about
Qualitative and quantitative structure-property relationships analysis of multicomponent potential bioglasses.Substitutions of cerium, gallium and zinc in ordered mesoporous bioactive glasses.Evaluation of the behaviour of fluorine-containing bioactive glasses: reactivity in a simulated body fluid solution assisted by multivariate data analysis.Gold-containing bioactive glasses: a solid-state synthesis to produce alternative biomaterials for bone implantations.The toxic effect of fluoride on MG-63 osteoblast cells is also dependent on the production of nitric oxide.Zinc-containing bioactive glasses: surface reactivity and behaviour towards endothelial cells.Properties of zinc releasing surfaces for clinical applications.Cytotoxicity of zinc-containing bioactive glasses in contact with human osteoblasts.SiO₂-CaO-P₂O₅ Bioactive Glasses: A Promising Curcuminoids Delivery System.Functionalization of sol gel bioactive glasses carrying Au nanoparticles: selective Au affinity for amino and thiol ligand groups.In vitro and in vivo behaviour of zinc-doped phosphosilicate glasses.Fluoride-containing bioactive glasses inhibit pentose phosphate oxidative pathway and glucose 6-phosphate dehydrogenase activity in human osteoblasts.Fluoride-containing bioactive glasses: surface reactivity in simulated body fluids solutions.Mesoporous bioactive scaffolds prepared with cerium-, gallium- and zinc-containing glasses.Gallium-containing phosphosilicate glasses: functionalization and in-vitro bioactivity.Highly-Bioreactive Silica-Based Mesoporous Bioactive Glasses Enriched with Gallium(III).New Insights into the Atomic Structure of 45S5 Bioglass by Means of Solid-State NMR Spectroscopy and Accurate First-Principles SimulationsNovel bio-conjugate materials: soybean peroxidase immobilized on bioactive glasses containing Au nanoparticlesConjugation of amino-bioactive glasses with 5-aminofluorescein as probe molecule for the development of pH sensitive stimuli-responsive biomaterialsNew formulation of functionalized bioactive glasses to be used as carriers for the development of pH-stimuli responsive biomaterials for bone diseasesThermodynamic aspects of the adsorption of hexametaphosphate on kaoliniteSynthesis and characterization of cerium-doped glasses and in vitro evaluation of bioactivityAn atomic-level look at the structure-property relationship of cerium-doped glasses using classical molecular dynamicsThe effect of composition on structural, thermal, redox and bioactive properties of Ce-containing glassesEvidence of Catalase Mimetic Activity in Ce3+/Ce4+ Doped Bioactive GlassesNew insights into the bioactivity of SiO2–CaO and SiO2–CaO–P2O5 sol–gel glasses by molecular dynamics simulationsStudy of the Structural Role of Gallium and Aluminum in 45S5 Bioactive Glasses by Molecular Dynamics SimulationsFirst-principles simulations of the 27Al and 17O solid-state NMR spectra of the CaAl2Si3O10 glassMolecular dynamics simulations of sodium silicate glasses: Optimization and limits of the computational procedureComputational Insight into the Effect of CaO/MgO Substitution on the Structural Properties of Phospho-Silicate Bioactive GlassesQuantitative Structure−Property Relationships of Potentially Bioactive Fluoro Phospho-silicate GlassesElastic