Investigating optimal time step intervals of imaging for data quality through a novel fully-automated cell tracking approach

Feng Wei Yang; Lea Tomášová; Zeno v. Guttenberg; Ke Chen; Anotida Madzvamuse

doi:10.3390/JIMAGING6070066

Investigating optimal time step intervals of imaging for data quality through a novel fully-automated cell tracking approach

Feng Wei Yang^*, Lea Tomášová, Zeno v. Guttenberg, Ke Chen, Anotida Madzvamuse^*

^*Corresponding author for this work

Mathematics And Statistics

Research output: Contribution to journal › Article › peer-review

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Abstract

Computer-based fully-automated cell tracking is becoming increasingly important in cell biology, since it provides unrivalled capacity and efficiency for the analysis of large datasets. However, automatic cell tracking’s lack of superior pattern recognition and error-handling capability compared to its human manual tracking counterpart inspired decades-long research. Enormous efforts have been made in developing advanced cell tracking packages and software algorithms. Typical research in this field focuses on dealing with existing data and finding a best solution. Here, we investigate a novel approach where the quality of data acquisition could help improve the accuracy of cell tracking algorithms and vice-versa. Generally speaking, when tracking cell movement, the more frequent the images are taken, the more accurate cells are tracked and, yet, issues such as damage to cells due to light intensity, overheating in equipment, as well as the size of the data prevent a constant data streaming. Hence, a trade-off between the frequency at which data images are collected and the accuracy of the cell tracking algorithms needs to be studied. In this paper, we look at the effects of different choices of the time step interval (i.e., the frequency of data acquisition) within the microscope to our existing cell tracking algorithms. We generate several experimental data sets where the true outcomes are known (i.e., the direction of cell migration) by either using an effective chemoattractant or employing no-chemoattractant. We specify a relatively short time step interval (i.e., 30 s) between pictures that are taken at the data generational stage, so that, later on, we may choose some portion of the images to produce datasets with different time step intervals, such as 1 min, 2 min, and so on. We evaluate the accuracy of our cell tracking algorithms to illustrate the effects of these different time step intervals. We establish that there exist certain relationships between the tracking accuracy and the time step interval associated with experimental microscope data acquisition. We perform fully-automatic adaptive cell tracking on multiple datasets, to identify optimal time step intervals for data acquisition, while at the same time demonstrating the performance of the computer cell tracking algorithms.

Original language	English
Article number	66
Number of pages	16
Journal	Journal of Imaging
Volume	6
Issue number	7
DOIs	https://doi.org/10.3390/JIMAGING6070066
Publication status	Published - 7 Jul 2020

Funding

Acknowledgments: (F.W.Y., L.T., Z.v.G., A.M.) would like to thank the Isaac Newton Institute for Mathematical Sciences for its hospitality during the programme [Coupling Geometric PDEs with Physics for Cell Morphology, Motility and Pattern Formation] supported by EPSRC Grant Number EP/K032208/1. (F.W.Y., K.C.) would like to thank Pump Priming funding from the Centre for Mathematics in Healthcare at the University of Liverpool to enable the research collaboration. AM is a Distinguished Visiting Scholar to the Department of Mathematics, University of Johannesburg, South Africa. Funding: This research (L.T., Z.v.G., A.M.) was funded by the European Union Horizon 2020 research and innovation programme under the Marie Skłodowska-Curie grant agreement No 642866. This work (A.M.) was partially funded by the EPSRC grant number EP/J016780/1 and the Leverhulme Trust Research Project Grant (RPG-2014-149), the Commission for Developing Countries, and by a grant from the Simons Foundation. A.M. is a Royal Society Wolfson Research Merit Award Holder funded generously by the Wolfson Foundation. F.W.Y. is funded by EPSRC EP/R001588/1. This research (L.T., Z.v.G., A.M.) was funded by the European Union Horizon 2020 research and innovation programme under the Marie Sk?odowska-Curie grant agreement No 642866. This work (A.M.) was partially funded by the EPSRC grant number EP/J016780/1 and the Leverhulme Trust Research Project Grant (RPG-2014-149), the Commission for Developing Countries, and by a grant from the Simons Foundation. A.M. is a Royal Society Wolfson Research Merit Award Holder funded generously by the Wolfson Foundation. F.W.Y. is funded by EPSRC EP/R001588/1.

