Single-molecule techniques in biophysics: a review of the progress in methods and applications
Helen Miller, Zhaokun Zhou, Jack Shepherd, Adam J. M. Wollman, and, Mark C. Leake

TL;DR
This review discusses recent advances in single-molecule biophysics techniques, highlighting their ability to reveal molecular heterogeneity and complex dynamics in biological systems across multiple scales.
Contribution
It provides a comprehensive overview of new experimental and theoretical methods that enhance the study of single molecules in biological contexts.
Findings
Advances in detector sensitivity enable detection of heterogeneous behaviors.
Development of multiplexed techniques allows complex biological problems to be addressed.
Single-molecule methods reveal dynamic inter-conversion kinetics in biological molecules.
Abstract
Single-molecule biophysics has transformed our understanding of the fundamental molecular processes involved in living biological systems, but also of the fascinating physics of life. Far more exotic than a collection of exemplars of soft matter behaviour, active biological matter lives far from thermal equilibrium, and typically covers multiple length scales from the nanometre level of single molecules up several orders of magnitude to longer length scales in emergent structures of cells, tissues and organisms. Biological molecules are often characterized by an underlying instability, in that multiple metastable free energy states exist which are separated by energy levels of typically just a few multiples of the thermal energy scale of kBT, where kB is the Boltzmann constant and T the absolute temperature, implying complex, dynamic inter-conversion kinetics across this bumpy free…
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