References
- National Cancer Institute CSFBaJC, In, National Cancer Institute. https://www.cancer.gov/.
- Magin RL, Peterson AF. Invited review: Non-invasive microwave phased arrays for local hyperthermia: A review. Int J Hyperther. 1989;5:429–450.
- Bellizzi GG, Drizdal T, van Rhoon GC, et al. The potential of constrained SAR focusing for hyperthermia treatment planning: analysis for the head & neck region. Phys Med Biol. 2019;64:10.
- Gas P, Miaskowski A. Sar optimization for multi-dipole antenna array with regard to local hyperthermia. Prz Elektrotechniczny. 2019;95:17–20.
- Nguyen PT. (2016). Focusing Microwave Hyperthermia in Realistic Environment for Breast Cancer Treatment.
- Chou HT, Chang CY. Application of rotman lens beamformer for relatively flexible multibeam coverage from electrically large-phased arrays of antennas. IEEE Trans Antennas Propag. 2019;67:3058–3066.
- Debnath OB, Saito K, Ito K, et al. Breast Cancer Treatment by Combining Microwave Hyperthermia and Radiation Brachytherapy. 2016 International Symposium on Antennas and Propagation. New York: Ieee. 2016. p 472-473.
- Li J, Xu L, Wang X. A computational study on number of elements in antenna array for focused microwave breast hyperthermia. In 2019 IEEE MTT-S International Microwave Biomedical Conference (IMBioC), vol. 1, IEEE, 2019. 1–3.
- Nguyen PT, Abbosh A, Crozier S. Microwave hyperthermia for breast cancer treatment using electromagnetic and thermal focusing tested on realistic breast models and antenna arrays. IEEE Trans Antennas Propag. 2015;63:4426–4434.
- Nguyen PT, Abbosh A, Crozier S. Three-dimensional microwave hyperthermia for breast cancer treatment in a realistic environment using particle swarm optimization. IEEE Trans Biomed Eng. 2017a;64:1335–1344.
- Nguyen PT, Abbosh AM, Crozier S. 3-D focused microwave hyperthermia for breast cancer treatment with experimental validation. IEEE Trans Antennas Propag. 2017b;65:3489–3500.
- Fan Q, Ma B, Guo A, et al. Surgical treatment of bone tumors in conjunction with microwave-induced hyperthermia and adjuvant immunotherapy. A preliminary report. Chin Med J. 1996a;109:425–431.
- Fan QY, Ma BA, Qiu XC, et al. Preliminary report on treatment of bone tumors with microwave-induced hyperthermia. Bioelectromagnetics. 1996b;17:218–222.
- Ji Z, Ma Y, Li W, et al. The healing process of intracorporeally and in situ devitalized distal femur by microwave in a dog model and its mechanical properties in vitro. PloS one. 2012;7:e30505.
- Takakuda K, Inaoka S, Saito H, et al. Microwave therapy for bone tumors. JSME international journal series C mechanical systems. Machine Elem Manuf. 2002;45:923–928.
- Converse M, Bond EJ, Veen B, et al. A computational study of ultra-wideband versus narrowband microwave hyperthermia for breast cancer treatment. IEEE Trans Microw Theory Tech. 2006;54:2169–2180.
- Zastrow E, Hagness SC, Van Veen BD, et al. Time-multiplexed beamforming for non-invasive microwave hyperthermia treatment. IEEE Trans Biomed Eng. 2011;58:1574–1584.
- Vasavada Y, Reed JH. Amplitude and Phase Calibration of Antenna Arrays. 2017 Ieee Mtt-S International Microwave and Rf Conference. New York: Ieee. 2017, p 90-94.
- Geyikoglu MD, Polat HK, Cavusoglu B. A New FlexibleAntenna array design for hyperthermia treatment of bone cancer. In 2019 Fifth International Electromagnetic Compatibility Conference (EMC Turkiye), vol. 1, IEEE, 2019. 1–5.
- Lakhssassi A, Kengne E, Semmaoui H. Modifed pennes’ equation modelling bio-heat transfer in living tissues: analytical and numerical analysis. Nat Sci (Irvine). 2010;02:1375.
- Conn AR, Gould NI, Toint PL. Trust. region methods. Siam; 2000.
- Seagrave RC. (1971). Biomedical Applications of Heat and Mass Transfer.
- OSI. (2020).
- America CTCo. (2021).
- Calttenburg R, Cohen J, Conner S, et al. Thermal properties of cancellous bone. J Biomed Mater Res 1975;9:169–182.
- Gabriel C. Dielectric properties of biological tissue: variation with age. Bioelectromagnetics. 2005;26:S12–S18.
- Karmani S. The thermal properties of bone and the effects of surgical intervention. Curr Orthop. 2006;20:52–58.
- Miklavčič D, Pavšelj N, Hart FX. Electric properties of tissues. Wiley encyclopedia of biomedical engineering. 2006.
- Amin B, Shahzad A, O’Halloran M, et al. Microwave bone imaging: A preliminary investigation on numerical bone phantoms for bone health monitoring. Sensors. 2020;20:6320.
- Lazebnik M, Okoniewski M, Booske JH, et al. Highly accurate Debye models for normal and malignant breast tissue dielectric properties at microwave frequencies. IEEE Microwave Wireless Compon. Lett. 2007;17:822–824.
- ITIS. (2021).