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International Journal of Hyperthermia Volume 29, 2013 - Issue 8: Magnetic Nanoparticle Hyperthermia
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Research Articles

Comparison of magnetic nanoparticle and microwave hyperthermia cancer treatment methodology and treatment effect in a rodent breast cancer model

Alicia A. PetrykThayer School of Engineering, Dartmouth College Hanover, New Hampshire;Geisel School of Medicine, Dartmouth College Hanover, New HampshireUSACorrespondence[email protected]
,
Andrew J. GiustiniThayer School of Engineering, Dartmouth College Hanover, New Hampshire;Geisel School of Medicine, Dartmouth College Hanover, New HampshireUSA
,
Rachel E. GottesmanGeisel School of Medicine, Dartmouth College Hanover, New HampshireUSA
,
B. Stuart TremblyThayer School of Engineering, Dartmouth College Hanover, New Hampshire
&
P. Jack HoopesThayer School of Engineering, Dartmouth College Hanover, New Hampshire;Geisel School of Medicine, Dartmouth College Hanover, New HampshireUSA
Pages 819-827 | Received 09 Jun 2013, Accepted 14 Sep 2013, Published online: 12 Nov 2013

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Jakub Mesicek & Kamil Kuca. (2018) Summary of numerical analyses for therapeutic uses of laser-activated gold nanoparticles. International Journal of Hyperthermia 34:8, pages 1255-1264.
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Mohammad Mahdi Attar, Saeid Amanpour, Mohammad Haghpanahi, Mahnaz Haddadi, Gita Rezaei, Samad Muhammadnejad, Mehran HajiAkhoundzadeh, Tahereh Barati, Fatemeh Sadeghi & Saba Javadi. (2016) Thermal analysis of magnetic nanoparticle in alternating magnetic field on human HCT-116 colon cancer cell line. International Journal of Hyperthermia 32:8, pages 858-867.
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Robert V. Stigliano, Fridon Shubitidze, James D. Petryk, Levan Shoshiashvili, Alicia A. Petryk & P. Jack Hoopes. (2016) Mitigation of eddy current heating during magnetic nanoparticle hyperthermia therapy. International Journal of Hyperthermia 32:7, pages 735-748.
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Christian Ndong, Seiko Toraya-Brown, Katsiaryna Kekalo, Ian Baker, Tillman U Gerngross, Steven N Fiering & Karl E Griswold. (2015) Antibody-mediated targeting of iron oxide nanoparticles to the folate receptor alpha increases tumor cell association in vitro and in vivo. International Journal of Nanomedicine 10, pages 2595-2617.
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Seiko Toraya-Brown & Steven Fiering. (2014) Local tumour hyperthermia as immunotherapy for metastatic cancer. International Journal of Hyperthermia 30:8, pages 531-539.
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Articles from other publishers (30)

Subenthung P. Tsopoe, Chandan Borgohain & Jyoti Prasad Borah. (2023) An Investigation of Inverted Core@Shell Nanostructure for Efficacious Magnetic Hyperthermia Applications. physica status solidi (a) 220:11.
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Tenzin Tsering Dongsar, Tenzin Sonam Dongsar, Mohammed A.S. Abourehab, Neelima Gupta & Prashant Kesharwani. (2023) Emerging application of magnetic nanoparticles for breast cancer therapy. European Polymer Journal 187, pages 111898.
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Manpreet Singh. (2023) Biological heat and mass transport mechanisms behind nanoparticles migration revealed under microCT image guidance. International Journal of Thermal Sciences 184, pages 107996.
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Muhammad Suleman. 2023. In Silico Approach Towards Magnetic Fluid Hyperthermia of Cancer Treatment. In Silico Approach Towards Magnetic Fluid Hyperthermia of Cancer Treatment 17 35 .
Neda Iranpour Anaraki & Somaiyeh Dadashi. 2023. Electromagnetic Waves-Based Cancer Diagnosis and Therapy. Electromagnetic Waves-Based Cancer Diagnosis and Therapy 65 88 .
