A role for surface topography in creating and maintaining bone at titanium endosseous implants.
about
Biomaterials approach to expand and direct differentiation of stem cellsStructure-activity relationship of human bone sialoprotein peptidesSpecific biomimetic hydroxyapatite nanotopographies enhance osteoblastic differentiation and bone graft osteointegration.The roles of extracellular signal-regulated kinase 1/2 pathway in regulating osteogenic differentiation of murine preosteoblasts MC3T3-E1 cells on roughened titanium surfaces.Influence of pores created by laser superfinishing on osseointegration of titanium alloy implants.Evaluation of titanium implants with surface modification by laser beam. Biomechanical study in rabbit tibias.Wetting behaviour of laser synthetic surface microtextures on Ti-6Al-4V for bioapplication.A histomorphometric study of dental implants with different surface characteristics.Dental implant systems.A novel multi-phosphonate surface treatment of titanium dental implants: a study in sheep.Cellular reactions of osteoblasts to micron- and submicron-scale porous structures of titanium surfaces.Early bone healing onto implant surface treated by fibronectin/oxysterol for cell adhesion/osteogenic differentiation: in vivo experimental study in dogs.Comparative in vivo study of commercially pure Ti implants with surfaces modified by laser with and without silicate deposition: biomechanical and scanning electron microscopy analysis.Reality of dental implant surface modification: a short literature review.Histometric analysis and topographic characterization of cp Ti implants with surfaces modified by laser with and without silica deposition.Nanometer-thin TiO₂ enhances skeletal muscle cell phenotype and behaviorMicro-topography and reactivity of implant surfaces: an in vitro study in simulated body fluid (SBF).Comparative evaluation of the three different surface treatments - conventional, laser and Nano technology methods in enhancing the surface characteristics of commercially pure titanium discs and their effects on cell adhesion: An in vitro studyIn vivo comparison between the effects of chemically modified hydrophilic and anodically oxidized titanium surfaces on initial bone healing.Porphyromonas gingivalis biofilm formation in different titanium surfaces, an in vitro study.Controlled laser texturing of titanium results in reliable osteointegration.In vivo evaluation of cp Ti implants with modified surfaces by laser beam with and without hydroxyapatite chemical deposition and without and with thermal treatment: topographic characterization and histomorphometric analysis in rabbits.UV photofunctionalization promotes nano-biomimetic apatite deposition on titanium.Synergistic interactions of blood-borne immune cells, fibroblasts and extracellular matrix drive repair in an in vitro peri-implant wound healing model.Significance of nano- and microtopography for cell-surface interactions in orthopaedic implantsSurface modifications of dental implants.Heat and radiofrequency plasma glow discharge pretreatment of a titanium alloy promote bone formation and osseointegration.Requirement for both micron- and submicron scale structure for synergistic responses of osteoblasts to substrate surface energy and topographyDissolution behavior and early bone apposition of calcium phosphate-coated machined implants.The effect of pretreating resorbable blast media titanium discs with an ultrasonic scaler or toothbrush on the bacterial removal efficiency of brushing.The influence of micro and macro-geometry in term of bone-implant interface in two implant systems: an histomorphometrical study.Different performance of platform switching in equicrestal position implant: an histological study.Structural influence from calcium phosphate coatings and its possible effect on enhanced bone integration.Comparison of the osteogenic potential of titanium- and modified zirconia-based bioceramics.Relative influence of surface topography and surface chemistry on cell response to bone implant materials. Part 2: biological aspects.Addition of nanoscaled bioinspired surface features: A revolution for bone related implants and scaffolds?Osseointegration: an updateImmediate loading in partially and completely edentulous jaws: a review of the literature with clinical guidelines.Fabrication mechanism of nanostructured HA/TNTs biomedical coatings: an improvement in nanomechanical and in vitro biological responses.Enhanced osteogenic differentiation of MC3T3-E1 cells on grid-topographic surface and evidence for involvement of YAP mediator.
