Search results for " SCAFFOLD."

showing 10 items of 272 documents

Contribution of outgrowth endothelial cells from human peripheral blood on in vivo vascularization of bone tissue engineered constructs based on star…

2009

In the present study we assessed the potential of human outgrowth endothelial cells (OEC), a subpopulation within endothelial progenitor cell cultures, to support the vascularization of a complex tissue engineered construct for bone. OEC cultured on starch polycaprolactone fiber meshes (SPCL) in monoculture retained their endothelial functionality and responded to angiogenic stimulation by VEGF (vascular endothelial growth factor) in fibrin gel-assays in vitro. Co-culture of OEC with human primary osteoblasts (pOB) on SPCL, induced an angiogenic activation of OEC towards microvessel-like structures achieved without additional supplementation with angiogenic growth factors. Effects of co-cul…

Mice SCID02 engineering and technologyBone tissueBone tissue engineeringNeovascularizationMicechemistry.chemical_compoundSubcutaneous TissueImplants ExperimentalTissue engineeringOsteogenesisEndothelial progenitor cells0303 health sciencesIn vivo testTissue ScaffoldsbiologyStarch021001 nanoscience & nanotechnology3. Good healthCell biologyVascular endothelial growth factorDrug CombinationsPhenotypemedicine.anatomical_structureMechanics of MaterialsProteoglycansCollagenmedicine.symptom0210 nano-technologyPolyestersBiophysicsNeovascularization PhysiologicBioengineeringEndothelial progenitor cellBone and BonesFibrinBiomaterials03 medical and health sciencesIn vivomedicineAnimalsHumansCell Proliferation030304 developmental biologyMatrigelScience & TechnologyOsteoblastsTissue EngineeringVascularizationEndothelial CellsCoculture TechniquesGene Expression RegulationchemistryCeramics and Compositesbiology.proteinLamininBiomedical engineeringBiomaterials
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Scaffold and scaffold-free self-assembled systems in regenerative medicine.

2016

Self-assembly in tissue engineering refers to the spontaneous chemical or biological association of components to form a distinct functional construct, reminiscent of native tissue. Such self-assembled systems have been widely used to develop platforms for the delivery of therapeutic and/or bioactive molecules and various cell populations. Tissue morphology and functional characteristics have been recapitulated in several self-assembled constructs, designed to incorporate stimuli responsiveness and controlled architecture through spatial confinement or field manipulation. In parallel, owing to substantial functional properties, scaffold-free cell-assembled devices have aided in the developm…

Modular engineeringTissue EngineeringTissue ScaffoldsCell-assembled devicesSettore CHIM/09 - Farmaceutico Tecnologico ApplicativoBiomimetic MaterialsGuided Tissue RegenerationHumansSelf-assemblyRegenerative MedicineDelivery of biologicsStimuli-responsive polymersExtracellular MatrixBiotechnology and bioengineering
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Biomaterials and bioactive molecules to drive differentiation in striated muscle tissue engineering

2015

International audience; The generation of engineered tissues and organs has entered into the clinical practice in response to the chronic lack of organ donors. In particular, for the skeletal and cardiac muscles the translational potential of tissue engineering approaches has clearly been shown, even though the construction of these tissues lags behind others given the hierarchical, highly organized architecture of striated muscles. Failure of the cardiac tissue leads to cardiovascular diseases, which are the leading cause of death in the developed world (Di Felice et al., 2014). On the other hand, there are many clinical cases where the loss of skeletal muscle due to a traumatic injury, an…

Muscle tissueStriated muscle tissuePathologymedicine.medical_specialtyPhysiology030204 cardiovascular system & hematologyRegenerative MedicineRegenerative medicinelcsh:PhysiologyBiomaterials03 medical and health sciencescardiac tissue engineering0302 clinical medicineTissue engineeringPhysiology (medical)[SDV.BBM] Life Sciences [q-bio]/Biochemistry Molecular BiologyMedicine[SDV.BBM]Life Sciences [q-bio]/Biochemistry Molecular Biologyskeletal muscle030304 developmental biologyDenervation0303 health scienceslcsh:QP1-981Tissue Engineeringbusiness.industryRegeneration (biology)Editorial ArticleSkeletal musclevasculature nicheBiomaterial3. Good healthmedicine.anatomical_structureTraumatic injuryscaffoldscardiac tissue engineering; regenerative medicine; scaffolds; skeletal muscle; stem cell transplantation; vasculature nichebusinessStem Cell Transplantation
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Optimization of a decellularized protocol of porcine tracheas. Long-term effects of cryopreservation. A histological study

