Search results for "SCAFFOLD"

showing 10 items of 470 documents

Improvement of osteogenic differentiation of human mesenchymal stem cells on composite poly l-lactic acid/nano-hydroxyapatite scaffolds for bone defe…

2020

Tissue engineering offers new approaches to repair bone defects, which cannot be repaired physiologically, developing scaffolds that mimic bone tissue architecture. Furthermore, biomechanical stimulation induced by bioreactor, provides biomechanical cues that regulate a wide range of cellular events especially required for cellular differentiation and function. The improvement of human mesenchymal stem cells (hMSCs) colonization in poly-L-lactic-acid (PLLA)/nano- hydroxyapatite (nHA) composite scaffold was evaluated in terms of cell proliferation (dsDNA content), bone differen- tiation (gene expression and protein synthesis) and ultrastructural analysis by comparing static (s3D) and dynamic…

0106 biological sciences0301 basic medicine3D cultureScaffoldCellular differentiationBioreactorBioengineeringBone tissue01 natural sciencesApplied Microbiology and BiotechnologyBone and BonesCell Line03 medical and health sciencesBioreactorsTissue engineeringPolylactic Acid-Polyglycolic Acid CopolymerPoly-L-lactic-acid/nano-hydroxyapatiteOsteogenesis010608 biotechnologyOsteogenic differentiation w/o growth factorsmedicineHumansBone regenerationCell ProliferationComposite scaffoldSettore ING-IND/24 - Principi Di Ingegneria ChimicaTissue EngineeringTissue ScaffoldsChemistryMesenchymal stem cell3D culture; Bioreactor; Composite scaffold; Osteogenic differentiation w/o growth factors; Poly-L-lactic-acid/nano-hydroxyapatite; Bioreactors; Bone and Bones; Cell Differentiation; Cell Line; Cell Proliferation; Durapatite; Humans; Mesenchymal Stem Cells; Osteogenesis; Polylactic Acid-Polyglycolic Acid Copolymer; Tissue Engineering; Tissue ScaffoldsSettore ING-IND/34 - Bioingegneria IndustrialeCell DifferentiationMesenchymal Stem CellsCell biologyRUNX2030104 developmental biologymedicine.anatomical_structureDurapatiteCell cultureBiotechnologyJournal of bioscience and bioengineering

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Hydrogel‐Based 3D Bioprinting for Bone and Cartilage Tissue Engineering

2020

As a milestone in soft and hard tissue engineering, a precise control over the micropatterns of scaffolds has lightened new opportunities for the recapitulation of native body organs through three dimentional (3D) bioprinting approaches. Well-printable bioinks are prerequisites for the bioprinting of tissues/organs where hydrogels play a critical role. Despite the outstanding developments in 3D engineered microstructures, current printer devices suffer from the risk of exposing loaded living agents to mechanical (nozzle-based) and thermal (nozzle-free) stresses. Thus, tuning the rheological, physical, and mechanical properties of hydrogels is a promising solution to address these issues. Th…

0106 biological sciences3D bioprintingMaterials scienceTissue EngineeringTissue Scaffolds010401 analytical chemistryBioprintingHydrogelsNanotechnologyGeneral MedicineHard tissue01 natural sciencesApplied Microbiology and BiotechnologyCartilage tissue engineeringBone tissue engineering0104 chemical scienceslaw.inventionCartilageBody organslaw010608 biotechnologyPrinting Three-DimensionalSelf-healing hydrogelsMolecular MedicineCellular MorphologyBiotechnology Journal

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Author response: Septin/anillin filaments scaffold central nervous system myelin to accelerate nerve conduction

2016

03 medical and health sciencesScaffoldMyelin0302 clinical medicinemedicine.anatomical_structureChemistryCentral nervous systemmedicine030212 general & internal medicineSeptinNerve conduction030217 neurology & neurosurgeryCell biology

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TCT-408 Thirty-day Outcome Following Polymeric Bioresorbable Scaffold Implantation in 347 STEMI Patients Enrolled in the Multicenter “Registro Absorb…

2016

03 medical and health sciencesmedicine.medical_specialty0302 clinical medicinebusiness.industryTHIRTY-DAYMedicine030212 general & internal medicine030204 cardiovascular system & hematologyCardiology and Cardiovascular MedicinebusinessBioresorbable scaffoldSurgeryJournal of the American College of Cardiology

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Amorphous, Smart, and Bioinspired Polyphosphate Nano/Microparticles: A Biomaterial for Regeneration and Repair of Osteo-Articular Impairments In-Situ

