Search results for "Clinical uses of mesenchymal stem cells"

showing 10 items of 15 documents

Towards an ideal source of mesenchymal stem cell isolation for possible therapeutic application in regenerative medicine.

2014

Background. The possibility of obtaining mesenchymal stem cells (MSCs) from fetal tissue such as amniotic fluid, chorionic villi and placenta is well-known and a comparison between MSCs originating in different sources such as fetal tissue and those from bone marrow in terms of yield and function is a topical issue. The mesenchymal stem cells isolated from bone marrow are well-characterized. Unfortunately the low quantitative yield during isolation is a major problem. For this reason, other tissue sources for MSCs are of paramount importance. Conclusion. In this review, starting from a description of the molecular and cellular biology of MSCs, we describe alternative sources of isolation ot…

Amniotic fluidPlacentaMesenchymal stem cellClinical uses of mesenchymal stem cellsBone Marrow CellsMesenchymal Stem CellsBiologyStem cell markerAmniotic FluidRegenerative MedicineRegenerative medicineGeneral Biochemistry Genetics and Molecular BiologyCell biologymedicine.anatomical_structureAdipose TissuePregnancyembryonic structuresImmunologymedicineChorionic villiHumansFemaleBone marrowChorionic VilliStem cell transplantation for articular cartilage repairBiomedical papers of the Medical Faculty of the University Palacky, Olomouc, Czechoslovakia
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Collecting evidence for a stem cell hypothesis in HCC.

2010

Ever since Ernest McCulloch and James E Till defined essential stem cell properties, the field of stem cell biology has attracted increasing interest.1 Manipulating embryonic stem cells has resulted in advanced genetic technologies such as knock-out and transgenic animals, providing valuable models to study genetic influence on a wide variety of diseases.2 The success in manipulating stem cells and the ability to differentiate them into diverse tissues brought with them countless concepts of utilising stem cells in medicine. The idea of perpetually dividing pluripotent cells, capable of differentiating into nearly every possible cell or tissue type, seems like an inexhaustible resource for …

Carcinoma HepatocellularStem cell theory of agingLiver NeoplasmsGastroenterologyClinical uses of mesenchymal stem cellsBiologyEmbryonic stem cellCell biologyRecurrenceImmunologyBiomarkers TumorNeoplastic Stem CellsHumansStem cellProgenitor cellInduced pluripotent stem cellAdult stem cellStem cell transplantation for articular cartilage repairGut
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Wharton’s Jelly Mesenchymal Stem Cells for the Treatment of Type 1 Diabetes

2014

Type 1 diabetes is an autoimmune disease caused by the destruction of endocrine pancreas β cells by T lymphocytes, for which genetic and environmental risk factors have been proposed. Patients require daily infusions of recombinant insulin to overcome the reduced production by their own cells, but there is an increasing demand for a permanent and efficient supplementation which could better modulate the need for the hormone during the normal activities. For this reason, transplant-based therapeutic models have been proposed such as whole organ transplantation and Langerhans islets transplantation. These techniques are limited by many factors such as the lack of donors, the risks linked to t…

Cell therapyAmniotic epithelial cellsWharton's jellyMesenchymal stem cellStem cell theory of agingImmunologyClinical uses of mesenchymal stem cellsBiologyStem cellStem cell transplantation for articular cartilage repair
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Human Wharton's jelly mesenchymal stem cells maintain the expression of key immunomodulatory molecules when subjected to osteogenic, adipogenic and c…

2013

Rheumatoid arthritis and osteoarthritis are the main diseases that imply an inflammatory process at the joints involving the articular cartilage. Recently, mesenchymal stem cells (MSCs) derived from perinatal tissues were considered good candidates for cellular therapy of musculoskeletal and orthopaedic diseases, since they can differentiate into multiple cell types and are an easily accessible cellular source. Therefore, several protocols exist on the differentiation of mesenchymal stem cells of different origins into osteoblasts and chondrocytes. Another key feature of MSCs is their capacity to modulate the immune system responses in vitro and in vivo. This may have critical outcomes in d…

Cellular differentiationImmune modulationBlotting WesternCell- and Tissue-Based TherapyMedicine (miscellaneous)Clinical uses of mesenchymal stem cellsBiologyReal-Time Polymerase Chain ReactionRegenerative medicineOsteocytesCell therapyImmunoenzyme TechniquesImmunomodulationChondrocytesImmune privilegeOsteogenic differentiationWharton's jellyAdipocytesHumansRNA MessengerWharton JellyTissue repairUmbilical cordCells CulturedStem cell transplantation for articular cartilage repairMesenchymal stem cellChondrogenic differentiationSettore BIO/16 - Anatomia UmanaReverse Transcriptase Polymerase Chain ReactionWharton's jellyMesenchymal stem cellCell DifferentiationMesenchymal Stem CellsGeneral MedicineCell biologyImmunologyAdipogenic differentiationRegenerative medicineCurrent stem cell researchtherapy
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Evidence for a common progenitor of epithelial and mesenchymal components of the liver

