Epidermal neural crest stem cell transplantation as a promising therapeutic strategy for ischemic stroke

Introduction: Cell-based therapy is considered as promising strategy to cure stroke. However, employing appropriate type of stem cell to fulfill many therapeutic needs of cerebral ischemia is still challenging. In this regard, the current study was designed to elucidate therapeutic potential of epidermal neural crest stem cells (EPI-NCSCs) compared to bone marrow mesenchymal stem cells (BM-MSCs) in rat model of ischemic stroke. Methods: Ischemic stroke was induced by middle cerebral artery occlusion (MCAO) for 45 minutes. Immediately after reperfusion, EPI-NCSCs or BM-MSCs were transplanted via intra-arterial or intravenous route. A test for neurological function was performed before ischemia and 1, 3, and 7 days after MCAO. Also, infarct volume ratio and relative expression of 15 selected target genes were evaluated 7 days after transplantation. Results: EPI-NCSCs transplantation (both intra-arterial and intravenous) and BM-MSCs transplantation (only intra-arterial) tended to result in a better functional outcome, compared to the MCAO group; however, this difference was not statistically significant. The infarct volume ratio significantly decreased in NCSC-intra-arterial, NCSC-intravenous and MSC-intra-arterial groups compared to the control. EPI-NCSCs interventions led to higher expression levels of Bdnf, nestin, Sox10, doublecortin, β-III tubulin, Gfap, and interleukin-6, whereas neurotrophin-3 and interleukin-10 were decreased. On the other hand, BM-MSCs therapy resulted in upregulation of Gdnf, β-III tubulin, and Gfap and down-regulation of neurotrophin-3, interleukin-1, and interleukin-10. Conclusion: These findings highlight the therapeutic effects of EPI-NCSCs transplantation, probably through simultaneous induction of neuronal and glial formation, as well as Bdnf over-expression in a rat model of ischemic strok

Experimental Models of SARS-CoV-2 Infection: Possible Platforms to Study COVID-19 Pathogenesis and Potential Treatments

In December 2019, a novel coronavirus crossed species barriers to infect humans and was effectively transmitted from person to person, leading to a worldwide pandemic. Development of effective clinical interventions, including vaccines and antiviral drugs that could prevent or limit the burden or transmission of severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), is a global health priority. It is thus of utmost importance to assess possible therapeutic strategies against SARS-CoV-2 using experimental models that recapitulate aspects of the human disease. Here, we review available models currently being developed and used to study SARS-CoV-2 infection and highlight their application to screen potential therapeutic approaches, including repurposed antiviral drugs and vaccines. Each identified model provides a valuable insight into SARS-CoV-2 cellular tropism, replication kinetics, and cell damage that could ultimately enhance understanding of SARS-CoV-2 pathogenesis and protective immunity

Substrate stiffness affects the morphology and gene expression of epidermal neural crest stem cells in a short term culture

According to the intrinsic plasticity of stem cells, controlling their fate is a critical issue in cell-based therapies. Recently, a growing body of evidence has suggested that substrate stiffness can affect the fate decisions of various stem cells. Epidermal neural crest stem cells as one of the main neural crest cell derivatives hold great promise for cell therapies due to presenting a high level of plasticity. This study was conducted to define the influence of substrate stiffness on the lineage commitment of these cells. Here, four different polyacrylamide hydrogels with elastic modulus in the range of 0.7-30kPa were synthesized and coated with collagen and stem cells were seeded on them for 24hr. The obtained data showed that cells can attach faster to hydrogels compared with culture plate and cells on <1kPa stiffness show more neuronal-like morphology as they presented several branches and extended longer neurites over time. Moreover, the transcription of actin downregulated on all hydrogels, while the expression of Nestin, Tubulin, and PDGFR-alpha increased on all of them and SOX-10 and doublecortin gene expression were higher only on <1kPa. Also, it was revealed that soft hydrogels can enhance the expression of glial cell line-derived neurotrophic factor, neurotrophin-3, and vascular endothelial growth factor in these stem cells. On the basis of the results, these cells can respond to the substrate stiffness in the short term culture and soft hydrogels can alter their morphology and gene expression. These findings suggested that employing proper substrate stiffness might result in cells with more natural profiles similar to the nervous system and superior usefulness in therapeutic applications

Substrate stiffness affects the morphology and gene expression of epidermal neural crest stem cells in a short term culture

According to the intrinsic plasticity of stem cells, controlling their fate is a critical issue in cell-based therapies. Recently, a growing body of evidence has suggested that substrate stiffness can affect the fate decisions of various stem cells. Epidermal neural crest stem cells as one of the main neural crest cell derivatives hold great promise for cell therapies due to presenting a high level of plasticity. This study was conducted to define the influence of substrate stiffness on the lineage commitment of these cells. Here, four different polyacrylamide hydrogels with elastic modulus in the range of 0.7-30kPa were synthesized and coated with collagen and stem cells were seeded on them for 24hr. The obtained data showed that cells can attach faster to hydrogels compared with culture plate and cells on <1kPa stiffness show more neuronal-like morphology as they presented several branches and extended longer neurites over time. Moreover, the transcription of actin downregulated on all hydrogels, while the expression of Nestin, Tubulin, and PDGFR-alpha increased on all of them and SOX-10 and doublecortin gene expression were higher only on <1kPa. Also, it was revealed that soft hydrogels can enhance the expression of glial cell line-derived neurotrophic factor, neurotrophin-3, and vascular endothelial growth factor in these stem cells. On the basis of the results, these cells can respond to the substrate stiffness in the short term culture and soft hydrogels can alter their morphology and gene expression. These findings suggested that employing proper substrate stiffness might result in cells with more natural profiles similar to the nervous system and superior usefulness in therapeutic applications