Background: Cardiomyocytes have small potential for renovation and proliferation in vivo. Consequently, the heart muscle has limited capacity of self-renewal. Mesenchymal stem cells (MSC) therapy, as well as MSC differentiated into cardiomyocytes, has been used in the attempt to minimize the effects of ischemic-hypoxic lesions and those affecting the electrical conduction system of the heart.
PURPOSE: To evaluate the effects of mesenchymal stem cells (MSC) from eight mice C57BL/6 gfp+ bone marrows expanded in cultures associated with platelets rich plasma (PRP) deriving from another eight mice, in the repair of critical defects in calvarial bone produced in twenty-four adult isogenic mice C57BL/6. METHODS: The animals were submitted to a cranial defect of 6.0mm in diameter and divided into two equal experimental groups. Control group did not receive treatment and the treated group received a MSC pellet containing 1.0 x 10(7) cells/mL associated with 50.0µL of plasma gel containing 1.0 x 10(9) autologous platelets within the defect. RESULTS: In the treated group was observed process of angiogenesis and bone repair better than control group. CONCLUSION: Mesenchymal stem cells derived from bone marrow of C57BL/6 gfp+ mice associated with PRP gel applied in bone critical defects produced in calvarial contributes positively to the process of bone repair.
Tissue engineering strategies, based on solid/porous scaffolds, suffer from several limitations, such as ineffective vascularization, poor cell distribution and organization within scaffold, in addition to low final cell density, among others. Therefore, the search for other tissue engineering approaches constitutes an active area of investigation. Decellularized matrices (DM) present major advantages compared to solid scaffolds, such as ideal chemical composition, the preservation of vascularization structure and perfect three-dimensional structure. In the present study, we aimed to characterize and investigate murine heart decellularized matrices as biomaterials for regular and whole organ tissue engineering. Heart decellularized matrices were characterized according to: 1. DNA content, through DNA quantificationo and PCR of isolated genomic DNA; 2. Histological structure, assessed after Hematoxylin and Eosin, as well as Masson’s Trichrome stainings; 3. Surface nanostructure analysis, performed, using SEM. Those essays allowed us to conclude that DM was indeed decellularized, with preserved extracellular matrix structure. Following characterization, decellularized heart slices were seeded with induced Pluripotent Stem cells (iPS). As expected, but – to the best of our knowledge - never shown before, decellularization of murine heart matrices maintained matrix biocompatibility, as iPS cells rapidly attached to the surface of the material and proliferated. Strikingly though, heart DM presented a differentiation induction effect over those cells, which lost their pluripotency markers after 7 days of culture in the DM. Such loss of differentiation markers was observed, even though bFGF containing media mTSR was used during such period. Gene expression of iPS cells cultured on DM will be further analyzed, in order to assess the effects of culturing pluripotent stem cells in decellularized heart matrices.
Mesenchymal stem cells (MSC) are present in specialized niches in perivascular regions of adult tissues and are able to differentiate into various cell types, such as those committed to repairing. Bone marrow derived MSC from eight young mice C57BL/ 6 gfp + were expanded in culture for repairing critical defects in calvarial bone produced in twenty-four young isogenic adult C57BL/6 mice. The animals were subjected to a cranial defect of 6.0mm diameter and divided into two equal experimental groups. Control group did not receive any treatment and the treated group received a MSC pellet containing 1.0 x 10 7 cells/mL into the defects. The group treated with MSC showed increased angiogenesis and amount of new bone deposited on the defect limits than that observed in the control group. The results demonstrated that transplantation of bone marrow-derived MSC of C57BL/6 gfp + mice to bone critical defects produced in mice calvarial contributes positively to the bone repair process. MSC presets ability to influence the correct functioning of osteoblasts, increases the amount of mobilized cells for the repairing process, speeds up growth, and increases deposition of bone matrix.
