amounts of input material. [1,2] While the sequencing-by-synthesis technology dominates currently, this technology requires significant sample preparation and amplification steps, the use of costly biological reagents such as fluorescently labeled molecules, and expensive imaging and data handling instruments. [3][4][5][6][7] Singlemolecule sequencing, which does not require amplification and labeling steps, would simplify the entire sequencing process significantly reducing costs and time of acquiring sequencing data, and is thus more adaptable to clinical translation to enable precision medicine even from mass-limited samples such as those provided by liquid biopsies. [8] Nanopores offer a fast and low-cost sequencing platform that does not require labeling and sample amplification. [6,7,[9][10][11][12][13] The basic principle of nanopore sequencing is to electrically drive charged single molecules, either an intact DNA molecule in strand sequencing or individual nucleotides cleaved from the DNA in exonuclease sequencing, [10,[13][14][15] through a nanopore and determine the identity of each constituent nucleotide by monitoring small changes in the ionic current flowing through the pore while individual nucleotides temporarily reside within the pore (i.e., resistive pulse sensing, RPS). [13,16] Strand nanopore sequencing has demonstrated whole-genome sequencing [14] Nanoscale electrophoresis allows for unique separations of single molecules, such as DNA/RNA nucleobases, and thus has the potential to be used as single molecular sensors for exonuclease sequencing. For this to be envisioned, label-free detection of the nucleotides to determine their electrophoretic mobility (i.e., time-of-flight, TOF) for highly accurate identification must be realized. Here, for the first time a novel nanosensor is shown that allows discriminating four 2-deoxyribonucleoside 5'-monophosphates, dNMPs, molecules in a label-free manner by nanoscale electrophoresis. This is made possible by positioning two sub-10 nm in-plane pores at both ends of a nanochannel column used for nanoscale electrophoresis and measuring the longitudinal transient current during translocation of the molecules. The dual nanopore TOF sensor with 0.5, 1, and 5 µm long nanochannel column lengths discriminates different dNMPs with a mean accuracy of 55, 66, and 94%, respectively. This nanosensor format can broadly be applicable to label-free detection and discrimination of other single molecules, vesicles, and particles by changing the dimensions of the nanochannel column and in-plane nanopores and integrating different pre-and postprocessing units to the nanosensor. This is simple to accomplish because the nanosensor is contained within a fluidic network made in plastic via replication.