Yu Shi, Chen Zhang, Chenxi Liu, Xinyong Ma & Zhe Liu. 2023. Visualized Medicine. Visualized Medicine 59 86 .
Md Abdus Subhan. (2022) Advances with metal oxide-based nanoparticles as MDR metastatic breast cancer therapeutics and diagnostics. RSC Advances 12:51, pages 32956-32978.
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Muhammad Suleman, Samia Riaz & Rashid Jalil. (2020) A mathematical modeling approach toward magnetic fluid hyperthermia of cancer and unfolding heating mechanism. Journal of Thermal Analysis and Calorimetry 146:3, pages 1193-1219.
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Helena Gavilán, Sahitya Kumar Avugadda, Tamara Fernández-Cabada, Nisarg Soni, Marco Cassani, Binh T. Mai, Roy Chantrell & Teresa Pellegrino. (2021) Magnetic nanoparticles and clusters for magnetic hyperthermia: optimizing their heat performance and developing combinatorial therapies to tackle cancer. Chemical Society Reviews 50:20, pages 11614-11667.
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Nickolas D. Polychronopoulos, Apostolos A. Gkountas, Ioannis E. Sarris & Leonidas A. Spyrou. (2021) A Computational Study on Magnetic Nanoparticles Hyperthermia of Ellipsoidal Tumors. Applied Sciences 11:20, pages 9526.
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Mehran Minbashi, Amirhossein Ahmadkhan Kordbacheh, Arash Ghobadi & Valery V. Tuchin. (2020) Optimization of power used in liver cancer microwave therapy by injection of Magnetic Nanoparticles (MNPs). Computers in Biology and Medicine 120, pages 103741.
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Gurmeet Singh, Neeraj Kumar & Pramod Kumar Avti. (2020) Computational evaluation of effectiveness for intratumoral injection strategies in magnetic nanoparticle assisted thermotherapy. International Journal of Heat and Mass Transfer 148, pages 119129.
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Pegah Faridi, Stefan H Bossmann & Punit Prakash. (2019) Simulation-based design and characterization of a microwave applicator for MR-guided hyperthermia experimental studies in small animals. Biomedical Physics & Engineering Express 6:1, pages 015001.
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Md. Salman Shakil, Md. Ashraful Hasan & Satya Ranjan Sarker. (2019) Iron Oxide Nanoparticles for Breast Cancer Theranostics. Current Drug Metabolism 20:6, pages 446-456.
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Vo Nguyen, Marie-Claire De Pauw-Gillet, Mario Gauthier & Olivier Sandre. (2018) Magnetic Polyion Complex Micelles for Cell Toxicity Induced by Radiofrequency Magnetic Field Hyperthermia. Nanomaterials 8:12, pages 1014.
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Ana C. Bohórquez, Mythreyi Unni, Sayali Belsare, Andreina Chiu-Lam, Lori Rice, Christine Pampo, Dietmar Siemann & Carlos Rinaldi. (2018) Stability and Mobility of Magnetic Nanoparticles in Biological Environments Determined from Dynamic Magnetic Susceptibility Measurements. Bioconjugate Chemistry 29:8, pages 2793-2805.
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Eudald Casals, Muriel F. Gusta, Macarena Cobaleda-Siles, Ana Garcia-Sanz & Victor F. Puntes. (2017) Cancer resistance to treatment and antiresistance tools offered by multimodal multifunctional nanoparticles. Cancer Nanotechnology 8:1.
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T Knopp, N Gdaniec & M Möddel. (2017) Magnetic particle imaging: from proof of principle to preclinical applications. Physics in Medicine & Biology 62:14, pages R124-R178.
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Brogan McWilliams, Hongwang Wang, Valerie Binns, Sergio Curto, Stefan Bossmann & Punit Prakash. (2017) Experimental Investigation of Magnetic Nanoparticle-Enhanced Microwave Hyperthermia. Journal of Functional Biomaterials 8:3, pages 21.