RESUMO Infecção relacionada com assistência à saúde (IRAS) é atribuída aos quadros adquiridos tanto no momento da admissão em ambientes de atenção à saúde, quanto durante a internação, e até mesmo após alta médica, sendo assim, correlacionada com a permanência hospitalar. Na rotina cirúrgica veterinária, pacientes tanto hígidos quanto imunocomprometidos, tornam-se susceptíveis. Ressalva-se, que a ferida cirúrgica infectada por microrganismos endógenos ou exógenos, com classificação de multirresistentes ou não, pode desencadear quadros sépticos. Denomina-se infecção no sítio cirúrgico (ISC), a colonização da ferida cirúrgica por microrganismos, sendo sua ocorrência no pós-operatório, uma das principais complicações relacionadas à IRAS. Os principais fatores que podem levar a ISC estão ligados ao pré, trans e pós-operatório. Os médicos veterinários que atuam diretamente em ambiente hospitalar, devem estar preparados para prevenir e tratar casos de ISC de maneira integrada e dinâmica. Entre as ferramentas importantes nesse processo, destacam-se os programas multidisciplinares de Antibiotic Stewardship associados ao desenvolvimento de técnicas diagnósticas rápidas e ao incentivo de medidas consagradas para o controle da infecção hospitalar. Objetiva-se com o presente trabalho ressaltar os principais fatores de risco, medidas profiláticas, e o programa Antibiotic Stewardship, para o controle da ISC.
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Traumatic spinal cord injury results in severe neurological deficits, mostly irreversible. The cell therapy represents a strategy for treatment particularly with the use of stem cells with satisfactory results in several experimental models. The aim of the study was to compare the treatment of spinal cord injury (SCI) with and without mesenchymal stem cells (MSC), to investigate whether MSCs migrate and/or remain at the site of injury, and to analyze the effects of MSCs on inflammation, astrocytic reactivity and activation of endogenous stem cells. Three hours after SCI, animals received bone marrow-derived MSCs (1×10 7 in 1mL PBS, IV). Animals were euthanized 24 hours, 7 and 21 days post-injury. The MSC were not present in the site of the lesion and the immunofluorescent evaluation showed significant attenuation of inflammatory response with reduction in macrophages labeled with anti-CD68 antibody (ED1), decreased immunoreactivity of astrocytes (GFAP+) and greater activation of endogenous stem cells (nestin+) in the treated groups. Therefore, cell transplantation have a positive effect on recovery from traumatic spinal cord injury possibly due to the potential of MSCs to attenuate the immune response. Key words: Cellular therapy. Neurosurgery. Stem cell. ResumoA lesão medular resulta em déficits neurológicos graves, a maioria irreversíveis. A terapia celular representa uma estratégia para o tratamento, especialmente com a utilização de células-tronco, com resultados satisfatórios em vários modelos experimentais. O objetivo do estudo foi comparar o tratamento de lesões da medula espinal (SCI), com e sem o uso de células-tronco mesenquimais (MSC), para investigar se as MSCs migram e/ou permanecem no local de lesão, e para analisar os efeitos de MSCs sobre a inflamação, reatividade astrocitária e ativação das células-tronco endógenas. Três horas depois da SCI, os animais receberam as MSC derivadas da medula óssea (1 × 10 7 em 1 mL de PBS, IV). Os animais foram sacrificados 24 horas, 7 e 21 dias pós-lesão. As MSC não estavam presentes no local da lesão e a avaliação por imunofluorescência demonstrou atenuação significativa da resposta inflamatória com redução em macrófagos marcados com anticorpo anti CD68 (ED1), diminuição da imunorreatividade de astrócitos (GFAP +) e maior ativação das células-tronco endógenas (nestin+) nos grupos tratados. Assim, o transplante de células teve efeito positivo sobre a recuperação de lesão traumática da medula espinal, possivelmente devido ao potencial das MSCs para atenuar a resposta imunológica. Palavras-chave: Células-tronco. Neurocirurgia. Terapia celular.
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