Search results for "Bone tissue"

showing 10 items of 78 documents

Effect of different cryosurgical protocols using liquid nitrogen on bone tissue: a histomorphological analyze

2011

The aim of the present experimental study was to evaluate the morphological effects of different liquid nitrogen cryosurgery protocols on bone tissue. The femoral diaphyses of 42 Wistar rats were exposed to three local and sequential applications of liquid nitrogen for 1 or 2 min, intercalated with periods of 5 min of passive thawing. The animals were sacrificed after 1, 2, 4 and 12 weeks and the specimens obtained were processed and analyzed histomorphologically. Histologically, an increase in bone necrosis was observed for the two protocols in the second week after cryotherapy. A significant osteogenic phase was observed after 4 weeks. Moreover, complete remodeling process was encountered…

Pathologymedicine.medical_specialtyNecrosisChemistrymedicine.medical_treatmentObservation periodOdontologíaCryotherapyLiquid nitrogen:CIENCIAS MÉDICAS [UNESCO]Bone tissueCiencias de la saludCryosurgerymedicine.anatomical_structureUNESCO::CIENCIAS MÉDICASmedicinemedicine.symptomGeneral DentistryJournal of Clinical and Experimental Dentistry
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Microvessel-like structures from outgrowth endothelial cells from human peripheral blood in 2-dimensional and 3-dimensional co-cultures with osteobla…

2007

Tissue regeneration involves complex processes in the interaction between different cell types that control the process of neo-vascularization. In bone, osteoblasts and bone marrow stem cells provide cue elements for the proliferation of endothelial cells, differentiation of endothelial precursors, and the maturation of a vascular network. In this study, we investigated outgrowth endothelial cells (OECs), a potential source of autologous endothelial cells derived from human peripheral blood, in direct 2-dimensional (2-D) and 3-D co-culture systems with cells relevant for the regeneration of bone tissue, such as osteoblasts. In the co-cultures, OECs were evaluated in terms of their stability…

Pathologymedicine.medical_specialtyeducation.field_of_studyCell typeOsteoblastsTissue EngineeringChemistryRegeneration (biology)MicrocirculationPopulationGeneral EngineeringBone Marrow Stem CellEndothelial CellsBone tissueCoculture TechniquesCell biologyEndothelial stem cellVasculogenesismedicine.anatomical_structuremedicineLeukocytes MononuclearHumanseducationMicrovesselCells CulturedTissue engineering
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In vitro and in vivo investigations of osteogenic differentiation ability of dental pulp stem cells (DPSCs) and gingival mesenchymal stem cells (GMSC…

2020

Thanks to the use of human mesenchymal stem cells (hMSCs), smart biomaterials and active biomolecules, Regenerative Medicine (RM) and Bone Tissue Engineering (BTE) can restore structure and function of injured tissues. Among the different sources of hMSCs, the oro-facial hMSCs have promising in vitro and in vivo regeneration potential; in particular, dental pulp and gingiva are valuable sources of autologous hMSCs. The aim of this PhD thesis is testing the in vitro and in vivo bone regeneration ability of hMSCs isolated from dental pulp and inflamed gingiva of periodontally-compromised teeth, up to now considered biological waste tissues and discarded during surgical procedures, on two comm…

Periodontitis bone resorption oral MSCs DPSCs GMSCs waste biological tissues periodontally-compromised teeth FISIOGRAFT Bone Granular® Matriderm® autologous bone tissue regenerationSettore MED/28 - Malattie Odontostomatologiche
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The use of hydrogels in bone-tissue engineering

2010

Many different types of scaffold materials have been used for tissue engineering applications, and hydrogels form one group of materials that have been used in a wide variety of applications. Hydrogels are hydrophilic polymer networks and they represent an important class of biomaterials in biotechnology and medicine because many hydrogels exhibit excellent biocompatibility with minimal inflammatory responses and tissue damage. Many studies have demonstrated the use of hydrogels in bone-tissue engineering applications. In this report, the summary was conducted on various kinds of polymers and different modification methods of hydrogels to enhance bone formation. The results revealed that hy…

