X
Search Filters
Format Format
Format Format
X
Sort by Item Count (A-Z)
Filter by Count
Journal Article (1565) 1565
Publication (156) 156
Book Chapter (48) 48
Magazine Article (16) 16
Conference Proceeding (15) 15
Book Review (13) 13
Dissertation (6) 6
more...
Subjects Subjects
Subjects Subjects
X
Sort by Item Count (A-Z)
Filter by Count
nanofibrous scaffolds (708) 708
index medicus (692) 692
tissue engineering (666) 666
electrospinning (622) 622
materials science, biomaterials (489) 489
scaffolds (449) 449
humans (382) 382
animals (379) 379
in-vitro (368) 368
polymer science (348) 348
engineering, biomedical (345) 345
nanofibers (311) 311
regeneration (293) 293
fibers (286) 286
fabrication (269) 269
biocompatibility (237) 237
collagen (233) 233
tissue scaffolds - chemistry (233) 233
poly (230) 230
mesenchymal stem-cells (224) 224
stem cells (224) 224
nanofibrous scaffold (223) 223
nanofibers - chemistry (222) 222
tissue-engineering (219) 219
tissue engineering - methods (218) 218
materials science, multidisciplinary (209) 209
membranes (209) 209
mechanical-properties (208) 208
differentiation (207) 207
nanofaser (202) 202
polymers (194) 194
biomedical materials (179) 179
chitosan (179) 179
nanoscience & nanotechnology (177) 177
nanostructure (174) 174
biomaterials (170) 170
porosity (167) 167
analysis (163) 163
mechanical properties (159) 159
elektrostatisches spinnen (157) 157
nanoparticles (156) 156
polyesters - chemistry (156) 156
tissue scaffolds (155) 155
chemistry, multidisciplinary (152) 152
polycaprolactone (145) 145
morphology (144) 144
cells, cultured (143) 143
biological products (138) 138
biocompatible materials - chemistry (137) 137
extracellular-matrix (134) 134
stem-cells (133) 133
cell proliferation (132) 132
tissue (132) 132
gelatin (123) 123
nanotechnology (120) 120
drug-delivery (118) 118
mice (118) 118
article (116) 116
biotechnology & applied microbiology (116) 116
materials testing (112) 112
rats (112) 112
scaffold (111) 111
polymer (108) 108
cells (107) 107
microscopy, electron, scanning (107) 107
adhesion (106) 106
osteogenic differentiation (106) 106
cell differentiation (102) 102
electrostatic-spinning (102) 102
hydrogels (101) 101
in-vivo (99) 99
nanocomposites (97) 97
proliferation (97) 97
bone regeneration (96) 96
hydroxyapatite (93) 93
chemistry, physical (91) 91
fibroblasts (91) 91
wound healing (90) 90
biomaterial (89) 89
cell adhesion (89) 89
nanofibrous membranes (88) 88
surface modification (88) 88
cell biology (87) 87
proteins (87) 87
controlled-release (85) 85
nanofibers - ultrastructure (85) 85
matrix (84) 84
mats (84) 84
pharmacology & pharmacy (84) 84
skin (84) 84
composite (83) 83
degradation (83) 83
biochemistry & molecular biology (82) 82
bone (82) 82
delivery (82) 82
drug delivery systems (82) 82
growth (81) 81
polymers - chemistry (80) 80
cartilage (78) 78
chemistry (78) 78
more...
Library Location Library Location
Language Language
Publication Date Publication Date
Click on a bar to filter by decade
Slide to change publication date range


Cytotechnology, ISSN 0920-9069, 5/2016, Volume 68, Issue 3, pp. 355 - 369
Journal Article
International Journal of Biological Macromolecules, ISSN 0141-8130, 2011, Volume 48, Issue 1, pp. 13 - 19
Journal Article
Journal Article
Materials Science & Engineering C, ISSN 0928-4931, 2007, Volume 27, Issue 3, pp. 504 - 509
Tissue engineering involves fabrication of three-dimensional scaffolds to support cellular in-growth and proliferation. The goal: generation of ‘neotissues’... 