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Shivani Thoidingjam & Ashu Bhan Tiku. (2017) New developments in breast cancer therapy: role of iron oxide nanoparticles. Advances in Natural Sciences: Nanoscience and Nanotechnology 8:2, pages 023002.
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Sayumi Kobayashi, Akiko Ohki, Minori Tanoue, Yoshimi Inaoka & Kenya Murase. (2017) Comparative Study of Extracellular and Intracellular Magnetic Hyperthermia Treatments Using Magnetic Particle Imaging. Open Journal of Applied Sciences 07:12, pages 647-660.
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AKIKO OHKI, MINORI TANOUE, SAYUMI KOBAYASHI & KENYA MURASE. (2017) Magnetic Particle Imaging for Quantitative Evaluation of Tumor Response to Magnetic Hyperthermia Treatment Combined with Chemotherapy Using Cisplatin. Thermal Medicine 33:2, pages 39-51.
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Uysal B. (2017) Hyperthermia and Breast cancer: A short review. Journal of Radiology and Oncology 1:3, pages 079-082.
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Jingsong Mao, Shunsong Tang, Duo Hong, Fan Zhao, Meng Niu, Xiangjun Han, Ji Qi, Han Bao, Yutian Jiang, Changhui Fu, Dan Long, Xianwei Meng & Hongying Su. (2017) Therapeutic efficacy of novel microwave-sensitized mPEG-PLGA@ZrO 2 @(DOX + ILS) drug-loaded microspheres in rabbit VX 2 liver tumours . Nanoscale 9:10, pages 3429-3439.
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Dimitrios Karponis, May Azzawi & Alexander Seifalian. (2016) An arsenal of magnetic nanoparticles; perspectives in the treatment of cancer. Nanomedicine 11:16, pages 2215-2232.
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Tomomi Kuboyabu, Isamu Yabata, Marina Aoki, Natsuo Banura, Kohei Nishimoto, Atsushi Mimura & Kenya Murase. (2016) Magnetic Particle Imaging for Magnetic Hyperthermia Treatment: Visualization and Quantification of the Intratumoral Distribution and Temporal Change of Magnetic Nanoparticles <i>in Vivo</i>. Open Journal of Medical Imaging 06:01, pages 1-15.
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Alicia A. Petryk, Adwiteeya Misra, Elliot J. Kastner, Courtney M. Mazur, James D. Petryk & P. Jack Hoopes. Similarities and differences in ablative and non-ablative iron oxide nanoparticle hyperthermia cancer treatment. Similarities and differences in ablative and non-ablative iron oxide nanoparticle hyperthermia cancer treatment.
Alicia A. Petryk, Adwiteeya Misra, Courtney M. Mazur, James D. Petryk & P. J. Hoopes. Magnetic nanoparticle hyperthermia cancer treatment efficacy dependence on cellular and tissue level particle concentration and particle heating properties. Magnetic nanoparticle hyperthermia cancer treatment efficacy dependence on cellular and tissue level particle concentration and particle heating properties.
Fridon Shubitidze, Katsiaryna Kekalo, Robert Stigliano & Ian Baker. (2015) Magnetic nanoparticles with high specific absorption rate of electromagnetic energy at low field strength for hyperthermia therapy. Journal of Applied Physics 117:9.
Crossref
Seiko Toraya-Brown, Mee Rie Sheen, Peisheng Zhang, Lei Chen, Jason R. Baird, Eugene Demidenko, Mary Jo Turk, P. Jack Hoopes, Jose R. Conejo-Garcia & Steven Fiering. (2014) Local hyperthermia treatment of tumors induces CD8+ T cell-mediated resistance against distal and secondary tumors. Nanomedicine: Nanotechnology, Biology and Medicine 10:6, pages 1273-1285.
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