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Engineering a Robust Photovoltaic Device with Quantum Dots and Bacteriorhodopsin.Development of a shear-force scanning near-field cathodoluminescence microscope for characterization of nanostructures' optical properties.A novel design of a scanning probe microscope integrated with an ultramicrotome for serial block-face nanotomography.Salmeterol restores secretory functions in cystic fibrosis airway submucosal gland serous cells.An instrumental approach to combining confocal microspectroscopy and 3D scanning probe nanotomography.Bioinspired lignocellulosic films to understand the mechanical properties of lignified plant cell walls at nanoscale.A new magnetic resonance imaging contrast agent loaded into poly(lacide-co-glycolide) nanoparticles for long-term detection of tumors.Etoposide encapsulation in surface-modified poly(lactide-co-glycolide) nanoparticles strongly enhances glioma antitumor efficiency.Hydrogels incorporating GdDOTA: towards highly efficient dual T1/T2 MRI contrast agents.Characterizations of Ohmic and Schottky-behaving contacts of a single ZnO nanowire.Analysis of the effect of LRP-1 silencing on the invasive potential of cancer cells by nanomechanical probing and adhesion force measurements using atomic force microscopy.Resonance energy transfer improves the biological function of bacteriorhodopsin within a hybrid material built from purple membranes and semiconductor quantum dots.Modeling progression of fluorescent probes in bioinspired lignocellulosic assemblies.Development and physicochemical characterization of copper complexes-loaded PLGA nanoparticles.Langmuir-Blodgett films of cellulose nanocrystals: preparation and characterization.A strain-induced exciton transition energy shift in CdSe nanoplatelets: the impact of an organic ligand shell.Electrodeposition and characterization of CdSe semiconducting nanowires.Structure and optical properties of plant cell wall bio-inspired materials: cellulose-lignin multilayer nanocomposites.Interaction of Aβ1-42 peptide or their variant with model membrane of different composition probed by infrared nanospectroscopy.Structural characterization and in vivo pro-tumor properties of a highly conserved matrikine.Biocompatibility of Gd-Loaded Chitosan-Hyaluronic Acid Nanogels as Contrast Agents for Magnetic Resonance Cancer Imaging.Chemical substitution of Cd ions by Hg in CdSe nanorods and nanodots: Spectroscopic and structural examinationQuantitative characterization of single-cell adhesion properties by atomic force microscopy using protein-functionalized microbeadsLinear and nonlinear optical effects induced by energy transfer from semiconductor nanoparticles to photosynthetic biological systemsNano-biophotonic hybrid materials with controlled FRET efficiency engineered from quantum dots and bacteriorhodopsinComparative Efficiency of Energy Transfer from CdSe-ZnS Quantum Dots or Nanorods to Organic Dye MoleculesControlled FRET efficiency in nano-bio hybrid materials made from semiconductor quantum dots and bacteriorhodopsinExtension of the spectral range of bacteriorhodopsin functional activity by energy transfer from quantum dotsSemiconductor quantum dots affect fluidity of purple membrane fromHalobacterium salinarumthrough disruption of bacteriorhodopsin trimer organizationCharge-controlled assembling of bacteriorhodopsin and semiconductor quantum dots for fluorescence resonance energy transfer-based nanophotonic applicationsEnergy transfer processes