and dynamical properties of alkali-silicate glasses from computer simulations techniquesElucidation of the Structural Role of Fluorine in Potentially Bioactive Glasses by Experimental and Computational InvestigationFFSiOH: a New Force Field for Silica Polymorphs and Their Hydroxylated Surfaces Based on Periodic B3LYP CalculationsMedium-range order in phospho-silicate bioactive glasses: Insights from MAS-NMR spectra, chemical durability experiments and molecular dynamics simulationsMolecular Dynamics Studies of Stress−Strain Behavior of Silica Glass under a Tensile LoadRole of Magnesium in Soda-Lime Glasses: Insight into Structural, Transport, and Mechanical Properties through Computer SimulationsA computational multiscale strategy to the study of amorphous materialsAn ab initio parameterized interatomic force field for hydroxyapatiteCrystallization Kinetics of Bioactive Glasses in the ZnO−Na2O−CaO−SiO2System
P50
Q31049588-434C33BA-6D63-4F8C-A42C-F0C9A542A8ADQ33932397-F0889F81-576B-40D2-9388-7BFBAC226FA6Q34115612-DAC0FB73-4D73-45B2-B39D-F796322FD1F3Q36767901-BD6330F3-3C22-467B-B883-886497672D5FQ39590369-ED841E97-5C5C-4BE9-B8CD-5851591A6D79Q39910834-26717E56-EB06-4BAF-AAD5-3AD49D3C0B75Q40108818-D802A421-3870-4C65-ADFB-AC1DD4F829D3Q40151508-0A73BDAA-0B0E-47D7-B6E8-4CB23E173E06Q40967673-FED7C8E9-4DEF-4AF9-A5EF-170CA9390800Q42797298-20F3659A-795B-48CE-A6C7-F1F13FE46A99Q42809579-5FE71B19-3A0B-4C58-8C13-FFB941A4723DQ43234177-DA3BED72-4AD3-4979-B53B-62F769A75ADAQ45970883-6250B7AC-5F1F-46C9-87B3-BB0EC31875F5Q46531043-EA15560E-7225-41D4-B409-53E863D3497AQ46557112-E0E7A52F-62C3-4419-B748-3A09FD7AE5FCQ55407139-1415E8A2-F6E4-4FD8-A835-55F82F6A8FCCQ56864439-C2200E86-FD5A-4FB2-B998-D312DA5B1825Q57086121-58EFEDB4-6151-4C20-9E4B-16ED759CA581Q57162669-C3CF8E6E-0C9F-4388-A2B9-60F3BFD83E62Q57164215-2BDBDC30-8C1D-4EF9-A44C-66ED18606079Q57363490-D116A382-16D4-4DE2-907E-F690DC9B62A6Q57642976-DE9A777A-A942-4BD5-A742-A770E71562BBQ59613553-CD1AF609-910C-4F90-A2BE-F8FF4A520E40Q59613638-23B6C7C6-EEE1-45A9-8175-066B92759EE7Q59613682-78FA5A48-7773-4A31-810E-F5462FE2120FQ59613800-07E9B43E-84CE-4BEF-A143-6B316E42D2D2Q59613813-EA02B1AC-17AC-4815-A29F-74CEA01C30FEQ59613833-47D8203E-BD18-462B-9493-F6DEE02EE435Q59613912-4FD7B7F3-E436-4609-BAC6-9327C650CCAEQ59613927-B8CDA9E5-A330-4334-BBEA-E7AC35B637A4Q59613943-DD551524-023B-4D47-BF4E-5AD5721D3974Q59613959-88776E4E-F23C-4F7D-8412-81E1439DAFABQ59613963-A59B5B91-7F23-4FBE-B6BC-F27828979437Q59613969-22D78D03-37E4-4A21-90BE-4EA5D53CCF5CQ59613974-6C1F34A6-56A1-4228-94DE-A89FD2504455Q59613977-4A31F257-7910-413A-A048-D13ECB0DE649Q59613990-662DBC5A-75BD-482E-835F-FAF7F61C7780Q59613996-F4F65BE5-A1CE-49B7-BFF7-FD20628444F3Q59614001-F6C01A66-19A9-4A06-AD83-A5F991E57601Q59614009-BE903FB9-C5D3-4B88-8B54-FAA2A3CB651A
P50
description
hulumtues
@sq
researcher
@en
wetenschapper
@nl
հետազոտող
@hy
name
Gianluca Malavasi
@ast
Gianluca Malavasi
@en
Gianluca Malavasi
@es
Gianluca Malavasi
@nl
Gianluca Malavasi
@sl
type
label
Gianluca Malavasi
@ast
Gianluca Malavasi
@en
Gianluca Malavasi
@es
Gianluca Malavasi
@nl
Gianluca Malavasi
@sl
prefLabel
Gianluca Malavasi
@ast
Gianluca Malavasi
@en
Gianluca Malavasi
@es
Gianluca Malavasi
@nl
Gianluca Malavasi
@sl
P1053
H-4658-2013
P106
P1153
55985170700
P21
P31
P3829
P496
0000-0002-4557-8135