Keywords: مهندسی بافت استخوان; Topology optimization; Homogenization; Bone tissue engineering; Selective laser sintering
مقالات ISI مهندسی بافت استخوان (ترجمه نشده)
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در صورتی که به ترجمه آماده هر یک از مقالات زیر نیاز داشته باشید، می توانید سفارش دهید تا مترجمان با تجربه این مجموعه در اسرع وقت آن را برای شما ترجمه نمایند.
Keywords: مهندسی بافت استخوان; Microcarriers; Bone tissue engineering; Growth factor delivery; Sustainable release; Bioactive glass;
Keywords: مهندسی بافت استخوان; Heparin; Glycosaminoglycan; Bone morphogenetic protein; Microparticle; Alkaline phosphatase; Bone tissue engineering;
Keywords: مهندسی بافت استخوان; Silk; Hydroxyapatite; Bone tissue engineering; Ceramic structure; Porosity;
Keywords: مهندسی بافت استخوان; Paper scaffold; Initiated chemical vapor deposition; Human adipose-derived stem cell; Osteogenic differentiation; Bone tissue engineering
Keywords: مهندسی بافت استخوان; Surface topography; Hydroxyapatite bioceramic scaffolds; Bone tissue engineering; Osteogenesis; Angiogenesis; Akt signaling pathway;
Keywords: مهندسی بافت استخوان; Mesoporous bioglass; Therapeutic ions; Drug/growth factor delivery; Bone tissue engineering; Osteogenesis; Angiogenesis
Keywords: مهندسی بافت استخوان; Silicate bioceramics; Vascularization; Osteogenesis; Bone tissue engineering
Keywords: مهندسی بافت استخوان; Anti-fouling; 3-D zwitterionic materials; rhBMP-2 delivery; Bone tissue engineering;
Keywords: مهندسی بافت استخوان; Chitosan; Silk fibroin; Electrospinning; Human mesenchymal stem cells; Bone tissue engineering; Composite nanofiber;
Keywords: مهندسی بافت استخوان; Autologous stem cells; Scaffold; Erythropoietin; Stromal derived factor-1α; Bone morphogenetic protein-2; Bone tissue engineering;
Keywords: مهندسی بافت استخوان; Polymer nanocomposites; Carbon nanotubes; Tungsten nanotubes; Mechanical properties; Bone tissue engineering;
Keywords: مهندسی بافت استخوان; 70S30C; Bioactive-glass; Composite scaffold; Bone tissue engineering; Dehydrothermal crosslinking;
Keywords: مهندسی بافت استخوان; Self-assembled monolayers; Substrate chemistry; Physiological fluid flow shear stress; The optimal combination; Osteoblasts; Bone tissue engineering;
Keywords: مهندسی بافت استخوان; Composites; Glass-ceramics; Hydroxyapatite; Bioceramics; Bone tissue engineering;
Keywords: مهندسی بافت استخوان; Bone tissue engineering; Chemotaxis; Hydroxyapatite coating; Platelet lysate; Mesenchymal stromal cell;
Keywords: مهندسی بافت استخوان; Bone defect; Mesenchymal progenitor cells; Allogenic; Bone tissue engineering; Ovine animal model;
Keywords: مهندسی بافت استخوان; Self-assembled monolayer; Material chemistry; Fluid flow shear stress; Osteoblasts; Bone tissue engineering; Synergistic responses;
Keywords: مهندسی بافت استخوان; Osteoinductivity; Hydrogel; Bone tissue engineering; Mesenchymal stem cells; Gum tragacanth
Keywords: مهندسی بافت استخوان; Tissue scaffolds; Nanocomposites; Strontium carbonate; Bone tissue engineering
Keywords: مهندسی بافت استخوان; Boron; Bone tissue engineering; Scaffold; Nanoparticle; Chitosan
Surface functionalization of halloysite nanotubes with supermagnetic iron oxide, chitosan and 2-D calcium-phosphate nanoflakes for synergistic osteoconduction enhancement of human adipose tissue-derived mesenchymal stem cells
Keywords: مهندسی بافت استخوان; Halloysite nanotubes; Multifunctional nanoscaffolds; Osteoconduction; hADMSCs; Bone tissue engineering; Calcium phosphate nanoflakes;
Decellularized bovine small intestinal submucosa-PCL/hydroxyapatite-based multilayer composite scaffold for hard tissue repair
Keywords: مهندسی بافت استخوان; Osteogenic scaffold; Decellularized bovine SIS; Hydroxyapatite; Multilayer hybrid template; Bone tissue engineering;
