School of Chemical and Material Engineering, Jiangnan University, Wuxi 214122, China.
School of Chemical and Material Engineering, Jiangnan University, Wuxi 214122, China; Key Laboratory of Food Colloids and Biotechnology, Ministry of Education, Wuxi 214122, China.
Biosens Bioelectron. 2016 May 15;79:457-66. doi: 10.1016/j.bios.2015.12.092. Epub 2015 Dec 25.
Graphene aerogel has attracted increasing attention due to its large specific surface area, high-conductivity and electronic interaction. The paper reported a facile synthesis of nitrogen-doped multiple graphene aerogel/gold nanostar (termed as N-doped MGA/GNS) and its use as the electrochemical sensing platform for detection of double stranded (dsDNA). On the one hand, the N-doped MGA offers a much better electrochemical performance compared with classical graphene aerogel. Interestingly, the performance can be enhanced by only increasing the cycle number of graphene oxide gelation. On the other hand, the hybridization with GNS further enhances the electrocatalytic activity towards Fe(CN)6(3-/4-). In addition, the N-doped MGA/GNS provides a well-defined three-dimensional architecture. The unique structure make it is easy to combine with dsDNA to form the electroactive bioconjugate. The integration not only triggers an ultrafast DNA electron and charge transfer, but also realizes a significant synergy between N-doped MGA, GNS and dsDNA. As a result, the electrochemical sensor based on the hybrid exhibits highly sensitive differential pulse voltammetric response (DPV) towards dsDNA. The DPV signal linearly increases with the increase of dsDNA concentration in the range from 1.0×10(-)(21) g ml(-)(1) to 1.0×10(-16) g ml(-1) with the detection limit of 3.9×10(-22) g ml(-1) (S/N=3). The sensitivity is much more than that of all reported DNA sensors. The analytical method was successfully applied in the electrochemical detection of circulating free DNA in human serum. The study also opens a window on the electrical properties of multiple graphene aerogel and DNA as well their hybrids to meet the needs of further applications as special nanoelectronics in molecule diagnosis, bioanalysis and catalysis.
石墨烯气凝胶因其大的比表面积、高导电性和电子相互作用而受到越来越多的关注。本文报道了一种简便的氮掺杂多石墨烯气凝胶/金纳米星(称为 N-掺杂 MGA/GNS)的合成方法及其作为电化学传感平台用于检测双链 DNA(dsDNA)。一方面,与经典的石墨烯气凝胶相比,N-掺杂 MGA 提供了更好的电化学性能。有趣的是,仅通过增加氧化石墨烯凝胶化的循环数即可增强性能。另一方面,与 GNS 杂交进一步增强了对 Fe(CN)6(3-/4-)的电催化活性。此外,N-掺杂 MGA/GNS 提供了一种明确的三维结构。独特的结构使其易于与 dsDNA 结合形成电活性生物缀合物。这种整合不仅引发了超快的 DNA 电子和电荷转移,而且还实现了 N-掺杂 MGA、GNS 和 dsDNA 之间的显著协同作用。结果,基于杂交的电化学传感器对 dsDNA 表现出高度灵敏的差分脉冲伏安法(DPV)响应。DPV 信号随 dsDNA 浓度在 1.0×10(-)(21) g ml(-)(1)至 1.0×10(-16) g ml(-1)范围内线性增加,检测限为 3.9×10(-22) g ml(-1)(S/N=3)。灵敏度远高于所有报道的 DNA 传感器。该分析方法成功应用于人血清中循环游离 DNA 的电化学检测。该研究还为多石墨烯气凝胶和 DNA 及其杂交物的电学性质开辟了一扇窗户,以满足作为特殊纳米电子器件在分子诊断、生物分析和催化方面的进一步应用的需求。
