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Hemalatha K, Alamelumangai K, Arulmozhi R, Parthiban G & Muralidharan Rajaram. (2021) Magnetic and X-ray photo electron spectroscopic analysis of samarium doped iron oxide nanoparticles. Materials Research Innovations 25:6, pages 372-379.
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H. Petra Kok, Erik N. K. Cressman, Wim Ceelen, Christopher L. Brace, Robert Ivkov, Holger Grüll, Gail ter Haar, Peter Wust & Johannes Crezee. (2020) Heating technology for malignant tumors: a review. International Journal of Hyperthermia 37:1, pages 711-741.
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Olivia L. Lanier, Olena I. Korotych, Adam G. Monsalve, Dayita Wable, Shehaab Savliwala, Noa W. F. Grooms, Christopher Nacea, Omani R. Tuitt & Jon Dobson. (2019) Evaluation of magnetic nanoparticles for magnetic fluid hyperthermia. International Journal of Hyperthermia 36:1, pages 686-700.
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Ruby Gupta & Deepika Sharma. (2019) Biofunctionalization of magnetite nanoparticles with stevioside: effect on the size and thermal behaviour for use in hyperthermia applications. International Journal of Hyperthermia 36:1, pages 301-311.
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Farnaz Assa, Hoda Jafarizadeh-Malmiri, Hossein Ajamein, Hamideh Vaghari, Navideh Anarjan, Omid Ahmadi & Aydin Berenjian. (2017) Chitosan magnetic nanoparticles for drug delivery systems. Critical Reviews in Biotechnology 37:4, pages 492-509.
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Legha Ansari & Bizhan Malaekeh-Nikouei. (2017) Magnetic silica nanocomposites for magnetic hyperthermia applications. International Journal of Hyperthermia 33:3, pages 354-363.
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Antonios Makridis, Magdalini Tziomaki, Konstantina Topouridou, Maria P. Yavropoulou, John G. Yovos, Orestis Kalogirou, Theodoros Samaras & Mavroeidis Angelakeris. (2016) A novel strategy combining magnetic particle hyperthermia pulses with enhanced performance binary ferrite carriers for effective in vitro manipulation of primary human osteogenic sarcoma cells. International Journal of Hyperthermia 32:7, pages 778-785.
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Juliane Pasold, Kathleen Zander, Benjamin Heskamp, Cordula Grüttner, Frank Lüthen, Thomas Tischer, Anika Jonitz-Heincke & Rainer Bader. (2015) Positive impact of IGF-1-coupled nanoparticles on the differentiation potential of human chondrocytes cultured on collagen scaffolds. International Journal of Nanomedicine 10, pages 1131-1143.
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Ki Soo Kim & Soo Yeol Lee. (2015) Nanoparticle-mediated radiofrequency capacitive hyperthermia: A phantom study with magnetic resonance thermometry. International Journal of Hyperthermia 31:8, pages 831-839.
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Articles from other publishers (54)
Kamil G. Gareev. (2023) Diversity of Iron Oxides: Mechanisms of Formation, Physical Properties and Applications. Magnetochemistry 9:5, pages 119.
Crossref
Crossref
Marta Vassallo, Daniele Martella, Gabriele Barrera, Federica Celegato, Marco Coïsson, Riccardo Ferrero, Elena S. Olivetti, Adriano Troia, Hüseyin Sözeri, Camilla Parmeggiani, Diederik S. Wiersma, Paola Tiberto & Alessandra Manzin. (2023) Improvement of Hyperthermia Properties of Iron Oxide Nanoparticles by Surface Coating. ACS Omega 8:2, pages 2143-2154.
Crossref
Crossref
Assel Nazarova, Artem L. Kozlovskiy, Vyacheslav S. Rusakov, Kamila B. Egizbek, Maxim S. Fadeev, Bekzat A. Prmantayeva, Dorota Chudoba, Maxim V. Zdorovets & Kayrat K. Kadyrzhanov. (2022) Study of the Applicability of Magnetic Iron-Containing Nanoparticles in Hyperthermia and Determination of Their Resistance to Degradation Processes. Crystals 12:12, pages 1816.
Crossref
Crossref
Belén García-Merino, Eugenio Bringas & Inmaculada Ortiz. (2022) Synthesis and applications of surface-modified magnetic nanoparticles: progress and future prospects. Reviews in Chemical Engineering 38:7, pages 821-842.