Nanofibers | Tissue engineering | Scaffolds | Topography | Electrospin | Biomaterials | MATRIX | tissue engineering | 3-DIMENSIONAL NANOFIBROUS SCAFFOLD | MATERIALS SCIENCE, MULTIDISCIPLINARY | topography | MEMBRANES | nanofibers | MESENCHYMAL STEM-CELLS | COMPOSITE | FIBERS | scaffolds | POLYMER | electrospin | biomaterials
Journal Article
Acta Biomaterialia, ISSN 1742-7061, 2006, Volume 2, Issue 4, pp. 377 - 385
The most common synthetic biodegradable polymers being investigated for tissue engineering applications are FDA approved, clinically used poly(α-hydroxy... 
Mesenchymal stem cell | Electrospinning | Nanofiber | Chondrocyte | Fiber | mesenchymal stem cell | POLYMERS | fiber | MATERIALS SCIENCE, BIOMATERIALS | 3-DIMENSIONAL NANOFIBROUS SCAFFOLD | ENGINEERING, BIOMEDICAL | nanofiber | CULTURE | MESENCHYMAL STEM-CELLS | HUMAN MARROW | chondrocyte | electrospinning | ARTICULAR-CARTILAGE | DIFFERENTIATION | BONE | MORPHOLOGY | Chondrocytes - cytology | Polyglycolic Acid - chemical synthesis | Cell Proliferation | Molecular Weight | Coated Materials, Biocompatible - chemical synthesis | Humans | Extracellular Matrix - metabolism | Glycolates - chemistry | Mesenchymal Stromal Cells - cytology | Mesenchymal Stromal Cells - ultrastructure | Chondrocytes - physiology | Cattle | Polyesters - chemical synthesis | Cell Culture Techniques | Glycolates - chemical synthesis | Chondrocytes - metabolism | Mesenchymal Stromal Cells - physiology | Tissue Engineering | Biodegradation, Environmental | Tensile Strength | Lactic Acid - chemistry | Polymers - chemical synthesis | Cartilage, Articular - cytology | Cells, Cultured | Coated Materials, Biocompatible - chemistry | Mesenchymal Stromal Cells - metabolism | Materials Testing | Polyesters - chemistry | Extracellular Matrix - ultrastructure | Animals | Chondrocytes - ultrastructure | Polyglycolic Acid - chemistry | Polymers - chemistry | Lactic Acid - chemical synthesis | Biological products | Chemical properties | Polymers | Drug approval | Nanotechnology | Stem cells
Journal Article
Journal of Cellular and Molecular Medicine, ISSN 1582-1838, 10/2012, Volume 16, Issue 10, pp. 2247 - 2270
Osteochondral tissue engineering has shown an increasing development to provide suitable strategies for the regeneration of damaged cartilage and underlying... 
osteochondral tissue engineering | scaffold designs | composites | bilayered scaffolds | scaffold fabrication | clinical relevance | Osteochondral tissue engineering | Scaffold fabrication | Composites | Clinical relevance | Scaffold designs | Bilayered scaffolds | MEDICINE, RESEARCH & EXPERIMENTAL | COMPOSITE SCAFFOLDS | GLASS-CERAMIC SCAFFOLDS | AXIAL VASCULARIZATION | MECHANICAL-PROPERTIES | NANOFIBROUS SCAFFOLDS | CELL BIOLOGY | IN-VITRO | BIPHASIC SCAFFOLD | BONE SUBSTITUTE | ARTICULAR-CARTILAGE | FIBROUS SCAFFOLDS | Chondrocytes - cytology | Tissue Engineering - methods | Bone and Bones - chemistry | Biocompatible Materials - chemistry | Humans | Prostheses and Implants | Bone Regeneration | Stem Cells - cytology | Tissue Scaffolds - chemistry | Animals | Ceramics - chemistry | Models, Animal | Cell Differentiation | Cartilage, Articular - chemistry | Tissue engineering | Stem cells | Biodegradability | Surface chemistry | Bond strength | Alcohol | Hydroxyapatite | Biomaterials | Fabrication | Cartilage | Engineering | Biomedical materials | Cell growth | Topography | Synthetic products | Biocompatibility | Polymers | Biodegradation | Mechanical properties | Shear strength | Cartilage (articular) | Ceramics | Bone (subchondral) | Medicine | Studies | Regeneration | Composite materials | Calcification | Composite structures | Scaffolds | Reviews
Journal Article