An electrical resistance-based particle counter (ERPC) with simpleoperation and high resolution has proved to be a promising biosensing toolkit, whereas amplification-free ERPC biosensors are incapable of analyzing trace smallmolecules due to their relatively low sensitivity. In this work, click chemistry-mediated particle counting sensing of small-molecule hazards in food samples with high sensitivity was developed. In this strategy, unbound alkyne-functionalized polystyrene microspheres were collected by magnetic separation from the copper-ion-mediated click reaction between alkyne-functionalized polystyrene microspheresand azido-functionalized magnetic beads, which could be used as signal probes forthe readout. This click chemistry-mediated ERPC biosensor converts the detectionof targets to the quantification of copper ions or ascorbic acid by performingcompetitive immunoassay-based coordination chemistry and enzymatic reaction ,respectively. The sensitivity of the ERPC biosensor has been improved by an order of magnitude due to the signal amplification effects of click chemistry, coordination adsorption, and enzyme catalysis. Furthermore, because of the efficient separation and enrichment of immunomagnetic beads and the robustness of click chemistry, the interference from food matrixes and immunoassay is effectively reduced, and thus, our strategy is exceedingly suitable for detecting trace targets in complex samples

• Institution
  华中农业大学