Effect of pixelation on the arameter estimation of single molecule trajectories
Effect of pixelation on the arameter estimation of single molecule trajectories
The advent of single molecule microscopy has rev- olutionized biological investigations by providing a powerful tool for the study of intercellular and intracellular trafficking processes of protein molecules which was not available before through conventional microscopy. In practice, pixelated detectors are used to acquire the images of fluorescently labeled objects moving in cellular environments. Then, the acquired fluorescence microscopy images contain the numbers of the photons detected in each pixel, during an exposure time interval. Moreover, instead of having the exact locations of detection of the photons, we only know the pixel areas in which the photons impact the detector. These challenges make the analysis of single molecule trajectories, from pixelated images, a complex problem. Here, we investigate the effect of pixelation on the parameter estimation of single molecule trajectories. In particular, we develop a stochastic framework to calculate the maximum likelihood estimates of the parameters of a stochastic differential equation that describes the motion of the molecule in living cells. We also calculate the Fisher information matrix for this parameter estimation problem. The analytical results are complicated through the fact that the observation process in a microscope prohibits the use of standard Kalman filter type approaches. The analytical framework presented here is illustrated with examples of low photon count scenarios for which we rely on Monte Carlo methods to compute the associated probability distributions
Cramer-Rao lower bound, Data models, Detectors, Fisher information matrix, Image quality, Maximum likelihood estimation, Microscopy, Monte Carlo, Photonics, Pixelated detectors, Probability density function, Single molecule tracking, Stochastic differential equations, Trajectory
Ober, R.J.
31f4d47f-fb49-44f5-8ff6-87fc4aff3d36
Vahid, Milad R.
6a1a88a4-9fcc-4ac5-84a4-0d4ee1088cc6
Hanzon, Bernard
ec8a3e31-d488-4a69-8318-6ff08024dd7c
Ober, R.J.
31f4d47f-fb49-44f5-8ff6-87fc4aff3d36
Vahid, Milad R.
6a1a88a4-9fcc-4ac5-84a4-0d4ee1088cc6
Hanzon, Bernard
ec8a3e31-d488-4a69-8318-6ff08024dd7c
Ober, R.J., Vahid, Milad R. and Hanzon, Bernard
(2020)
Effect of pixelation on the arameter estimation of single molecule trajectories.
IEEE Transactions on Computational Imaging.
(doi:10.1109/TCI.2020.3039951).
Abstract
The advent of single molecule microscopy has rev- olutionized biological investigations by providing a powerful tool for the study of intercellular and intracellular trafficking processes of protein molecules which was not available before through conventional microscopy. In practice, pixelated detectors are used to acquire the images of fluorescently labeled objects moving in cellular environments. Then, the acquired fluorescence microscopy images contain the numbers of the photons detected in each pixel, during an exposure time interval. Moreover, instead of having the exact locations of detection of the photons, we only know the pixel areas in which the photons impact the detector. These challenges make the analysis of single molecule trajectories, from pixelated images, a complex problem. Here, we investigate the effect of pixelation on the parameter estimation of single molecule trajectories. In particular, we develop a stochastic framework to calculate the maximum likelihood estimates of the parameters of a stochastic differential equation that describes the motion of the molecule in living cells. We also calculate the Fisher information matrix for this parameter estimation problem. The analytical results are complicated through the fact that the observation process in a microscope prohibits the use of standard Kalman filter type approaches. The analytical framework presented here is illustrated with examples of low photon count scenarios for which we rely on Monte Carlo methods to compute the associated probability distributions
Text
Two-column_manuscript[1]
- Accepted Manuscript
More information
Accepted/In Press date: 15 October 2020
e-pub ahead of print date: 23 November 2020
Additional Information:
Publisher Copyright:
CCBY
Copyright:
Copyright 2020 Elsevier B.V., All rights reserved.
Keywords:
Cramer-Rao lower bound, Data models, Detectors, Fisher information matrix, Image quality, Maximum likelihood estimation, Microscopy, Monte Carlo, Photonics, Pixelated detectors, Probability density function, Single molecule tracking, Stochastic differential equations, Trajectory
Identifiers
Local EPrints ID: 445440
URI: http://eprints.soton.ac.uk/id/eprint/445440
ISSN: 2333-9403
PURE UUID: 3cf21dc4-6bed-4a75-a9d9-13a3bada9251
Catalogue record
Date deposited: 09 Dec 2020 17:30
Last modified: 17 Mar 2024 06:07
Export record
Altmetrics
Contributors
Author:
Milad R. Vahid
Author:
Bernard Hanzon
Download statistics
Downloads from ePrints over the past year. Other digital versions may also be available to download e.g. from the publisher's website.
View more statistics
