3D Macro-Micro-Mesoporous FeC2O4/Graphene Hydrogel Electrode for High-Performance 2.5 V Aqueous Asymmetric Supercapacitors

Distinguished from commonly used Fe2O3 and Fe3O4,a three-dimensional multilevel macromicro-mesoporous structure of FeC2O4/graphene composite has been prepared as binderfree electrode for supercapacitors.The as-prepared materials are composed of macroporous graphene and microporous/mesoporous ferrous oxalate.Generally,the decomposition voltage of water is 1.23 V and the practical voltage window limit is about 2 V for asymmetric supercapacitors in aqueous electrolytes.When FeC2O4/rGO hydrogel was used as the negative electrode and a pure rGO hydrogel was used as the positive electrode,the asymmetrical supercapacitor voltage window raised to 1.7 V in KOH(1.0 mol/L)electrolyte and reached up to 2.5 V in a neutral aqueous Na2SO4(1.0 mol/L)electrolyte.Correspondingly it also exhibits a high performance with an energy density of 59.7 Wh/kg.By means of combining a metal oxide that owns micro-mesoporous structure with graphene,this work provides a new opportunity for preparing high-voltage aqueous asymmetric supercapacitors without addition of conductive agent and binder.

3D ECM凝胶支架对干细胞或祖细胞来源心脏细胞行为的影响

细胞外基质(extracellular matrix,ECM)是一种高度动态的结构,参与细胞增殖、迁移和分化等的调节过程。利用ECM构建的三维(three dimension,3D)培养体系能够模拟体内微环境,促进干细胞或祖细胞来源诱导性心肌细胞(induced cardiomyocytes,iCMs)的成熟和功能化;ECM与3D打印相结合能够促进心脏类器官的生成和应用;外科移植ECM补丁至受损心脏有利于改善其结构和功能。但体内、外研究表明,心脏修复的整体效率低下,ECM与细胞间的作用机制有待进一步探究。该文综述了ECM的组成、重构和功能,水凝胶的成分(ECM来源、组成比例)和弹性模量以及微脉管系统等对3D培养体系中心脏细胞行为的影响,阐述了ECM在3D打印技术和受损心脏体内修复中的应用,为心脏再生修复、疾病模型构建、药物筛选和发育机理探讨等研究奠定基础。

基于原代肺癌细胞3D培养模型的建立及其药物敏感性研究

目的构建基于原代肺癌细胞的3D水凝胶培养模型并研究其在抗肿瘤药物敏感性测试中的应用。方法采用条件性重编程技术培养患者来源的肺癌细胞;利用海藻酸钠与钙离子凝胶反应原理构建海藻酸钠-透明质酸3D微球培养原代肺癌细胞;应用扫描电子显微镜观察3D微球的结构;流式细胞术检测细胞周期分布;Transwell实验考察细胞的迁移和侵袭能力;MTS法检测原代肺癌细胞经顺铂、卡铂、紫杉醇、多西他赛、长春瑞滨、扁塑藤素等药物处理后的细胞活力;Caspase-3活力检测试剂盒检测细胞内Caspase-3含量;Western blot实验检测细胞蛋白表达水平的变化。结果海藻酸钠-透明质酸微球内部呈均匀多孔结构,3D培养的原代肺癌细胞以细胞团形式生长。与2D培养方式相比,3D微球培养的原代肺癌细胞G0/G1期细胞阻滞增多,增殖速率变低,迁移和侵袭能力增强,肿瘤干细胞标志物表达显著提升,对抗肿瘤药物敏感性下降,且细胞抗凋亡能力增强;此外,与2D培养的细胞相比,3D微球培养的原代肺癌细胞Akt/GSK3β通路激活水平显著升高。结论3D水凝胶细胞培养能够更好地模拟体内肺癌肿瘤组织的生长特点和微环境,客观反映体内肺癌肿瘤组织对药物的反应过程,有利于更准确地体外评估抗肿瘤药物的敏感性。