Human dental pulp stem cells transplantation combined with treadmill training in rats after traumatic spinal cord injury

Spinal cord injury (SCI) is a disabling condition resulting in deficits of sensory and motor functions, and has no effective treatment. Considering that protocols with stem cell transplantation and treadmill training have shown promising results, the present study evaluated the effectiveness of stem cells from human exfoliated deciduous teeth (SHEDs) transplantation combined with treadmill training in rats with experimental spinal cord injury. Fifty-four Wistar rats were spinalized using NYU impactor. The rats were randomly distributed into 5 groups: Sham (laminectomy with no SCI, n=10); SCI (laminectomy followed by SCI, n=12); SHEDs (SCI treated with SHEDs, n=11); TT (SCI treated with treadmill training, n=11); SHEDs+TT (SCI treated with SHEDs and treadmill training; n=10). Treatment with SHEDs alone or in combination with treadmill training promoted functional recovery, reaching scores of 15 and 14, respectively, in the BBB scale, being different from the SCI group, which reached 11. SHEDs treatment was able to reduce the cystic cavity area and glial scar, increase neurofilament. Treadmill training alone had no functional effectiveness or tissue effects. In a second experiment, the SHEDs transplantation reduced the TNF-a levels in the cord tissue measured 6 h after the injury. Contrary to our hypothesis, treadmill training either alone or in combination, caused no functional improvement. However, SHEDs showed to be neuroprotective, by the reduction of TNF-a levels, the cystic cavity and the glial scar associated with the improvement of motor function after SCI. These results provide evidence that grafted SHEDs might be an effective therapy to spinal cord lesions, with possible anti-inflammatory action

Matrizes de nanofibras alinhadas com fator de crescimento epidermal incorporado como suporte eficiente para a diferenciação de células-tronco em células neurais

Danos ao sistema nervoso central (SCN) resultam em perda de conexões axonais, das funções motoras e sensoriais. Uma das estratégias para seu reparo é o transplante de células-tronco mesenquimais (CTMs). Porém essa alternativa requer uma adequada via de aplicação. Nesse sentido, o uso de matrizes alinhadas pode ser usado para apoiar o crescimento e diferenciação das CTMs e, quando incorporadas com fatores de crescimento, otimizam o processo de regeneração tecidual. O objetivo desse trabalho foi avaliar a diferenciação neural das CTMs cultivadas sobre matrizes de nanofibras orientadas com o fator de crescimento epidermal (EGF) incorporado. Os scaffolds com fibras alinhadas foram produzidos por electrospinning de emulsão e avaliados conforme a sua morfologia, o diâmetro das nanofibras, a degradabilidade e a liberação do EGF. As CTMs utilizadas foram provenientes da polpa de dentes decíduos esfoliados humanos. Essas células foram cultivadas nos scaffolds e avaliadas conforme os testes biológicos: adesão, viabilidade, proliferação, citotoxicidade e diferenciação neural. Os scaffolds com fibras alinhadas controle (AC) e contendo o EGF (AE) apresentaram morfologia, diâmetro das nanofibras e tempo de degradação semelhantes. Com base no total de EGF presente na matriz AE, 90,14% foi liberado após 28 dias. O citoesqueleto e o núcleo das CTMs cultivadas nos scaffolds AC e AE estavam mais alongados e alinhados quando comparado com as CTMs cultivadas no poço de cultura (controle). As CTMs aderiram mais nas matrizes AE em relação às matrizes AC, porém a proliferação e viabilidade celular foram similares, exceto no