Preparation, properties and biocompatibility of magnetic ...



Preparation, properties and biocompatibility of magnetic particles | |

|1 |Laccase immobilized on magnetic carriers for biotechnology applications |

|2 |High content analysis of the biocompatibility of nickel nanowires |

|3 |Functionalization of magnetic nanoparticles with 3-aminopropyl silane |

|4 |Dipolar chains formed by chemically-synthesized cobalt nanocubes |

|5 |Preparation of biodegradable magnetic microspheres with poly(lactic acid) coated magnetite |

|6 |Characterization of a magnetic carrier encapsulating europium and ferrite nanoparticles for biomolecular recognition |

| |and imaging |

|7 |Synthesis and characterization of multifunctional silica core-shell nanocomposites with magnetic and fluorescent |

| |functionalities |

|8 |Synthesis of the ultrasmall nanoparticles of magnetic iron oxides and study of their colloid and surface chemistry |

|9 |Probing temperature-sensitive behavior of pNIPAAm coated iron oxide nanoparticles using frequency dependent magnetic |

| |measurements |

|10 |Magnetic iron oxide nanopowders produced by CO2 laser evaporation - ‘in situ’ coating and particle embedding in a |

| |ceramic matrix |

|11 |Multifunctional, multicompartment polyorganosiloxane magnetic nanoparticles for biomedical applications |

|12 |Preparation of NiZn-ferrite nanofibers by electrospinning for DNA separation |

|13 |Synthesis and characterization of biocompatible magnetic glyconanoparticles |

|14 |Surface modification of magnetite nanoparticles for biomedical applications |

|15 |Monte Carlo simulation of magnetic multi-core nanoparticles |

|16 |Dispersibility improvement of gold/iron-oxide composite nanoparticles by polyethylenimine modification |

|17 |Synthesis and characterization of functionalized core-shell gFe2O3@SiO2 nanoparticles |

|18 |Synthesis of hollow ferrite nanospheres for biomedical applications |

|19 |Preparation of spherical and uniform-sized ferrite nanoparticles with diameters between 50–150 nm for biomedical |

| |applications |

|20 |Fabrication of water-soluble magnetic nanoparticles using thermo-responsive polymers |

|21 |Preparation and characterization of multi-functional CoFe2O4@ZnO nanocomposites |

|22 |Water soluble magnetic nanoparticles with biologically active stabilizers |

|Magnetic carriers as characterization tools |

|23 |Use of a magnetic fluid for particle size analysis by a sedimentation method |

|Magnetic separation |

|24 |Microfabricated magnetic sifter for high-throughput and high-gradient magnetic separation |

|25 |Design, fabrication and demonstration of a magnetophoresis chamber with 25 output fractions |

|26 |Theory for nanoparticle retention time in the helical channel of quadrupole magnetic field-flow fractionation |

|27 |Formation and properties of magnetic chains for 100 nm nanoparticles used in separations of molecules and cells |

|Applications and properties of magnetic particles in biology and medicine |

|28 |Characterization of magnetite nanoparticles for SQUID-relaxometry and magnetic needle biopsy |

|29 |Quantification of magnetic nanoparticles for cancer therapy |

|30 |Magnetic nanoparticles coated with carboxymethylated polysaccharide shells – Interaction with human cells |

|31 |Dependence of adenine isolation efficiency on the chain length evidenced using paramagnetic particles and voltammetry|

| |measurements |

|32 |Invert sugar formation with Saccharomyces cerevisiae cells encapsulated in magnetically responsive alginate |

| |microparticles |

|33 |Biocompatibility of various ferrite nanoparticles evaluated by in vitro cytotoxicity assays using HeLa cells |

|34 |Research on relationship between surface structure and morphology of Fe3O4/Silica composite nanospheres and nucleic |

| |acid extraction |

|Hyperthermia with magnetic particles |

|35 |Magnetic hyperthermia with biphasic gel of La1-xSrxMnO3 and maghemite |

|36 |Heat dissipation mechanism of magnetite nanoparticles in magnetic fluid hyperthermia |

|37 |Adiabatic versus non-adiabatic determination of specific absorption rate of ferrofluids |

|38 |Ferrofluids of magnetic multicore nanoparticles for biomedical applications |

|39 |Effect of poly(ethylene glycol) coating on the magnetic and thermal properties of biocompatible magnetic liquids |

|40 |Suitability of commercial colloids in magnetic hyperthermia |

|41 |Influence of Co amount on the efficiency of energy absorption of Fe-Co ferrite nanoparticles |