Crossref
Crossref
Basil Shava, Fayomi David Ayodeji, Abbas Rahdar, Hafiz M.N. Iqbal & Muhammad Bilal. (2022) Magnetic nanoparticles-based systems for multifaceted biomedical applications. Journal of Drug Delivery Science and Technology 74, pages 103616.
Crossref
Crossref
K. Frank, C.R. Bernau & J.F. Buyel. (2022) Spherical nanoparticles can be used as non-penetrating tracers to determine the extra-particle void volume in packed-bed chromatography columns. Journal of Chromatography A 1675, pages 463174.
Crossref
Crossref
Oleg A. Kulikov, Mikhail N. Zharkov, Valentin P. Ageev, Denis E. Yakobson, Vasilisa I. Shlyapkina, Andrey V. Zaborovskiy, Vera I. Inchina, Larisa A. Balykova, Alexander M. Tishin, Gleb B. Sukhorukov & Nikolay A. Pyataev. (2022) Magnetic Hyperthermia Nanoarchitectonics via Iron Oxide Nanoparticles Stabilised by Oleic Acid: Anti-Tumour Efficiency and Safety Evaluation in Animals with Transplanted Carcinoma. International Journal of Molecular Sciences 23:8, pages 4234.
Crossref
Crossref
Harshal B. Desai, Sougata Ghosh, Rabia Pandit & Ashish R. Tanna. (2021) Synergistic Bacteriostatic Effect of Streptomycin-Coated Nanomagnetic Functional Oxides. BioNanoScience 12:1, pages 62-73.
Crossref
Crossref
Snehasis Biswas & Jayesh Bellare. 2022. Metal Oxides for Biomedical and Biosensor Applications. Metal Oxides for Biomedical and Biosensor Applications
3
33
.
Jochen Franke & Jorge Chacon-Caldera. 2022. Magnetic Materials and Technologies for Medical Applications. Magnetic Materials and Technologies for Medical Applications
339
393
.
Satoshi Ota, Suko Bagus Trisnanto, Seiji Takeuchi, Jiaojiao Wu, Yu Cheng & Yasushi Takemura. (2021) Quantitation method of loss powers using commercial magnetic nanoparticles based on superparamagnetic behavior influenced by anisotropy for hyperthermia. Journal of Magnetism and Magnetic Materials 538, pages 168313.
Crossref
Crossref
David Egea-Benavente, Jesús G. Ovejero, María del Puerto Morales & Domingo F. Barber. (2021) Understanding MNPs Behaviour in Response to AMF in Biological Milieus and the Effects at the Cellular Level: Implications for a Rational Design That Drives Magnetic Hyperthermia Therapy toward Clinical Implementation. Cancers 13:18, pages 4583.
Crossref
Crossref
Ruby Gupta & Deepika Sharma. (2021) (Carboxymethyl-stevioside)-coated magnetic dots for enhanced magnetic hyperthermia and improved glioblastoma treatment. Colloids and Surfaces B: Biointerfaces 205, pages 111870.
Crossref
Crossref
Ya. G. Toropova, M. N. Gorshkova, D. S. Motorina, D. V. Korolev, Yu. A. Skorik, G. A. Shulmeister, E. Yu. Podyacheva & A. Ya. Bagrov. (2021) Influence of Iron Oxide-Based Nanoparticles with Various Shell Modifications on the Generation of Reactive Oxygen Species in Stimulated Human Blood Cells in vitro. Journal of Evolutionary Biochemistry and Physiology 57:4, pages 782-791.
Crossref
Crossref
Nadina Liana Pop, Alexandrina Nan, Andrada Elena Urda-Cimpean, Adrian Florea, Vlad Alexandru Toma, Remus Moldovan, Nicoleta Decea, Daniela Rodica Mitrea & Remus Orasan. (2021) Chitosan Functionalized Magnetic Nanoparticles to Provide Neural Regeneration and Recovery after Experimental Model Induced Peripheral Nerve Injury. Biomolecules 11:5, pages 676.
Crossref
Crossref
Kwaku Baryeh, Mohammed Attia, Joshua Chaj Ulloa & Jing Yong Ye. 2021. Magnetic Nanoparticle-Based Hybrid Materials. Magnetic Nanoparticle-Based Hybrid Materials
387
423
.
