Plesa C, van Loo N, Dekker C
Department of Bionanoscience, Kavli Institute of Nanoscience, Delft University of Technology, Lorentzweg 1, 2628 CJ Delft, The Netherlands.
Nanoscale. 2015 Aug 28;7(32):13605-9. doi: 10.1039/c5nr02793d. Epub 2015 Jul 24.
Nanopore experiments have traditionally been carried out with chloride-based solutions. Here we introduce silver/silver-glutamate-based electrochemistry as an alternative, and study the viscosity, conductivity, and nanopore translocation characteristics of potassium-, sodium-, and lithium-glutamate solutions. We show that it has a linear response at typical voltages and can be used to detect DNA translocations through a nanopore. The glutamate anion also acts as a redox-capable thickening agent, with high-viscosity solutions capable of slowing down the DNA translocation process by up to 11 times, with a corresponding 7 time reduction in signal. These results demonstrate that glutamate can replace chloride as the primary anion in nanopore resistive pulse sensing.
传统上,纳米孔实验是在基于氯化物的溶液中进行的。在此,我们引入基于银/银-谷氨酸的电化学方法作为替代方案,并研究了谷氨酸钾、谷氨酸钠和谷氨酸锂溶液的粘度、电导率和纳米孔转运特性。我们表明,它在典型电压下具有线性响应,可用于检测DNA通过纳米孔的转运。谷氨酸阴离子还充当具有氧化还原能力的增稠剂,高粘度溶液能够使DNA转运过程减慢多达11倍,信号相应降低7倍。这些结果表明,谷氨酸可以替代氯化物作为纳米孔电阻脉冲传感中的主要阴离子。