Improving survival and efficacy of pluripotent stem cell–derived cardiac grafts

Human embryonic stem cells (hESCs) can be differentiated into structurally and electrically functional myocardial tissue and have the potential to regenerate large regions of infarcted myocardium. One of the key challenges that needs to be addressed towards full‐scale clinical application of hESCs is enhancing survival of the transplanted cells within ischaemic or scarred, avascular host tissue. Shortly after transplantation, most hESCs are lost as a result of multiple mechanical, cellular and host factors, and a large proportion of the remaining cells undergo apoptosis or necrosis shortly thereafter, as a result of loss of adhesion‐related signals, ischaemia, inflammation or immunological rejection. Blocking the apoptotic signalling pathways of the cells, using pro‐survival cocktails, conditioning hESCs prior to transplant, promoting angiogenesis, immunosuppressing the host and using of bioengineered matrices are among the emerging techniques that have been shown to optimize cell survival. This review presents an overview of the current strategies for optimizing cell and host tissue to improve the survival and efficacy of cardiac cells derived from pluripotent stem cells.     

负载噬菌体内溶素Lys84水凝胶的制备及性能表征

探究聚(N-异丙基丙烯酰胺)[poly(N-isopropylacrylamide)]基互穿网络(interpenetrating polymer network)温敏水凝胶(记作:IPNT)作为噬菌体内溶素Lys84递送载体的可行性,及载药水凝胶作为抗菌材料的应用潜力。以海藻酸钠和N-异丙基丙烯酰胺为原材料,通过自由基聚合的方法制备互穿网络温敏水凝胶,采用干态浸泡法负载金黄色葡萄球菌(Staphylococcus aureus)噬菌体内溶素Lys84获得载药水凝胶(IPNT-Lys84)。通过红外光谱仪、扫描电子显微镜(scanning electron microscopy,SEM)、差示扫描量热仪(differential scanning calorimetry,DSC)对水凝胶载药前后的物理性能进行表征,并研究水凝胶溶胀、退溶胀以及内溶素Lys84释放情况、在不同温度及不同浓度药液浸泡的抗菌性能。结果表明,IPNT-Lys84水凝胶孔洞均匀,低临界溶解温度(lower critical solution temperature,LCST)为32°C;水凝胶平衡溶胀度为30 g/g,退溶胀时失水率为88%;在37°C时内溶素释放率在6 h内达到70%以上;IPNT-Lys84水凝胶杀菌率达99.9%以上。研究表明,采用IPNT递送内溶素Lys84具有可行性,IPNT-Lys84水凝胶有望成为针对多重耐药金黄色葡萄球菌的有效抗菌材料。     

Stable hydrogel adhesion to polydimethylsiloxane enables cyclic mechanical stimulation of 3D-bioprinted smooth muscle constructs

During normal urination, smooth muscle cells (SMCs) in the lower urinary tract (LUT) are exposed to mechanical signals that have a critical impact on tissue structure and function. Nevertheless, the mechanisms underlying the maintenance of the contractile phenotype of SMCs remain poorly understood. This is due, in part, to a lack of studies that have examined the effects of mechanical loading using three-dimensional (3D) models. In this study, surface modifications of polydimethylsiloxane (PDMS) membrane were evaluated to investigate the effects of cyclic mechanical stimulation on SMC maturation in 3D constructs. Commercially available cell stretching plates were modified with amino or methacrylate groups to promote adhesion of 3D constructs fabricated by bioprinting. After 6 days of stimulation, the effects of mechanical stimulation on the expression of contractile markers at the mRNA and protein levels were analyzed. Methacrylate-modified surfaces supported stable adhesion of the 3D constructs to the membrane and facilitated cyclic mechanical stimulation, which significantly increased the expression of contractile markers at the mRNA and protein levels. These effects were found to be mediated by activation of the p38 MAPK pathway, as inhibition of this pathway abolished the effects of stimulation in a dose-dependent manner. These results provide valuable insights into the role of mechanical signaling in maintaining the contractile phenotype of bladder SMCs, which has important implications for the development of future treatments for LUT diseases.     

Ultrastructural immunolocalization of hyaluronate in regenerating tail of lizards and amphibians supports an immune‐suppressive role to favor regeneration

Hyaluronate is produced in high amount during the initial stages of regeneration of the tail and limbs of lizards, newts, and frog tadpoles. The fine distribution of hyaluronate in the regenerating tail blastemas has been assessed by ultrastructural immunolocalization of the Hyaluronate Binding Protein (HABP), a protein that indirectly reveals the presence of hyaluronate in tissues. The present electron microscopic study shows that HABP is detected in the cytoplasm but this proteins is mainly localized on the surfaces of cells in the wound epidermis and mesenchymal cells of the blastema. HABP appears, therefore, accumulated along the cell surface, indicating that hyaluronate coats these embryonic‐like cells and their antigens. The high level of hyaluronate in the blastema, aside favoring tissue hydration, cell movements, and remodeling for blastema formation and growth, likely elicits a protection from the possible immune‐reaction of lymphocytes and macrophages to embryonic‐fetal‐like antigens present on the surface of blastema and epidermal cells. Their survival, therefore, allows the continuous multiplication of these cells in regions rich in hyaluronate, promoting the regeneration of a new tail or limbs. The study suggests that organ regeneration in vertebrates is only possible in the presence of high hyaluronate content and hydration. These two conditions facilitate cell movement, immune‐protection, and activate the Wnt signaling pathway, like during development.     

