Search results for "vascular tissue engineering"

showing 9 items of 9 documents

Multicellular Interactions in 3D Engineered Myocardial Tissue

2018

Cardiovascular disease is a leading cause of death in the US and many countries worldwide. Current cell-based clinical trials to restore cardiomyocyte (CM) health by local delivery of cells have shown only moderate benefit in improving cardiac pumping capacity. CMs have highly organized physiological structure and interact dynamically with non-CM populations, including endothelial cells and fibroblasts. Within engineered myocardial tissue, non-CM populations play an important role in CM survival and function, in part by secreting paracrine factors and cell-cell interactions. In this review, we will summarize the progress of engineering myocardial tissue with pre-formed physiological multice…

0301 basic medicinelcsh:Diseases of the circulatory (Cardiovascular) systemMini Reviewcardiomyocyte02 engineering and technologyDiseaseCardiovascular MedicineBiologyengineered myocardiumfibroblast03 medical and health sciencesParacrine signallingcardiovascular tissue engineeringMyocardial tissueTranslation (biology)021001 nanoscience & nanotechnologyco-culture3. Good healthCell biologystem cellEndothelial stem cellMulticellular organism030104 developmental biologylcsh:RC666-701endothelial cellStem cell0210 nano-technologyCardiology and Cardiovascular MedicineFunction (biology)Frontiers in Cardiovascular Medicine
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Poly-left-lactic acid tubular scaffolds via diffusion induced phase separation: Control of morphology

2013

n this work, tubular poly-left-lactic acid scaffolds for vascular tissue engineering applications were produced by an innovative two-step method. The scaffolds were obtained by performing a dip-coating around a nylon fiber, followed by a diffusion induced phase separation process. Morphological analysis revealed that the internal lumen of the as-obtained scaffold is equal to the diameter of the fiber utilized; the internal surface is homogeneous with micropores 1–2 μm large. Moreover, a porous open structure was detected across the thickness of the walls of the scaffold. An accurate analysis of the preparation process revealed that it is possible to tune up the morphology of the scaffold (w…

Settore ING-IND/24 - Principi Di Ingegneria ChimicaScaffoldMaterials sciencescaffold poly-lactic acid tissue engineeringDiffusion Induced Phase separationPolymers and PlasticsPhase separation processPoly-left lactic acidvascular tissue engineeringGeneral ChemistryLactic acidchemistry.chemical_compoundSettore ING-IND/22 - Scienza E Tecnologia Dei MaterialichemistryTissue engineeringHomogeneousSettore BIO/10 - BiochimicaMaterials ChemistryComposite materialPorosityWall thicknessIn vitro cell culturePolymer Engineering & Science
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Using Polymeric Scaffolds for Vascular Tissue Engineering

2014

With the high occurrence of cardiovascular disease and increasing numbers of patients requiring vascular access, there is a significant need for small-diameter (<6 mm inner diameter) vascular graft that can provide long-term patency. Despite the technological improvements, restenosis and graft thrombosis continue to hamper the success of the implants. Vascular tissue engineering is a new field that has undergone enormous growth over the last decade and has proposed valid solutions for blood vessels repair. The goal of vascular tissue engineering is to produce neovessels and neoorgan tissue from autologous cells using a biodegradable polymer as a scaffold. The most important advantage of …

ScaffoldAutologous cellPolymers and PlasticsSettore BIO/16 - Anatomia Umanabusiness.industryVascular accessmedicine.diseaselcsh:Chemical technologySettore MED/18 - Chirurgia GeneralePOLYMERIC SCAFFOLDS VASCULAR TISSUE ENGINEERING VASCULAR GRAFTSRestenosisTissue engineeringSettore BIO/13 - Biologia ApplicatamedicineVascular tissue engineeringInner diameterlcsh:TP1-1185businessVascular graftBiomedical engineeringInternational Journal of Polymer Science
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Double Flow Bioreactor for In Vitro Test of Drug Delivery.

2015

In this work, double-structured polymeric scaffolds were produced, and a double flow bioreactor was designed and set up in order to create a novel system to carry out advanced in vitro drug delivery tests. The scaffolds, consisting of a cylindrical porous matrix, are able to host cells, thus mimicking a three-dimensional tumor mass: moreover, a “pseudo-vascular” structure was embedded into the matrix, with the aim of allowing a flow circulation. The structure that emulates a blood vessel is a porous tubular-shaped scaffold prepared by Diffusion Induced Phase Separation (DIPS), with an internal lumen of 2 mm and a wall thickness of 200 micrometers. The as-prepared vessel was incorporated…

