Key Laboratory for Large-Format Battery Materials and System, Ministry of Education, Hubei Key Laboratory of Material Chemistry and Service Failure, School of Chemistry and Chemical Engineering, Huazhong University of Science and Technology, Wuhan, 430074, China.
School of Physics, Huazhong University of Science and Technology, Wuhan, 430074, China.
Anal Chim Acta. 2019 Jan 24;1047:197-207. doi: 10.1016/j.aca.2018.10.008. Epub 2018 Oct 9.
This study introduces a new strategy for periodic stacking of positively charged NiAl layered double hydroxides (LDHs) nanosheets with negatively charged monolayers of graphene (G) by systematically optimizing several parameters in a controlled co-feeding fashion and resultant heterostacked NiAl LDH/G LBL nanocomposites have been practically applied in sensitive detection of dopamine released from live cells as early Parkinson's disease (PD) diagnostic tool. PD is the second most chronic neurodegenerative disorder with gradual progressive loss of movement and muscle control causing substantial disability and threatening the life seriously. Unfortunately majority of dopaminergic neurons present in substantia nigra of PD patients are destroyed before it is being clinically diagnosed, so early stages PD diagnosis is essential. Because of direct neighboring of extremely conductive graphene to semiconductive LDHs layers, enhanced intercalation capability of LDHs, and huge surface area with numerous active sites, good synergy effect is harvested in heteroassembled NiAl LDH/G LBL material, which in turn shows admirable electrocatalytic ability in DA detection. The interference induced by UA and AA is effectively eliminated especially after the modifying the electrode with Nafion. The outstanding electrochemical sensing performance of NiAl LDH/G LBL modified electrode has been achieved in terms of broad linear range and lowest real detection limit of 2 nM (S/N = 3) towards DA oxidation. Benefitting from superior efficiency, biosensor has been successfully used for real-time in-vitro tracking of DA efflux from live human nerve cell after being stimulated. We believe that our biosensing platform of structurally integrated well-ordered LBL heteroassembly by inserting graphene directly to the interlayer galleries of LDHs material will open up new avenue in diseases determination window.
本研究通过系统地优化几个参数,以受控共进料的方式引入了一种新的策略,将带正电荷的 NiAl 层状双氢氧化物(LDHs)纳米片与带负电荷的单层石墨烯(G)周期性堆叠,所得的异质堆叠 NiAl LDH/G LBL 纳米复合材料已实际应用于从活细胞中释放的多巴胺的灵敏检测,作为早期帕金森病(PD)诊断工具。PD 是第二大慢性神经退行性疾病,其运动和肌肉控制逐渐丧失,导致严重的残疾和生命威胁。不幸的是,PD 患者黑质中的多巴胺能神经元在临床上被诊断出来之前就已经大量被破坏,因此早期 PD 诊断至关重要。由于极其导电的石墨烯与半导体 LDHs 层的直接相邻,LDHs 的插层能力增强,并且具有大量的活性位点的巨大表面积,在异质组装的 NiAl LDH/G LBL 材料中收获了良好的协同效应,这反过来在 DA 检测中表现出令人钦佩的电催化能力。在修饰电极后,可以有效消除 UA 和 AA 引起的干扰,尤其是使用 Nafion 修饰电极后。在 DA 氧化方面,NiAl LDH/G LBL 修饰电极具有宽线性范围和最低实际检测限 2 nM(S/N = 3)的出色电化学传感性能。受益于高效率,生物传感器已成功用于实时跟踪刺激后活人体神经细胞中 DA 的流出。我们相信,我们的生物传感平台通过将石墨烯直接插入 LDHs 材料的层间空隙中,实现了结构整合的有序 LBL 异质组装,将为疾病确定窗口开辟新途径。
