Search results for "Polymeric scaffold"

showing 6 items of 6 documents

3D polymeric supports promote the growth and progression of anaplastic thyroid carcinoma.

2020

Abstract Anaplastic thyroid carcinoma (ATC) is a rare and aggressive malignancy that accounts for the majority of deaths from all thyroid cancers. ATC exhibits invasiveness and highly resistance to conventional therapies which include cytotoxic chemotherapy, the combination of BRAF and MEK inhibition and, more recently, immunotherapies, that have shown promising but still limited results. A growing knowledge on ATC tumor biology is needed for developing more effective therapies with significant better survival. Researchers have begun to utilize 3D models to culture cancer cells for in vitro studies. In this work, C643 ATC cell line was cultured on polymeric scaffolds with high-interconnecte…

0301 basic medicinePolymersBiophysicsMalignancyStem cell markerThyroid Carcinoma AnaplasticBiochemistryMetastasis03 medical and health sciences0302 clinical medicineCancer stem cellCell Line TumormedicineBiomarkers TumorHumansDoxorubicin3D tumor model Anaplastic thyroid carcinoma Doxorubicin Polymeric scaffold Stem cell markersMolecular BiologyThyroid cancerCell ShapeCell ProliferationTissue Scaffoldsbusiness.industryThyroidCell Biologymedicine.disease030104 developmental biologymedicine.anatomical_structureDoxorubicin030220 oncology & carcinogenesisCancer cellCancer researchDisease ProgressionNeoplastic Stem Cellsbusinessmedicine.drugBiochemical and biophysical research communications
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Pd nanoparticles formation inside porous polymeric scaffolds followed by in situ XANES/SAXS

2015

International audience; Simultaneous time-resolved SAXS and XANES techniques were employed to follow in situ the formation of Pd nanoparticles from palladium acetate precursor in two porous polymeric supports: polystyrene (PS) and poly(4-vinyl-pyridine) (P4VP). In this study we have investigated the effect of the use of different reducing agents (H-2 and CO) from the gas phase. These results, in conjunction with data obtained by diffuse reflectance IR (DRIFT) spectroscopy and TEM measurements, allowed us to unravel the different roles played by gaseous H-2 and CO in the formation of the Pd nanoparticles for both PS and P4VP hosting scaffolds

HistoryMaterials scienceAbsorption spectroscopyNanoparticlechemistry.chemical_elementreduction02 engineering and technologypolystyrene010402 general chemistry01 natural sciencesEducationP4VPchemistry.chemical_compoundPdPd nanoparticles formation inside porous polymeric scaffoldspaladumchemistry.chemical_classification[PHYS]Physics [physics]Small-angle X-ray scatteringnanoparticlein situSAXS XANES Pd paladum nanoparticle polystyrene P4VP DRIFT TEM reduction in situSAXSPolymer021001 nanoscience & nanotechnologyXANESXANES0104 chemical sciencesComputer Science ApplicationsCrystallographyDRIFTchemistryChemical engineeringTEMPolystyreneDiffuse reflection0210 nano-technologyPalladium
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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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O-102 Polymeric scaffold loaded with CD133+ BMDSCs for endometrial regeneration in Asherman’s syndrome

2021

Abstract Study question Can CD133+ bone marrow-derived stem cells (BMDSCs) loaded in polyethylene glycol diacrylate (PEGda) and gelatin divide and decidualize? Summary answer Biocompatible porous PEGda and gelatin scaffold provides a three-dimensional environment for CD133+ cells to attach, divide, and decidualize in vitro. What is known already Intrauterine adhesions (IUA) develop due to acquired damages in the endometrium resulting in partial to complete endometrial dysfunction in the Asherman syndrome. Previous works from our group have demonstrated the engraftment of CD133+ BMDSCs and its paracrine effect on endometrial proliferation, improved endometrial thickness and clinical outcome …

Reproductive MedicineChemistryRegeneration (biology)RehabilitationmedicineObstetrics and GynecologyAsherman's syndromePolymeric scaffoldmedicine.diseaseCell biologyHuman Reproduction
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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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A Versatile Technique to Produce Porous Polymeric Scaffolds: The Thermally Induced Phase Separation (TIPS) Method

2017

Among the various scaffold fabrication techniques, thermally induced phase separation (TIPS) is one of the most versatile methods to produce porous polymeric scaffold and it has been largely used for its capability to produce highly porous and interconnected scaffolds. The scaffold architecture can be closely controlled by varying the process parameters, including polymer type and concentration, solvent/non-solvent ratio and thermal history. TIPS technique has been widely employed, also, to produce scaffolds with a hierarchical pore structure and composite polymeric matrix/inorganic filler foams.

chemistry.chemical_classificationMaterials scienceComposite numbertechnology industry and agriculturePolymeric matrixNanotechnologyPolymerMicrobiologySolventchemistryHighly porousPolymeric scaffoldScaffold architecturePorosityArchives in Chemical Research
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