tempo de 72 horas, o qual a viabilidade no grupo controle foi maior, em comparação aos demais grupos. Os scaffolds AC e AE não foram tóxicos para as CTMs. Em relação aos resultados da neuro-diferenciação, a expressão de nestina e neurofilamentos consideravelmente maior em todos os grupos analisados quando comparado ao grupo controle. A expressão de βIII-tubulina e GFAP foi maior em todos os grupos diferenciados quando comparada ao grupo controle. A maioria das CTMs cultivadas nas matrizes AC e AE, induzidas ou não à diferenciação neural, apresentaram correntes dependente de voltagem para sódio. O valor de condutância máxima foi maior para todos os grupos analisados quando comparado ao grupo controle onde as células não foram diferenciadas. Portanto, as matrizes com nanofibras orientadas induzem à diferenciação neural das CTMs em neurônios funcionais tanto na ausência como na presença de EGF incorporado. As matrizes AE ainda mostraram ser capazes de melhorar a adesão celular. Dessa forma, conclui-se que as matrizes de nanofibras estudadas são uma possível estratégia para otimização da regeneração de lesões neurológicas.Damage to the central nervous system (CNS) results in loss of axonal connections and motor and sensory functions. One of the strategies for its repair is the transplantation of mesenchymal stem cells (MSCs). However, this requires a suitable application route. Accordingly, the use of scaffolds support the growth of MSCs and, when incorporated with growth factors, optimize the regeneration process. The purpose of this study was to evaluate the neural differentiation of MSCs cultured on nanofiber matrices oriented with epidermal growth factor (EGF) incorporated. Aligned scaffolds were produced by electrospinning emulsion and evaluated according to their degradation, the morphology and diameter of the nanofibers, and release of EGF from the nanofibers. MSCs used were from human exfoliated deciduous teeth (SHED). These cells were cultured on the scaffolds and evaluated according to biological tests: adhesion, viability, proliferation, cytotoxicity and neural differentiation. The aligned control scaffolds (AC) containing EGF (AE) presented similar morphology, diameter of nanofibers and degradation time. Based on the total EGF present in the scaffold AE, 90.14% was released after 28 days. The cytoskeleton and the core of the MSCs cultured on scaffolds AC and AE were more aligned and elongated when compared to the MSCs grown on plate wells (control). MSCs adhered more to matrices AE when compared to matrices AC, although proliferation and cell viability were similar, except after 72 hours. In this period, the viability of the control group was higher when compared to the rest of the groups. Scaffolds AC and AE were not toxic to MSCs. In regard to the results of neuro-differentiation, the expression of nestin and neurofilament was much higher in all groups than the control group. The expression of βIII tublin and GFAP was higher in all differentiated groups than the control group. Most of the MSCs grown in matrices AC and AE, induced or not to neural differentiation, showed voltage-dependent sodium currents. The maximum value of conductance of these groups was higher for the cells in all groupscompared to the control group, where the cells were not differentiated. Therefore, oriented nanofiber matrices induce neural differentiation of MSCs into functional neurons both in the absence and in the presence of incorporated EGF. The matrices AE also showed improved cell adhesion. Thus, these matrices are a possible strategy for optimizing the regeneration of neurologic lesions