2018

Using femur explants from mice as an in vitro model, we investigated the effect of the physiological polymer, inorganic polyphosphate (polyP), on differentiation of the cells of the bone marrow in their natural microenvironment into the osteogenic and chondrogenic lineages. In the form of amorphous Ca-polyP nano/microparticles, polyP retains its function to act as both an intra- and extracellular metabolic fuel and a stimulus eliciting morphogenetic signals. The method for synthesis of the nano/microparticles with the polyanionic polyP also allowed the fabrication of hybrid particles with the bisphosphonate zoledronic acid, a drug used in therapy of bone metastases in cancer patients. The r…

0301 basic medicineBone Regenerationlong bone defects; bone marrow cells; inorganic polyphosphate; microparticles; bisphosphonates; <i>Runx2</i>; <i>Sox9</i>; cathepsin-K; tumor metastases; human mesenchymal stem cellsmedicine.medical_treatmentBiocompatible MaterialsCore Binding Factor Alpha 1 SubunitZoledronic Acidlcsh:ChemistryMiceRunx2OsteogenesisPolyphosphatesFemurlcsh:QH301-705.5tumor metastasesSpectroscopymicroparticlescathepsin-KDiphosphonatesTissue ScaffoldsChemistryImidazolesBiomaterialSOX9 Transcription FactorGeneral MedicineUp-RegulationComputer Science ApplicationsCell biologyRUNX2medicine.anatomical_structureinorganic polyphosphateChondrogenesisSox9medicine.drugArticleCatalysisChondrocyteInorganic Chemistryhuman mesenchymal stem cells03 medical and health sciencesOsteoclastmedicineAnimalsHumansPhysical and Theoretical Chemistrybone marrow cellsbisphosphonatesMolecular BiologyOrganic ChemistryMesenchymal stem cellMesenchymal Stem CellsBisphosphonateRatslong bone defects030104 developmental biologyZoledronic acidlcsh:Biology (General)lcsh:QD1-999Gene Expression RegulationNanoparticlesBone marrowInternational Journal of Molecular Sciences

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CD34+cells seeded in collagen scaffolds promote bone formation in a mouse calvarial defect model

2017

Bone tissue engineering (BTE) holds promise for managing the clinical problem of large bone defects. However, clinical adoption of BTE is limited due to limited vascularization of constructs, which could be circumvented by pre-cultivation of osteogenic and endothelial derived cells in natural-based polymer scaffolds. However, until now not many studies compared the effect of mono- and cocultures pre-seeded in collagen before implantation. We utilized a mouse calvarial defect model and compared five groups of collagen scaffolds: a negative control of a collagen scaffold alone, a positive control treated with BMP-7, monocultures of either human osteoblasts (hOBs) or CD34+ cells, and a cocultu…

0301 basic medicineCalvarial defectMaterials scienceAngiogenesisCd34 cellsBiomedical EngineeringCD34Bone healingCell biologyBiomaterials03 medical and health sciences030104 developmental biologyBone formationBone regenerationCollagen scaffoldBiomedical engineeringJournal of Biomedical Materials Research Part B: Applied Biomaterials

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Relevance of 3d culture systems to study osteosarcoma environment

2018

Abstract Osteosarcoma (OS) is the most common primary malignant tumor of bone, which preferentially develops lung metastasis. Although standard chemotherapy has significantly improved long-term survival over the past few decades, the outcome for patients with metastatic or recurrent OS remains dramatically poor. Novel therapies are therefore required to slow progression and eradicate the disease. Furthermore, to better understand the cellular and molecular mechanisms responsible for OS onset and progression, the development of novel predictive culture systems resembling the native three-dimensional (3D) tumor microenvironment are mandatory. ‘Tumor engineering’ approaches radically changed t…

0301 basic medicineCancer Research3D cell culture system; Osteosarcoma; Scaffolds; SpheroidsLung metastasisCell Culture TechniquesBone NeoplasmsReviewDiseaselcsh:RC254-282Scaffold03 medical and health sciences3D cell culture0302 clinical medicineSettore BIO/13 - Biologia ApplicataSlow progressionSpheroids CellularTumor MicroenvironmentmedicineAnimalsHumans3D cell culture systemScaffoldsOsteosarcomaTumor microenvironmentTissue Scaffoldsbusiness.industrylcsh:Neoplasms. Tumors. Oncology. Including cancer and carcinogensmedicine.disease3. Good healthClinical Practice030104 developmental biologyOncologyCell culture030220 oncology & carcinogenesisCancer researchOsteosarcomaSpheroidsbusinessJournal of Experimental & Clinical Cancer Research

