Experimental measurement of kinetic parameters using quantum plasmonic sensing

TL;DR

This paper demonstrates that quantum plasmonic sensing with single photons can improve the precision of kinetic parameter estimation in biochemical interactions, surpassing classical methods.

Contribution

The study introduces a quantum sensing approach using single photons to measure kinetic parameters with higher precision than classical techniques.

Findings

Achieved up to 31.8% improvement in kinetic parameter precision.

Used quantum states of light to enhance biochemical sensing.

Potential for further enhancement in quantum sensing setup.

Abstract

Kinetic models are essential for describing how molecules interact in a variety of biochemical processes. The estimation of a model's kinetic parameters by experiment enables researchers to understand how pathogens, such as viruses, interact with other entities like antibodies and trial drugs. In this work, we report a simple proof-of-principle experiment that uses quantum sensing techniques to give a more precise estimation of kinetic parameters than is possible with a classical approach. The interaction we study is that of bovine serum albumin (BSA) binding to gold via an electrostatic mechanism. BSA is an important protein in biochemical research as it can be conjugated with other proteins and peptides to create sensors with a wide range of specificity. We use single photons generated via parametric down-conversion to probe the BSA-gold interaction in a plasmonic resonance sensor. We find that sub-shot-noise level fluctuations in the sensor signal allow us to achieve an improvement in the precision of up to 31.8% for the values of the kinetic parameters. This enhancement can in principle be further increased in the setup. Our work highlights the potential use of quantum states of light for sensing in biochemical research.