Evaluation of magnetic nanoparticles for magnetic fluid hyperthermia

Lanier, Olivia L.; Korotych, Olena; Monsalve, Adam; Wable, Dayita; Savliwala, Shehaab; Grooms, Noa W. F.; Nacea, Christopher; Tuitt, Omani R; Dobson, Jon

doi:10.1080/02656736.2019.1628313

Cited by 121 publications

(96 citation statements)

References 67 publications

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“…The size, size distribution, and shape of a particular NM have a clear impact on its magnetic properties [ 31 ]. These parameters should ideally be optimized [ 32 ] so as to exhibit the highest heating power under a selected AMF frequency [ 33 , 34 , 35 ], while displaying minimal toxicity if not subjected to an external magnetic field. This optimization also minimizes the need to revise extrinsic parameters, such as the NM concentration or the AMF power.…”

Section: Main Parameters Influencing the Outcome Of A Preclinical mentioning

confidence: 99%

“…Very distinct types of magnetic materials have been used for MHT purposes, including metal nanoparticles (e.g., Fe, Co, and Ni), metal alloy nanoparticles (e.g., FeCo, FePt, CoPt, and FePd), metal oxide nanoparticles (e.g., Fe 3 O 4 , Fe 2 O 3 , and MnO), ferrite nanoparticles (e.g., MnFe 2 O 4 , NiFe 2 O 4 , and ZnFe 2 O 4 ), metal-doped iron oxide nanoparticles (e.g., Mg, Mn, and Zn doped iron oxide), and core-shell magnetic nanoparticles (e.g., Fe@Fe 3 O 4 , Co@Co 2 P, and CoFe 2 O 4 @MnFe 2 O 4 ) [ 44 ]. Since the magnetic properties of the NMs depend on their size, shape, composition, and structure, these characteristics need to be crucially controlled during NMs synthesis [ 32 ]. As an example, magnesium-doped maghemite superparamagnetic nanoparticles with 100× higher heating power (see Section 2.3.1 ) than the commercial Resovist formulation allowed the induction of complete necrosis of glioblastoma cells by applying a low AMF ( Hf product = 1.22 × 10 9 A m −1 s −1 ) [ 45 ].…”

Section: Main Parameters Influencing the Outcome Of A Preclinical mentioning

confidence: 99%

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Magnetic Hyperthermia for Cancer Treatment: Main Parameters Affecting the Outcome of In Vitro and In Vivo Studies

2020

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Magnetic hyperthermia (MHT) is being investigated as a cancer treatment since the 1950s. Recent advancements in the field of nanotechnology have resulted in a notable increase in the number of MHT studies. Most of these studies explore MHT as a stand-alone treatment or as an adjuvant therapy in a preclinical context. However, despite all the scientific effort, only a minority of the MHT-devoted nanomaterials and approaches made it to clinical context. The outcome of an MHT experiment is largely influenced by a number of variables that should be considered when setting up new MHT studies. This review highlights and discusses the main parameters affecting the outcome of preclinical MHT, aiming to provide adequate assistance in the design of new, more efficient MHT studies.

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Section: Main Parameters Influencing the Outcome Of A Preclinical mentioning

confidence: 99%

Section: Main Parameters Influencing the Outcome Of A Preclinical mentioning

confidence: 99%

Magnetic Hyperthermia for Cancer Treatment: Main Parameters Affecting the Outcome of In Vitro and In Vivo Studies

2020

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“…Here, two different kinds of particles were studied, IONs (Sigma-Aldrich < 50 nm) and our custom magnetic microdiscs (1.5 µm in diameter, 80 nm in thickness), which were simulated as spherical particles with three different hydrodynamic diameters (D hd ): 70 nm (lower bound), 618 nm (equivalent magnetic volume of microdisc: 1.24 × 10 −19 m 3 ), and 1.5 µm (upper bound). In the case of the IONs, they were simulated with hydrodynamic diameters of 50 nm as defined by Sigma-Aldrich (< 50 nm) and 124 nm considering the hydrodynamic diameter measured in [37], as well as many other diameters accounting for particle aggregation. In Supplementary Material Figure S4, all D hd simulated for IONs are shown with their respective capture efficiencies.…”