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Type 5 phosphodiesterase (PDE5) and the vascular tree: from embryogenesis to aging and disease

2020

Highlights • Vascular development depends on the timely differentiation of endothelial and smooth muscle cells, that mutually influence their developmental fate. • Endothelial and vascular smooth muscle cell (VSMC) compartments can mutually influence cell and tissue modifications during vascular aging and in vascular disease. • Keeping in mind that PDE5 is mainly expressed in VSMCs, we surveyed the literature on the role of PDE5 in vascular development, aging and disease. • Although most results have been obtained by PDE5 pharmacological inhibition, no data are available, to date, on vascular development, aging or disease following PDE5 genetic ablation.

0301 basic medicineCell typeAgingVascular smooth muscleMyocytes Smooth MuscleVSMCsEmbryonic DevelopmentECsContext (language use)DiseaseBiologyMuscle Smooth VascularArticle03 medical and health sciences0302 clinical medicinenitric oxidevascular smooth muscle cellsHumansBioresorbable vascular scaffoldCyclic Nucleotide Phosphodiesterases Type 5ECEmbryogenesisPhosphodiesteraseVascular agingCell biologycGMPSettore MED/23ECs; PDE5; VSMCs; cGMP; nitric oxide030104 developmental biologyVascular aging; vascular smooth muscle cells; phosphodiesterasePDE5phosphodiesterase030217 neurology & neurosurgeryFunction (biology)Developmental Biology

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2017

Although a lot of research has been performed, large segmental bone defects caused by trauma, infection, bone tumors or revision surgeries still represent big challenges for trauma surgeons. New and innovative bone substitutes are needed. Three-dimensional (3D) printing is a novel procedure to create 3D porous scaffolds that can be used for bone tissue engineering. In the present study, solid discs as well as porous cage-like 3D prints made of polylactide (PLA) are coated or filled with collagen, respectively, and tested for biocompatibility and endotoxin contamination. Microscopic analyses as well as proliferation assays were performed using various cell types on PLA discs. Stromal-derived…

0301 basic medicineCollagen iCell typeBone substituteBiocompatibilityChemistryCell growthAngiogenesisOrganic Chemistry02 engineering and technologyGeneral Medicine021001 nanoscience & nanotechnologyCatalysisPorous scaffoldComputer Science ApplicationsInorganic Chemistry03 medical and health sciences030104 developmental biologyIn vitro studyPhysical and Theoretical Chemistry0210 nano-technologyMolecular BiologySpectroscopyBiomedical engineeringInternational Journal of Molecular Sciences

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Electrospun poly(hydroxybutyrate) scaffolds promote engraftment of human skin equivalents via macrophage M2 polarization and angiogenesis.

2018

Human dermo-epidermal skin equivalents (DE) comprising in vitro expanded autologous keratinocytes and fibroblasts are a good option for massive burn treatment. However, the lengthy expansion time required to obtain sufficient surface to cover an extensive burn together with the challenging surgical procedure limits their clinical use. The integration of DE and biodegradable scaffolds has been proposed in an effort to enhance their mechanical properties. Here, it is shown that poly(hydroxybutyrate) electrospun scaffolds (PHB) present good biocompatibility both in vitro and in vivo and are superior to poly-epsilon-caprolactone electrospun scaffolds as a substrate for skin reconstruction. Impl…

0301 basic medicineKeratinocytesMaleBiocompatibilityAngiogenesisPolymersBiomedical EngineeringMedicine (miscellaneous)HydroxybutyratesNeovascularization PhysiologicHuman skinhuman skin xenograftBiocompatible Materials02 engineering and technologyNodMice SCIDpoly(hydroxybutyrate)Biomaterials03 medical and health sciencesIn vivoMice Inbred NODProhibitinsHuman Umbilical Vein Endothelial CellsAnimalsHumansRats WistarelectrospinningCell ProliferationSkin ArtificialTissue EngineeringTissue ScaffoldsChemistryMacrophagestechnology industry and agricultureCell PolarityCell DifferentiationM2 polarizationDermisSkin Transplantation021001 nanoscience & nanotechnologyM2 MacrophageIn vitro030104 developmental biologyskin equivalentsEpidermis0210 nano-technologyBiomedical engineeringJournal of tissue engineering and regenerative medicine

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