M Arifuzzaman, M B Hossen, M H Rashid, M S Ahmed & M S Islam. (2020) Effect of annealing temperature on the structural, dielectric and electric properties of $$\hbox {Ni}_{{0.7}} \hbox {Cd}_{0.3}\hbox {Fe}_{2}\hbox {O}_{4}$$ ferrites. Bulletin of Materials Science 43:1.
Crossref
Crossref
J. Shebha Anandhi, G. Antilen Jacob & R. Justin Joseyphus. (2020) Factors affecting the heating efficiency of Mn-doped Fe3O4 nanoparticles. Journal of Magnetism and Magnetic Materials 512, pages 166992.
Crossref
Crossref
Gabriel C. Lavorato, Aldo A. Rubert, Yutao Xing, Raja DasJoshua Robles, F. Jochen Litterst, Elisa Baggio-Saitovitch, Manh-Huong Phan, Hariharan Srikanth, Carolina Vericat & Mariano H. Fonticelli. (2020) Shell-mediated control of surface chemistry of highly stoichiometric magnetite nanoparticles. Nanoscale 12:25, pages 13626-13636.
Crossref
Crossref
Yonghong Song, Dongdong Li, Yang Lu, Kun Jiang, Yi Yang, Yunjun Xu, Liang Dong, Xu Yan, Daishun Ling, Xianzhu Yang & Shu-Hong Yu. (2020)
Ferrimagnetic mPEG-
b
-PHEP copolymer micelles loaded with iron oxide nanocubes and emodin for enhanced magnetic hyperthermia–chemotherapy
. National Science Review 7:4, pages 723-736.
Crossref
Crossref
Gabriel C. Lavorato, Raja Das, Yutao Xing, Joshua Robles, F. Jochen Litterst, Elisa Baggio-Saitovitch, Manh-Huong Phan & Hariharan Srikanth. (2020) Origin and Shell-Driven Optimization of the Heating Power in Core/Shell Bimagnetic Nanoparticles. ACS Applied Nano Materials 3:2, pages 1755-1765.
Crossref
Crossref
Frederik Soetaert, Preethi Korangath, David Serantes, Steven Fiering & Robert Ivkov. (2020) Cancer therapy with iron oxide nanoparticles: Agents of thermal and immune therapies. Advanced Drug Delivery Reviews 163-164, pages 65-83.
Crossref
Crossref
Shehaab Savliwala, Andreina Chiu-Lam, Mythreyi Unni, Angelie Rivera-Rodriguez, Eric Fuller, Kacoli Sen, Marcus Threadcraft & Carlos Rinaldi. 2020. Nanoparticles for Biomedical Applications. Nanoparticles for Biomedical Applications
195
221
.
Shoeb Ansari, Eleonora Ficiarà, Federico Ruffinatti, Ilaria Stura, Monica Argenziano, Ornella Abollino, Roberta Cavalli, Caterina Guiot & Federico D’Agata. (2019) Magnetic Iron Oxide Nanoparticles: Synthesis, Characterization and Functionalization for Biomedical Applications in the Central Nervous System. Materials 12:3, pages 465.
Crossref
Crossref
Roto Roto. 2018. Advanced Surface Engineering Research. Advanced Surface Engineering Research.
Nan Zhu, Haining Ji, Peng Yu, Jiaqi Niu, M. Farooq, M. Akram, I. Udego, Handong Li & Xiaobin Niu. (2018) Surface Modification of Magnetic Iron Oxide Nanoparticles. Nanomaterials 8:10, pages 810.
Crossref
Crossref
Alessio Adamiano, Michele Iafisco & Anna Tampieri. 2018. Core-Shell Nanostructures for Drug Delivery and Theranostics. Core-Shell Nanostructures for Drug Delivery and Theranostics
259
296
.
I. Baker. 2018. Nanobiomaterials. Nanobiomaterials
197
229
.
Blanca Laffon, Natalia Fernández-Bertólez, Carla Costa, Fátima Brandão, João Paulo Teixeira, Eduardo Pásaro & Vanessa Valdiglesias. 2018. Cellular and Molecular Toxicology of Nanoparticles. Cellular and Molecular Toxicology of Nanoparticles
199
213
.
