Revealing Ionic Signal Enhancement with Probe Grafting Density on the Outer Surface of Nanochannels

Probe-modified nanopores/nanochannels are one of the most advanced sensors because the probes interact strongly with ions and targets in nanoconfinement and create a sensitive and selective ionic signal. Recently, ionic signals have been demonstrated to be sensitive to the probe-target interaction on the outer surface of nanopores/nanochannels, which can offer more open space for target recognition and signal conversion than nanoconfined cavities. To enhance the ionic signal, we investigated the effect of grafting density, a critical parameter of the sensing interface, of the probe on the outer surface of nanochannels on the change rate of the ionic signal before and after target recognition (beta). Electroneutral peptide nucleic acids and negatively charged DNA are selected as probes and targets, respectively. The experimental results showed that when adding the same number of targets, the beta value increased with the probe grafting density on the outer surface. A theoretical model with clearly defined physical properties of each probe and target has been established. Numerical simulations suggest that the decrease of the background current and the aggregation of targets at the mouth of nanochannels with increasing probe grafting density contribute to this enhancement. This work reveals the signal mechanism of probe-target recognition on the outer surface of nanochannels and suggests a general approach to the nanochannel/nanopore design leading to sensitivity improvement on the basis of relatively good selectivity.

Automated summary

This study investigates the impact of probe grafting density on the outer surface of nanochannels on the change rate of ionic signals before and after target recognition. The experimental results show that with the same number of targets, the beta value increases with the probe grafting density. A theoretical model is established with clearly defined physical properties of each probe and target, while numerical simulations suggest that background current decrease and target aggregation contribute to signal enhancement. This work reveals the signal mechanism of probe-target recognition and suggests a general approach to sensitive nanochannel/nanopore design with good selectivity.