| human | Q5 |
| P973 | described at URL | https://msc-med.u-paris.fr/index.php/2024/02/19/florence-gazeau-recoit-la-medaille-dargent-du-cnrs/ |
| P1960 | Google Scholar author ID | shPWptkAAAAJ |
| P269 | IdRef ID | 153127651 |
| P213 | ISNI | 0000000358624433 |
| P496 | ORCID iD | 0000-0002-6482-3597 |
| P2038 | ResearchGate profile ID | Florence_Gazeau |
| P214 | VIAF ID | 209273314 |
| P166 | award received | CNRS silver medal | Q3332287 |
| P27 | country of citizenship | France | Q142 |
| P184 | doctoral advisor | Régine Perzynski | Q103830485 |
| P69 | educated at | Paris Diderot University | Q1235608 |
| P101 | field of work | nanomagnetics | Q113829270 |
| P735 | given name | Florence | Q950780 |
| Florence | Q950780 | ||
| P1412 | languages spoken, written or signed | French | Q150 |
| P106 | occupation | physicist | Q169470 |
| researcher | Q1650915 | ||
| P39 | position held | Director of Research at CNRS | Q3029430 |
| P21 | sex or gender | female | Q6581072 |
| Q44909482 | Adipose tissue macrophages: MR tracking to monitor obesity-associated inflammation |
| Q77806531 | Anisotropy of the structure factor of magnetic fluids under a field probed by small-angle neutron scattering |
| Q57559341 | Anti-Estrogen-Loaded Superparamagnetic Liposomes for Intracellular Magnetic Targeting and Treatment of Breast Cancer Tumors |
| Q57559453 | Binding of biological effectors on magnetic nanoparticles measured by a magnetically induced transient birefringence experiment |
| Q51737548 | Biodegradation mechanisms of iron oxide monocrystalline nanoflowers and tunable shield effect of gold coating. |
| Q46604977 | Biodegradation of iron oxide nanocubes: high-resolution in situ monitoring |
| Q57559250 | Biotransformations of magnetic nanoparticles in the body |
| Q38838647 | Carbon Nanotube Degradation in Macrophages: Live Nanoscale Monitoring and Understanding of Biological Pathway |
| Q33642971 | Cell labeling with magnetic nanoparticles: opportunity for magnetic cell imaging and cell manipulation |
| Q51549412 | Cell sorting by endocytotic capacity in a microfluidic magnetophoresis device. |
| Q51799776 | Cell-derived vesicles as a bioplatform for the encapsulation of theranostic nanomaterials. |
| Q50665105 | Cellular transfer of magnetic nanoparticles via cell microvesicles: impact on cell tracking by magnetic resonance imaging. |
| Q57559285 | Colloidal Ordered Assemblies in a Polymer Shell—A Novel Type of Magnetic Nanobeads for Theranostic Applications |
| Q38919104 | Combining magnetic nanoparticles with cell derived microvesicles for drug loading and targeting |
| Q41626412 | Controlled clustering of superparamagnetic nanoparticles using block copolymers: design of new contrast agents for magnetic resonance imaging |
| Q57559318 | Cooperative Organization in Iron Oxide Multi-Core Nanoparticles Potentiates Their Efficiency as Heating Mediators and MRI Contrast Agents |
| Q57559342 | Correlating Magneto-Structural Properties to Hyperthermia Performance of Highly Monodisperse Iron Oxide Nanoparticles Prepared by a Seeded-Growth Route |
| Q59652032 | Covalent Functionalization of Multi-walled Carbon Nanotubes with a Gadolinium Chelate for EfficientT1-Weighted Magnetic Resonance Imaging |
| Q42916245 | Degradability of superparamagnetic nanoparticles in a model of intracellular environment: follow-up of magnetic, structural and chemical properties |
| Q57183917 | Design of biomimetic vascular grafts with magnetic endothelial patterning |
| Q30863938 | Design of covalently functionalized carbon nanotubes filled with metal oxide nanoparticles for imaging, therapy, and magnetic manipulation |
| Q35972352 | Designing 3D Mesenchymal Stem Cell Sheets Merging Magnetic and Fluorescent Features: When Cell Sheet Technology Meets Image-Guided Cell Therapy |
| Q57559348 | Doxorubicin Release Triggered by Alginate Embedded Magnetic Nanoheaters: A Combined Therapy |
| Q100996691 | Endocytosis-driven gold nanoparticle fractal rearrangement in cells and its influence on photothermal conversion |
| Q57184374 | Endothelial cell-derived microparticles loaded with iron oxide nanoparticles: feasibility of MR imaging monitoring in mice |
| Q39167673 | Endowing carbon nanotubes with superparamagnetic properties: applications for cell labeling, MRI cell tracking and magnetic manipulations |
