Mesoscopic hydrogel molding to control the 3D geometry of bioartificial muscle tissues - Wikidata - wikimedia - TriplyDB

Mesoscopic hydrogel molding to control the 3D geometry of bioartificial muscle tissues

Mesoscopic hydrogel molding to control the 3D geometry of bioartificial muscle tissues

http://www.wikidata.org/entity/Q30496172

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Neonatal mouse-derived engineered cardiac tissue: a novel model system for studying genetic heart disease Tissue-engineered cardiac patch for advanced functional maturation of human ESC-derived cardiomyocytes Biomaterial-based delivery for skeletal muscle repair Functional cardiac tissue engineering μOrgano: A Lego®-Like Plug & Play System for Modular Multi-Organ-Chips Induced pluripotent stem cell-derived cardiac progenitors differentiate to cardiomyocytes and form biosynthetic tissues Modelling sarcomeric cardiomyopathies in the dish: from human heart samples to iPSC cardiomyocytes Micromechanical regulation in cardiac myocytes and fibroblasts: implications for tissue remodeling Local tissue geometry determines contractile force generation of engineered muscle networks Engineering biosynthetic excitable tissues from unexcitable cells for electrophysiological and cell therapy studies.Formation and optogenetic control of engineered 3D skeletal muscle bioactuators.Measuring collective cell movement and extracellular matrix interactions using magnetic resonance imaging.Biomimetic engineered muscle with capacity for vascular integration and functional maturation in vivo Impact of Cell Composition and Geometry on Human Induced Pluripotent Stem Cells-Derived Engineered Cardiac Tissue.Controlling the structural and functional anisotropy of engineered cardiac tissues.Microscale 3-D hydrogel scaffold for biomimetic gastrointestinal (GI) tract model.Use of flow, electrical, and mechanical stimulation to promote engineering of striated muscles.Macrophage embedded fibrin gels: an in vitro platform for assessing inflammation effects on implantable glucose sensors Skeletal muscle tissue engineering: methods to form skeletal myotubes and their applications.Laser microfabricated poly(glycerol sebacate) scaffolds for heart valve tissue engineering Mechanistic investigation of adult myotube response to exercise and drug treatment in vitro using a multiplexed functional assay system The role of extracellular matrix composition in structure and function of bioengineered skeletal muscle Soluble miniagrin enhances contractile function of engineered skeletal muscle.Anisotropic engineered heart tissue made from laser-cut decellularized myocardium.Microdomain heterogeneity in 3D affects the mechanics of neonatal cardiac myocyte contraction.Endothelial cell sensing, restructuring, and invasion in collagen hydrogel structures.Engineered contractile skeletal muscle tissue on a microgrooved methacrylated gelatin substrate Design, evaluation, and application of engineered skeletal muscle.Engineered human cardiac tissue.Synergizing Engineering and Biology to Treat and Model Skeletal Muscle Injury and Disease.Engineering skeletal muscle repair.A topographically modified substrate-embedded MEA for directed myotube formation at electrode contact sites.Myocardial scaffold-based cardiac tissue engineering: application of coordinated mechanical and electrical stimulations.Tissue-engineered 3-dimensional (3D) microenvironment enhances the direct reprogramming of fibroblasts into cardiomyocytes by microRNAs.Strategies for directing the structure and function of three-dimensional collagen biomaterials across length scales.Strategies for tissue engineering cardiac constructs to affect functional repair following myocardial infarction.Engineered skeletal muscle tissue for soft robotics: fabrication strategies, current applications, and future challenges.Utilization and control of bioactuators across multiple length scales.Cardiac tissue engineering: renewing the arsenal for the battle against heart disease.Robust T-tubulation and maturation of cardiomyocytes using tissue-engineered epicardial mimetics.

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Mesoscopic hydrogel molding to control the 3D geometry of bioartificial muscle tissues

http://www.wikidata.org/entity/Q30496172

description

2009 nî lūn-bûn

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2009 թուականի Սեպտեմբերին հրատարակուած գիտական յօդուած

@hyw

2009 թվականի սեպտեմբերին հրատարակված գիտական հոդված

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2009年の論文

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2009年論文

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2009年論文

@zh-hant

2009年論文

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2009年論文

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2009年論文

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2009年论文

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name

Mesoscopic hydrogel molding to control the 3D geometry of bioartificial muscle tissues

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Mesoscopic hydrogel molding to control the 3D geometry of bioartificial muscle tissues

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type

label

Mesoscopic hydrogel molding to control the 3D geometry of bioartificial muscle tissues

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Mesoscopic hydrogel molding to control the 3D geometry of bioartificial muscle tissues

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prefLabel

Mesoscopic hydrogel molding to control the 3D geometry of bioartificial muscle tissues

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Mesoscopic hydrogel molding to control the 3D geometry of bioartificial muscle tissues

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Nature Protocols

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Mesoscopic hydrogel molding to control the 3D geometry of bioartificial muscle tissues

@en

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Nima Badie

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Weining Bian

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P2860

Basic Mechanisms of Cardiac Impulse Propagation and Associated Arrhythmias

Taking cell-matrix adhesions to the third dimension

Cells lying on a bed of microneedles: an approach to isolate mechanical force

Tissue engineering

The origins and the future of microfluidics

Accordion-like honeycombs for tissue engineering of cardiac anisotropy

Microfabricated tissue gauges to measure and manipulate forces from 3D microtissues

Engineered skeletal muscle tissue networks with controllable architecture

Cell-induced alignment augments twitch force in fibrin gel-based engineered myocardium via gap junction modification

Cardiomyocyte hypertrophy and degradation of connexin43 through spatially restricted autocrine/paracrine heparin-binding EGF

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1522-1534

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10.1038/NPROT.2009.155

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10

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4

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2924624

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