Matrizes de nanofibras alinhadas com fator de crescimento epidermal incorporado como suporte eficiente para a diferenciação de células-tronco em células neurais

Danos ao sistema nervoso central (SCN) resultam em perda de conexões axonais, das funções motoras e sensoriais. Uma das estratégias para seu reparo é o transplante de células-tronco mesenquimais (CTMs). Porém essa alternativa requer uma adequada via de aplicação. Nesse sentido, o uso de matrizes alinhadas pode ser usado para apoiar o crescimento e diferenciação das CTMs e, quando incorporadas com fatores de crescimento, otimizam o processo de regeneração tecidual. O objetivo desse trabalho foi avaliar a diferenciação neural das CTMs cultivadas sobre matrizes de nanofibras orientadas com o fator de crescimento epidermal (EGF) incorporado. Os scaffolds com fibras alinhadas foram produzidos por electrospinning de emulsão e avaliados conforme a sua morfologia, o diâmetro das nanofibras, a degradabilidade e a liberação do EGF. As CTMs utilizadas foram provenientes da polpa de dentes decíduos esfoliados humanos. Essas células foram cultivadas nos scaffolds e avaliadas conforme os testes biológicos: adesão, viabilidade, proliferação, citotoxicidade e diferenciação neural. Os scaffolds com fibras alinhadas controle (AC) e contendo o EGF (AE) apresentaram morfologia, diâmetro das nanofibras e tempo de degradação semelhantes. Com base no total de EGF presente na matriz AE, 90,14% foi liberado após 28 dias. O citoesqueleto e o núcleo das CTMs cultivadas nos scaffolds AC e AE estavam mais alongados e alinhados quando comparado com as CTMs cultivadas no poço de cultura (controle). As CTMs aderiram mais nas matrizes AE em relação às matrizes AC, porém a proliferação e viabilidade celular foram similares, exceto no tempo de 72 horas, o qual a viabilidade no grupo controle foi maior, em comparação aos demais grupos. Os scaffolds AC e AE não foram tóxicos para as CTMs. Em relação aos resultados da neuro-diferenciação, a expressão de nestina e neurofilamentos consideravelmente maior em todos os grupos analisados quando comparado ao grupo controle. A expressão de βIII-tubulina e GFAP foi maior em todos os grupos diferenciados quando comparada ao grupo controle. A maioria das CTMs cultivadas nas matrizes AC e AE, induzidas ou não à diferenciação neural, apresentaram correntes dependente de voltagem para sódio. O valor de condutância máxima foi maior para todos os grupos analisados quando comparado ao grupo controle onde as células não foram diferenciadas. Portanto, as matrizes com nanofibras orientadas induzem à diferenciação neural das CTMs em neurônios funcionais tanto na ausência como na presença de EGF incorporado. As matrizes AE ainda mostraram ser capazes de melhorar a adesão celular. Dessa forma, conclui-se que as matrizes de nanofibras estudadas são uma possível estratégia para otimização da regeneração de lesões neurológicas.Damage to the central nervous system (CNS) results in loss of axonal connections and motor and sensory functions. One of the strategies for its repair is the transplantation of mesenchymal stem cells (MSCs). However, this requires a suitable application route. Accordingly, the use of scaffolds support the growth of MSCs and, when incorporated with growth factors, optimize the regeneration process. The purpose of this study was to evaluate the neural differentiation of MSCs cultured on nanofiber matrices oriented with epidermal growth factor (EGF) incorporated. Aligned scaffolds were produced by electrospinning emulsion and evaluated according to their degradation, the morphology and diameter of the nanofibers, and release of EGF from the nanofibers. MSCs used were from human exfoliated deciduous teeth (SHED). These cells were cultured on the scaffolds and evaluated according to biological tests: adhesion, viability, proliferation, cytotoxicity and neural differentiation. The aligned control scaffolds (AC) containing EGF (AE) presented similar morphology, diameter of nanofibers and degradation time. Based on the total EGF present in the scaffold AE, 90.14% was released after 28 days. The cytoskeleton and the core of the MSCs cultured on scaffolds AC and AE were more aligned and elongated when compared to the MSCs grown on plate wells (control). MSCs adhered more to matrices AE when compared to matrices AC, although proliferation and cell viability were similar, except after 72 hours. In this period, the viability of the control group was higher when compared to the rest of the groups. Scaffolds AC and AE were not toxic to MSCs. In regard to the results of neuro-differentiation, the expression of nestin and neurofilament was much higher in all groups than the control group. The expression of βIII tublin and GFAP was higher in all differentiated groups than the control group. Most of the MSCs grown in matrices AC and AE, induced or not to neural differentiation, showed voltage-dependent sodium currents. The maximum value of conductance of these groups was higher for the cells in all groupscompared to the control group, where the cells were not differentiated. Therefore, oriented nanofiber matrices induce neural differentiation of MSCs into functional neurons both in the absence and in the presence of incorporated EGF. The matrices AE also showed improved cell adhesion. Thus, these matrices are a possible strategy for optimizing the regeneration of neurologic lesions

Electrical stimulation applied during hiPSC differentiation drives the hiPSC-CMs towards a mature cardiac conduction-like cells

