Search results for "scaffolds"

showing 10 items of 208 documents

A facile and eco-friendly route to fabricate poly(Lactic acid) scaffolds with graded pore size

2016

Over the recent years, functionally graded scaffolds (FGS) gaineda crucial role for manufacturing of devices for tissue engineering. The importance of this new field of biomaterials research is due to the necessity to develop implants capable of mimicking the complex functionality of the various tissues, including a continuous change from one structure or composition to another. In this latter context, one topic of main interest concerns the design of appropriate scaffolds for bone-cartilage interface tissue. In this study, three-layered scaffolds with graded pore size were achieved by melt mixing poly(lactic acid) (PLA), sodium chloride (NaCl) and polyethylene glycol (PEG). Pore size distr…

Pore sizeMaterials sciencePolymersGeneral Chemical EngineeringParticulate leachingBiocompatible MaterialsBioengineeringContext (language use)02 engineering and technologyPolyethylene glycol010402 general chemistry01 natural sciencesGeneral Biochemistry Genetics and Molecular BiologyPolyethylene Glycolschemistry.chemical_compoundTissue engineeringMelt mixingPEG ratioHumansLactic AcidPorosityTissue EngineeringTissue ScaffoldsGeneral Immunology and MicrobiologyGeneral NeuroscienceInterface tissue engineeringPore size gradientFunctionally graded scaffold021001 nanoscience & nanotechnologyEnvironmentally friendlyPEG0104 chemical sciencesLactic acidchemistryChemical engineeringPLA0210 nano-technologyPorosity
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Poly(ethylenglycol) mimics adhesive capability of the ECM treatment on 3D polylactide-based scaffolds to study in vitro human hepatocarcinoma process…

2011

Porous scaffolds PLA PEG
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Nanotechnology, and scaffold implantation for the effective repair of injured organs: An overview on hard tissue engineering

2020

The tissue engineering of hard organs and tissues containing cartilage, teeth, and bones is a widely used and rapidly progressing field. One of the main features of hard organs and tissues is the mineralization of their extracellular matrices (ECM) to enable them to withstand pressure and weight. Recently, a variety of printing strategies have been developed to facilitate hard organ and tissue regeneration. Fundamentals in three-dimensional (3D) printing techniques are rapid prototyping, additive manufacturing, and layered built-up and solid-free construction. This strategy promises to replicate the multifaceted architecture of natural tissues. Nowadays, 3D bioprinting techniques have prove…

Rapid prototyping0303 health sciences3D bioprintingScaffoldTissue EngineeringTissue ScaffoldsComputer scienceCartilageBioprintingPharmaceutical ScienceNanotechnology02 engineering and technology021001 nanoscience & nanotechnologyHard tissuelaw.invention03 medical and health sciencesmedicine.anatomical_structureTissue engineeringlawPrinting Three-DimensionalmedicineNanotechnology0210 nano-technology030304 developmental biologyJournal of Controlled Release
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SCAFFOLDS BASED ON HYALURONIC ACID AND POLYAMINOACIDS AS ARTIFICIAL ECM SUBSTITUTES

2009

SCAFFOLDS HYALURONIC ACID POLYAMINOACIDSSettore CHIM/09 - Farmaceutico Tecnologico Applicativo
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Biologic response of inguinal hernia prosthetics: a comparative study of conventional static meshes versus 3D dynamic implants.

2015

Despite improvements in prosthetics and surgical techniques, the rate of complications following inguinal hernia repair remains high. Among these, discomfort and chronic pain have become a source of increasing concern among surgeons. Poor quality of tissue ingrowth, such as thin scar plates or shrinking scars-typical results with conventional static implants and plugs-may contribute to these adverse events. Recently, a new type of 3D dynamically responsive implant was introduced to the market. This device, designed to be placed fixation-free, seems to induce ingrowth of viable and structured tissue instead of regressive fibrotic scarring. To elucidate the differences in biologic response be…

Sampling StudieTime FactorsTime FactorProstheses and ImplantBiomedical EngineeringMedicine (miscellaneous)BioengineeringBiocompatible MaterialsHernia InguinalPolypropylenesProsthesis DesignSampling StudiesStatistics NonparametricImaging Three-DimensionalProstheseTensile StrengthMaterials TestingHumansHerniorrhaphyBiocompatible MaterialMedicine (all)Inguinal herniaImplantTissue scaffoldProstheses and ImplantsSurgical MeshBiomaterialImmunohistochemistryProsthesis FailureSettore MED/18 - Chirurgia GeneraleTissue regenerationBiomaterials; Herniorrhaphy; Implants; Inguinal hernia; Prostheses; Tissue regeneration; Tissue scaffolds; Biocompatible Materials; Hernia Inguinal; Herniorrhaphy; Humans; Imaging Three-Dimensional; Immunohistochemistry; Materials Testing; Polypropylenes; Prosthesis Design; Prosthesis Failure; Sampling Studies; Statistics Nonparametric; Tensile Strength; Time Factors; Prostheses and Implants; Surgical Mesh; Biomaterials; Biomedical Engineering; Bioengineering; Medicine (miscellaneous); Medicine (all)PolypropyleneHumanArtificial organs
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Silk fibroin scaffolds enhance cell commitment of adult rat cardiac progenitor cells.

