about
Nanoparticles: Alternatives Against Drug-Resistant Pathogenic MicrobesMicrofabricated, amperometric, enzyme-based biosensors for in vivo applicationsBiocompatible and bioactive surface modifications for prolonged in vivo efficacyBiocompatible materials for continuous glucose monitoring devicesCombinatorial hydrogel library enables identification of materials that mitigate the foreign body response in primatesSize- and shape-dependent foreign body immune response to materials implanted in rodents and non-human primates.Neutrophil Responses to Sterile Implant MaterialsThe agar diffusion scratch assay--A novel method to assess the bioactive and cytotoxic potential of new materials and compounds.Recent Nanotechnology Approaches for Prevention and Treatment of Biofilm-Associated Infections on Medical DevicesRecent advances in nano scaffolds for bone repairFabricated ElastinToxicology of antimicrobial nanoparticles for prosthetic devicesThe surface properties of nanoparticles determine the agglomeration state and the size of the particles under physiological conditionsScaffold design for bone regenerationWireless communication with implanted medical devices using the conductive properties of the bodyProteins, platelets, and blood coagulation at biomaterial interfacesSurface thermal oxidation on titanium implants to enhance osteogenic activity and in vivo osseointegrationCarbon Nanostructures in Bone Tissue EngineeringLigation of the spermatic cord in dogs with a self-locking device of a resorbable polyglycolic based co-polymer--feasibility and long-term follow-up study.Effect of the interplay between protein and surface on the properties of adsorbed protein layersProtein adsorption in three dimensionsVolumetric interpretation of protein adsorption: kinetics of protein-adsorption competition from binary solution.A simple implantation method for flexible, multisite microelectrodes into rat brains.Scaffold-free, Human Mesenchymal Stem Cell-Based Tissue Engineered Blood VesselsPreparation and tribological properties of polyetheretherketone composites.Thromboelastometric and platelet responses to silk biomaterialsNanofunctionalized zirconia and barium sulfate particles as bone cement additives.Biocompatibility of chitosan carriers with application in drug delivery.Extracellular matrix molecules facilitating vascular biointegrationEngineering cellular response using nanopatterned bulk metallic glassCharacterization of topographical effects on macrophage behavior in a foreign body response modelThe shape and size of hydroxyapatite particles dictate inflammatory responses following implantation.Biocompatibility of intracortical microelectrodes: current status and future prospects.Real-time in vivo detection of biomaterial-induced reactive oxygen species.Ni ion release, osteoblast-material interactions, and hemocompatibility of hafnium-implanted NiTi alloy.Adhesion, activation, and aggregation of blood platelets and biofilm formation on the surfaces of titanium alloys Ti6Al4V and Ti6Al7Nb.High-resolution three-dimensional probes of biomaterials and their interfaces.Biochemical characterization of the cell-biomaterial interface by quantitative proteomics.Regulation of epithelial cell morphology and functions approaching to more in vivo-like by modifying polyethylene glycol on polysulfone membranesCell specific cytotoxicity and uptake of graphene nanoribbons.
P2860
Q26746108-29718D87-2BB4-4FBE-99DB-EFD119573192Q26764976-7B350706-EF06-42C3-AD1F-EC39035C810EQ26823128-DE69CD03-6632-4088-981D-7E1412BB10AAQ26823654-94C6D824-AC52-4DB8-9112-C1ED45BCA17EQ27313644-DEC9EC5E-0334-4BFF-8385-773620ECCE61Q27314755-6B2D5626-2D8B-4010-9026-E50AFE0E3BCCQ27318618-63F3B484-3733-40A6-9335-5402190857D4Q27349888-3602A32D-7710-4DD6-B870-3F1EBF311F71Q28074875-7509313E-2BC4-445C-B5A4-B76631FEC171Q28077442-B1E0EFB9-52BC-4CB0-AA97-4DD054A9F64DQ28087162-658BD5AE-2194-4458-B108-F840BF0AAC05Q28393315-2F3C0740-B91C-4F27-BDFA-9E1B80017C40Q28397222-FB7CCB50-3656-4AE7-9446-A3BE1287BC7AQ28538144-31838939-602C-4205-9BFB-2618473FA726Q28655988-54A16F09-1DBB-41CC-A4F5-D9DCCF17F292Q28828698-FA3ABB34-D682-4A7D-AF85-A112A42B5000Q28829485-A7DF5D33-A975-4D68-B224-80E17A75CB97Q29249067-26A0BDE9-282F-40F7-B8F9-14BF91DBE166Q30424447-4EB8EAEA-4E9A-4F60-A0BC-051571BD86A8Q30433559-3FB956B7-F732-447D-8594-E4049DFC202DQ30458536-4236A8AE-08D5-430F-A9B1-AB3070B1F8C7Q30478839-714A6CCD-CFC3-4F68-A935-E34ECCCD0E77Q30541767-0B3CDEBD-2AC0-4DB1-856F-54EC2CDDF795Q30667582-8D69C42B-2A3F-43B4-8ADF-AF879A893C20Q33545707-67ADEDF0-D572-4E1D-80AD-4FF0707EB443Q33602094-DC6A10F1-F2AC-44B0-A73D-DC865D763C61Q33644865-CB6895D7-CCB3-4411-8D10-98D14CDA1033Q33649839-6ED8CC55-9462-4A16-B542-710A42001FA8Q33649857-410AF24E-2121-435C-A942-C79471325D32Q33716042-83165D63-D265-4B3E-AE69-13E468A51B38Q33721768-03E68DFA-5AC9-4090-A4CF-4CA781D506DDQ33774310-17A338EE-C132-4BB7-81E9-8B6C894C2D80Q33930065-BA3B1BE8-B405-40DE-94F8-079E859DC7E3Q34034885-C8A94376-1D82-449E-BEA2-EAE189B02AC9Q34084549-D3B3B08D-78A0-4BAB-915F-F45746D0E016Q34124818-727FBF85-A2BA-4B75-B91F-E0256FCC32FDQ34164325-1E2694FE-69AD-4972-B807-881CC20B37D1Q34193604-CC894764-79D8-4E68-8058-D6BAAE6B9212Q34257157-1BF5DA1F-6911-4D9F-959C-7E2F4E5FED7FQ34306510-959E2FD6-16CF-4DC5-82CA-692BA6E17A7B
P2860
description
article científic
@ca
article scientifique
@fr
articolo scientifico
@it
artigo científico
@pt
bilimsel makale
@tr
gotara zanistî
@ku-latn
scientific article published on 28 April 2008
@en
vedecký článok
@sk
vetenskaplig artikel
@sv
videnskabelig artikel
@da
name
On the mechanisms of biocompatibility.
@en
On the mechanisms of biocompatibility.
@nl
type
label
On the mechanisms of biocompatibility.
@en
On the mechanisms of biocompatibility.
@nl
prefLabel
On the mechanisms of biocompatibility.
@en
On the mechanisms of biocompatibility.
@nl
P1433
P1476
On the mechanisms of biocompatibility.
@en
P2093
David F Williams
P304
P356
10.1016/J.BIOMATERIALS.2008.04.023
P577
2008-04-28T00:00:00Z