0000000000266352

AUTHOR

Isabel Schick

showing 6 related works from this author

Effect of Charge Transfer in Magnetic-Plasmonic Au@MOx (M = Mn, Fe) Heterodimers on the Kinetics of Nanocrystal Formation

2015

Heteronanoparticles represent a new class of nanomaterials exhibiting multifunctional and collective properties, which could find applications in medical imaging and therapy, catalysis, photovoltaics, and electronics. This present work demonstrates the intrinsic heteroepitaxial linkage in heterodimer nanoparticles to enable interaction of the individual components across their interface. It revealed distinct differences between Au@MnO and Au@Fe3O4 regarding the synthetic procedure and growth kinetics, as well as the properties to be altered by the variation of the electronic structure of the metal oxides. The chemically related metal oxides differ concerning their band gap; while MnO is a M…

Materials sciencebusiness.industryBand gapGeneral Chemical EngineeringNanoparticleNanotechnologyGeneral ChemistryElectronic structureSemimetalNanomaterialsMetalSemiconductorNanocrystalChemical physicsvisual_artMaterials Chemistryvisual_art.visual_art_mediumbusinessChemistry of Materials
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Comparative evaluation of the impact on endothelial cells induced by different nanoparticle structures and functionalization

2015

In the research field of nanoparticles, many studies demonstrated a high impact of the shape, size and surface charge, which is determined by the functionalization, of nanoparticles on cell viability and internalization into cells. This work focused on the comparison of three different nanoparticle types to give a better insight into general rules determining the biocompatibility of gold, Janus and semiconductor (quantum dot) nanoparticles. Endothelial cells were subject of this study, since blood is the first barrier after intravenous nanoparticle application. In particular, stronger effects on the viability of endothelial cells were found for nanoparticles with an elongated shape in compa…

Materials scienceBiocompatibilitymedia_common.quotation_subjectJanus particlesGeneral Physics and AstronomyNanoparticleJanus particlesNanotechnologyquantum dotslcsh:Chemical technologylcsh:TechnologyFull Research PaperNanotechnologylcsh:TP1-1185General Materials ScienceViability assayElectrical and Electronic Engineeringlcsh:ScienceInternalizationNanoparticle Applicationcell viabilitymedia_commonlcsh:Tlcsh:QC1-999internalizationNanoscienceColloidal goldgold nanoparticlesSurface modificationlcsh:Qlcsh:PhysicsBeilstein Journal of Nanotechnology
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Inorganic Janus particles for biomedical applications.

2014

Based on recent developments regarding the synthesis and design of Janus nanoparticles, they have attracted increased scientific interest due to their outstanding properties. There are several combinations of multicomponent hetero-nanostructures including either purely organic or inorganic, as well as composite organic–inorganic compounds. Janus particles are interconnected by solid state interfaces and, therefore, are distinguished by two physically or chemically distinct surfaces. They may be, for instance, hydrophilic on one side and hydrophobic on the other, thus, creating giant amphiphiles revealing the endeavor of self-assembly. Novel optical, electronic, magnetic, and superficial pro…

Materials scienceBiocompatibilitysynthesisJanus particlesGeneral Physics and AstronomyNanoparticleNanotechnologyJanus particlesProtein CoronaReviewlcsh:Chemical technologylcsh:TechnologyNanomaterialshetero-nanoparticlesprotein coronaMulti-photon)AmphiphileNanotechnologylcsh:TP1-1185General Materials ScienceElectrical and Electronic Engineeringlcsh:ScienceNanoscopic scalePlasmonlcsh:Tbioimaging (CTlcsh:QC1-999Nanosciencelcsh:Qlcsh:PhysicsMRIBeilstein journal of nanotechnology
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A plasma protein corona enhances the biocompatibility of Au@Fe3O4 Janus particles

2015

AbstractAu@Fe3O4 Janus particles (JPs) are heteroparticles with discrete domains defined by different materials. Their tunable composition and morphology confer multimodal and versatile capabilities for use as contrast agents and drug carriers in future medicine. Au@Fe3O4 JPs have colloidal properties and surface characteristics leading to interactions with proteins in biological fluids. The resulting protein adsorption layer (“protein corona”) critically affects their interaction with living matter. Although Au@Fe3O4 JPs displayed good biocompatibility in a standardized in vitro situation, an in-depth characterization of the protein corona is of prime importance to unravel underlying mecha…

endocrine systemMaterials scienceBiocompatibilitySurface PropertiesJanus particlesBiophysicsContrast MediaJanus particlesProtein CoronaNanotechnologyBioengineeringMultimodal ImagingNanocapsulesBiomaterialsMiceCoated Materials BiocompatibleNanocapsulesAnimalsHumansTissue DistributionNanotoxicityParticle SizeMagnetite NanoparticlesEndothelial CellsBlood ProteinsAdhesionMagnetic Resonance ImagingNanomedicineProtein coronaNanotoxicologyMechanics of MaterialsIn vivo imagingBiophysicsCeramics and CompositesAdsorptionGoldParticle sizeTomography X-Ray ComputedProtein adsorptionBiomaterials
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Multifunctional two-photon active silica-coated Au@MnO Janus particles for selective dual functionalization and imaging.

2014

Monodisperse multifunctional and nontoxic Au@MnO Janus particles with different sizes and morphologies were prepared by a seed-mediated nucleation and growth technique with precise control over domain sizes, surface functionalization, and dye labeling. The metal oxide domain could be coated selectively with a thin silica layer, leaving the metal domain untouched. In particular, size and morphology of the individual (metal and metal oxide) domains could be controlled by adjustment of the synthetic parameters. The SiO2 coating of the oxide domain allows biomolecule conjugation (e.g., antibodies, proteins) in a single step for converting the photoluminescent and superparamagnetic Janus nanopar…

Diagnostic ImagingCell SurvivalSurface PropertiesDispersityOxideMetal NanoparticlesJanus particlesNanotechnologyBiochemistryCatalysischemistry.chemical_compoundColloid and Surface ChemistryMicroscopy Electron TransmissionCell Line TumorMicroscopySpectroscopy Fourier Transform InfraredHumansParticle SizePhotonsChemistryBiological TransportGeneral ChemistrySilicon DioxideTransmission electron microscopySurface modificationNanoparticlesParticle sizeGoldSuperparamagnetismHeLa CellsJournal of the American Chemical Society
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Anti-oxidative effects and harmlessness of asymmetric Au@Fe3O4 Janus particles on human blood cells

2014

AbstractThe physical properties of asymmetric Janus particles are highly promising for future biomedical applications. However, only a few data is available on their biological impact on human cells. We investigated the biological impact of different Au@Fe3O4 Janus particle formulations in vitro to analyse specific uptake modalities and their potential cytotoxic effects on human cells of the blood regarding intravenous injection. We demonstrate that Au@Fe3O4 Janus particles exhibit a similar or even better biocompatibility compared to the well-studied spherical iron oxide nanoparticles. The impact of Janus particles on cells depends mainly on three factors. (1) Surface functionalization: NH…

Blood cellsMaterials scienceBiophysicsUptakeNanoparticleBioengineeringJanus particlesNanotechnologyBiomaterialsCell membranechemistry.chemical_compoundAmino functionalizationmedicineJanusCell metabolismAdhesionJanus particlemedicine.anatomical_structurechemistryMechanics of MaterialsCeramics and CompositesBiophysicsParticleSurface modificationCell membraneIron oxide nanoparticlesBiomaterials
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