2021

[EN] Objective: The aim of this study was to optimize a decellularization protocol in the trachea of Sus scrofa domestica (pig) as well as to study the effects of long-term cryopreservation on the extracellular matrix of decellularized tracheas. Methods: Porcine tracheas were decellularized using Triton X-100, SDC, and SDS alone or in combination. The effect of these detergents on the extracellular matrix characteristics of decellularized porcine tracheas was evaluated at the histological, biomechanical, and biocompatibility level. Morphometric approaches were used to estimate the effect of detergents on the collagen and elastic fibers content as well as on the removal of chondrocytes from …

OctoxynolSwine0206 medical engineeringTracheal stenosisBiomedical EngineeringMedicine (miscellaneous)Bioengineering02 engineering and technologyCryopreservationBiomaterialsAndrology03 medical and health sciences0302 clinical medicineMedicineSDSCryopreservationDecellularizationTissue EngineeringTissue Scaffoldsbusiness.industryTracheal histologyDecellularized tracheasAirway tissue engineeringGeneral Medicine020601 biomedical engineeringTracheal StenosisSus scrofa domesticaExtracellular MatrixTrachea030220 oncology & carcinogenesisFISICA APLICADAbusiness
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Preparation and characterization of multilayer porous PLA scaffolds

2013

PLA scaffolds biomaterials
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Paintings as Solid Affective Scaffolds

2019

PaintingVisual Arts and Performing Artstaidemaalaritpainters (visual artists)affective scaffoldingpaintingsVisual artsPhilosophytunteetta6131maalauksetluova toimintaPsychologyta611Musiccreative activityJournal of Aesthetics and Art Criticism
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Scaffolding for motivation by parents, and child homework motivations and emotions: Effects of a training programme

2018

Background and aims Based on the principles of scaffolding for motivation and on the assumptions of self-determination theory, two studies aimed to assess the role played by perceived parental autonomy-supportive scaffolding on child homework autonomous motivation, self-efficacy, affect, and engagement. Samples and results The results of Study 1, which involved 122 parents and their children, showed that the higher the parental autonomous motivation, the more their children perceived them as autonomy-supportive while scaffolding for motivation, and hence developed autonomous motivation, self-efficacy, and engagement in homework. In Study 2, 37 parents were involved in a four-session trainin…

ParentsAdultMaleScaffold3304media_common.quotation_subjecteducationEmotionsscaffoldingAffect (psychology)EducationDevelopmental psychologySettore M-PSI/04 - Psicologia Dello Sviluppo E Psicologia Dell'EducazioneDevelopmental and Educational PsychologyHumans0501 psychology and cognitive sciencesParent-Child RelationsChildTraining programmemedia_commonSelf-efficacyEmotionMotivationModalitiestrainingParentingAutonomy supportTeaching05 social sciences050301 educationautonomous motivationSelf-determinationautonomous motivation; engagement; homework; scaffolding; training; 3304; Developmental and Educational PsychologyParentPersonal AutonomyFemalePositive attitudePsychology0503 education050104 developmental & child psychologyengagementhomeworkHumanParent-Child Relation
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Cardiac tissue engineering: a reflection after a decade of hurry

2014

The heart is a perfect machine whose mass is mainly composed of cardiomyocytes, but also fibroblasts, endothelial, smooth muscle, nervous, and immune cells are represented. One thousand million cardiomyocytes are estimated to be lost after myocardial infarction, their loss being responsible for the impairment in heart contractile function (Laflamme and Murry, 2005). The potential success of cardiac cell therapy relies almost completely on the ability of the implanted cells to differentiate toward mature cardiomyocytes. These cells must be able to reinforce the pumping activity of the injured heart in the absence of life-threatening arrhythmias due to electrophysiological incompatibility. Th…