Helena Gavilán, Anja Kowalski, David Heinke, Abhilash Sugunan, Jens Sommertune, Miriam Varón, Lara K. Bogart, Oliver Posth, Lunjie Zeng, David González-Alonso, Christoph Balceris, Jeppe Fock, Erik Wetterskog, Cathrine Frandsen, Nicole Gehrke, Cordula Grüttner, Andrea Fornara, Frank Ludwig, Sabino Veintemillas-Verdaguer, Christer Johansson & M. Puerto Morales. (2017) Colloidal Flower-Shaped Iron Oxide Nanoparticles: Synthesis Strategies and Coatings. Particle & Particle Systems Characterization 34:7, pages 1700094.
Crossref
Crossref
Zheyu Shen, Aiguo Wu & Xiaoyuan Chen. (2016) Iron Oxide Nanoparticle Based Contrast Agents for Magnetic Resonance Imaging. Molecular Pharmaceutics 14:5, pages 1352-1364.
Crossref
Crossref
Ildikó Y. Tóth, Dániel Nesztor, Levente Novák, Erzsébet Illés, Márta Szekeres, Tamás Szabó & Etelka Tombácz. (2017) Clustering of carboxylated magnetite nanoparticles through polyethylenimine: Covalent versus electrostatic approach. Journal of Magnetism and Magnetic Materials 427, pages 280-288.
Crossref
Crossref
Kerstin Witte, Knut Müller, Cordula Grüttner, Fritz Westphal & Christer Johansson. (2017) Particle size- and concentration-dependent separation of magnetic nanoparticles. Journal of Magnetism and Magnetic Materials 427, pages 320-324.
Crossref
Crossref
Lucia Calucci, Agostina Grillone, Eugenio Redolfi Riva, Virgilio Mattoli, Gianni Ciofani & Claudia Forte. (2016) NMR Relaxometric Properties of SPION-Loaded Solid Lipid Nanoparticles. The Journal of Physical Chemistry C 121:1, pages 823-829.
Crossref
Crossref
G. Kiliç, N. Fernández-Bertólez, C. Costa, F. Brandão, J.P. Teixeira, E. Pásaro, B. Laffon & V. Valdiglesias. 2017. Neurotoxicity of Nanomaterials and Nanomedicine. Neurotoxicity of Nanomaterials and Nanomedicine
127
150
.
Silvio Dutz. (2016) Are Magnetic Multicore Nanoparticles Promising Candidates for Biomedical Applications?. IEEE Transactions on Magnetics 52:9, pages 1-3.
Crossref
Crossref
Xudong Zhang, Hongqiu Zhang, Xin Liang, Jinxie Zhang, Wei Tao, Xianbing Zhu, Danfeng Chang, Xiaowei Zeng, Gan Liu & Lin Mei. (2016) Iron Oxide Nanoparticles Induce Autophagosome Accumulation through Multiple Mechanisms: Lysosome Impairment, Mitochondrial Damage, and ER Stress. Molecular Pharmaceutics 13:7, pages 2578-2587.
Crossref
Crossref
Thomas Carter, Paul Mulholland & Kerry Chester. (2016) Antibody-targeted nanoparticles for cancer treatment. Immunotherapy 8:8, pages 941-958.
Crossref
Crossref
K. Simeonidis, S. Liébana-Viñas, U. Wiedwald, Z. Ma, Z.-A. Li, M. Spasova, O. Patsia, E. Myrovali, A. Makridis, D. Sakellari, I. Tsiaoussis, G. Vourlias, M. Farle & M. Angelakeris. (2016) A versatile large-scale and green process for synthesizing magnetic nanoparticles with tunable magnetic hyperthermia features. RSC Advances 6:58, pages 53107-53117.
Crossref
Crossref
R. Hudson. (2016)
Coupling the magnetic and heat dissipative properties of Fe
3
O
4
particles to enable applications in catalysis, drug delivery, tissue destruction and remote biological interfacing
. RSC Advances 6:5, pages 4262-4270.
Crossref
Crossref
Chunbai He, Jianqin Lu & Wenbin Lin. (2015) Hybrid nanoparticles for combination therapy of cancer. Journal of Controlled Release 219, pages 224-236.
Crossref
Crossref
Alba Garzón-Manjón, Eduardo Solano, María de la Mata, Roger Guzmán, Jordi Arbiol, Teresa Puig, Xavier Obradors, Ramón Yáñez, Susagna Ricart & Josep Ros. (2015) Induced shape controllability by tailored precursor design in thermal and microwave-assisted synthesis of $$\mathrm{Fe}_{3}\mathrm{O}_{4}$$ Fe 3 O 4 nanoparticles. Journal of Nanoparticle Research 17:7.