ScaffoldBiocompatibilityTissue EngineeringTissue ScaffoldsChemistrytechnology industry and agricultureNanotechnologyHydrogelsmacromolecular substances:CIENCIAS MÉDICAS [UNESCO]complex mixturesBone tissue engineeringBone and BonesOtorhinolaryngologyTissue engineeringTissue damageSelf-healing hydrogelsUNESCO::CIENCIAS MÉDICASSurgeryBone formationBone regenerationGeneral Dentistry
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The Deep-Sea Natural Products, Biogenic Polyphosphate (Bio-PolyP) and Biogenic Silica (Bio-Silica), as Biomimetic Scaffolds for Bone Tissue Engineeri…

2013

Bone defects in human, caused by fractures/nonunions or trauma, gain increasing impact and have become a medical challenge in the present-day aging population. Frequently, those fractures require surgical intervention which ideally relies on autografts or suboptimally on allografts. Therefore, it is pressing and likewise challenging to develop bone substitution materials to heal bone defects. During the differentiation of osteoblasts from their mesenchymal progenitor/stem cells and of osteoclasts from their hemopoietic precursor cells, a lineage-specific release of growth factors and a trans-lineage homeostatic cross-talk via signaling molecules take place. Hence, the major hurdle is to fab…

ScaffoldCell signalingOsteoclastsPharmaceutical Sciencebio-polyphosphateReview02 engineering and technologyscaffoldBone morphogenetic protein 2Bone and BonesExtracellular matrix03 medical and health sciencesOsteoprotegerinBiomimetic MaterialsPolyphosphatesBMP-2Drug DiscoveryMorphogenesisAnimalsHumansbone tissue engineeringPharmacology Toxicology and Pharmaceutics (miscellaneous)lcsh:QH301-705.5030304 developmental biologymorphogenetic scaffoldsBiological Products0303 health sciencesOsteoblastsTissue EngineeringTissue Scaffoldsbiologybio-silicaChemistryMesenchymal stem cellRANKLAnatomySilicon Dioxide021001 nanoscience & nanotechnologyCell biologylcsh:Biology (General)RANKLosteoprotegerinbiology.proteinStem cell0210 nano-technologyMarine Drugs
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Response of micro- and macrovascular endothelial cells to starch-based fiber meshes for bone tissue engineering.

2006

The establishment of a functional vasculature is as yet an unrealized milestone in bone reconstruction therapy. For this study, fiber-mesh scaffolds obtained from a blend of starch and poly(caprolactone) (SPCL), that have previously been shown to be an excellent material for the proliferation and differentiation of bone marrow cells and thereby represent great potential as constructs for bone regeneration, were examined for endothelial cell (EC) compatibility. To be successfully applied in vivo, this tissue engineered construct should also be able to support the growth of ECs in order to facilitate vascularization and therefore assure the viability of the construct upon implantation. The ma…

ScaffoldMaterials scienceCellular differentiationEndothelial cellsBiophysicsNeovascularization PhysiologicBioengineering02 engineering and technologyComplex MixturesStarch-based scaffoldsCell junctionBone and BonesBone tissue engineeringBiomaterials03 medical and health sciencesmedicineBone regenerationCells Cultured030304 developmental biology0303 health sciencesScience & TechnologyTissue EngineeringCell adhesion moleculeVascularizationCell DifferentiationStarch021001 nanoscience & nanotechnologyCell biologyEndothelial stem cellmedicine.anatomical_structureMechanics of MaterialsCell cultureCeramics and CompositesBone marrowEndothelium Vascular0210 nano-technologyBiomedical engineeringBiomaterials
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Endothelial cell colonization and angiogenic potential of combined nano- and micro-fibrous scaffolds for bone tissue engineering

2008

Presently the majority of tissue engineering approaches aimed at regenerating bone relies only on postimplantation vascularization. Strategies that include seeding endothelial cells (ECs) on biomaterials and promoting their adhesion, migration and functionality might be a solution for the formation of vascularized bone. Nano/micro-fiber-combined scaffolds have an innovative structure, inspired by extracellular matrix (ECM) that combines a nano-network, aimed to promote cell adhesion, with a micro-fiber mesh that provides the mechanical support. In this work we addressed the influence of this nano-network on growth pattern, morphology, inflammatory expression profile, expression of structura…