2013

Tissues of the adult organism maintain the homeostasis and respond to injury by means of progenitor/stem cell compartments capable to give rise to appropriate progeny. In organs composed by histotypes of different embryological origins (e.g. The liver), the tissue turnover may in theory involve different stem/precursor cells able to respond coordinately to physiological or pathological stimuli. In the liver, a progenitor cell compartment, giving rise to hepatocytes and cholangiocytes, can be activated by chronic injury inhibiting hepatocyte proliferation. The precursor compartment guaranteeing turnover of hepatic stellate cells (HSCs) (perisinusoidal cells implicated with the origin of the …

Cellular differentiationLiver Stem CellDesminMice0302 clinical medicineMESH: AnimalsMESH: Nerve Tissue ProteinsHepatic stellate cellCells Cultured0303 health sciencesMesenchymal Stromal CellStem CellsCell DifferentiationCell biologyEndothelial stem cellMESH: DesminMESH: Models AnimalLiverMESH: Epithelial CellsDifferentiationModels Animal030211 gastroenterology & hepatologyStem cellMESH: Stem Cell Transplantationhepatic stellate cell; cell transplantation; liver stem cell; differentiationMESH: Cells CulturedMESH: Cell DifferentiationCell transplantation; Differentiation; Hepatic stellate cell; Liver stem cell; Animals; Cell Differentiation; Cell Line; Cell Lineage; Cell Proliferation; Cells Cultured; Desmin; Epithelial Cells; Glial Fibrillary Acidic Protein; In Vitro Techniques; Liver; Mesenchymal Stromal Cells; Mice; Mice Nude; Models Animal; Nerve Tissue Proteins; Stem Cell Transplantation; Stem Cells; Cell Biology; Molecular BiologyClinical uses of mesenchymal stem cellsMice NudeNerve Tissue ProteinsMESH: Stem Cells[SDV.BC]Life Sciences [q-bio]/Cellular BiologyBiologyIn Vitro TechniquesCell Line03 medical and health sciencesStem CellMESH: Cell ProliferationGlial Fibrillary Acidic ProteinMESH: Mice NudeAnimalsCell LineageProgenitor cellMESH: MiceMolecular Biology030304 developmental biologyCell ProliferationOriginal PaperEpithelial CellAnimalIn Vitro TechniqueMesenchymal stem cellEpithelial CellsMesenchymal Stem CellsCell BiologyMESH: Cell LineageMESH: Cell LineLiver stem cellNerve Tissue ProteinHepatic stellate cellMESH: Mesenchymal Stromal CellsCell transplantationMESH: LiverStem Cell Transplantation
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New emerging potentials for human Wharton's jelly mesenchymal stem cells: immunological features and hepatocyte-like differentiative capacity.

2010

In recent years, human mesenchymal stem cells (MSC) have been extensively studied. Their key characteristics of long-term self-renewal and a capacity to differentiate into diverse mature tissues favour their use in regenerative medicine applications. Stem cells can be found in embryonic and extra-embryonic tissues as well as in adult organs. Several reports indicate that cells of Wharton's jelly (WJ), the main component of umbilical cord extracellular matrix, are multipotent stem cells, expressing markers of bone marrow mesenchymal stem cells (BM-MSC), and giving rise to different cellular types of both connective and nervous tissues. Wharton's jelly mesenchymal stem cells (WJ-MSC) express …

Clinical uses of mesenchymal stem cellsBone Marrow CellsBiologyRegenerative MedicineUmbilical CordImmunomodulationMesodermWharton's jellyAnimalsHumansCell LineageStem cell transplantation for articular cartilage repairCell ProliferationSettore BIO/16 - Anatomia UmanaMultipotent Stem CellsMesenchymal stem cellEndodermCell DifferentiationMesenchymal Stem CellsCell BiologyHematologyCell biologyExtracellular MatrixMultipotent Stem CellAmniotic epithelial cellsImmunologyHepatocytesmesenchymal stem cells umbilical cord Wharton's jelly differentiation hepatocyteStem cellBiomarkersDevelopmental BiologyAdult stem cellStem cells and development
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Wharton’s Jelly Mesenchymal Stem Cells as Candidates for Beta Cells Regeneration: Extending the Differentiative and Immunomodulatory Benefits of Adul…