| Q51212493 | Ferritin Protein Regulates the Degradation of Iron Oxide Nanoparticles. |
| Q57559427 | Fluorescence-Modified Superparamagnetic Nanoparticles: Intracellular Uptake and Use in Cellular Imaging |
| Q39891505 | Formation of a three-dimensional multicellular assembly using magnetic patterning |
| Q30996711 | Generation of superparamagnetic liposomes revealed as highly efficient MRI contrast agents for in vivo imaging |
| Q44833631 | Glucose-receptor MR imaging of tumors: study in mice with PEGylated paramagnetic niosomes |
| Q99233675 | Gold-based therapy: From past to present |
| Q57559368 | High-Resolution 1.5-Tesla Magnetic Resonance Imaging for Tissue-Engineered Constructs: A Noninvasive Tool to Assess Three-Dimensional Scaffold Architecture and Cell Seeding |
| Q48714897 | High-resolution cellular MRI: gadolinium and iron oxide nanoparticles for in-depth dual-cell imaging of engineered tissue constructs |
| Q57559257 | Hollow Iron Oxide Nanoparticles in Polymer Nanobeads as MRI Contrast Agents |
| Q39339408 | How cellular processing of superparamagnetic nanoparticles affects their magnetic behavior and NMR relaxivity |
| Q57559233 | Imaging and Therapeutic Potential of Extracellular Vesicles |
| Q38728175 | In vivo degeneration and the fate of inorganic nanoparticles |
| Q37680053 | In vivo imaging of transplanted hepatocytes with a 1.5-T clinical MRI system--initial experience in mice |
| Q39912699 | In vivo single cell detection of tumor-infiltrating lymphocytes with a clinical 1.5 Tesla MRI system |
| Q57559322 | Intercellular Carbon Nanotube Translocation Assessed by Flow Cytometry Imaging |
| Q40237616 | Internal structure of magnetic endosomes |
| Q57559350 | Intracellular Confinement of Magnetic Nanoparticles by Living Cells: Impact for Imaging and Therapeutic Applications |
| Q108886099 | Intracellular Fate of Hydrophobic Nanocrystal Self‐Assemblies in Tumor Cells |
| Q57559401 | Intracellular Trafficking of Magnetic Nanoparticles to Design Multifunctional Biovesicles |
| Q29248258 | Intracellular degradation of functionalized carbon nanotube/iron oxide hybrids is modulated by iron via Nrf2 pathway |
| Q40104377 | Intracellular heating of living cells through Néel relaxation of magnetic nanoparticles |
| Q57559326 | Iron Oxide Monocrystalline Nanoflowers for Highly Efficient Magnetic Hyperthermia |
| Q51956840 | Linear patterning of magnetically labeled Dictyostelium cells to display confined development. |
| Q104483850 | Local administration of stem cell-derived extracellular vesicles in a thermoresponsive hydrogel promotes a pro-healing effect in a rat model of colo-cutaneous post-surgical fistula |
| Q40392870 | Localization and relative quantification of carbon nanotubes in cells with multispectral imaging flow cytometry |
| Q57559352 | Long term in vivo biotransformation of iron oxide nanoparticles |
| Q61787815 | Magnetic Targeting of Rhodamine-Labeled Superparamagnetic Liposomes to Solid Tumors: In Vivo Tracking by Fibered Confocal Fluorescence Microscopy |
| Q43550977 | Magnetic and photoresponsive theranosomes: translating cell-released vesicles into smart nanovectors for cancer therapy |
| Q50989748 | Magnetic control of vascular network formation with magnetically labeled endothelial progenitor cells. |
| Q78080245 | Magnetic fluid under vorticity: Free precession decay of magnetization and optical anisotropy |
| Q37855910 | Magnetic labeling, imaging and manipulation of endothelial progenitor cells using iron oxide nanoparticles |
| Q57559377 | Magnetic micro-manipulations to probe the local physical properties of porous scaffolds and to confine stem cells |
| Q57559385 | Magnetic nanoparticles: Internal probes and heaters within living cells |
| Q39675267 | Magnetic tagging of cell-derived microparticles: new prospects for imaging and manipulation of these mediators of biological information |
| Q39896527 | Magnetic targeting of iron-oxide-labeled fluorescent hepatoma cells to the liver |
| Q50480585 | Magnetic targeting of magnetoliposomes to solid tumors with MR imaging monitoring in mice: feasibility. |
| Q33287383 | Magnetic targeting of nanometric magnetic fluid loaded liposomes to specific brain intravascular areas: a dynamic imaging study in mice |