in semiconductor quantum dots: bacteriorhodopsin hybrid systemPhotoluminescence quantum yield of CdSe-ZnS/CdS/ZnS core-multishell quantum dots approaches 100% due to enhancement of charge carrier confinementLangmuir–Blodgett Procedure to Precisely Control the Coverage of Functionalized AFM Cantilevers for SMFS Measurements: Application with Cellulose NanocrystalsSilicon Wafer Functionalization with a Luminescent Tb(III) Coordination Complex: Synthesis, Characterization, and Application to the Optical Detection of NO in the Gas Phase.Template assisted electrodeposition of germanium and silicon nanowires in an ionic liquidGrowth of silicon nanowires of controlled diameters by electrodeposition in ionic liquid at room temperatureVectorization of copper complexes via biocompatible and biodegradable PLGA nanoparticlesElectrodeposition of silicon nanotubes at room temperature using ionic liquidDevelopment of an improved Kelvin probe force microscope for accurate local potential measurements on biased electronic devicesCharacterization of Gd loaded chitosan-TPP nanohydrogels by a multi-technique approach combining dynamic light scattering (DLS), asymetrical flow-field-flow-fractionation (AF4) and atomic force microscopy (AFM) and design of positive contrast agents
P50
Q34435611-358F2030-00E9-4A00-BC77-E616C795072DQ36002269-27859EDC-D265-4E76-A1F5-6CCC17FA4046Q36294364-0D546073-2ADC-44BF-9176-CBDE64B6F9E7Q36568698-C39D7E23-6DCD-4AE2-9BFE-57E0EB4523BDQ38696509-51981508-3735-4C03-8FD9-BA22BED6A6F3Q38748451-49B5B910-7092-4213-9858-4361DA6A2EAEQ38946945-6A851087-211F-4503-963F-F0896C580302Q39259254-D546521E-5066-41EC-9359-1E9231C6B213Q39302040-2F8233DE-60DC-43A5-93F5-645A1A21CC95Q39345750-4DFF0796-1A23-4574-8736-1743B6DDEB11Q39930551-3AE077DF-78A1-4C22-BAE0-31C91C564DE6Q43045305-007E6737-5AC3-48D8-A4F5-79DF2E33E36BQ43934400-C31110EB-04ED-4CD3-B338-EB0366A57946Q46018825-0029FE29-A5C2-4DA8-BAFD-DC9E7D17DEC7Q46980451-DFA07563-6F3F-45EA-A32B-F53E56C08AE4Q47608694-593EB719-9B5E-4127-B539-26768D46BA6CQ47619593-329E9D3C-9246-45E5-9A36-CFBE208CD3C9Q51499880-E0473D95-5833-4401-9AC7-1D90B24435B0Q51750146-1A659A27-A59D-45D9-BB75-D50BAF8895C3Q55008820-3775EF0D-DAE7-4005-AE57-B7A68E9FFCB9Q55080578-8C77835F-F212-4C58-814F-FD98AA22D84CQ57346928-6D50601C-CE89-4A80-9902-475553F05532Q58597985-5E3DDC56-E397-4F08-94F6-B85DE15BF025Q60407353-0A0BACBF-E035-47FD-B45D-49647F21FF37Q60407374-17FEEE72-3575-4A79-B467-D7C5B499DEDEQ60407399-7D2155D8-530F-4368-A527-4E7B7A997146Q60407404-0FA90E52-9CB3-4D83-8802-52F5D153E849Q60407409-510F8C57-899B-439C-9609-CA3FEDB24D71Q60407439-63A9AC8D-E952-43BC-8F41-96AE7EEB5BA4Q60407449-7E0B2830-8780-4C60-8718-E901E0F2643AQ60407472-2E66DAF1-F851-45FC-BB79-DD77FB5288D4Q62098772-12D0CD54-990B-43E9-B228-D1E479D4A220Q63406701-B54764FE-FBE0-452B-AEE0-FE7F8A976272Q64938129-547D9B3A-6282-45CE-8D32-C0330F00231DQ79661301-82E876BE-E610-41EB-9F19-305B4D049E26Q81960325-33D1DE83-A268-4602-8EE7-B1A68F6D77A8Q83939511-00378996-8A1D-487D-A6B3-2715CD128485Q87298748-8F1A5AA6-4D4F-434A-A75E-53FF9253B2E6Q87796279-402BC913-3369-410C-B4CD-62F2D2DA3C4DQ89371712-81DE1D75-4DD8-4ADC-978E-B7D2138F6FE6
P50
description
researcher ORCID ID = 0000-0001-9906-655X
@en
wetenschapper
@nl
name
Michael Molinari
@ast
Michael Molinari
@en
Michael Molinari
@es
Michael Molinari
@nl
type
label
Michael Molinari
@ast
Michael Molinari
@en
Michael Molinari
@es
Michael Molinari
@nl
prefLabel
Michael Molinari
@ast
Michael Molinari
@en
Michael Molinari
@es
Michael Molinari
@nl
P1153
14619563600
P21
P31
P496
0000-0001-9906-655X