International audienceTracking single molecules in living cells provides invaluable information on their environment and on the interactions that underlie their motion. New experimental techniques now permit the recording of large amounts of individual trajectories, enabling the implementation of advanced statistical tools for data analysis. In this primer, we present a Bayesian approach toward treating these data, and we discuss how it can be fruitfully employed to infer physical and biochemical parameters from single-molecule trajectories
The advent of single molecule microscopy has rev- olutionized biological investigations by providing...
Free to read at publisher The movement of molecules inside living cells is a fundamental feature of ...
AbstractWe propose here an approach for the analysis of single-molecule trajectories which is based ...
Membrane proteins move in heterogeneous environments with spatially (sometimes temporally) varying f...
Membrane proteins move in heterogeneous environments with spatially (sometimes temporally) varying f...
Quantitative tracking of particle motion using live-cell imaging is a powerful approach to understan...
AbstractThe ability to measure the properties of proteins at the single-molecule level offers an unp...
AbstractQuantitative tracking of particle motion using live-cell imaging is a powerful approach to u...
Fluorescence microscopy is a powerful technique for understanding the organization, structure and dy...
Using fluorescence microscopy with single molecule sensitivity it is now possible to follow the move...
Single particle tracking (SPT) enables the investigation of biomolecular dynamics at a high temporal...
Diffusing membrane constituents are constantly exposed to a variety of forces that influence their s...
AbstractSingle molecule tracking is widely used to monitor the change in position of lipids and prot...
Single-Particle Tracking (SPT) in living cells informs the dynamics of target molecules and enables ...
International audienceCurrently used techniques for the analysis of single-molecule trajectories onl...
The advent of single molecule microscopy has rev- olutionized biological investigations by providing...
Free to read at publisher The movement of molecules inside living cells is a fundamental feature of ...
AbstractWe propose here an approach for the analysis of single-molecule trajectories which is based ...
Membrane proteins move in heterogeneous environments with spatially (sometimes temporally) varying f...
Membrane proteins move in heterogeneous environments with spatially (sometimes temporally) varying f...
Quantitative tracking of particle motion using live-cell imaging is a powerful approach to understan...
AbstractThe ability to measure the properties of proteins at the single-molecule level offers an unp...
AbstractQuantitative tracking of particle motion using live-cell imaging is a powerful approach to u...
Fluorescence microscopy is a powerful technique for understanding the organization, structure and dy...
Using fluorescence microscopy with single molecule sensitivity it is now possible to follow the move...
Single particle tracking (SPT) enables the investigation of biomolecular dynamics at a high temporal...
Diffusing membrane constituents are constantly exposed to a variety of forces that influence their s...
AbstractSingle molecule tracking is widely used to monitor the change in position of lipids and prot...
Single-Particle Tracking (SPT) in living cells informs the dynamics of target molecules and enables ...
International audienceCurrently used techniques for the analysis of single-molecule trajectories onl...
The advent of single molecule microscopy has rev- olutionized biological investigations by providing...
Free to read at publisher The movement of molecules inside living cells is a fundamental feature of ...
AbstractWe propose here an approach for the analysis of single-molecule trajectories which is based ...