Size and property bimodality in magnetic nanoparticle dispersions: single domain particles vs. strongly coupled nanoclusters

Wetterskog, Erik; Castro, Alejandra; Zeng, Lunjie; Petronis, Šarūnas; Heinke, David; Olsson, Eva; Nilsson, Lars; Gehrke, Nicole; Svedlindh, Peter

doi:10.1039/c7nr00023e

Cited by 21 publications

(37 citation statements)

References 42 publications

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“…These observations verify that the samples FS-XS→XXL contain in fact distinct fractions of core-clusters with systematically increasing size. Considering that for isometric clusters we would expect a bell-like shape of P (r), the elongated shape of the experimentally determined distributions for all seven samples suggests that the clusters tend to be anisotropic, as also observed by electron microscopy in [21].…”

Section: Saxssupporting

confidence: 69%

Influence of clustering on the magnetic properties and hyperthermia performance of iron oxide nanoparticles

et al. 2018

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Clustering of magnetic nanoparticles can drastically change their collective magnetic properties, which in turn may influence their performance in technological or biomedical applications. Here, we investigate a commercial colloidal dispersion (FeraSpinR), which contains dense clusters of iron oxide cores (mean size around 9 nm according to neutron diffraction) with varying cluster size (about 18-56 nm according to small angle x-ray diffraction), and its individual size fractions (FeraSpinXS, S, M, L, XL, XXL). The magnetic properties of the colloids were characterized by isothermal magnetization, as well as frequency-dependent optomagnetic and AC susceptibility measurements. From these measurements we derive the underlying moment and relaxation frequency distributions, respectively. Analysis of the distributions shows that the clustering of the initially superparamagnetic cores leads to remanent magnetic moments within the large clusters. At frequencies below 10 rad s, the relaxation of the clusters is dominated by Brownian (rotation) relaxation. At higher frequencies, where Brownian relaxation is inhibited due to viscous friction, the clusters still show an appreciable magnetic relaxation due to internal moment relaxation within the clusters. As a result of the internal moment relaxation, the colloids with the large clusters (FS-L, XL, XXL) excel in magnetic hyperthermia experiments.

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Section: Saxssupporting

confidence: 69%

Influence of clustering on the magnetic properties and hyperthermia performance of iron oxide nanoparticles

et al. 2018

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“…by a factor ∼10 only ( × < 5 • 10 9 A•m −1 •s −1 ), as proposed by Dutz and Hergt. 13 As reported in literature, [14][15][16] higher specific heating rates of multicore IONPs as compared to single core IONPs are ascribed to "spin glass" dynamics of the magnetic moments within a cluster, strongly correlated by the exchange interaction. This collective behaviour enhances the magnetic susceptibility, i.e.…”

Section: Introductionsupporting

confidence: 50%

Monocorevs.multicore magnetic iron oxide nanoparticles: uptake by glioblastoma cells and efficiency for magnetic hyperthermia

Hemery

Genevois

Couillaud

et al. 2017

Mol. Syst. Des. Eng.

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“…FeraSpin R consists of elementary crystallites of iron-oxide, nominally γ-Fe 2 O 3 , with a diameter of 5–7 nm, according to which some of these crystallites aggregate to form particles with a larger diameter, such that there is a broader distribution due to these multi-cores [ 20 ] ( Figure 1 ). The mean hydrodynamic diameter is 60 nm.…”

Section: Introductionmentioning

confidence: 99%

“…A series of different multi-core size fractions have been isolated from FeraSpin R, namely, FeraSpin XS, FeraSpin M and FeraSpin XL, in which each fraction has a narrower multi-core size distribution than the parent material, and a mean hydrodynamic diameter of 15 nm, 35 nm, and 55 nm, respectively ( Figure 1 a). The magnetic core of FeraSpin XS has been shown from transmission electron microscopy (TEM) to be on the order of the elementary crystallites, with a mean of 5.8 nm, whereas FeraSpin L (not studied here) has larger aggregates with a mean magnetic core size of 33 nm [ 20 ]. Therefore, the average particle size of the fractions increases from XS to XL.…”

Section: Introductionmentioning

confidence: 99%

“…Therefore, the average particle size of the fractions increases from XS to XL. Although several studies have been made on FeraSpin R and the FeraSpin series in relation to their performance in MPI [ 17 , 18 , 20 , 21 , 22 , 23 ], this study performs a more detailed magnetic characterization on the immobilized particles. The magnetic properties of the immobilized particles are compared to the magnetic properties and image performance of Resovist.…”

Section: Introductionmentioning

confidence: 99%

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Enhanced Methods to Estimate the Efficiency of Magnetic Nanoparticles in Imaging

et al. 2017

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Magnetic resonance imaging (MRI) and magnetic particle imaging (MPI) are powerful methods in the early diagnosis of diseases. Both imaging techniques utilize magnetic nanoparticles that have high magnetic susceptibility, strong saturation magnetization, and no coercivity. FeraSpinTM R and its fractionated products have been studied for their imaging performances; however, a detailed magnetic characterization in their immobilized state is still lacking. This is particularly important for applications in MPI that require fixation of magnetic nanoparticles with the target cells or tissues. We examine the magnetic properties of immobilized FeraSpinTM R, its size fractions, and Resovist®, and use the findings to demonstrate which magnetic properties best predict performance. All samples show some degree of oxidation to hematite, and magnetic interaction between the particles, which impact negatively on image performance of the materials. MRI and MPI performance show a linear dependency on the slope of the magnetization curve, i.e., initial susceptibility, and average blocking temperature. The best performance of particles in immobilized state for MPI is found for particle sizes close to the boundary between superparamagnetic (SP) and magnetically ordered, in which only Néel relaxation is important. Initial susceptibility and bifurcation temperature are the best indicators to predict MRI and MPI performance.

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Size and property bimodality in magnetic nanoparticle dispersions: single domain particles vs. strongly coupled nanoclusters

Cited by 21 publications

References 42 publications

Influence of clustering on the magnetic properties and hyperthermia performance of iron oxide nanoparticles

Influence of clustering on the magnetic properties and hyperthermia performance of iron oxide nanoparticles

Monocorevs.multicore magnetic iron oxide nanoparticles: uptake by glioblastoma cells and efficiency for magnetic hyperthermia

Enhanced Methods to Estimate the Efficiency of Magnetic Nanoparticles in Imaging

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