|42 |Tomographic examination of magnetic nanoparticles used as drug carriers |

|43 |Magnetic properties and heating effect in bacterial magnetic nanoparticles |

|44 |Biocompatible high-moment FeCo magnetic nanoparticles for magnetic hyperthermia treatment optimization |

|Imaging of magnetic particles, magnetic resonance imaging (MRI) contrast agents |

|45 |Nanoscale assembly of amine functionalized colloidal iron oxide |

|46 |Synthetic and biogenic magnetite nanoparticles for tracking of stem cells and dendritic cells |

|47 |Effect of different magnetic nanoparticle coatings on the efficiency of stem cell labeling |

|48 |Optimization of nanoparticle core size for magnetic particle imaging |

|49 |Synchronous ultrasonic Doppler imaging of magnetic microparticles in biological tissues |

|50 |Optical imaging and magnetophoresis of nanorods |

|51 |Dependence of size evaluation of lymph nodes on MRI protocol using ultrasmall superparamagnetic iron oxide |

| |nanoparticles |

|Magnetic drug delivery |

|52 |Development of a magnetic system for the treatment of Helicobacter pylori infections |

|53 |Magnetic capture of superparamagnetic nanoparticles in a constant pressure microcapillary flow |

|54 |Biodistribution of doxorubicin and nanostructured ferrocarbon carrier particles in organism during magnetically |

| |controlled drug delivery |

|55 |Formulation development and evaluation of metronidazole magnetic nanosuspension as a magnetic targeted and polymeric |

| |controlled drug delivery system |

|56 |In vitro study of magnetic particle seeding for implant assisted-magnetic drug targeting: seed and magnetic drug |

| |carrier particle capture |

|57 |In vivo interactions of magnetic nanoparticles with the blood-brain-barrier |

|58 |Towards dynamic control of magnetic fields to focus magnetic carriers to targets deep inside the body |

|59 |Preparation, characterization and in vitro cytotoxicity of BSA-based nanospheres containing nanosized magnetic |

| |particles and/or photosensitizer |

|60 |Bioavailability of magnetic nanoparticles to the brain |

|61 |Cellular uptake of folate conjugated lipophilic superparamagnetic iron oxide nanoparticles |

|62 |Synthesis and characterization of polymeric nanospheres and magnetic particles loaded with the anticancer drug |

| |paclitaxel |

|Magnetic biosensors and sensitive analytical assays based on magnetic carriers |

|63 |Specific binding of magnetic nanoparticle probes to platelets in whole blood detected by magnetorelaxometry |

|64 |AC susceptibility of magnetic markers in suspension for liquid phase immunoassay |

|65 |High-throughput bioscreening system utilizing high-performance affinity magnetic carriers exhibiting minimal |

| |non-specific protein binding |

|66 |Binding assays with streptavidin-functionalized superparamagnetic nanoparticles and biotinylated analytes using |

| |fluxgate magnetorelaxometry |

|67 |Magnetic permeability based diagnostic test for the determination of the canine C-reactive protein concentration in |

| |undiluted whole blood |

|68 |Application of magnetic poly(styrene-glycidyl methacrylate) microspheres for immunomagnetic separation of bone marrow|

| |cells |

|69 |Multiparametric magnetic immunoassays utilizing non-linear signatures of magnetic labels |

|70 |Characterization of magnetic core-shell nanoparticles by fluxgate magnetorelaxometry, ac susceptibility, transmission|

| |electron microscopy and photon correlation spectroscopy – a comparative study |

|71 |Compact sensor for measuring nonlinear rotational dynamics of driven magnetic microspheres with biomedical |

| |applications |

|72 |Characterization of magnetic labels for bioassays |

|73 |Highly sensitive room-temperature method of non-invasive in vivo detection of magnetic nanoparticles |

|74 |Digital biomagnetism: Electrodeposited multilayer magnetic barcodes |

|75 |Separation of PCR-ready DNA from dairy products using magnetic hydrophilic microspheres and poly(ethylene |

| |glycol)-NaCl water solutions |

|76 |Development of a magnetic lab-on-a-chip for point-of-care sepsis diagnosis |

|77 |Magnetic iron particles with high magnetization useful for immunoassay |

|78 |Lateral flow immunoassay using magnetoresistive sensors |

|79 |Micromagnetic simulations on detection of magnetic labelled biomolecules using MR sensors |

|80 |Application of magnetic nanoparticles to full-automated chemiluminescent enzyme immunoassay |

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