P2860
Q24647654-8659710A-6A38-4E93-AF36-7DE66A937FE6Q28910471-FBB97DBB-4F6B-43FD-A9D3-667DF2D95341Q30433985-7896D6C8-3325-447F-8D26-D276796CF7AFQ31035872-BA5176F5-8B62-4DAB-B714-C95D476F9DC8Q31058001-00E2740C-D3CF-4B35-A651-6F86D69F5217Q33494053-09F6F48A-7413-4F60-B76A-A15A0C249F8BQ33544084-C3CBC111-F6C2-4F5E-B940-7C036063868AQ33802541-CC51D694-293F-4E6E-894F-73068513F9A4Q33853901-20FB96E6-F6F2-4C1E-BFDA-9371D86D80C2Q34317948-97ADCF52-4DB6-4C3B-8E83-EA0FC1B20B4BQ34369262-C766441E-21A4-4DD4-9E91-C60426AB5F4AQ34436627-66BDAD03-9C96-4FDB-BF10-09E83EA2A618Q34454907-4D9059CD-7AFE-4986-BFE8-D094215BA09EQ34508120-83C23128-E724-48B1-BED2-F24BD772859BQ35130404-0E94844D-1B19-4FBA-9E2D-F6C7ECD93422Q35547229-3648786C-D336-420B-9B09-9ECF0AC2E1E7Q35558720-AC9D452B-3E41-4569-82A8-58DD9CCBF31EQ35642900-19A931B2-C943-48AF-994C-0A0124F46C3DQ35679485-4B74CB94-015F-4B5A-AC9F-4A3A73F4BDEDQ35739285-5FDF5EFE-2D74-481F-88D9-9256769BC7ECQ36053547-29039796-1550-4424-B3AD-AF5716E7F243Q36105128-5B5F3254-5757-4EFE-8DDD-F59606BA1936Q36473548-5FE6BC43-36FA-4A8B-AD8B-8F181BA831E1Q36587587-C9948A4D-0979-4259-83F4-81B525AE5C30Q37084527-7F741E17-017E-437E-8733-259CC4E2FE1DQ37171108-E979E6E4-55F4-45B3-8D1F-57F18ED30517Q37205191-7C654EB4-4221-4AF0-AA55-CAB0A772672FQ37369565-738DE1C2-1B42-4F87-9AB3-397140C69D8AQ37478994-E02B566A-7D43-4205-9810-D5CC60049CD5Q37479000-2F0ED5AB-30CD-4EB3-ABF8-DD0D300AEC7FQ37508632-2C6B975A-2A8B-43B1-9E1A-9700CEE678AAQ37508747-21CAFEAC-E3E7-4D8A-8111-B160899F658DQ37590221-C29FF34A-1CB3-49E0-BF5F-0BDFCDF4E485Q37684076-8F83556E-2653-46E4-BB6F-34FE19547EC6Q37834565-DE6785E0-1876-43F1-90B8-F1BAAE6983F2Q38087300-690EAD29-98A9-4CC2-AB5F-D4C0CBAE6DDEQ38178944-941FE985-A748-4F2D-AD66-F2840ECA6CFFQ38239921-FA8EECE9-AFFE-4932-904C-4A67DD5FC6E0Q38748759-2621FB24-16AD-406B-BE71-460D8947FF86Q38805304-72394920-A229-45AA-AE29-2BAA706B75E0
P2860
A role for surface topography in creating and maintaining bone at titanium endosseous implants.
description
2000 nî lūn-bûn
@nan
2000 թուականի Նոյեմբերին հրատարակուած գիտական յօդուած
@hyw
2000 թվականի նոյեմբերին հրատարակված գիտական հոդված
@hy
2000年の論文
@ja
2000年学术文章
@wuu
2000年学术文章
@zh-cn
2000年学术文章
@zh-hans
2000年学术文章
@zh-my
2000年学术文章
@zh-sg
2000年學術文章
@yue
name
A role for surface topography ...... titanium endosseous implants.
@ast
A role for surface topography ...... titanium endosseous implants.
@en
A role for surface topography ...... titanium endosseous implants.
@nl
type
label
A role for surface topography ...... titanium endosseous implants.
@ast
A role for surface topography ...... titanium endosseous implants.
@en
A role for surface topography ...... titanium endosseous implants.
@nl
prefLabel
A role for surface topography ...... titanium endosseous implants.
@ast
A role for surface topography ...... titanium endosseous implants.
@en
A role for surface topography ...... titanium endosseous implants.
@nl
P356
P1476
A role for surface topography ...... t titanium endosseous implants
@en
P2093
P304
P356
10.1067/MPR.2000.111966
P407
P577
2000-11-01T00:00:00Z