Electrospun composite PLLA/Oyster shell scaffold enhances proliferation and osteogenic differentiation of stem cells
Keywords: مهندسی بافت استخوان; Oyster shell; Stem cells; Electrospinning; Bone tissue engineering; PLLA;
Fabrication of hierarchical meso/macroporous TiO2 scaffolds by evaporation-induced self-assembly technique for bone tissue engineering applications
Keywords: مهندسی بافت استخوان; Hierarchical scaffolds; TiO2; Bone tissue engineering; Macropores; Mesopores; Sol-gel;
Non-invasive tri-modal visualisation via PET/SPECT/μCT of recombinant human bone morphogenetic protein-2 retention and associated bone regeneration: A proof of concept
Keywords: مهندسی بافت استخوان; Bone tissue engineering; Hydrogel; Micro computed tomography; Positron emission tomography; Single-photon emission computed tomography; Bone morphogenetic protein 2;
Polymer coated mesoporous ceramic for drug delivery in bone tissue engineering
Keywords: مهندسی بافت استخوان; Ceramics; Mesoporous materials; Drug delivery; Bone tissue engineering;
Multilayered co-electrospun scaffold containing silver sulfadiazine as a prophylactic against osteomyelitis: Characterization and biological in vitro evaluations
Keywords: مهندسی بافت استخوان; Co-electrospinning; Silver sulfadiazine; Antibacterial activity; Bone tissue engineering;
Synthesis, microstructure, and mechanical behaviour of a unique porous PHBV scaffold manufactured using selective laser sintering
Keywords: مهندسی بافت استخوان; Selective laser sintering; Poly(3-hydroxybutyrate-co-3-hydroxyvalerate)(PHBV); Mechanical properties; Scaffold; Bone tissue engineering;
Synthesis and investigations of mineral ions-loaded apatite from fish scale and PLA/chitosan composite for bone scaffolds
Keywords: مهندسی بافت استخوان; Hydroxyapatite; Fish scale; Bone tissue engineering; Natural resource; Composite scaffolds;
Harnessing macrophage-mediated degradation of gelatin microspheres for spatiotemporal control of BMP2 release
Keywords: مهندسی بافت استخوان; Macrophages; Inflammation; BMP; Immunomodulation; Bone tissue engineering; Controlled drug release;
Poly(lactic-co-glycolic acid)(PLGA)/TiO2 nanotube bioactive composite as a novel scaffold for bone tissue engineering: In vitro and in vivo studies
Keywords: مهندسی بافت استخوان; Poly (lactic-co-glycolic acid); TiO2 nanotube; Nanocomposite; Bone tissue engineering; Microsphere sintering;
Bidirectional juxtacrine ephrinB2/Ephs signaling promotes angiogenesis of ECs and maintains self-renewal of MSCs
Keywords: مهندسی بافت استخوان; EphrinB2/Ephs; Angiogenesis; Self-renewal; Co-transplantation; Bone tissue engineering;
Polycaprolactone/carboxymethyl chitosan nanofibrous scaffolds for bone tissue engineering application
Keywords: مهندسی بافت استخوان; Carboxymethyl chitosan; Nanofibers; Osteoblast cells; Electrospinning; Bone tissue engineering;
Light-based additive manufacturing of PolyHIPEs: Controlling the surface porosity for 3D cell culture applications
Keywords: مهندسی بافت استخوان; Bone tissue engineering; PolyHIPE; Emulsion templating; Vat photopolymerisation; Stereolithography; 3D cell culture; Tinuvin;
3D porous poly(ε-caprolactone)/58S bioactive glass-sodium alginate/gelatin hybrid scaffolds prepared by a modified melt molding method for bone tissue engineering
Keywords: مهندسی بافت استخوان; Bone tissue engineering; Scaffold; Sodium alginate; Gelatin; 58S bioactive glass; Poly(ε-caprolactone);
BMP2 expressing genetically engineered mesenchymal stem cells on composite fibrous scaffolds for enhanced bone regeneration in segmental defects