Three-dimensional bioprinting of stem cell-derived central nervous system cells enables astrocyte growth,vasculogenesis, and enhances neural differentiation/function

Current research tools for preclinical drug development such as rodent models and two-dimensional immortalized monocultures have failed to serve as effective translational models for human central nervous system (CNS) disorders. Recent advancements in the development of induced pluripotent stem cells (iPSCs) and three-dimensional (3D) culturing can improve the in vivo-relevance of preclinical models, while generating 3D cultures though novel bioprinting technologies can offer increased scalability and replicability. As such, there is a need to develop platforms that combine iPSC-derived cells with 3D bioprinting to produce scalable, tunable, and biomimetic cultures for preclinical drug discovery applications. We report a biocompatible poly(ethylene glycol)-based matrix which incorporates Arg-Gly-Asp and Tyr-Ile-Gly-Ser-Arg peptide motifs and full-length collagen IV at a stiffness similar to the human brain (1.5 kPa). Using a high-throughput commercial bioprinter we report the viable culture and morphological development of monocultured iPSC-derived astrocytes, brain microvascular endothelial-like cells, neural progenitors, and neurons in our novel matrix. We also show that this system supports endothelial-like vasculogenesis and enhances neural differentiation and spontaneous activity. This platform forms a foundation for more complex, multicellular models to facilitate high-throughput translational drug discovery for CNS disorders.     

Optimization and characterization of sertaconazole nitrate flexisomes embedded in hydrogel for improved antifungal activity

The aim of the present research work was to develop, characterize and optimize sertaconazole nitrate (STZN) embedded flexisomes (STZN-FS) to improve the cutaneous anti-fungal activity of STZN. Flexisomes are self-aggregating, flexible, deformable lipidic vesicles possessing an aqueous core. A 3² factorial design was implemented to optimize the effects of the critical material attributes of concentration of phospholipid (X₁) and edge activator (X₂) on the critical quality attributes of particle size (Y₁), entrapment efficiency (Y₂), and deformability index (Y₃). Statistical analysis was performed to be identify the best fit model and determine its significance. The sizes of the optimized STZN-FS were found to be 246.2?±?2.49?nm with entrapment efficiencies of 86.16?±?0.56% and deformability indices of 30.46?±?0.41. Zeta potential analysis showed negatively charged surface with a zeta potential value of ?30.9?mV. TEM analysis showed spherical shapes, confirming the vesicular characteristics. The optimized STZN-FS were further formulated into hydrogels. The % drug diffusion of STZN-FS hydrogels was found to be 13.24% and drug deposition in the skin layers was found to be 83.54%, showing that a high concentration of the drug was available at the site of action. The zone of inhibition STZN-FS hydrogel (30?mm) was higher than the marketed formulation (22?mm) and the plain STZN hydrogel (14?mm) against Candida albicans. From the above studies, it was concluded that STZN loaded STZN-FS shows high flexibility and enhanced antifungal activity. STZN-FS are thus found to be potential carriers for drug deposition in skin layers without disturbing their integrity.     

Enhanced infarct myocardium repair mediated by thermosensitive copolymer hydrogel-based stem cell transplantation

Mesenchymal stem cell (MSC) transplantation by intramyocardial injection has been proposed as a promising therapy strategy for cardiac repair after myocardium infarction. However, low retention and survival of grafted MSCs hinder its further application. In this study, copolymer with N-isopropylacrylamide/acrylic acid/2-hydroxylethyl methacrylate-poly(ɛ-caprolactone) ratio of 88:9.6:2.4 was bioconjugated with type I collagen to construct a novel injectable thermosensitive hydrogel. The injectable and biocompatible hydrogel-mediated MSC transplantation could enhance the grafted cell survival in the myocardium, which contributed to the increased neovascularization, decreased interstitial fibrosis, and ultimately improved heart function to a significantly greater degree than regular MSC transplantation. We suggest that this novel hydrogel has the potential for future stem cell transplantation.     

FRET Imaging in Three-dimensional Hydrogels

Imaging of Förster resonance energy transfer (FRET) is a powerful tool for examining cell biology in real-time. Studies utilizing FRET commonly employ two-dimensional (2D) culture, which does not mimic the three-dimensional (3D) cellular microenvironment. A method to perform quenched emission FRET imaging using conventional widefield epifluorescence microscopy of cells within a 3D hydrogel environment is presented. Here an analysis method for ratiometric FRET probes that yields linear ratios over the probe activation range is described. Measurement of intracellular cyclic adenosine monophosphate (cAMP) levels is demonstrated in chondrocytes under forskolin stimulation using a probe for EPAC1 activation (ICUE1) and the ability to detect differences in cAMP signaling dependent on hydrogel material type, herein a photocrosslinking hydrogel (PC-gel, polyethylene glycol dimethacrylate) and a thermoresponsive hydrogel (TR-gel). Compared with 2D FRET methods, this method requires little additional work. Laboratories already utilizing FRET imaging in 2D can easily adopt this method to perform cellular studies in a 3D microenvironment. It can further be applied to high throughput drug screening in engineered 3D microtissues. Additionally, it is compatible with other forms of FRET imaging, such as anisotropy measurement and fluorescence lifetime imaging (FLIM), and with advanced microscopy platforms using confocal, pulsed, or modulated illumination.