0000000000517188

AUTHOR

Gloria Gallego Ferrer

showing 3 related works from this author

Implantation of a polycaprolactone scaffold with subchondral bone anchoring ameliorates nodules formation and other tissue alterations

2015

Purpose: Articular cartilage has limited repair capacity. Two different implant devices for articular cartilage regeneration were tested in vivo in a sheep model to evaluate the effect of subchondral bone anchoring for tissue repair. Methods: The implants were placed with press-fit technique in a cartilage defect after microfracture surgery in the femoral condyle of the knee joint of the sheep and histologic and mechanical evaluation was done 4.5 months later. The first group consisted of a biodegradable polycaprolactone (PCL) scaffold with double porosity. The second test group consisted of a PCL scaffold attached to a poly(L-lactic acid) (PLLA) pin anchored to the subchondral bone. Result…

CartílagsCartilage ArticularScaffoldTime FactorsPolymersPolyestersBiomedical EngineeringMedicine (miscellaneous)BioengineeringKnee JointBone NailsProsthesis DesignBiomaterials03 medical and health scienceschemistry.chemical_compound0302 clinical medicineTissue engineeringTeixit ossiAbsorbable ImplantsmedicineAnimalsOrthopedic ProceduresTissue engineeringLactic Acid030222 orthopedicsSheepTissue ScaffoldsChemistryCartilageRegeneration (biology)Cartilage engineering030229 sport sciencesGeneral MedicineChondrogenesisSubchondral bone alterationsPolycaprolactonemedicine.anatomical_structureFISICA APLICADAPolycaprolactoneModels AnimalMAQUINAS Y MOTORES TERMICOSFemaleJointsImplantChondrogenesisPorosityBiomedical engineering
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Combination of silica nanoparticles with hydroxyapatite reinforces poly (l-lactide acid) scaffolds without loss of bioactivity

2013

Composite scaffolds of poly(l-lactide acid) and hydroxyapatite are of great interest in bone tissue engineering, but their mechanical properties are typically inferior to scaffolds of pure poly(l-lactide acid) due to agglomeration of the particles and weak interfacial component interaction. Fabrication strategies like double sonication of hydroxyapatite or increasing the amount of this inorganic filler do not effectively enhance the mechanical performance. In this study, poly(l-lactide acid) composites combining two types of fillers, mesoporous silica (SiO2) nanoparticles and hydroxyapatite, were developed to reinforce the poly(l-lactide acid) scaffold without any loss of bioactivity. A 5%…

BiomaterialsSilica nanoparticlesMaterials sciencePolymers and PlasticsChemical engineeringPoly-L-lactideComposite numberMaterials ChemistryBioengineeringBone tissue engineeringJournal of Bioactive and Compatible Polymers
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Fibrin-chitosan composite substrate for in vitro culture of chondrocytes

2013

The aim of this study was to develop a biocompatible monolayer substrate based on fibrin and chitosan for in vitro culture of chondrocytes. Fibrin-chitosan composite substrates combined the proved cell adhesion properties of fibrin with the hydrophilicity and poor adhesion capacity of chitosan. Chitosan microspheres were produced by coacervation method, agglomerated within a fibrin network and subsequently crosslinked with genipin. The composite substrate was stable for 28 days of culture due to the high crosslinking density. Human chondrocytes cultured on the composite substrate were viable during the culture period. At the end of culture time (28 days) the composite substrate showed low c…

Materials scienceCell SurvivalComposite numberBiomedical EngineeringCell Culture Techniquesmacromolecular substancesFibrinBiomaterialsChitosanchemistry.chemical_compoundChondrocytesHumansIridoidscompositefibrinCell adhesionCell ShapeCells Culturedbiologytechnology industry and agricultureMetals and AlloysSubstrate (chemistry)AdhesionDNAChondrogenesisExtracellular MatrixmicrospheresCross-Linking ReagentschemistryMAQUINAS Y MOTORES TERMICOSCeramics and Compositesbiology.proteinBiophysicsGenipinchitosanBiomedical engineeringchondrocyte redifferentiation
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