about
Biocompatibility evaluation of a novel hydroxyapatite-polymer coating for medical implants (in vitro tests).Immobilization of urease by laser techniques: synthesis and application to urea biosensors.Specific biofunctional performances of the hydroxyapatite-sodium maleate copolymer hybrid coating nanostructures evaluated by in vitro studies.Tailoring immobilization of immunoglobulin by excimer laser for biosensor applications.Levan nanostructured thin films by MAPLE assembling.Dermal cells distribution on laser-structured ormosils.MAPLE-based method to obtain biodegradable hybrid polymeric thin films with embedded antitumoral agents.Combinatorial MAPLE gradient thin film assemblies signalling to human osteoblasts.Isolation method and xeno-free culture conditions influence multipotent differentiation capacity of human Wharton's jelly-derived mesenchymal stem cells.Cell adhesion response on femtosecond laser initiated liquid assisted silicon surface.AP-3 and Rabip4' coordinately regulate spatial distribution of lysosomes.Endocytosis and trafficking of human lactoferrin in macrophage-like human THP-1 cells (1).The influence of silicon substitution on the properties of spherical- and whisker-like biphasic α-calcium-phosphate/hydroxyapatite particles.Liposomalization of lactoferrin enhanced its anti-tumoral effects on melanoma cells.Productive folding of tyrosinase ectodomain is controlled by the transmembrane anchor.Differentiation of mesenchymal stem cells onto highly adherent radio frequency-sputtered carbonated hydroxylapatite thin films.Tissue transglutaminase regulates interactions between ovarian cancer stem cells and the tumor niche.Targeting the Microenvironment in High Grade Serous Ovarian CancerValue of dopachrome tautomerase detection in the assessment of melanocytic tumorsAdhesion and Osteogenic Differentiation of Human Mesenchymal Stem Cells: Supported by B-Type Carbonated HydroxylapatiteSmall Molecules Target the Interaction between Tissue Transglutaminase and FibronectinHuman Mesenchymal Stem Cell Response to Lactoferrin-based Composite CoatingsAnalysis of EYA3 Phosphorylation by Src Kinase Identifies Residues Involved in Cell Proliferation
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Q30835556-7D9F1088-C53F-4644-80E0-050EFDFDC6D0Q33330349-BE1F113D-3A2B-41DD-B135-80B612ADBDA5Q33471556-CC67DF95-B009-4226-9F41-8A4EEB9AE869Q33775893-FC130A84-7F8E-407F-8739-46C2CC40A3EEQ33882119-C1122EE4-A2C0-4E82-BE2B-57A823CCEF1DQ34085519-1BBA5706-4F68-4B5A-A3F0-4F4E2FA7028EQ34866755-6A9028F3-2C13-49D8-BA8D-086DD103F23AQ35175153-F8795A01-0A4E-4D0E-BF1F-3A43E23361CBQ37372524-360A2688-A263-4473-8407-424958BB55E4Q38180189-CB118584-84A6-4318-8114-0601D395E7AFQ39246279-E682111F-A4D1-4A16-8D01-B88715C2BC17Q39387594-0415EDD7-5497-4B23-A15B-F45FFF98E534Q39493547-7966402D-FB45-4D93-87AA-450BDEAA3227Q39733922-600E2FCB-1C3F-4341-B335-A9ACC1FACDFAQ40273382-86EA7CD3-0ACB-4CDA-9B62-5596F7A789DBQ43883416-26A998A8-FAF5-4AA0-9136-21B99E379DC7Q52365303-C25FC695-594D-4748-932D-5C5B0773D2AEQ58789499-E7AB6B3E-B4CC-41AA-A3B2-91F3ADCEB718Q60202716-8F3D46C9-3B0D-4CD2-BDB5-28C4CF92F2E5Q60202758-AC8EE2EF-0B71-47F6-986A-D832CDED0047Q90250923-A6AC95CC-F3BE-44D0-AA80-9EC2BAE7C318Q90852182-A8BB89CE-E5D7-44E7-9F13-2DF2E51AFDACQ92049097-7F0905ED-CC0D-4A58-BB36-9CF051849E76
P50
description
hulumtuese
@sq
researcher
@en
wetenschapper
@nl
հետազոտող
@hy
name
Livia Sima
@ast
Livia Sima
@en
Livia Sima
@es
Livia Sima
@nl
Livia Sima
@sl
type
label
Livia Sima
@ast
Livia Sima
@en
Livia Sima
@es
Livia Sima
@nl
Livia Sima
@sl
altLabel
Livia Zdrentu
@en
prefLabel
Livia Sima
@ast
Livia Sima
@en
Livia Sima
@es
Livia Sima
@nl
Livia Sima
@sl
P1053
C-2882-2011
P106
P21
P31
P3829
P496
0000-0002-3404-4162