| Q48912485 | Magnetic targeting of rhodamine-labeled superparamagnetic liposomes to solid tumors: in vivo tracking by fibered confocal fluorescence microscopy |
| Q57559329 | Magnetic vesicles as MRI-trackable biogenic nanovectors |
| Q47233482 | Magnetically induced hyperthermia: size-dependent heating power of γ-Fe(2)O(3) nanoparticles |
| Q57559464 | Magnetophoresis and ferromagnetic resonance of magnetically labeled cells |
| Q48783861 | Magnetophoresis at the nanoscale: tracking the magnetic targeting efficiency of nanovectors |
| Q43512074 | Managing magnetic nanoparticle aggregation and cellular uptake: a precondition for efficient stem-cell differentiation and MRI tracking |
| Q57559237 | Medical Applications of Iron Oxide Nanoparticles |
| Q57559357 | Modeling magnetic nanoparticle dipole-dipole interactions inside living cells |
| Q89429452 | Modification of Extracellular Vesicles by Fusion with Liposomes for the Design of Personalized Biogenic Drug Delivery Systems |
| Q57559360 | Multifunctional nanovectors based on magnetic nanoparticles coupled with biological vesicles or synthetic liposomes |
| Q39398202 | Nanomagnetic sensing of blood plasma protein interactions with iron oxide nanoparticles: impact on macrophage uptake |
| Q57559363 | Nanomagnetism reveals the intracellular clustering of iron oxide nanoparticles in the organism |
| Q57559328 | Nanoparticules magnétiques au cœur des cellules : des outils pour les thérapies cellulaires |
| Q48183060 | Nanoprobe Synthesized by Magnetotactic Bacteria, Detecting Fluorescence Variations under Dissociation of Rhodamine B from Magnetosomes following Temperature, pH Changes, or the Application of Radiation |
| Q42266386 | Nanoscale Brownian heating by interacting magnetic dipolar particles |
| Q37331799 | Optimizing magnetic nanoparticle design for nanothermotherapy |
| Q53739678 | Overcoming the tumor microenvironment: the role of nanohyperthermia. |
| Q50481310 | Phenotypic study of human gingival fibroblasts labeled with superparamagnetic anionic nanoparticles. |
| Q50073663 | Physical oncology: New targets for nanomedicine |
| Q37571239 | Physiological Remediation of Cobalt Ferrite Nanoparticles by Ferritin |
| Q95301765 | Raman reporters derived from aryl diazonium salts for SERS encoded-nanoparticles |
| Q57559390 | Reactivity of the monocyte/macrophage system to superparamagnetic anionic nanoparticles |
| Q46433474 | Real-time high-resolution magnetic resonance tracking of macrophage subpopulations in a murine inflammation model: a pilot study with a commercially available cryogenic probe |
| Q57559308 | Revisiting MRI Contrast Properties of Nanoparticles: Beyond the Superparamagnetic Regime |
| Q52566756 | Rotational magnetic endosome microrheology: viscoelastic architecture inside living cells. |
| Q47303393 | Size-sorted anionic iron oxide nanomagnets as colloidal mediators for magnetic hyperthermia |
| Q38779443 | Successful chondrogenesis within scaffolds, using magnetic stem cell confinement and bioreactor maturation |
| Q51612769 | The MRI assessment of intraurethrally--delivered muscle precursor cells using anionic magnetic nanoparticles. |
| Q53429140 | The One Year Fate of Iron Oxide Coated Gold Nanoparticles in Mice. |
| Q39682120 | The role of cell-released microvesicles in the intercellular transfer of magnetic nanoparticles in the monocyte/macrophage system |
| Q57795189 | Thermoresponsive Gel Embedded with Adipose Stem-Cell-Derived Extracellular Vesicles Promotes Esophageal Fistula Healing in a Thermo-Actuated Delivery Strategy |
| Q61798816 | Thermoresponsive Iron Oxide Nanocubes for an Effective Clinical Translation of Magnetic Hyperthermia and Heat-Mediated Chemotherapy |
| Q40096804 | Tumour cell toxicity of intracellular hyperthermia mediated by magnetic nanoparticles |
| Q92094552 | Unexpected intracellular biodegradation and recrystallization of gold nanoparticles |
| Q37153898 | Universal cell labelling with anionic magnetic nanoparticles |
| Q57559246 | Zinc substituted ferrite nanoparticles with Zn0.9Fe2.1O4 formula used as heating agents for in vitro hyperthermia assay on glioma cells |
| Q103830485 | Régine Perzynski | doctoral student | P185 |
| Florence Gazeau | wikipedia |
Search more.