Abstract
Single particle tracking (SPT) is one of the most widely used tools in optical microscopy to evaluate particle mobility in a variety of situations, including cellular and model membrane dynamics. Recent technological developments, such as Interferometric Scattering microscopy, have allowed recording of long, uninterrupted single particle trajectories at kilohertz framerates. The resulting data, where particles are continuously detected and do not displace much between observations, thereby do not require complex linking algorithms. Moreover, while these measurements offer more details into the short-term diffusion behaviour of the tracked particles, they are also subject to the influence of localisation uncertainties, which are often underestimated by conventional analysis pipelines. we thus developed a Python library, under the name of TRAIT2D (Tracking Analysis Toolbox - 2D version), in order to track particle diffusion at high sampling rates, and analyse the resulting trajectories with an innovative approach. The data analysis pipeline introduced is more localisation-uncertainty aware, and also selects the most appropriate diffusion model for the data provided on a statistical basis. A trajectory simulation platform also allows the user to handily generate trajectories and even synthetic time-lapses to test alternative tracking algorithms and data analysis approaches. A high degree of customisation for the analysis pipeline, for example with the introduction of different diffusion modes, is possible from the source code. Finally, the presence of graphical user interfaces lowers the access barrier for users with little to no programming experience.
Highlights
While this is not a review article, it seems that the introduction ignores a large body of literature and code on Single particle tracking (SPT) and STA
The particles are detected using spot enhancing filter (SEF)32 and sub-pixel localisation is estimated by the radial symmetry centre approach
The combination of particle tracking, simulation, and trajectory analysis in the same package provides a number of benefits for the user
Summary
We state clearly, following reviewer’s feedback, that in analyzing Brownian diffusing particles’ motion, software users should take care in using an appropriate number of data points More information about this topic can be found in the expanded list of references, which will guide them toward a more detailed understanding of the theory underlying Single Particle Tracking and the analysis of experimental data collected thereof. The use of large scattering tags is nowadays not necessary anymore to reach nanometer levels of localisation precision.7,8 The rise of such SPT-capable techniques, characterized by fast sampling and high data throughput, generates the need to adapt previously developed tracking and analysis pipelines. We added the possibility of generating movies from the simulated trajectories with variable levels of contrast, and a user-specified Point Spread Function This last module can serve as a validation tool of further particle tracking and analysis pipelines
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