Small Multifunctional Nanoclusters (Nanoroses) for Targeted Cellular Imaging and Therapy

Li, Leo; Feldman, Marc D.; Tam, Jason; Paranjape, Amit S.; Cheruku, Kiran K.; Larson, Timothy; Tam, Justina; Ingram, Davis R.; Paramita, Vidia; Villard, Joseph W.; Jenkins, James T.; Wang, Tianyi; Clarke, Geoffrey D.; Asmis, Reto; Sokolov, Konstantin; Chandrasekar, Bysani; Milner, Thomas E.; Johnston, Keith P.

doi:10.1021/nn900440e

Cited by 190 publications

(225 citation statements)

References 55 publications

(181 reference statements)

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“…The TEM image of the sample prepared at an MR value of 5.2 has several branched flower-like particles that are similar to the 'nanoroses' described in a recent report (26). The mean size (diameter of an equivalent circle having the same projected area) is not reported due to the highly irregular shape of the particles.…”

Section: Variation Of Mean Nanoparticle Size With Mr Valuesupporting

confidence: 73%

Room-temperature synthesis of gold nanoparticles — Size-control by slow addition

2010

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We report a simple and rapid process for the roomtemperature synthesis of gold nanoparticles using tannic acid, a green reagent, as both the reducing and stabilising agent. We systematically investigated the effect of pH on the size distribution of nanoparticles synthesized. Based on induction time and -potential measurements, we show that particle size distribution is controlled by a fine balance between the rates of reduction (determined by the initial pH of reactants) and coalescence (determined by the pH of the reaction mixture) in the initial period of growth. This insight led to the optimal batch process for size-controlled synthesis of 2-10 nm gold nanoparticles -slow addition (within 10 minutes) of chloroauric acid into tannic acid.

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Section: Variation Of Mean Nanoparticle Size With Mr Valuesupporting

confidence: 73%

Room-temperature synthesis of gold nanoparticles — Size-control by slow addition

2010

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“…In this direction, improved or collective physical properties can be obtained by bringing magnetic nanocrystals next to one another at distances where they can interact. If preformed, they can be encapsulated in an organic [13][14][15][16][17] or inorganic [18][19][20] matrix in order to form an aggregate or can grow and assemble together at high temperature via a single-step process. Colloidal assemblies of either type have been stabilized by the balance between the electrostatic, entailing the capping molecules and the magnetic interactions involving the incorporated inorganic subunits.…”

Section: Introductionmentioning

confidence: 99%

Colloidal magnetic nanocrystal clusters: variable length-scale interaction mechanisms, synergetic functionalities and technological advantages

Κωστοπούλου

Lappas

2015

Nanotechnology Reviews

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Magnetic particles of optimized nanoscale dimensions can be utilized as building blocks to generate colloidal nanocrystal assemblies with controlled size, well-defined morphology, and tailored properties. Recent advances in the state-of-the-art surfactant-assisted approaches for the directed aggregation of inorganic nanocrystals into cluster-like entities are discussed, and the synthesis parameters that determine their geometrical arrangement are highlighted. This review pays attention to the enhanced physical properties of iron oxide nanoclusters, while it also points to their emerging collective magnetic response. The current progress in experiment and theory for evaluating the strength and the role of intra-and inter-cluster interactions is analyzed in view of the spatial arrangement of the component nanocrystals. Numerous approaches have been proposed for the critical role of dipole-dipole and exchange interactions in establishing the nature of the nanoclusters' cooperative magnetic behavior (be it ferromagnetic or spin-glass like). Finally, we point out why the purposeful engineering of the nanoclusters' magnetic characteristics, including their surface functionality, may facilitate their use in diverse technological sectors ranging from nanomedicine and photonics to catalysis.

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“…The gold-iron oxide composites exhibit the occurrence of the 15 nm-sized iron oxide USM nanoparticles accompanied by submicrometre flower-like structures. Branched and flower-like morphology has been widely reported both for nanostructured gold, and for gold-iron oxide nanoheterostructures [27,30,39].…”

Section: Resultsmentioning

confidence: 99%

Assessing the hyperthermic properties of magnetic heterostructures: the case of gold–iron oxide composites

et al. 2016

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Gold-iron oxide composites were obtained by in situ reduction of an Au(III) precursor by an organic reductant (either potassium citrate or tiopronin) in a dispersion of preformed iron oxide ultrasmall magnetic (USM) nanoparticles. X-ray diffraction, transmission electron microscopy, chemical analysis and mid-infrared spectroscopy show the successful deposition of gold domains on the preformed magnetic nanoparticles, and the occurrence of either citrate or tiopronin as surface coating. The potential of the USM@Au nanoheterostructures as heat mediators for therapy through magnetic fluid hyperthermia was determined by calorimetric measurements under sample irradiation by an alternating magnetic field with intensity and frequency within the safe values for biomedical use. The USM@Au composites showed to be active heat mediators for magnetic fluid hyperthermia, leading to a rapid increase in temperature under exposure to an alternating magnetic field even under the very mild experimental conditions adopted, and their potential was assessed by determining their specific absorption rate (SAR) and compared with the pure iron oxide nanoparticles. Calorimetric investigation of the synthesized nanostructures enabled us to point out the effect of different experimental conditions on the SAR value, which is to date the parameter used for the assessment of the hyperthermic efficiency.

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Small Multifunctional Nanoclusters (Nanoroses) for Targeted Cellular Imaging and Therapy

Cited by 190 publications

References 55 publications

Room-temperature synthesis of gold nanoparticles — Size-control by slow addition

Room-temperature synthesis of gold nanoparticles — Size-control by slow addition

Colloidal magnetic nanocrystal clusters: variable length-scale interaction mechanisms, synergetic functionalities and technological advantages

Assessing the hyperthermic properties of magnetic heterostructures: the case of gold–iron oxide composites

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Small Multifunctional Nanoclusters (Nanoroses) for Targeted Cellular Imaging and Therapy

Cited by 190 publications

References 55 publications

Room-temperature synthesis of gold nanoparticles &#x2014; Size-control by slow addition

Room-temperature synthesis of gold nanoparticles &#x2014; Size-control by slow addition

Colloidal magnetic nanocrystal clusters: variable length-scale interaction mechanisms, synergetic functionalities and technological advantages

Assessing the hyperthermic properties of magnetic heterostructures: the case of gold–iron oxide composites

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Room-temperature synthesis of gold nanoparticles — Size-control by slow addition

Room-temperature synthesis of gold nanoparticles — Size-control by slow addition