Bone marrow-derived mesenchymal stem cell microtissues (BMSCMT) enhanced cardiomyogenesis in vitro and cardiac repairs of myocardial infarcted hearts in vivo are documented. Producing human BMSCMT onto patches in vitro for cardiac tissue engineering has not been reported. For possibly producing human bone marrow-derived mesenchymal stem cell microtissues (hBMSCMT) on an elastic silk fibroin (SF)-poly(ε-caprolactone) (PCL) based patches is hereby designed. After an elastic SF-PCL (SP) patch is fabricated, hyaluronic acid (HA)/SF-PCL(HSP) and HA-GRGD/SF-PCL(HGSP) patches are fabricated by photochemically grafting HA and HA-GRGD onto SP surfaces. The results show that the proliferations of hBMSC on HGSP patches significantly exceed those on the other patches, as determined by 3-(4,5-dimethylthiazol-2-yl)-5-(3-carboxymethoxyphenyl)-2-(4-sulfophenyl)-2H-tetrazolium assay. Notably, the formation of 5-aza inducing cardiomyogenic differentiations of hBMSCMT/HGSP patches is observed with typical sizes of ≈317 μm wide and 26 μm high. The cardiomyogenesis of hBMSCMT/HGSP patches including the expressions of cardiac-specific genes (e.g., Gata4) and proteins (e.g., connexin43 (CX43)) significantly exceeds those of hBMSC monolayer on the HSP and SP patches. Promoting in vitro cardiomyogenesis of hBMSC with forming cardiomyogenic differentiation of hBMSCMT/HGSP hybrid patch is possibly mediated by the synergistic functions of HA-GRGD on enhancing the activity of F-actin. The hBMSCMT/HGSP cardiac patch may be further employed to cardiac tissue engineering.
Silk fibroin (SF) and hyaluronic acid (HA) were crosslinked by horseradish peroxidase (HRP)/H2O2, and 1,4-Butanediol di-glycidyl ether (BDDE), respectively, to produce HA/SF-IPN (interpenetration network) (HS-IPN) hydrogels. HS-IPN hydrogels consisted of a SF strain with a high content of tyrosine (e.g., strain A) increased viscoelastic modules compared with those with low contents (e.g., strain B and C). Increasing the quantities of SF in HS-IPN hydrogels (e.g., HS7-IPN hydrogels with weight ratio of HA/SF, 5:7) increased viscoelastic modules of the hydrogels. In addition, the mean pores size of scaffolds of the model hydrogels were around 38.96 ± 5.05 μm which was between those of scaffolds H and S hydrogels. Since the viscoelastic modulus of the HS7-IPN hydrogel were similar to those of human nucleus pulposus (NP), it was chosen as the model hydrogel for examining the differentiation of human bone marrow-derived mesenchymal stem cell (hBMSC) to NP. The differentiation of hBMSC induced by transforming growth factor β3 (TGF-β3) in the model hydrogels to NP cells for 7 d significantly enhanced the expressions of glycosaminoglycan (GAG) and collagen type II, and gene expressions of aggrecan and collagen type II while decreased collagen type I compared with those in cultural wells. In summary, the model hydrogels consisted of SF of strain A, and high concentrations of SF showed the highest viscoelastic modulus than those of others produced in this study, and the model hydrogels promoted the differentiation of hBMSC to NP cells.
The effects of the stiffness of substrates on the cell behaviours of human bone marrow-derived mesenchymal stem cells (hBMSC) have been investigated, but the effects of the secondary structures of proteins in the substrates on the morphological transformation and differentiation of hBMSC have yet been elucidated. To investigate these issues, silk fibroin-poly(ε-caprolactone) SP cardiac patches of poly(ε-caprolactone; P), on which is grafted by silk fibroin (SF) with various β-sheet contents (or crystallinity) to provide various degrees of stiffness, were produced to examine the in vitro behaviours of hBMSC during proliferation, and cardiomyogenesis on the SP patches. β-sheet contents of SF from 20% to 44% (SP20 to SP44, respectively) were induced on patches, which were examined by attenuated total reflection Fourier-transform infrared (ATR-FTIR) spectroscopy, and analysed using the Fourier self-deconvolution method. The stiffness of the SP patches, quantified by their Young's moduli and elasticities, increased with the crystallinity of the SF. During 3 days of proliferation, hBMSC migrated and morphologically transformed into 3D microtissues with diameters of approximately 150-200 μm on low-stiffness SP20 and SP30 patches, whereas 2D monolayers were observed on the SP37 and SP44 patches. The 3D microtissues/patch yielded more extensive in vitro cardiomyogenesis of hBMSC than the 2D cell monolayer with significantly higher expressions of all examined cardiac-specific proteins after induction by 5-aza. Notably, in vivo subcutaneously growing 3D microtissues on SP20 patches and a 2D monolayer on SP44 patches were preliminarily demonstrated in a rat model. Morphological transformations of hBMSC from a 2D monolayer to a 3D microtissue by low-stiffness SP cardiac patches, promoting cardiomyogenesis, provide a new opportunity for cardiac tissue engineering.
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