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Surface thermal oxidation on titanium implants to enhance osteogenic activity and in vivo osseointegrationA functionalized surface modification with vanadium nanoparticles of various valences against implant-associated bloodstream infectionMagnesium ion implantation on a micro/nanostructured titanium surface promotes its bioactivity and osteogenic differentiation functionExistence, release, and antibacterial actions of silver nanoparticles on Ag-PIII TiO₂ films with different nanotopographiesSilver-nanoparticles-modified biomaterial surface resistant to staphylococcus: new insight into the antimicrobial action of silver.Antibacterial ability and hemocompatibility of graphene functionalized germanium.Antibacterial activity of large-area monolayer graphene film manipulated by charge transfer.Alkali-treated titanium selectively regulating biological behaviors of bacteria, cancer cells and mesenchymal stem cells.Antimicrobial activity and cytocompatibility of Ag plasma-modified hierarchical TiO2 film on titanium surface.Vacuum extraction enhances rhPDGF-BB immobilization on nanotubes to improve implant osseointegration in ovariectomized rats.Enhanced Anti-Infective Efficacy of ZnO Nano-Reservoirs Through a Combination of Intrinsic Anti-Biofilm Activity and Reinforced Innate Defense.Band Gap Engineering of Titania Film through Cobalt Regulation for Oxidative Damage of Bacterial Respiration and Viability.Nano-layered magnesium fluoride reservoirs on biomaterial surfaces strengthen polymorphonuclear leukocyte resistance to bacterial pathogens.Antibacterial Surface Design of Titanium-Based Biomaterials for Enhanced Bacteria-Killing and Cell-Assisting Functions Against Periprosthetic Joint Infection.Influence of sulfur content on bone formation and antibacterial ability of sulfonated PEEK.Anti-biofouling function of amorphous nano-Ta2O5 coating for VO2-based intelligent windows.Oxidative stress-mediated selective antimicrobial ability of nano-VO2 against Gram-positive bacteria for environmental and biomedical applications.Selective Tumor Cell Inhibition Effect of Ni-Ti Layered Double Hydroxides Thin Films Driven by the Reversed pH Gradients of Tumor Cells.Poly(styrenesulfonate)-Modified Ni-Ti Layered Double Hydroxide Film: A Smart Drug-Eluting Platform.CVD Growth of Graphene on NiTi Alloy for Enhanced Biological Activity.Valence State Manipulation of Cerium Oxide Nanoparticles on a Titanium Surface for Modulating Cell Fate and Bone Formation.Zinc-Modified Sulfonated Polyetheretherketone Surface with Immunomodulatory Function for Guiding Cell Fate and Bone RegenerationNano vanadium dioxide films deposited on biomedical titanium: a novel approach for simultaneously enhanced osteogenic and antibacterial effectsVanadium Dioxide Nanocoating Induces Tumor Cell Death through Mitochondrial Electron Transport Chain InterruptionCorrection to "Poly(styrenesulfonate)-Modified Ni-Ti Layered Double Hydroxide Film: A Smart Drug Eluting Platform"Advanced antibacterial activity of biocompatible tantalum nanofilm via enhanced local innate immunityA surface-engineered polyetheretherketone biomaterial implant with direct and immunoregulatory antibacterial activity against methicillin-resistant Staphylococcus aureus
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Q28829485-8B0EC84A-D401-48A5-BE3C-60A4DEEEA33BQ33596392-71DDA4CE-DB09-416C-B583-9BB35462BA78Q33734392-19A63DF5-8A48-40E5-BC22-D5A0649F1C7AQ33933826-A0A814A6-0012-41AF-B15F-3E8075BA2B7EQ37236632-0486363C-2B2A-46AB-9477-28995F4B3E57Q37431282-41EA6587-00C0-4FB0-95E3-7626F7F58B51Q37632031-2703553C-3F36-4C13-958B-AB73D2D2B3D6Q38951983-77F150E0-3074-402B-A349-EA423F8EFC2EQ39090221-68CE38EC-321A-49B8-8CBA-41EF7CC76C1FQ39157090-B173AAF2-6B8C-4AF3-B0E5-B607636D1517Q40061013-B959EBEC-0A1B-4B5C-97B6-57EBCDA5D480Q40117662-EE7BD99B-1047-42D6-A831-360FCB38EFA9Q40403175-9E2D8080-BD12-42C8-894E-E6BCBDC949C0Q40724659-6E7A6D82-930A-4870-8B9E-3EE77955FB36Q40831194-3BDC2782-BD65-4780-96C0-E8C5FDAEDACBQ46391956-84B0737B-E3DA-428F-912D-D2F0ACF6A6CCQ46540493-CD6A3367-640B-49D7-9669-14EF59605068Q46750944-EE430E1A-9445-4127-8A63-8802631DC351Q50155216-F838B22C-7BBE-4828-8688-D010900F44E6Q50712299-4C2532E8-1261-44C7-A196-A12BE9682563Q52611464-EA8B2827-D162-4ACC-93A3-543DB1C55758Q57824238-4DAF3782-F0E8-40A5-A57D-D26D9B42C948Q88116255-3EC0F19E-161A-4A72-A406-CBFF333DAA7BQ90356749-DE012EE0-F33D-4922-9346-D03ADA83855FQ90791039-D3F70DE1-BC2E-4B13-84FF-9314FA884049Q92421943-53EED306-17CC-4731-8A67-545F38C6FAA7Q93101028-59BB0B24-7605-4415-8939-9D05312A30B3
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description
researcher (ORCID 0000-0003-1110-7471)
@en
wetenschapper
@nl
name
Jinhua Li
@en
Jinhua Li
@nl
type
label
Jinhua Li
@en
Jinhua Li
@nl
prefLabel
Jinhua Li
@en
Jinhua Li
@nl
P31
P496
0000-0003-1110-7471