermic Oncol.
,
Vol. 14, pp. 15-22, 1998.
[29] M. Shinkai, M. Matsui, T. Kobayashi, “Heat properties of magnetoliposomes for
local hyperthermia,”
Jpn. J. Hyperthermic Oncol.
, Vol. 10, pp. 168-177, 1994.
[30] Y. Kotsuka et al., “New wireless thermometer for RF and microwave thermal
therapy using an MMIC in an Si BJT VCO type,”
IEEE Trans. Microwave Theory
Te ch .
, Vol. 47, No. 12, pp. 2630-2635, Dec. 1999.
[31] Y. Kotsuka, “Heating characteristics of small and high efficiency implant for
thermal therapy,”
Proc. URSI GA.
, Maastricht, The Netherlands, Aug. 2002.
[32] Y. Kotsuka, H. Okada, “Development of small high efficiency implant for deep
local hyperthermia,”
Jpn. J. Hyperthermic Oncol.
, Vol. 19, No. 1, pp. 11-22, Mar.
2003.
[33] W. Bush, “Über den Finfluss, wetchen heftigere Eryspelen zuweilen auf
organlsierte Neubildungen dusuben,”
Verh. Naturh. Preuss. Rhein. Westphal.
, Vol.
23, pp. 28-30, 1886.
[34] F. Westermark, “Über die Behandlung des ulcerirenden Cervix carcinomas mittels
Konstanter Wärme,”
Zentralbl. Gynkol.
, pp. 1335-1339, 1898.
[35] A. Westra, W. C. Dewey, “Variation in sensitivity to heat shock during the cell-
cycle of Chinese hamster cell in vitro,”
Int. J. Radiat. Biol.
, Vol. 19, pp. 467-477,
1971.
[36] J. Overgaard, P. Bichel, “The influence of hypoxia and acidity on the hyperther-
mia response of malignant cells in vitro,”
Radiology
, Vol. 123, pp. 511-514, 1977.
[37] G. Crile, Jr., “Selective distribution of cancers after exposure to heat,”
Ann. Surg.
,
Vol. 156, pp. 404-407, 1962.
[38] E. Ben-Hur, B. Bronk, et al., “Thermally enhanced radio-response of cultured
Chinese hamster ceels-Inhibition of repair of sublethal damage and enhancement
of lethal damage,”
Radiat. Res
., Vol. 58, pp. 38-51, 1974.
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