about
Mechanical stress downregulates MHC class I expression on human cancer cell membraneNanoscale chemical mapping using three-dimensional adiabatic compression of surface plasmon polaritons.Enhancing plasma peptide MALDI-TOF-MS profiling by mesoporous silica assisted crystallization.Monitoring human leukocyte antigen class I molecules by micro-Raman spectroscopy at single-cell level.Highly efficient human serum filtration with water-soluble nanoporous nanoparticles.Lipid droplets: a new player in colorectal cancer stem cells unveiled by spectroscopic imaging.The structure of DNA by direct imagingFT-IR, Raman, RRS measurements and DFT calculation for doxorubicin.Raman database of amino acids solutions: a critical study of extended multiplicative signal correction.Microfluidic biofunctionalisation protocols to form multi-valent interactions for cell rolling and phenotype modification investigations.Microfluidic devices modulate tumor cell line susceptibility to NK cell recognition.Nanoparticle microinjection and Raman spectroscopy as tools for nanotoxicology studies.Water soluble nanoporous nanoparticle for in vivo targeted drug delivery and controlled release in B cells tumor context.Electroless deposition and nanolithography can control the formation of materials at the nano-scale for plasmonic applications.An Overview of Lipid Droplets in Cancer and Cancer Stem Cells.Microtexturing of the conductive PEDOT:PSS polymer for superhydrophobic organic electrochemical transistors.Monitoring multiple myeloma by idiotype-specific peptide binders of tumor-derived exosomes.Detection of single amino acid mutation in human breast cancer by disordered plasmonic self-similar chain.H ferritin silencing induces protein misfolding in K562 cells: A Raman analysis.Two sides of the same coin? Unraveling subtle differences between human embryonic and induced pluripotent stem cells by Raman spectroscopy.Microfluidic device for continuous single cells analysis via Raman spectroscopy enhanced by integrated plasmonic nanodimers.Folic acid functionalized surface highlights 5-methylcytosine-genomic content within circulating tumor cells.Selective on site separation and detection of molecules in diluted solutions with super-hydrophobic clusters of plasmonic nanoparticles.Plasmonic Nanowires for Wide Wavelength Range Molecular Sensing.Photolithography and micromolding techniques for the realization of 3D polycaprolactone scaffolds for tissue engineering applicationsThe Five Ws (and one H) of Super-Hydrophobic Surfaces in MedicineSpecial issue on surface-enhanced Raman spectroscopyNovel Plasmonic Probes and Smart Superhydrophobic Devices, New Tools for Forthcoming Spectroscopies at the NanoscaleA microfluidic device integrating plasmonic nanodevices for Raman spectroscopy analysis on trapped single living cellsWaveguiding and SERS Simplified Raman Spectroscopy on Biological SamplesNano-patterned SERS substrate: application for protein analysis vs. temperatureSuperhydrophobic surfaces as smart platforms for the analysis of diluted biological solutionsDirect determination of the resonance properties of metallic conical nanoantennasA Disposable Passive Microfluidic Device for Cell CulturingA Passive Microfluidic Device for Chemotaxis StudiesKey Role of Cytochrome C for Apoptosis Detection Using Raman Microimaging in an Animal Model of Brain Ischemia with Insulin TreatmentEmerging Designs of Electronic Devices in BiomedicineCell Theranostics on Mesoporous Silicon SubstratesTailoring Chemometric Models on Blood-Derived Cultures Secretome to Assess Personalized Cancer Risk Score
P50
Q30422252-6A5B38F3-A8C4-452A-B820-F90603E213C5Q33516545-2488713B-04A3-45C9-A93C-211FF718B460Q33524942-241D617A-AC2B-4E4B-AE81-3D45988E0421Q33574846-502B2D16-D99B-4D17-87F3-B642DAA00106Q34440014-7F439354-2CD4-4BF4-A9E4-892EE56E57A3Q35030903-8986BC97-2BF0-4DF4-9386-A527888165B5Q35851155-18B2F159-CBF8-411E-9CC9-6807BF93ADABQ37709968-816F42F0-390C-416A-947E-7DDB15B472EDQ38155062-4CBF7A3A-3B2E-45F8-806D-3C7C6DC4612EQ39160938-F1861E60-4CB2-4A4E-AE5B-7E587920CAB4Q39320294-4C17B39E-479A-4DE7-8683-6457FFAD3BCFQ39481901-4D7B8888-6907-4C81-AC82-1E65865ACA73Q39656680-6DC708FB-40EC-4C22-83B5-B8FC603F636BQ39838438-E61E717F-54C1-4978-9A54-9DAF74EBCCFEQ41528938-9C179247-CDE4-4892-A869-EFED19DBE725Q41820640-349828DC-2E9A-4CFC-9305-C70893A593FDQ42377367-48EF5558-6A28-41BA-AAFD-82CB8DDDA801Q42619896-C32D5A94-D9A8-4DA2-89D8-29DE2A9D11D1Q46656668-1B1C935F-1413-436E-AF07-4CF4D9A985E2Q47305844-330B8CC9-6E5C-49D1-B7FC-CB27E4E8BC80Q50264039-56997D3E-A2C4-4821-8E04-93F725E70427Q51067212-7F9E0F0C-ED20-4959-8A69-4475B5E8CD77Q53525155-CD99CEB8-ED93-4E20-9AFE-D774F3DD63C0Q55344653-2CA15097-12A3-4F47-BA3A-14AE55154E41Q58230963-2B4D46F5-6D79-48A4-BF1E-6FE1D187BF4AQ58230967-589CC784-1B90-48B6-8665-AAEFCC8B89A6Q58465021-73794E63-CD86-49A9-95A6-EEFB01F9AAD2Q58483813-2C9F4777-792A-4A4D-AC54-B5A4CFC2533FQ58483832-51FA640C-A56F-4ECF-BA52-56BE0A837389Q64070391-2358887E-1134-42ED-B807-E7B8AC34F586Q79769292-F7351300-F569-49CA-9A8C-E70D8E922B4BQ84200474-B03BD18B-DD32-4D4E-8C81-6C0F52E867F7Q87216054-1ED3E2AD-87D7-4DAF-939E-69F633831681Q89977744-73443DD1-3A39-45E4-8E05-C56CAF1166BDQ92752595-741FAFEE-02CB-4BC2-987D-C146E7394B3EQ92896342-D0D5CF12-C27B-4F6B-875E-AEB5B847B420Q92921350-E1903550-FA16-456C-8D9D-2161509F8BDFQ95929890-72FA6415-5CF9-49D1-BD34-6985A80B0C2CQ95932081-8ADFAD55-95DC-4451-8224-672F0E7EE3F0
P50
description
hulumtues
@sq
onderzoeker
@nl
researcher
@en
հետազոտող
@hy
name
Patrizio Candeloro
@ast
Patrizio Candeloro
@en
Patrizio Candeloro
@es
Patrizio Candeloro
@nl
Patrizio Candeloro
@sl
type
label
Patrizio Candeloro
@ast
Patrizio Candeloro
@en
Patrizio Candeloro
@es
Patrizio Candeloro
@nl
Patrizio Candeloro
@sl
prefLabel
Patrizio Candeloro
@ast
Patrizio Candeloro
@en
Patrizio Candeloro
@es
Patrizio Candeloro
@nl
Patrizio Candeloro
@sl
P1053
K-8097-2016
P106
P1153
57189351819
P21
P31
P3829
P496
0000-0001-6156-887X