2015

The use of three-dimensional (3D) cultures may induce cardiac progenitor cells to synthesize their own extracellular matrix (ECM) and sarcomeric proteins to initiate cardiac differentiation. 3D cultures grown on synthetic scaffolds may favour the implantation and survival of stem cells for cell therapy when pharmacological therapies are not efficient in curing cardiovascular diseases and when organ transplantation remains the only treatment able to rescue the patient’s life. Silk fibroin-based scaffolds may be used to increase cell affinity to biomaterials and may be chemically modified to improve cell adhesion. In the present study, porous, partially orientated and electrospun nanometric n…

Sarcomeresprogenitor cellCell SurvivalCell Culture TechniquesBiocompatible MaterialsReal-Time Polymerase Chain ReactionZ-bodieMicroscopy Electron TransmissionCell AdhesionElectrochemistryAnimalsConnectinnatural polymermyocardial tissue; progenitor cells; Z-bodies; tissue engineering; natural polymers; silk fibroinTissue EngineeringTissue ScaffoldsMyocardiumStem CellsWaterCell Differentiationmyocardial tissueBombyxFlow CytometryExtracellular MatrixRatssilk fibroinMicroscopy Electron ScanningCollagenFibroinsPorosityJournal of tissue engineering and regenerative medicine
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Porous biomaterials and scaffolds for tissue engineering

2019

In the present article, an overview of the definition of tissue engineering and scaffold requirements is reported. In particular, scaffold porosity and its relevance for several tissue target regeneration is highlighted. Different scaffold fabrication techniques are reported and explained in details, highlighting advantages and disadvantages for all of these techniques, regarding the specific final applications.

Scaffold fabricationScaffoldsScaffoldMaterials scienceTissue engineeringScaffold fabrication techniquesRegeneration (biology)Settore ING-IND/34 - Bioingegneria IndustrialeNanotechnologyTissue engineeringPorosityPorosity
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Channeled scaffolds implanted in adult rat brain.

2012

Scaffolds with aligned channels based on acrylate copolymers, which had previously demonstrated good com- patibility with neural progenitor cells were studied as coloniz- able structures both in vitro with neural progenitor cells and in vivo, implanted without cells in two different locations, in the cortical plate of adult rat brains and close to the subven- tricular zone. In vitro, neuroprogenitors colonize the scaffold and differentiate into neurons and glia within its channels. When implanted in vivo immunohistochemical analysis by confocal microscopy for neural and endothelial cells markers demonstrated that the scaffolds maintained continuity with the surrounding neural tissue and wer…

ScaffoldAgingMaterials scienceAngiogenesisbrainBiomedical EngineeringSubventricular zoneNeovascularization PhysiologicScaffold SeedingNeural tissue engineeringGlial scarScaffoldBiomaterialsangiogenesisbiocompatibilityImplants ExperimentalNeural Stem CellsIn vivomedicineAnimalsRats WistarCerebral CortexNeuronsTissue ScaffoldsMetals and AlloysBrainCell DifferentiationNeural stem cellRatsAdult Stem Cellsmedicine.anatomical_structureMicroscopy FluorescenceMAQUINAS Y MOTORES TERMICOSCeramics and CompositesMicroscopy Electron ScanningFemaleneural regenerationNeurogliaBiomedical engineeringStem Cell TransplantationJournal of biomedical materials research. Part A
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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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Biosilica-loaded poly(ϵ-caprolactone) nanofibers mats provide a morphogenetically active surface scaffold for the growth and mineralization of the os…

2014

Bioprinting/3D cell printing procedures for the preparation of scaffolds/implants have the potential to revolutionize regenerative medicine. Besides biocompatibility and biodegradability, the hardness of the scaffold material is of critical importance to allow sufficient mechanical protection and, to the same extent, allow migration, cell–cell, and cell–substrate contact formation of the matrix-embedded cells. In the present study, we present a strategy to encase a bioprinted, cell-containing, and soft scaffold with an electrospun mat. The electrospun poly(e-caprolactone) (PCL) nanofibers mats, containing tetraethyl orthosilicate (TEOS), were subsequently incubated with silicatein. Silicate…

ScaffoldBiocompatibilityPolyestersNanofibersOsteoclastsNanotechnologyBiocompatible MaterialsApplied Microbiology and BiotechnologyMineralization (biology)chemistry.chemical_compoundCalcification PhysiologicOsteoclastCell Line TumormedicineHumansNanotechnologySaos-2 cellsCell ProliferationTissue ScaffoldsChemistrytechnology industry and agricultureGeneral MedicineSilicon DioxideElectrospinning3. Good healthTetraethyl orthosilicatemedicine.anatomical_structureChemical engineeringNanofiberMolecular MedicineBiotechnologyBiotechnology journal
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