Cubic Anisotropic Co- and Zn-Substituted Ferrite Nanoparticles as Multimodal Magnetic Agents

Pardo, Alberto; Yáñez, Susana; Piñeiro, Yolanda; Iglesias‐Rey, Ramón; Al‐Modlej, Abeer; Barbosa, Sílvia; Rivas, José; Taboada, Pablo

doi:10.1021/acsami.9b20496

Cited by 37 publications

(24 citation statements)

References 100 publications

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“…Similarly, a heating efficiency of about 3.5 kW/g was measured for 22 nm Co-Mn doped ferrites in aqueous dispersion; however, such heating performance was due to Brownian motion, not hysteresis, and consequently decreased in high viscosity glycerol solutions that simulate cellular media [37]. These results are in agreement with those reported in cubic Co-and Zn-substituted ferrites after their cell internalization [38], where the SAR showed a reduction of about 60% in the case of Zn 0.21 Fe 2.79 O 4 . The same tendency applies to monodisperse Fe 3 O 4 /Co x Zn 1-x Fe 2 O 4 core-shell NPs [39].…”

Section: Comparison With Other Core-shell Systemssupporting

confidence: 86%

Finding the Limits of Magnetic Hyperthermia on Core-Shell Nanoparticles Fabricated by Physical Vapor Methods

Martínez-Boubeta¹,

Simeonidis²,

Oró‐Solé

et al. 2021

Magnetochemistry

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Magnetic nanoparticles can generate heat when exposed to an alternating magnetic field. Their heating efficacy is governed by their magnetic properties that are in turn determined by their composition, size and morphology. Thus far, iron oxides (e.g., magnetite, Fe3O4) have been the most popular materials in use, though recently bimagnetic core-shell structures are gaining ground. Herein we present a study on the effect of particle morphology on heating efficiency. More specifically, we use zero waste impact methods for the synthesis of metal/metal oxide Fe/Fe3O4 nanoparticles in both spherical and cubic shapes, which present an interesting venue for understanding how spin coupling across interfaces and also finite size effects may influence the magnetic response. We show that these particles can generate sufficient heat (hundreds of watts per gram) to drive hyperthermia applications, whereas faceted nanoparticles demonstrate superior heating capabilities than spherical nanoparticles of similar size.

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Section: Comparison With Other Core-shell Systemssupporting

confidence: 86%

Finding the Limits of Magnetic Hyperthermia on Core-Shell Nanoparticles Fabricated by Physical Vapor Methods

Martínez-Boubeta¹,

Simeonidis²,

Oró‐Solé

et al. 2021

Magnetochemistry

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“…In this context, the substitution of Fe 2+ (d 6 ) cations in B sites with Mn 2+ (d 5 ) cations, bearing a larger magnetic moment of 5µ B per formula unit due to their five unpaired valence electrons, led to an increase of the saturation magnetization (M s ) of ferrite particles and thus to an enhancement of their heating capabilities [17][18][19][20][21]. The replacement of Fe 2+ (d 6 ) cations in B sites by more anisotropic Co 2+ (d 7 ) cations, conducted to ferrite particles with larger coercivity values and a wider hysteresis loop, which improved considerably the production of heat under AMF [22][23][24][25]. A particular different situation is offered by the diamagnetic Zn 2+ (d 10 ) cations once incorporated in the spinel structure, as they can produce significant enhancement of the ferrite particle s magnetic moment, compared to pure Fe 3 O 4 [26][27][28].…”

Section: Introductionmentioning

confidence: 99%

“…Several synthesis routes have been employed for the preparation of ZnF particles, exhibiting different particle size histograms, cation distribution between the two sublattices, and magnetic properties. The preparation of single-crystalline monodisperse ZnF-particles with magnetic properties closed to bulk-like ones has been achieved by thermal decomposition of metal acetylacetonates and oleates in organic solvents at high temperatures [25,26,28,29,[31][32][33][34]. In most cases, this method enables the formation of secondary phases as wüstite [35].…”

Section: Introductionmentioning

confidence: 99%

The Effect of Zn-Substitution on the Morphological, Magnetic, Cytotoxic, and In Vitro Hyperthermia Properties of Polyhedral Ferrite Magnetic Nanoparticles

et al. 2021

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The clinical translation of magnetic hyperthermia (MH) needs magnetic nanoparticles (MNPs) with enhanced heating properties and good biocompatibility. Many studies were devoted lately to the increase in the heating power of iron oxide MNPs by doping the magnetite structure with divalent cations. A series of MNPs with variable Zn/Fe molar ratios (between 1/10 and 1/1) were synthesized by using a high-temperature polyol method, and their physical properties were studied with different techniques (Transmission Electron Microscopy, X-ray diffraction, Fourier Transform Infrared Spectroscopy). At low Zn doping (Zn/Fe ratio 1/10), a significant increase in the saturation magnetization (90 e.m.u./g as compared to 83 e.m.u./g for their undoped counterparts) was obtained. The MNPs’ hyperthermia properties were assessed in alternating magnetic fields up to 65 kA/m at a frequency of 355 kHz, revealing specific absorption rates of up to 820 W/g. The Zn ferrite MNPs showed good biocompatibility against two cell lines (A549 cancer cell line and BJ normal cell line) with a drop of only 40% in the viability at the highest dose used (500 μg/cm2). Cellular uptake experiments revealed that the MNPs enter the cells in a dose-dependent manner with an almost 50% higher capacity of cancer cells to accommodate the MNPs. In vitro hyperthermia data performed on both cell lines indicate that the cancer cells are more sensitive to MH treatment with a 90% drop in viability after 30 min of MH treatment at 30 kA/m for a dose of 250 μg/cm2. Overall, our data indicate that Zn doping of iron oxide MNPs could be a reliable method to increase their hyperthermia efficiency in cancer cells.

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“…The 12 ± 1 nm Zn-ferrite NC (Zn 0.2 Fe 2.8 O 4 ) sample showed a significantly low coercive field and high saturation magnetization at both 300 K and 10 K, being superparamagnetic at 300 K, in accordance with the literature. 7,47 The inclusion of cobalt ions into the Zn-Co-ferrite NC of the 11 nm sample (Zn 0.1 Co 0.5 Fe 2.4 O 4 ) also showed superparamagnetic behaviour at 300 K, but the H c drastically increased at 10 K (1600 kA m −1 ), so other magnetic structures may have affected the overall magnetic features. In general, such a behaviour is ascribed to the formation of core-shell structures, 16,48 which may lead to the hypothesis that the NCs present an iron-rich core and a Zn/Co-rich shell ferrite structure.…”

Section: Synthesis Of Mixed Ferrite Ncs: Control Over the Compositionmentioning

confidence: 99%

Di- and tri-component spinel ferrite nanocubes: synthesis and their comparative characterization for theranostic applications

et al. 2021

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Cubic Anisotropic Co- and Zn-Substituted Ferrite Nanoparticles as Multimodal Magnetic Agents

Cited by 37 publications

References 100 publications

Finding the Limits of Magnetic Hyperthermia on Core-Shell Nanoparticles Fabricated by Physical Vapor Methods

Finding the Limits of Magnetic Hyperthermia on Core-Shell Nanoparticles Fabricated by Physical Vapor Methods

The Effect of Zn-Substitution on the Morphological, Magnetic, Cytotoxic, and In Vitro Hyperthermia Properties of Polyhedral Ferrite Magnetic Nanoparticles

Di- and tri-component spinel ferrite nanocubes: synthesis and their comparative characterization for theranostic applications

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