3003ScaffoldMaterials scienceIn vitro testPharmaceutical PreparationPolymersSurface PropertiesSurface PropertieBioreactorPhase separationDrug Evaluation PreclinicalVascular tissue engineeringPharmaceutical ScienceNanotechnology02 engineering and technology010402 general chemistry01 natural sciencesFluid dynamicBioreactorsDrug Delivery SystemsBioreactorHumansParticle SizePolymerPorositychemistry.chemical_classificationFluid dynamic Vascular Tissue EngineeringMedicine (all)PolymerEquipment Design021001 nanoscience & nanotechnology0104 chemical sciencesShear strechemistryPharmaceutical PreparationsPoly-L-lactic acidDrug deliveryParticle size0210 nano-technologyDrug Delivery SystemHumanLumen (unit)Biomedical engineeringCurrent drug delivery
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PLLA/Fibrin Tubular Scaffold: A New Way for Reliable Endothelial Cell Seeding

2014

In the present work a simple and quick technique for cell seeding into tubular-shaped scaffolds, which allows a homogeneous cell distribution, was tested. The poly-L-lactide (PLLA) scaffolds, prepared via diffusion induced phase separation (DIPS), were filled with fibrin gel in order to obtain a hybrid scaffold for Vascular Tissue Engineering applications. The formation of immobilized fibrin networks on the inner surface of the tubular scaffolds was observed using confocal microscopy and SEM. Morphological analysis of the so-obtained scaffold revealed that the fibrin gel is uniformly distributed on the internal surface of the scaffold, leading to an organized structure. Moreover a penetrati…

FibrinScaffoldMaterials sciencebiologyCell growthGeneral MedicinePenetration (firestop)Fibrinlaw.inventionEndothelial stem cellPhase SeparationTubular scaffoldConfocal microscopylawbiology.proteinSeedingVascular Tissue EngineeringBiomedical engineeringConference Papers in Science
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Tubular scaffold for vascular tissue engineering application

2010

A critical obstacle in tissue engineering is the inability to maintain large masses of living cells upon transfer from the in vitro culture conditions into the host in vivo. Capillaries, and the vascular system, are required to supply essential nutrients, including oxygen, remove waste products and provide a biochemical communication “highway”. Another goal in this research field is the possibility to tune the biodegradability of the scaffold. After implantation, the scaffold has to be gradually replaced by cells and extra cellular matrix and it is crucial that this replacement takes place with an appropriate dynamics. A premature degradation, in fact, could lead to a collapse of the struct…

Settore ING-IND/24 - Principi Di Ingegneria ChimicaSettore ING-IND/26 - Teoria Dello Sviluppo Dei Processi ChimiciScaffoldMaterials scienceVascular grafts Tissue enginering PLLAExtracellular matrixSettore ING-IND/22 - Scienza E Tecnologia Dei MaterialiTubular scaffoldTissue engineeringIn vivoHomogeneousVascular tissue engineeringGeneral Materials ScienceBiomedical engineeringInternational Journal of Material Forming
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PLLA-fibrin scaffolds for Vascular Tissue Engineering

2013

FibrinSettore ING-IND/24 - Principi Di Ingegneria ChimicaSettore ING-IND/22 - Scienza E Tecnologia Dei MaterialiSettore BIO/10 - BiochimicaPoly Lactic AcidVascular Tissue Engineering
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Bioengineered vascular scaffolds: the state of the art

2014

To date, there is increasing clinical need for vascular substitutes due to accidents, malformations, and ischemic diseases. Over the years, many approaches have been developed to solve this problem, starting from autologous native vessels to artificial vascular grafts; unfortunately, none of these have provided the perfect vascular substitute. All have been burdened by various complications, including infection, thrombogenicity, calcification, foreign body reaction, lack of growth potential, late stenosis and occlusion from intimal hyperplasia, and pseudoaneurysm formation. In the last few years, vascular tissue engineering has emerged as one of the most promising approaches for producing …

EngineeringIntimal hyperplasiaBiomedical EngineeringMedicine (miscellaneous)ThrombogenicityNew materialsBioengineeringBiocompatible MaterialsVascular graftBiomaterialsTissue engineeringBlood vessel prosthesisBiomaterials; Tissue engineering; Vascular grafts; Vascular prosthesesmedicineHumansTissue engineeringTissue Scaffoldsbusiness.industrySettore ING-IND/34 - Bioingegneria IndustrialeGeneral Medicinemedicine.diseaseBiocompatible materialBiomaterialBlood Vessel ProsthesisStenosisSettore MED/18 - Chirurgia GeneraleVascular tissue engineeringVascular prosthesesbusinessBiomedical engineering
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Tissue engineered vascular grafts based on poly-lactic acid blends

2013

A great deal of research has been pursued in the last decade with the goal of developing blood vessel substitutes. Tissue engineering has emerged as a promising approach to address the shortcomings of current options. One of the major tasks in this research field is the possibility to tune the biodegradability of the implantable devices (scaffolds). After implantation, the scaffold has to be replaced by extra cellular matrix; with this respect, it is crucial that this replacement takes place with appropriate dynamics and a well-defined timescale. In this work tissue-engineered vascular graft were produced, utilizing several PLLA/PLA blends (100/0, 90/10, 75/25 wt/wt) in order to tune their …

ScaffoldPolymer BlendsVascular Tissue Engineering
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