Pathologymedicine.medical_specialtyheart regenerationPhysiologycardiac progenitor cellsClinical uses of mesenchymal stem cellsproto-tissueslcsh:PhysiologyTissue engineeringPhysiology (medical)MedicineInduced pluripotent stem cellStem cell transplantation for articular cartilage repairlcsh:QP1-981business.industryRegeneration (biology)Mesenchymal stem cellOpinion Articletissue engineeringscaffoldsStem cellbusinessNeurosciencecardiac progenitor cells proto-tissues heart regeneration tissue engineering scaffolds biomaterialsbiomaterialsAdult stem cell
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Establishment of a pulmonary epithelial barrier on biodegradable poly-L-lactic-acid membranes

2019

Development of biocompatible and functional scaffolds for tissue engineering is a major challenge, especially for development of polarised epithelia that are critical structures in tissue homeostasis. Different in vitro models of the lung epithelial barrier have been characterized using non-degradable polyethylene terephthalate membranes which limits their uses for tissue engineering. Although poly-L-lactic acid (PLLA) membranes are biodegradable, those prepared via conventional Diffusion Induced Phase Separation (DIPS) lack open-porous geometry and show limited permeability compromising their use for epithelial barrier studies. Here we used PLLA membranes prepared via a modification of the…

PhysiologyCell MembranesCell Culture TechniquesBiocompatible Materials02 engineering and technologyEpitheliumTissue engineeringAnimal CellsAbsorbable ImplantsMaterials TestingElectric ImpedanceMedicine and Health SciencesLungTissue homeostasisBarrier functionStaining0303 health sciencesMultidisciplinaryTissue ScaffoldsTight junctionPolyethylene TerephthalatesChemistryQRCell Staining021001 nanoscience & nanotechnologyMembrane StainingElectrophysiologyMembranePhysical SciencesMedicineCytokinesBiological CulturesCellular Structures and OrganellesJunctional ComplexesCellular TypesAnatomy0210 nano-technologyResearch ArticleCell PhysiologySciencePolyestersMaterials ScienceMaterial PropertiesResearch and Analysis MethodsMembrane PotentialPermeabilityCell LineTight Junctions03 medical and health sciencesCell AdhesionHumans030304 developmental biologyBiochemistry Genetics and Molecular Biology (all)Tissue EngineeringBiology and Life SciencesEpithelial CellsMembranes ArtificialCell BiologyCell CulturesBiological TissueAgricultural and Biological Sciences (all)Specimen Preparation and TreatmentCell culturePermeability (electromagnetism)BiophysicsCytokine secretionPLOS ONE
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Preparation of Poly(l-lactic acid) Scaffolds by Thermally Induced Phase Separation: Role of Thermal History

2018

Abstract Poly-L-Lactic Acid (PLLA) scaffolds for tissue engineering were prepared via thermally induced phase separation of a ternary system PLLA/dioxane/tetrahydrofurane. An extension to solution of a previously developed method for solidification from the melt was adopted, the technique being based on a Continuous Cooling Transformation (CCT) approach, consisting in recording the thermal history of rapidly cooled samples and analysing the resulting morphology. Different foams were produced by changing the thermal history, the dioxane to THF ratio (50/50, 70/30, 90/10 v/v) and the polymer concentration (2, 2.5, 4 ° wt) in the starting ternary solution. Pore size, porosity, melting and crys…

Poly l lactic acidPore sizeMorphology (linguistics)Materials sciencePolymers and PlasticsBiocompatibilitySpinodal decompositionGeneral Chemical Engineering02 engineering and technology010402 general chemistryMEMBRANES01 natural sciencesSPINODAL DECOMPOSITIONIndustrial and Manufacturing EngineeringBIOCOMPATIBILITYPOROUS SCAFFOLDSTISSUE REGENERATIONTissue engineeringMaterials ChemistryPOLYMERIC SCAFFOLDSTernary numeral systemPORE-SIZECELL TRANSPLANTATION021001 nanoscience & nanotechnology0104 chemical sciencesMembraneChemical engineeringMORPHOLOGY0210 nano-technologyBEHAVIOR
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