Single-Objective Evanescent Scattering Microscopy for Imaging Single Proteins and Binding Kinetics

Abstract

AbstractPlasmonic scattering microscopy has advanced the evanescent detection approaches by offering wide-field single-molecule imaging capability. However, two limitations prevent the broader application of plasmonic single-molecule imaging. One is the heating effect accompanying the plasmonic enhancement, and the other is the complicated system structure resulting from the two-objective optical arrangement. Here, we report single-objective evanescent scattering microscopy. The evanescent field is created by total internal reflection instead of the surface plasmon resonance on the gold film. As a result, the sensing substrate without gold film produces little heat, and allows excitation and observation using one objective. In addition, this system enables quantification of protein binding kinetics by simultaneously counting the binding of individual molecules and recording their binding sites with nanometer precision, providing a digital method to measure binding kinetics with high spatiotemporal resolution. This work may pave a road for label-free single protein analysis in conventional microscopy.TeaserLabel-free single-molecule imaging on a total internal reflection fluorescence objective.