2010

Mesenchymal stem cells (MSC) are uniquely capable of crossing germinative layers borders (i.e. are able to differentiate towards ectoderm-, mesoderm- and endoderm-derived cytotypes) and are viewed as promising cells for regenerative medicine approaches in several diseases. Type I diabetes therapy should potentially benefit from such differentiated cells: the search for alternatives to organ/islet transplantation strategies via stem cells differentiation is an ongoing task, significant goals having been achieved in most experimental settings (e.g. insulin production and euglycaemia restoration), though caution is still needed to ensure safe and durable effects in vivo. MSC are obtainable in …

Graft RejectionCancer ResearchCellular differentiationCell Culture TechniquesClinical uses of mesenchymal stem cellsBiologyMesenchymal Stem Cell TransplantationRegenerative medicineUmbilical CordImmunomodulationMesenchymal stem cells Umbilical cord Wharton’s jelly Type 1 diabetes Beta cells Differentiation markers Pancreas development Inflammation Immune modulation HypoimmunogenicityInsulin-Secreting CellsWharton's jellyAnimalsHumansRegenerationEmbryonic Stem CellsSettore BIO/16 - Anatomia UmanaRegeneration (biology)Mesenchymal stem cellCell DifferentiationMesenchymal Stem CellsCell BiologyAntigens DifferentiationTransplantationAdult Stem CellsDiabetes Mellitus Type 1Adipose TissueImmunologyCancer researchCord Blood Stem Cell TransplantationStem cellStem Cell Reviews and Reports
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Human Wharton's jelly-derived mesenchymal stem cells express several immunomodulatory molecules both in their naïve state and hepatocyte-like differe…

2011

Wharton’s jelly (WJ), the main constituent of umbilical cord, is a reliable source of mesenchymal stem cells (MSC). WJ-MSC show unique ability in crossing lineage borders. As other extraembryonic mesenchymal populations (placenta and amnionderived cells), WJ-MSC express several immunomodulatory molecules, essential during the initial phases of human development. Indeed, our recent work pointed out the expression of non-classical HLA molecules as HLA-G in such cells, together with a favorable combination of B7 costimulators. Very few data in literature suggest that some of the immune features of the naïve cells are maintained after performing differentiation. The aim of this work was extendi…

Hepatocyte differentiationSettore BIO/16 - Anatomia UmanaImmunogenicityMesenchymal stem cellImmune regulationObstetrics and GynecologyClinical uses of mesenchymal stem cellsBiologyUmbilical cordCell biologymedicine.anatomical_structureReproductive MedicineHepatocyteImmunologyWharton's jellymedicineWharton's jelly mesenchymal stem cells umbilical cord hepatocyte differentiation markers immunogenicity immune regulationDevelopmental BiologyPlacenta
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Isolation and characterization of Oct-4+/HLA-G+ mesenchymal stem cells from human umbilical cord matrix: differentiation potential and detection of n…

2008

The presence of multipotent cells in several adult and embryo-related tissues opened new paths for their use in regenerative medicine. Extraembryonic tissues such as umbilical cord are considered a promising source of stem cells, potentially useful in therapy. The characterization of cells from the umbilical cord matrix (Wharton''s Jelly) and amniotic membrane revealed the presence of a population of mesenchymal-like cells, sharing a set of core-markers expressed by "mesenchymal stem cells". Several reports enlightened the differentiation capabilities of these cells, even if at times the lack of an extensive characterization of surface markers and immune co-stimulators expression revealed h…

HistologyCell Culture TechniquesClinical uses of mesenchymal stem cellsCell SeparationBiologyUmbilical CordHLA AntigensHumansAmnionMolecular BiologyCell ProliferationStem cell transplantation for articular cartilage repairHLA-G AntigensSettore BIO/16 - Anatomia UmanaMultipotent Stem CellsHistocompatibility Antigens Class IMesenchymal stem cellCell DifferentiationMesenchymal Stem CellsAmniotic stem cellsCell BiologyTelomereCord liningCell biologyMedical Laboratory TechnologyMesenchymal stem cells Umbilical cord matrix Differentiation protocols Tolerogenic properties Self-renewal markersAmniotic epithelial cellsImmunologyStem cellOctamer Transcription Factor-3BiomarkersAdult stem cellHistochemistry and Cell Biology
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Isolation, cultivation and characterization of human somatic stem cells from adult skin, adipose tissue and bone marrow

2008

Isolation, cultivation and characterization of human somatic stem cells from adult skin, adipose tissue and bone marrow

Pathologymedicine.medical_specialtyInduced stem cellsintegumentary systemClinical uses of mesenchymal stem cellsAdipose tissueCell BiologyBiologyStem cell markermedicine.anatomical_structureImmunologymedicineBone marrowStem cellMolecular BiologyStem cell transplantation for articular cartilage repairAdult stem cellCell Research
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