Section: Multi-physics Simulationsmentioning

confidence: 99%

A High-Throughput Microfluidic Magnetic Separation (µFMS) Platform for Water Quality Monitoring

2019

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The long-term aim of this work is to develop a biosensing system that rapidly detects bacterial targets of interest, such as Escherichia coli, in drinking and recreational water quality monitoring. For these applications, a standard sample size is 100 mL, which is quite large for magnetic separation microfluidic analysis platforms that typically function with <20 µL/s throughput. Here, we report the use of 1.5-µm-diameter magnetic microdisc to selectively tag target bacteria, and a high-throughput microfluidic device that can potentially isolate the magnetically tagged bacteria from 100 mL water samples in less than 15 min. Simulations and experiments show~90% capture efficiencies of magnetic particles at flow rates up to 120 µL/s. Also, the platform enables the magnetic microdiscs/bacteria conjugates to be directly imaged, providing a path for quantitative assay.From the large-volume samples experiments with IONs, the magnetic separation microfluidic device was capable of processing > 50 mL samples (Figure 7). The 50 mL sample (IONs concentration of 100 µg/mL) was filtered in~7 min at a flow rate of 120 µL/s and the estimated capture efficiency was 70.0 ± 2.3%. Similarly, the 100 mL sample (IONs concentration 12.5 µg/mL, 100 mL) was filtered in Micromachines 2020, 11, 16 9 of 13 15 min at a flow rate of 120 µL/s and the estimated capture efficiency was 72.2 ± 2.0%. Figure 7 show 100 mL sample experiment images of the solutions before filtering (A), after filtering (B), the µFMS device with all captured IONs (C), and the VSM data to estimate capture efficiency for 100 mL sample (D).

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“…Magnetic nanoparticles (MNPs) were first proposed by Gilchrist et al [58]. Further developments have resulted in intriguing materials for clinical conductive heating [59][60][61]. When exposed to an external magnetic field, the magnetic materials will respond by aligning their atomic moments with the field, thus producing a magnetization that persists for a characteristic duration after the external magnetic field is removed [62,63].…”

Section: Conductive Heatingmentioning

confidence: 99%

Heating technology for malignant tumors: a review

Kok

Cressman

Ceelen

et al. 2020

International Journal of Hyperthermia

275

188

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The therapeutic application of heat is very effective in cancer treatment. Both hyperthermia, i.e., heating to 39-45 C to induce sensitization to radiotherapy and chemotherapy, and thermal ablation, where temperatures beyond 50 C destroy tumor cells directly are frequently applied in the clinic. Achievement of an effective treatment requires high quality heating equipment, precise thermal dosimetry, and adequate quality assurance. Several types of devices, antennas and heating or power delivery systems have been proposed and developed in recent decades. These vary considerably in technique, heating depth, ability to focus, and in the size of the heating focus. Clinically used heating techniques involve electromagnetic and ultrasonic heating, hyperthermic perfusion and conductive heating. Depending on clinical objectives and available technology, thermal therapies can be subdivided into three broad categories: local, locoregional, or whole body heating. Clinically used local heating techniques include interstitial hyperthermia and ablation, high intensity focused ultrasound (HIFU), scanned focused ultrasound (SFUS), electroporation, nanoparticle heating, intraluminal heating and superficial heating. Locoregional heating techniques include phased array systems, capacitive systems and isolated perfusion. Whole body techniques focus on prevention of heat loss supplemented with energy deposition in the body, e.g., by infrared radiation. This review presents an overview of clinical hyperthermia and ablation devices used for local, locoregional, and whole body therapy. Proven and experimental clinical applications of thermal ablation and hyperthermia are listed. Methods for temperature measurement and the role of treatment planning to control treatments are discussed briefly, as well as future perspectives for heating technology for the treatment of tumors.

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Evaluation of magnetic nanoparticles for magnetic fluid hyperthermia

Cited by 121 publications

References 67 publications

Magnetic Hyperthermia for Cancer Treatment: Main Parameters Affecting the Outcome of In Vitro and In Vivo Studies

Magnetic Hyperthermia for Cancer Treatment: Main Parameters Affecting the Outcome of In Vitro and In Vivo Studies

A High-Throughput Microfluidic Magnetic Separation (µFMS) Platform for Water Quality Monitoring

Heating technology for malignant tumors: a review

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