Various somatic tissue-derived mesenchymal stromal cells (MSCs) have been considered as an attractive therapeutic tool for treatment of liver diseases in which the secretion of soluble factors or extracellular vesicles (EVs) is the most probable mechanism. The experimental application of human embryonic stem cell-derived MSC (ES-MSC) increased rapidly and showed promising results, in vitro and in vivo. However, possible therapeutic effects of human ES-MSC and their EVs on Thioacetamide (TAA)-induced chronic liver injury have not been evaluated yet. Our data indicated that human ES-MSC can significantly suppress the proliferation of peripheral blood mononuclear cells compared to bone marrow (BM)-MSC and adipose (AD)-MSC. Moreover, ES-MSC increased the secretion of anti-inflammatory cytokines (i.e., TGF-β and IL-10) and decreased IFN-γ, compared to other MSCs. ES-MSC EVs demonstrated immunomodulatory activities comparable to parental cells and ameliorated cirrhosis in TAA-induced chronic rat liver injury, that is, reduction in fibrosis and collagen density, necrosis, caspase density, portal vein diameter, and transaminitis. The gene expression analyses also showed upregulation in collagenases (MMP9 and MMP13), anti-apoptotic gene (BCL-2) and anti-inflammatory cytokines (TGF-β1 and IL-10) and down-regulation of major contributors to fibrosis (Col1α, αSMA, and TIMP1), pro-apoptotic gene (BAX) and pro-inflammatory cytokines (TNFα and IL-2) following treatment with ES-MSC and ES-MSC-EV. These results demonstrated that human ES-MSC and ES-MSC EV as an off-the-shelf product, that needs further assessment to be suggested as an allogeneic product for therapeutic applications for liver fibrosis.
Cartilage tissue engineering is the interdisciplinary science that will help to improve cartilage afflictions, such as arthrosis, arthritis, or following joints traumatic injuries.In the present work, we developed an injectable hydrogel which derived from decellularized extracellular matrix of sheep cartilage. Successful decellularization was evaluated by measuring the DNA, glycosaminoglycans (GAG), collagen contents, and histological analyses. There was a minor difference in GAG and collagen contents among natural cartilage and decellularized tissue as well as ultimate hydrogel. Rheological analysis showed that the temperature and gelation time of prepared hydrogel were 37 C and between 5 and 7 min, respectively. Mechanical properties evaluation indicated a storage modulus of 20 kPa. The results show that prepared hydrogel possessed cell-friendly microenvironment as confirmed via calcein staining and MTT assay. Also, cells were able to proliferate which observed by H&E and alcian blue staining. Cell attachment and proliferation at the surface of the decellularized hydrogel was apparent by Scanning Electron Microscope (SEM) images and microphotographs. Furthermore, the cells embedded within the hydrogel were able to differentiate into chondrocyte with limited evidence of hypertrophy and osteogenesis in utilized cells which proved by SOX9, CoL2, ACAN, and also CoL1 and CoL10 gene expression levels. In summary, the results suggest that developed novel injectable hydrogel from decellularized cartilage could be utilized as a promising substrate for cartilage tissue engineering applications.
K E Y W O R D Sbiocompatible, cartilage, decellularized ECM, injectable hydrogel, mesenchymal stem cell
Many people worldwide suffer from motor neuron-related disorders such as amyotrophic lateral sclerosis and spinal cord injuries. Recently, several attempts have been made to recruit stem cells to modulate disease progression in ALS and also regenerate spinal cord injuries. Chorion-derived mesenchymal stem cells (C-MSCs), used to be discarded as postpartum medically waste product, currently represent a class of cells with self renewal property and immunomodulatory capacity. These cells are able to differentiate into mesodermal and nonmesodermal lineages such as neural cells. On the other hand, gelatin, as a simply denatured collagen, is a suitable substrate for cell adhesion and differentiation. It has been shown that electrospinning of scaffolds into fibrous structure better resembles the physiological microenvironment in comparison with two-dimensional (2D) culture system. Since there is no report on potential of human chorion-derived MSCs to differentiate into motor neuron cells in two- and three-dimensional (3D) culture systems, we set out to determine the effect of retinoic acid (RA) and sonic hedgehog (Shh) on differentiation of human C-MSCs into motor neuron-like cells cultured on tissue culture plates (2D) and electrospun nanofibrous gelatin scaffold (3D).
Mesenchymal stem cells (MSCs) are considered primary candidates for treating complex bone defects in cell-based therapy and tissue engineering. Compared with monolayer cultures, spheroid cultures of MSCs (mesenspheres) are favorable due to their increased potential for differentiation, extracellular matrix (ECM) synthesis, paracrine activity, and in vivo engraftment. Here, we present a strategy for the incorporation of microparticles for the fabrication of osteogenic micro-tissues from mesenspheres in a cost-effective and scalable manner. A facile method was developed to synthesize mineral microparticles with cell-sized spherical shape, biphasic calcium phosphate composition (hydroxyapatite and β-tricalcium phosphate), and a microporous structure. Calcium phosphate microparticles (CMPs) were incorporated within the mesenspheres through mixing with the single cells during cell aggregation. Interestingly, the osteogenic genes were upregulated significantly (collagen type 1 (Col 1) 30-fold, osteopontin (OPN) 10-fold, and osteocalcin (OCN) 3-fold) after 14 days of culture with the incorporated CMPs, while no significant upregulation was observed with the incorporation of gelatin microparticles. The porous structure of the CMPs was exploited for loading and sustained release of an angiogenic small molecule. Dimethyloxaloylglycine (DMOG) was loaded efficiently onto the CMPs (loading efficiency: 65.32 ± 6%) and showed a sustained release profile over 12 days. Upon incorporation of the DMOG-loaded CMPs (DCMPs) within the mesenspheres, a similar osteogenic differentiation and an upregulation in angiogenic genes (VEGF 5-fold and kinase insert domain (KDR) 2-fold) were observed after 14 days of culture. These trends were also observed in immunostaining analysis. To evaluate scalable production of the osteogenic micro-tissues, the incorporation of microparticles was performed during cell aggregation in a spinner flask. The DCMPs were efficiently incorporated and directed the mesenspheres toward osteogenesis and angiogenesis. Finally, the DCMP mesenspheres were loaded within a three-dimensional printed cell trapper and transplanted into a critical-sized defect in a rat model. Computed tomography and histological analysis showed significant bone formation with blood vessel reconstruction after 8 weeks in this group. Taken together, we provide a scalable and cost-effective approach for fabrication of osteogenic micro-tissues, as building blocks of macro-tissues, that can address the large amounts of cells required for cell-based therapies.
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