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MRI relaxation properties of water-soluble apoferritin-encapsulated gadolinium oxide-hydroxide nanoparticles.Native and synthetic ferritins for nanobiomedical applications: recent advances and new perspectives.Apomaghemite as a doxorubicin carrier for anticancer drug delivery.Covalent deposition of ferritin nanoparticles onto gold surfaces.In vivo long-term magnetic resonance imaging activity of ferritin-based magnetic nanoparticles versus a standard contrast agent.Catechol releases iron(III) from ferritin by direct chelation without iron(II) production.Hexacyanocobaltate(III) anions as precursors of Co(II)-Ni(II) cyano-bridged multidimensional assemblies: hydrothermal syntheses, crystal and powder X-ray structures, and magnetic properties.Rate of iron transfer through the horse spleen ferritin shell determined by the rate of formation of Prussian Blue and Fe-desferrioxamine within the ferritin cavity.Nanopatterning of Magnetic CrNi Prussian Blue Nanoparticles Using a Bacterial S-Layer as a Biotemplate.Preparation of Cu and CuFe Prussian Blue derivative nanoparticles using the apoferritin cavity as nanoreactor.From synthetic to natural nanoparticles: monitoring the biodegradation of SPIO (P904) into ferritin by electron microscopyMagnetic nanoparticles--templated assembly of protein subunits: a new platform for carbohydrate-based MRI nanoprobesSurface effects in noninteracting and interacting γ-Fe2O3 nanoparticlesApoferritin Protein Amyloid Fibrils with Tunable Chirality and PolymorphismStructural and magnetic characterization of Pd nanoparticles encapsulated in apoferritinMagnetic Langmuir-Blodgett films of ferritin with different iron contentsFluorescence resonance energy transfer in ferritin labeled with multiple fluorescent dyesComparative structural and chemical studies of ferritin cores with gradual removal of their iron contentsThermal induced phase transitions and structural relaxation in apoferritin encapsulated copper nanoparticlesA bioinspired approach to the synthesis of bimetallic CoNi nanoparticlesA new approach to the ferritin iron core growth: influence of the H/L ratio on the core shapeElectrochromic polyoxometalate material as a sensor of bacterial activityBioinspired magneto-optical bacteria
P50
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P50
description
researcher ORCID ID = 0000-0003-4286-6278
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wetenschapper
@nl
name
N Galvez
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N Galvez
@en
N Galvez
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type
label
N Galvez
@ast
N Galvez
@en
N Galvez
@nl
prefLabel
N Galvez
@ast
N Galvez
@en
N Galvez
@nl
P31
P496
0000-0003-4286-6278