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2 article(s) from Tremel, Wolfgang

Comparative evaluation of the impact on endothelial cells induced by different nanoparticle structures and functionalization

Lisa Landgraf,
Ines Müller,
Peter Ernst,
Miriam Schäfer,
Christina Rosman,
Isabel Schick,
Oskar Köhler,
Hartmut Oehring,
Vladimir V. Breus,
Thomas Basché,
Carsten Sönnichsen,
Wolfgang Tremel and
Ingrid Hilger

Beilstein J. Nanotechnol. 2015, 6, 300–312, doi:10.3762/bjnano.6.28

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Figure 1: Impact of different shaped and functionalized nanoparticles on the cellular ATP-level of different ...

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Figure 2: Comparative impact of quantum dots (QDs) with different surface coatings on cells measured after 24...

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Figure 3: Size effects of the different manganese oxide nanoparticle formulations on the cellular ATP levels ...

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Figure 4: Internalization of different nanoparticles by endothelial cells depends mainly on the surface charg...

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Figure 5: Transmission electron microscopy (TEM) images of different endothelial cells determined after 1 h a...

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Figure 6: Microscopy images of endothelial cells and semi quantitative analysis of nanoparticle uptake to det...

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Figure 7: Impact of gold nanoparticles on cellular ATP levels of endothelial cells after the use of different...

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Supp Info

Full Research Paper

Published 27 Jan 2015

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Inorganic Janus particles for biomedical applications

Isabel Schick,
Steffen Lorenz,
Dominik Gehrig,
Stefan Tenzer,
Wiebke Storck,
Karl Fischer,
Dennis Strand,
Frédéric Laquai and
Wolfgang Tremel

Beilstein J. Nanotechnol. 2014, 5, 2346–2362, doi:10.3762/bjnano.5.244

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Figure 1: Illustrations of the transition from isotropic to anisotropic particles.

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Figure 2: a) Evolution of the PL-peak position, b) schematic representation, and c) evolution of the PL-quant...

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Figure 3: Summary of synthetic routes towards organic Janus particles. (a) Directed functionalization after i...

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Figure 4: (a) Schematic representation of bimetallic Janus particles at the hexane–water interface (gold: gol...

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Figure 5: (A) SEM top view image of a typical kaolinite platelet (left), schematic picture of kaolinite plate...

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Figure 6: a) Proposed photocatalytic process for efficient hydrogen generation using the Janus Au@TiO₂ nanost...

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Figure 7: a) UV–vis spectra of Au@Fe₃O₄ nanoparticles corresponding to schematic representations in b). The s...

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Figure 8: TEM bright field images of Au nanoparticles with different diameters (a) 4 nm, (b) 8 nm, and (c) 15...

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Figure 9: TEM bright field images of Au@MnO and Au@Fe₃O₄ heterodimer-nanoparticles: (a) 9@18 nm Au@MnO, (b) 4...

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Figure 10: Domain size dependency of absorption maximum of Au@MnO nanoparticles determined by UV–vis spectrosc...

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Figure 11: UV–vis spectra of Au (solid), Au@MnO (dashed), and Au@Fe₃O₄ (dotted) nanoparticles normalized to th...

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Figure 12: Schematic representation of the formation of Cu@Fe₃O₄ heterodimers with different morphologies base...

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Figure 13: Synthetic protocol of the synthesis of Co@Fe₂O₃ heterodimer and phase pure CoFe₂O₄ nanoparticles (t...

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Figure 14: CLSM images of HeLa cells co-incubated with Au@MnO@SiO₂-Atto495 Janus particles (green) for 24 h at...

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Scheme 1: Seed-mediated synthesis of Au@MO_x heterodimers, subsequent encapsulation with silica and functional...

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Figure 15: TEM micrographs of silica encapsulated Janus particles; (a,b) Au@MnO@SiO₂ (10@20 nm), and (c,d) Au@...

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Figure 16: Dynamic light scattering results of Au (red dots), Au@Fe₃O₄ (blue dots) dispersed in n-heptane, and...

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Figure 17: (a) Time-resolved fluorescence spectra of Au nanoparticles (green), Atto495 (orange), MnO@SiO₂ (red...

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Figure 18: Labelfree LC-MS Analysis of the hard protein corona of Fe₃O₄@SiO₂, MnO@SiO₂, and Au@MnO@SiO₂ nanopa...

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Review

Published 05 Dec 2014

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