Tissue Engineering Research Group (TERG), Department of Anatomy, School of Pharmacy and Department of MCT, Royal College of Surgeons in Ireland, Dublin 2, Ireland.
Advanced Materials and Bioengineering Research (AMBER) Centre, Trinity College Dublin, Ireland and Royal College of Surgeons in Ireland, Dublin 2, Ireland.
Adv Mater. 2018 Apr;30(15):e1706442. doi: 10.1002/adma.201706442. Epub 2018 Mar 5.
Electroconductive substrates are emerging as promising functional materials for biomedical applications. Here, the development of biohybrids of collagen and pristine graphene that effectively harness both the biofunctionality of the protein component and the increased stiffness and enhanced electrical conductivity (matching native cardiac tissue) obtainable with pristine graphene is reported. As well as improving substrate physical properties, the addition of pristine graphene also enhances human cardiac fibroblast growth while simultaneously inhibiting bacterial attachment (Staphylococcus aureus). When embryonic-stem-cell-derived cardiomyocytes (ESC-CMs) are cultured on the substrates, biohybrids containing 32 wt% graphene significantly increase metabolic activity and cross-striated sarcomeric structures, indicative of the improved substrate suitability. By then applying electrical stimulation to these conductive biohybrid substrates, an enhancement of the alignment and maturation of the ESC-CMs is achieved. While this in vitro work has clearly shown the potential of these materials to be translated for cardiac applications, it is proposed that these graphene-based biohybrid platforms have potential for a myriad of other applications-particularly in electrically sensitive tissues, such as neural and neural and musculoskeletal tissues.
导电基底作为有前途的生物医学应用功能材料而崭露头角。在这里,我们开发了胶原蛋白和原始石墨烯的生物杂交材料,有效地利用了蛋白质成分的生物功能,以及原始石墨烯带来的增加的刚性和增强的导电性(与天然心脏组织匹配)。除了改善基底的物理性质外,添加原始石墨烯还可以增强人心脏成纤维细胞的生长,同时抑制细菌附着(金黄色葡萄球菌)。当胚胎干细胞衍生的心肌细胞(ESC-CMs)在这些基底上培养时,含有 32wt%石墨烯的生物杂交材料显著提高了代谢活性和横纹肌结构,表明基底的适用性得到了改善。然后,通过对这些导电生物杂交基底施加电刺激,实现了 ESC-CMs 的取向和成熟的增强。虽然这项体外工作清楚地表明了这些材料在心脏应用方面具有转化的潜力,但据推测,这些基于石墨烯的生物杂交平台具有多种其他应用的潜力——特别是在神经和肌肉骨骼组织等对电敏感的组织中。
