Efficiency of magnetic hyperthermia in the presence of rotating and static fields

Iszály, Zs.; Lovasz, K.; Nagy, I.; Márián, I. G.; Rácz, J.; Szabó, I.A.; Tóth, László Zoltán; Vas, Norman Félix; Vékony, Vilmos; Nándori, I.

doi:10.1016/j.jmmm.2018.07.043

Cited by 12 publications

(15 citation statements)

References 36 publications

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“…In this paper, the dynamics of a superparamagnetic nanoparticle in a viscous fluid in RMF is studied using both numerical simulation and analytical calculations. This topic has recently attracted considerable interest [33][34][35][36][37][38][39][40][41][42][43] in view of the possibility of using magnetic nanoparticles in magnetic hyperthermia for the cancer treatment. Unfortunately, in experiments [41,43] very small SAR values, of the order of several watts per gram, have been measured in RMF for assembly of superparamagnetic nanoparticles distributed in a viscous liquid.…”

Section: Discussionmentioning

confidence: 99%

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Dynamics of superparamagnetic nanoparticle in viscous liquid in rotating magnetic field

Usov¹,

Rytov²,

Bautin³

2019

Preprint

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The dynamics of magnetic nanoparticle in a viscous liquid in rotating magnetic field has been studied by means of numerical simulation and analytical calculations. In the magneto- dynamics approximation three different modes of motion of the unit magnetization vector and particle director are distinguished depending on the rotating magnetic field frequency and amplitude. The specific absorption rate of a dilute assembly of superparamagnetic nanoparticles in rotating magnetic field is calculated by solving the Landau – Lifshitz stochastic equation for unit magnetization vector and stochastic equation for particle director. At elevated frequencies an optimal range of particle diameters is found where the specific absorption rate of an assembly in rotating magnetic field has a maximum. It is shown that for magnetic hyperthermia in rotating magnetic field it is preferable to use rotating magnetic fields of moderate amplitude, H 0 = 100 Oe, in the frequency range 400-600 kHz.

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Section: Discussionmentioning

confidence: 99%

“…Recently, the application of a rotating magnetic field (RMF) in biomedicine, in particular in magnetic hyperthermia, has been studied both theoretically [33][34][35][36][37][38][39] and experimentally [40][41][42][43].…”

Section: Introductionmentioning

confidence: 99%

Dynamics of superparamagnetic nanoparticle in viscous liquid in rotating magnetic field

Usov¹,

Rytov²,

Bautin³

2019

Preprint

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“…Another simple separation method for the isolation of the protein corona can be applied for the class of magnetic nanocarriers.I ng eneral, magnetic materials are interesting for certain applications in nanomedicine;f or example,t o direct nanocarriers to and focus them on atarget region by an outer magnetic field [25][26][27] or to kill cancer cells by magnetically induced hyperthermia. [28,29] Moreover,m agnetism can be exploited for the separation of the nanocarrier-protein complex from the excess biological medium, where different separation set-ups are possible.T he basic separation is achieved by bringing am agnet into close proximity to the sample and removing the supernatant as long as the nanoparticles are concentrated near the magnet, similar to pellet formation. After re-suspension in buffer, the procedure is repeated to wash the sample.O verall, the applied steps to obtain the corona via magnetism are similar to those for the centrifugation process and further analysis can be applied subsequently.P rotein corona analysis following magnetic separation-for example,i dentification of the adsorbed proteins by LC-MS-has already been done,a lthough without obtaining any information about the binding affinities of the proteins that were present.…”

Section: Protein Corona Isolations Based On Washing Stepsmentioning

confidence: 99%

Possibilities and Limitations of Different Separation Techniques for the Analysis of the Protein Corona

2019

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One of the biggest challenges in the field of nanomedicine is the adsorption of biomolecules on the nanomaterial upon contact with a biological medium. The interactions of the resulting protein corona are essential for their behavior in a biological system. Thus, it is now commonly accepted that understanding the formation and consequently understanding the influence of the protein corona on the biological response is crucial. However, the outcome of the protein corona characterization cannot easily be compared between different studies and techniques, since many different sample preparation procedures exist that are suitable for different materials or methods. Depending on the applied procedure, the nanomaterial–protein system will be altered in a certain way, so that it is necessary to consider the individual influence on the protein corona. Accordingly, the aim of this Minireview is to give an overview of the applied sample preparation methods for the analysis of the protein corona and to evaluate their influence on the outcome of the results especially with regard to the introduced terms “soft” and “hard protein corona”. Special focus will be placed on the comparison of the most commonly used techniques such as centrifugation, magnetic, and chromatographic separation.

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“…B. um Nanoträger durch ein äußeres Magnetfeld auf ein Zielgebiet zu fokussieren [25][26][27] oder Krebszellen durch magnetisch induzierte Hyperthermie abzutçten. [28,29] [32] Auch Sakulkuh et al [33,34] machten eine klare Aussage,indem sie spezifizierten, dass in dem von ihnen getesteten System ausschließlich die harte Korona isoliert wurde.Sie verglichen die harte Korona von superparamagnetischen Eisenoxid-Nanoträgern (SPIONs) in Rattenplasma in vitro und in vivo und fanden heraus,d ass sich die Korona je nach Probenvorbereitung signifikant unterscheidet. [33] Zusätzlich wurden verschiedene Oberflächenfunktionalisierungend er SPI-ONs [34] Durch die magnetische Tr ennung wird ein allgemein vielseitiges Verfahren bereitgestellt, das jedoch auf bestimmte Materialien beschränkt ist und nicht als allgemeines Verfahren angewendet werden kann.…”

Section: Isolierung Der Proteinkorona Basierend Auf Waschschrittenunclassified

Möglichkeiten und Limitierungen verschiedener Trenntechniken zur Analyse der Proteinkorona

2019

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Die gebildete Proteinkorona ist für das Verhalten von Nanoträgern im biologischen System mitverantwortlich. Die Aufklärung der Bildung und des Einflusses der Proteinkorona auf die biologische Antwort ist daher entscheidend. Ergebnisse der Proteinkorona‐Charakterisierung können jedoch nicht ohne Weiteres untereinander verglichen werden, da es zahlreiche verschiedene Verfahren zur Probenvorbereitung gibt, die jeweils für unterschiedliche Materialien und Fragestellungen geeignet sind. Abhängig von der verwendeten Methode wird der Nanoträger‐Protein‐Komplex auf bestimmte Weise verändert, sodass der individuelle Einfluss der Probenvorbereitung auf die Proteinkorona berücksichtigt werden muss. Ziel dieses Kurzaufsatzes ist es daher, einen Überblick über Probevorbereitungsverfahren für die Analyse der Proteinkorona zu geben und ihren Einfluss auf das Ergebnis zu beurteilen, besonders im Hinblick auf die eingeführten Begriffe “weiche” und “harte” Proteinkorona. Im Fokus liegen dabei vor allem die am häufigsten verwendeten Techniken wie Zentrifugation, magnetische sowie chromatographische Trennungen.

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Efficiency of magnetic hyperthermia in the presence of rotating and static fields

Cited by 12 publications

References 36 publications

Dynamics of superparamagnetic nanoparticle in viscous liquid in rotating magnetic field

Dynamics of superparamagnetic nanoparticle in viscous liquid in rotating magnetic field

Possibilities and Limitations of Different Separation Techniques for the Analysis of the Protein Corona

Möglichkeiten und Limitierungen verschiedener Trenntechniken zur Analyse der Proteinkorona

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