ScaffoldMaterials scienceEndothelial cellsMaterials ScienceBiophysicsNeovascularization PhysiologicNano-fibersBioengineering02 engineering and technologyStarch-based scaffoldsCell morphologyBone and BonesBone tissue engineeringBiomaterialsExtracellular matrix03 medical and health sciencesEngineeringMicroscopy Electron TransmissionTissue engineeringHumansVimentinBone regenerationCell adhesionCells Cultured030304 developmental biologyInflammation0303 health sciencesScience & TechnologyTissue EngineeringVascularizationtechnology industry and agriculture021001 nanoscience & nanotechnologyNanostructuresCell biologyPlatelet Endothelial Cell Adhesion Molecule-1Endothelial stem cellGene Expression RegulationMechanics of MaterialsNanofiberMicroscopy Electron ScanningCeramics and Composites0210 nano-technologyBiomedical engineeringBiomaterials
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The chemical composition of synthetic bone substitutes influences tissue reactions in vivo : histological and histomorphometrical analysis of the cel…

2012

Bone substitute material properties such as granule size, macroporosity, microporosity and shape have been shown to influence the cellular inflammatory response to a bone substitute material. Keeping these parameters constant, the present study analyzed the in vivo tissue reaction to three bone substitute materials (granules) with different chemical compositions (hydroxyapatite (HA), beta-tricalcium phosphate (TCP) and a mixture of both with a HA/TCP ratio of 60/40 wt%). Using a subcutaneous implantation model in Wistar rats for up to 30 days, tissue reactions, including the induction of multinucleated giant cells and the extent of implantation bed vascularization, were assessed using histo…

ScaffoldMaterials scienceGranule (cell biology)Biomedical EngineeringBioengineeringInflammationAnatomyPhosphateBone tissueBiomaterialschemistry.chemical_compoundmedicine.anatomical_structurechemistryIn vivoGiant cellmedicineBiophysicsHydroxyapatitesmedicine.symptomBiomedical Materials
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Polylactide-based materials science strategies to improve tissue-material interface without the use of growth factors or other biological molecules

2018

In a large number of medical devices, a key feature of a biomaterial is the ability to successfully bond to living tissues by means of engineered mechanisms such as the enhancement of biomineralization on a bone tissue engineering scaffold or the mimicking of the natural structure of the extracellular matrix (ECM). This ability is commonly referred to as "bioactivity". Materials sciences started to grow interest in it since the development of bioactive glasses by Larry Hench five decades ago. As the main goal in applications of biomedical devices and tissue scaffolds is to obtain a seamless tissue-material interface, achieving optimal bioactivity is essential for the success of most biomate…

ScaffoldMaterials sciencePolyestersInterface (computing)Materials SciencePolyesterCompositeBioengineeringNanotechnologyCondensed Matter Physic02 engineering and technology010402 general chemistryBioactivity01 natural sciencesPolylactic acidBone tissue engineeringScaffoldBiomaterialsTissue ScaffoldTissue engineeringIntercellular Signaling Peptides and ProteinAnimalsHumansMechanics of Materialchemistry.chemical_classificationTissue ScaffoldsTissue EngineeringAnimalMechanical EngineeringBiomoleculeBiomedical polymersBiomaterialExtracellular matrix021001 nanoscience & nanotechnology0104 chemical scienceschemistryMechanics of MaterialsIntercellular Signaling Peptides and ProteinsTissue materialMaterials Science (all)0210 nano-technologyTissue-material interfaceHumanMaterials Science and Engineering: C
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Improving vascularization of engineered bone through the generation of pro-angiogenic effects in co-culture systems

2014

One of the major problems with bone tissue engineering is the development of a rapid vascularization after implantation to supply the growing osteoblast cells with the nutrients to grow and survive as well as to remove waste products. It has been demonstrated that capillary-like structures produced in vitro will anastomose rapidly after implantation and become functioning blood vessels. For this reason, in recent years many studies have examined a variety of human osteoblast and endothelial cell co-culture systems in order to distribute osteoblasts on all parts of the bone scaffold and at the same time provide conditions for the endothelial cells to migrate to form a network of capillary-li…

ScaffoldOsteoblastsTissue EngineeringTissue ScaffoldsAngiogenesisEndothelial CellsNeovascularization PhysiologicPharmaceutical ScienceBone scaffoldOsteoblastBiologyCoculture TechniquesIn vitroBone tissue engineeringCell biologyEndothelial stem cellmedicine.anatomical_structureOsteogenesisImmunologymedicineHumansCell ProliferationEndothelial Progenitor CellsAdvanced Drug Delivery Reviews
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