Crossref
Crossref
M. Angelakeris, Zi-An Li, M. Hilgendorff, K. Simeonidis, D. Sakellari, M. Filippousi, H. Tian, G. Van Tendeloo, M. Spasova, M. Acet & M. Farle. (2015) Enhanced biomedical heat-triggered carriers via nanomagnetism tuning in ferrite-based nanoparticles. Journal of Magnetism and Magnetic Materials 381, pages 179-187.
Crossref
Crossref
Dániel Nesztor, Krisztina Bali, Ildikó Y. Tóth, Márta Szekeres & Etelka Tombácz. (2015) Controlled clustering of carboxylated SPIONs through polyethylenimine. Journal of Magnetism and Magnetic Materials 380, pages 144-149.
Crossref
Crossref
Despoina Sakellari, Stella Mathioudaki, Zoi Kalpaxidou, Konstantinos Simeonidis & Makis Angelakeris. (2015) Exploring multifunctional potential of commercial ferrofluids by magnetic particle hyperthermia. Journal of Magnetism and Magnetic Materials 380, pages 360-364.
Crossref
Crossref
Kenya Murase, Marina Aoki, Natsuo Banura, Kohei Nishimoto, Atsushi Mimura, Tomomi Kuboyabu & Isamu Yabata. (2015) Usefulness of Magnetic Particle Imaging for Predicting the Therapeutic Effect of Magnetic Hyperthermia. Open Journal of Medical Imaging 05:02, pages 85-99.
Crossref
Crossref
Y. Lv, Y. Yang, J. Fang, H. Zhang, E. Peng, X. Liu, W. Xiao & J. Ding. (2015)
Size dependent magnetic hyperthermia of octahedral Fe
3
O
4
nanoparticles
. RSC Advances 5:94, pages 76764-76771.
Crossref
Crossref
Yanjiao Lu, Bicheng He, Jie Shen, Jie Li, Wantai Yang & Meizhen Yin. (2015) Multifunctional magnetic and fluorescent core–shell nanoparticles for bioimaging. Nanoscale 7:5, pages 1606-1609.
Crossref
Crossref
L. Gutiérrez, R. Costo, C. Grüttner, F. Westphal, N. Gehrke, D. Heinke, A. Fornara, Q. A. Pankhurst, C. Johansson, S. Veintemillas-Verdaguer & M. P. Morales. (2015) Synthesis methods to prepare single- and multi-core iron oxide nanoparticles for biomedical applications. Dalton Transactions 44:7, pages 2943-2952.
Crossref
Crossref
George Stefanou, Despina Sakellari, Konstantinos Simeonidis, Theodora Kalabaliki, Makis Angelakeris, Catherine Dendrinou-Samara & Orestis Kalogirou. (2014) Tunable AC Magnetic Hyperthermia Efficiency of Ni Ferrite Nanoparticles. IEEE Transactions on Magnetics 50:12, pages 1-7.
Crossref
Crossref
Silvio Dutz & Rudolf Hergt. (2014) Magnetic particle hyperthermia—a promising tumour therapy?. Nanotechnology 25:45, pages 452001.
Crossref
Crossref
Jiangtao Li, Zheng Liang, Xu Zhong, Zhijie Zhao & Jianhao Li. (2014) Study on the Thermal Characteristics of Fe<sub>3</sub>O<sub>4</sub> Nanoparticles and Gelatin Compound for Magnetic Fluid Hyperthermia in Radiofrequency Magnetic Field. IEEE Transactions on Magnetics 50:11, pages 1-4.
Crossref
Crossref
J Nowak, F Wiekhorst, L Trahms & S Odenbach. (2014) The influence of hydrodynamic diameter and core composition on the magnetoviscous effect of biocompatible ferrofluids. Journal of Physics: Condensed Matter 26:17, pages 176004.
Crossref
Crossref
Aziliz Hervault & Nguyễn Thị Kim Thanh. (2014) Magnetic nanoparticle-based therapeutic agents for thermo-chemotherapy treatment of cancer. Nanoscale 6:20, pages 11553-11573.
Crossref
Crossref