The stimulation of myoblast differentiation by electrically conductive sub-micron fibers.
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A conducting polymer with enhanced electronic stability applied in cardiac models.Nanotopography-guided tissue engineering and regenerative medicine.Cell infiltration and growth in a low density, uncompressed three-dimensional electrospun nanofibrous scaffold.Enhanced growth and osteogenic differentiation of human osteoblast-like cells on boron-doped nanocrystalline diamond thin filmsBiomaterial guides for lymphatic endothelial cell alignment and migrationSkeletal myotube formation enhanced by electrospun polyurethane carbon nanotube scaffoldsEffects of substrate conductivity on cell morphogenesis and proliferation using tailored, atomic layer deposition-grown ZnO thin filmsDuctile electroactive biodegradable hyperbranched polylactide copolymers enhancing myoblast differentiationDirect-write, highly aligned chitosan-poly(ethylene oxide) nanofiber patterns for cell morphology and spreading control.Electroconductive Nanopatterned Substrates for Enhanced Myogenic Differentiation and Maturation.Rational design of nanofiber scaffolds for orthopedic tissue repair and regenerationRelationship between nanotopographical alignment and stem cell fate with live imaging and shape analysis.Combining topographical and genetic cues to promote neuronal fate specification in stem cells.Engineering skeletal muscle tissue--new perspectives in vitro and in vivo.Review paper: progress in the field of conducting polymers for tissue engineering applications.Electrospun synthetic and natural nanofibers for regenerative medicine and stem cells.The applications of conductive nanomaterials in the biomedical field.Stem Cell Differentiation Toward the Myogenic Lineage for Muscle Tissue Regeneration: A Focus on Muscular Dystrophy.Cell-Instructive Graphene-Containing Nanocomposites Induce Multinucleated Myotube Formation.Mechanistic contribution of electroconductive hydroxyapatite-titanium disilicide composite on the alignment and proliferation of cells.Rationalization of specific structure formation in electrospinning process: Study on nano-fibrous PCL- and PLGA-based scaffolds.Highly conductive stretchable and biocompatible electrode-hydrogel hybrids for advanced tissue engineering.Effect of topological cues on material-driven fibronectin fibrillogenesis and cell differentiation.Synthesis and characterization of conductive, biodegradable, elastomeric polyurethanes for biomedical applications.Electroactive polyurethane/siloxane derived from castor oil as a versatile cardiac patch, part I: Synthesis, characterization, and myoblast proliferation and differentiation.Protocol and cell responses in three-dimensional conductive collagen gel scaffolds with conductive polymer nanofibres for tissue regeneration.In vitro and in vivo evaluation of (L)-lactide/ε-caprolactone copolymer scaffold to support myoblast growth and differentiation.The nanofibrous PAN-PANi scaffold as an efficient substrate for skeletal muscle differentiation using satellite cells.Electrical Stimulation of Human Mesenchymal Stem Cells on Conductive Nanofibers Enhances their Differentiation toward Osteogenic Outcomes.The incorporation of bFGF mediated by heparin into PCL/gelatin composite fiber meshes for guided bone regeneration.Electroactive electrospun polyaniline/poly[(L-lactide)-co-(ε-caprolactone)] fibers for control of neural cell function.Prospectus of cultured meat—advancing meat alternatives.A facile approach for the fabrication of core–shell PEDOT nanofiber mats with superior mechanical properties and biocompatibilityBiomaterials in Tendon and Skeletal Muscle Tissue Engineering: Current Trends and ChallengesAmphiphilic random copolymer vesicle induces differentiation of mouse C2C12 myoblastsElectrical Stimulation of Myoblast Proliferation and Differentiation on Aligned Nanostructured Conductive Polymer PlatformsStem cell differentiation on conducting polyanilineInsulating and semiconducting polymeric free-standing nanomembranes with biomedical applicationsElectronic, electric and electrochemical properties of bioactive nanomembranes made of polythiophene:thermoplastic polyurethaneThe Importance of Biophysical and Biochemical Stimuli in Dynamic Skeletal Muscle Models
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P2860
The stimulation of myoblast differentiation by electrically conductive sub-micron fibers.
description
2009 nî lūn-bûn
@nan
2009年の論文
@ja
2009年学术文章
@wuu
2009年学术文章
@zh-cn
2009年学术文章
@zh-hans
2009年学术文章
@zh-my
2009年学术文章
@zh-sg
2009年學術文章
@yue
2009年學術文章
@zh
2009年學術文章
@zh-hant
name
The stimulation of myoblast differentiation by electrically conductive sub-micron fibers.
@en
The stimulation of myoblast differentiation by electrically conductive sub-micron fibers.
@nl
type
label
The stimulation of myoblast differentiation by electrically conductive sub-micron fibers.
@en
The stimulation of myoblast differentiation by electrically conductive sub-micron fibers.
@nl
prefLabel
The stimulation of myoblast differentiation by electrically conductive sub-micron fibers.
@en
The stimulation of myoblast differentiation by electrically conductive sub-micron fibers.
@nl
P2093
P1433
P1476
The stimulation of myoblast differentiation by electrically conductive sub-micron fibers.
@en
P2093
Heungsoo Shin
Indong Jun
Sungin Jeong
P304
P356
10.1016/J.BIOMATERIALS.2008.12.063
P577
2009-01-14T00:00:00Z