Keywords: مهندسی بافت استخوان; Genetic engineering; Mesenchymal stem cells; Bone tissue engineering; Critical sized defects; Plasmid based transfection;
3D printing of concentrated alginate/gelatin scaffolds with homogeneous nano apatite coating for bone tissue engineering
Keywords: مهندسی بافت استخوان; Nano apatite; 3D printing; Mineralization; Bone tissue engineering;
Poly L lysine-modified PHBV based nanofibrous scaffolds for bone cell mineralization and osteogenic differentiation
Keywords: مهندسی بافت استخوان; Poly(3-hydroxybutyrate-co-3-hydroxyvalerate); Surface modification; Bredigite; Poly L lysine; Nanofibrous scaffolds; Bone tissue engineering;
Fabrication and characterization of highly porous barium titanate based scaffold coated by Gel/HA nanocomposite with high piezoelectric coefficient for bone tissue engineering applications
Keywords: مهندسی بافت استخوان; Bone tissue engineering; Foam replication method; Piezoelectric ceramics; Barium titanate; BaTiO3; d33;
Natural and synthetic polymers/bioceramics/bioactive compounds-mediated cell signalling in bone tissue engineering
Keywords: مهندسی بافت استخوان; ALP; alkaline phosphatase; ANG; angiogenin; AuNPs; gold nanoparticles; BMP; bone morphogenetic protein; BSP; bone sialoprotein; BTE; bone tissue engineering; COL1; collagen type 1; CSL; CBF1/Su(H)/Lag-1 protein; ERK; extracellular signal-regulated kinase;
Injectable degradable PVA microgels prepared by microfluidic technology for controlled osteogenic differentiation of mesenchymal stem cells
Keywords: مهندسی بافت استخوان; Microfluidics; Degradable PVA microgels; Bone tissue engineering; Mesenchymal stem cells; Osteogenic differentiation;
Remote regulation of magnetic particle targeted Wnt signaling for bone tissue engineering
Keywords: مهندسی بافت استخوان; Mesenchymal stem cells; Magnetic nanoparticles; Wnt signaling; Bone tissue engineering;
Tailoring weight ratio of PCL/PLA in electrospun three-dimensional nanofibrous scaffolds and the effect on osteogenic differentiation of stem cells
Keywords: مهندسی بافت استخوان; Electrospinning; Nanofiber; 3D scaffold; Bone tissue engineering; Osteogenic; Differentiation;
In vitro characterization of 3D printed scaffolds aimed at bone tissue regeneration
Keywords: مهندسی بافت استخوان; Bone tissue engineering; Rapid prototyping; 3D printing; Cylindrical hybrid scaffolds; Graphene oxide;
3D porous collagen/functionalized multiwalled carbon nanotube/chitosan/hydroxyapatite composite scaffolds for bone tissue engineering
Keywords: مهندسی بافت استخوان; Scaffold; Hydroxyapatite; Biomimetic method; Bone tissue engineering;
Biomineralized poly (l-lactic-co-glycolic acid)-tussah silk fibroin nanofiber fabric with hierarchical architecture as a scaffold for bone tissue engineering
Keywords: مهندسی بافت استخوان; Tussah silk fibroin; Mineralization; Nanofiber fabric; Hierarchical architecture; Bone tissue engineering;
Controlled degradability of PCL-ZnO nanofibrous scaffolds for bone tissue engineering and their antibacterial activity
Keywords: مهندسی بافت استخوان; Bone tissue engineering; ZnO; Polycaprolactone; Degradation rate; Mineralization; Antibacterial;
Fabrication of in vitro 3D mineralized tissue by fusion of composite spheroids incorporating biomineral-coated nanofibers and human adipose-derived stem cells
Keywords: مهندسی بافت استخوان; Composite spheroid; Mineralized bone tissue construct; Mineralized fibers; Fragmented fibers; Micro-tissue; Bone tissue engineering;
Antioxidant activity of novel PCL/bioactive glass composites enriched with polyphenolic compounds extracted from fruits and leaves of sweet cherry (Prunus avium L.)
Keywords: مهندسی بافت استخوان; Biomaterials; Bone tissue engineering; Polyphenolic compounds; In vitro bioactivity; Antioxidant activity;