Os cardiomiócitos derivados de células-tronco pluripotentes induzidas humanas (hiPSC-CMs) se assemelham aos cardiomiócitos fetais e o estímulo elétrico (ES) tem sido explorado para amadurecer as células diferenciadas. Aqui, levantamos a hipótese de que o ES aplicado no início do processo de diferenciação desencadeia tanto a diferenciação dos hiPSC-CMs em um fenótipo especializado do sistema de condução (CS) quanto a maturação celular. Aplicamos o ES por 15 dias a partir do dia 0 do processo de diferenciação e encontramos um aumento da expressão de fatores de transcrição e proteínas associadas ao desenvolvimento e função do CS, incluindo IRX3 e NKX2.5 e SCN5A, Hcn4 e contactina 2, respectivamente. Também encontramos ativação de proteínas de disco intercalares (Nrap e ?-catenina). Detectamos a maturação de CMs induzida por ES, conforme indicada pelo aumento da expressão de TNNI1 e TNNI3. Micrografias confocais mostraram uma mudança em direção à expressão da proteína das junções gap, conexina 40, nos hiPSC-CMs com ES em comparação com a expressão mais dominante da conexina 43 nos controles. Finalmente, a análise dos parâmetros funcionais revelou que os hiPSC-CMs com ES exibiram transientes intracelulares de Ca2+ mais longos, despolarização do potencial de ação (AP) mais rápida e duração mais lenta do AP em 90% da repolarização, assemelhando-se com as fibras de condução rápida. Em conjunto, fornecemos evidências de que o ES aplicado durante a diferenciação das hiPSCs em cardiomiócitos leva ao desenvolvimento de células do tipo de condução cardíaca com citoarquitetura mais madura. Assim, os hiPSC-CMs expostos ao ES durante a diferenciação podem ser cruciais para o desenvolvimento de células do CS para modelagem de doenças cardíacas, triagem de medicamentos individuais em uma plataforma do tipo medicamento de precisão e apoiar o desenvolvimento de novas terapias para arritmiasHuman induced pluripotent stem cell derived cardiomyocytes (hiPSC-CMs) resemble fetal cardiomyocytes and electrical stimulation (ES) has been explored to mature the differentiated cells. Here, we hypothesize that ES applied at the beginning of the differentiation process, triggers both differentiation of the hiPSC-CMs into a specialized conduction system (CS) phenotype and cell maturation. We applied ES for 15 days starting on day 0 of the differentiation process and found an increased expression of transcription factors and proteins associated with the development and function of CS including IRX3, NKX2.5 and contactin 2, Hcn4 and SCN5A, respectively. We also found activation of intercalated disc proteins (Nrap and beta-catenin). We detected ES-induced CM maturation as indicated by increased TNNI1 and TNNI3 expression. Confocal micrographs showed a shift towards expression of the gap junction protein connexin 40 in ES hiPSC-CMs compared to the more dominant expression of connexin 43 in controls. Finally, analysis of functional parameters revealed that ES hiPSC-CMs exhibited faster action potential (AP) depolarization, longer intracellular Ca2+ transients, and slower AP duration at 90% of repolarization, resembling fast conducting fibers. Altogether, we provided evidence that ES during the differentiation of hiPSCs to cardiomyocytes lead to development of cardiac conduction-like cells with more mature cytoarchitecture. Thus, hiPSC-CMs exposed to ES during differentiation can be instrumental to develop CS cells for cardiac disease modelling, screening individual drugs on a precision medicine type platform and support the development of novel therapeutics for arrhythmia

Diario de Valencia: Diario de Valencia - Año VIII Número 2615 - 1918 julio 5 (05/07/1918)

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A Sodium Oxalate-Rich Diet Induces Chronic Kidney Disease and Cardiac Dysfunction in Rats

International audienceChronic kidney disease (CKD) is a worldwide public health issue affecting 14% of the general population. However, research focusing on CKD mechanisms/treatment is limited because of a lack of animal models recapitulating the disease physiopathology, including its complications. We analyzed the effects of a three-week diet rich in sodium oxalate (OXA diet) on rats and showed that, compared to controls, rats developed a stable CKD with a 60% reduction in glomerular filtration rate, elevated blood urea levels and proteinuria. Histological analyses revealed massive cortical disorganization, tubular atrophy and fibrosis. Males and females were sensitive to the OXA diet, but decreasing the diet period to one week led to GFR significance but not stable diminution. Rats treated with the OXA diet also displayed classical CKD complications such as elevated blood pressure and reduced hematocrit. Functional cardiac analyses revealed that the OXA diet triggered significant cardiac dysfunction. Altogether, our results showed the feasibility of using a convenient and non-invasive strategy to induce CKD and its classical systemic complications in rats. This model, which avoids kidney mass loss or acute toxicity, has strong potential for research into CKD mechanisms and novel therapies, which could protect and postpone the use of dialysis or transplantation

Human Induced Pluripotent Stem (hiPS) Cells from Urine Samples: A Non-Integrative and Feeder-Free Reprogramming Strategy

International audienceHuman induced pluripotent stem (hiPS) cell technology has already revolutionized some aspects of fundamental and applied research such as study of disease mechanisms and pharmacology screening. The first clinical trial using hiPS cell-derived cells began in Japan, only 10 years after the publication of the proof-of concept article. In this exciting context, strategies to generate hiPS cells have evolved quickly, tending towards non-invasive protocols to sample somatic cells combined with "safer" reprogramming strategies. In this unit, we describe a protocol combining both of these advantages to generate hiPS cells with episomal plasmid transfection from urine samples of individuals carrying the desired genotype. Based on previous published works, this simplified protocol requires minimal equipment and reagents, and is suitable both for scientists familiar with the hiPS cells technology and neophytes. HiPS cells displaying classical features of pluripotency and suitable for all desired downstream applications are generated rapidly (\textless10 weeks) and with high efficiency. © 2017 by John Wiley & Sons, Inc