Keywords

chemotaxis
directed cell migration
fully-automated cell tracking
microscope data acquisition
optimal time step intervals
particle tracking
phase-contrast microscopy
segmentation
tracking accuracy

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10.3390/JIMAGING6070066Licence: CC BY 4.0

Yang-etal-JI-2020-Investigating-optimal-time-step-intervals-of-imaging-for-data-qualityFinal published version, 7.6 MBLicence: CC BY 4.0

Cite this

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title = "Investigating optimal time step intervals of imaging for data quality through a novel fully-automated cell tracking approach",

abstract = "Computer-based fully-automated cell tracking is becoming increasingly important in cell biology, since it provides unrivalled capacity and efficiency for the analysis of large datasets. However, automatic cell tracking{\textquoteright}s lack of superior pattern recognition and error-handling capability compared to its human manual tracking counterpart inspired decades-long research. Enormous efforts have been made in developing advanced cell tracking packages and software algorithms. Typical research in this field focuses on dealing with existing data and finding a best solution. Here, we investigate a novel approach where the quality of data acquisition could help improve the accuracy of cell tracking algorithms and vice-versa. Generally speaking, when tracking cell movement, the more frequent the images are taken, the more accurate cells are tracked and, yet, issues such as damage to cells due to light intensity, overheating in equipment, as well as the size of the data prevent a constant data streaming. Hence, a trade-off between the frequency at which data images are collected and the accuracy of the cell tracking algorithms needs to be studied. In this paper, we look at the effects of different choices of the time step interval (i.e., the frequency of data acquisition) within the microscope to our existing cell tracking algorithms. We generate several experimental data sets where the true outcomes are known (i.e., the direction of cell migration) by either using an effective chemoattractant or employing no-chemoattractant. We specify a relatively short time step interval (i.e., 30 s) between pictures that are taken at the data generational stage, so that, later on, we may choose some portion of the images to produce datasets with different time step intervals, such as 1 min, 2 min, and so on. We evaluate the accuracy of our cell tracking algorithms to illustrate the effects of these different time step intervals. We establish that there exist certain relationships between the tracking accuracy and the time step interval associated with experimental microscope data acquisition. We perform fully-automatic adaptive cell tracking on multiple datasets, to identify optimal time step intervals for data acquisition, while at the same time demonstrating the performance of the computer cell tracking algorithms.",

keywords = "chemotaxis, directed cell migration, fully-automated cell tracking, microscope data acquisition, optimal time step intervals, particle tracking, phase-contrast microscopy, segmentation, tracking accuracy",

author = "Yang, {Feng Wei} and Lea Tom{\'a}{\v s}ov{\'a} and Guttenberg, {Zeno v.} and Ke Chen and Anotida Madzvamuse",

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AU - Yang, Feng Wei

AU - Tomášová, Lea

AU - Guttenberg, Zeno v.

AU - Chen, Ke

AU - Madzvamuse, Anotida

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AB - Computer-based fully-automated cell tracking is becoming increasingly important in cell biology, since it provides unrivalled capacity and efficiency for the analysis of large datasets. However, automatic cell tracking’s lack of superior pattern recognition and error-handling capability compared to its human manual tracking counterpart inspired decades-long research. Enormous efforts have been made in developing advanced cell tracking packages and software algorithms. Typical research in this field focuses on dealing with existing data and finding a best solution. Here, we investigate a novel approach where the quality of data acquisition could help improve the accuracy of cell tracking algorithms and vice-versa. Generally speaking, when tracking cell movement, the more frequent the images are taken, the more accurate cells are tracked and, yet, issues such as damage to cells due to light intensity, overheating in equipment, as well as the size of the data prevent a constant data streaming. Hence, a trade-off between the frequency at which data images are collected and the accuracy of the cell tracking algorithms needs to be studied. In this paper, we look at the effects of different choices of the time step interval (i.e., the frequency of data acquisition) within the microscope to our existing cell tracking algorithms. We generate several experimental data sets where the true outcomes are known (i.e., the direction of cell migration) by either using an effective chemoattractant or employing no-chemoattractant. We specify a relatively short time step interval (i.e., 30 s) between pictures that are taken at the data generational stage, so that, later on, we may choose some portion of the images to produce datasets with different time step intervals, such as 1 min, 2 min, and so on. We evaluate the accuracy of our cell tracking algorithms to illustrate the effects of these different time step intervals. We establish that there exist certain relationships between the tracking accuracy and the time step interval associated with experimental microscope data acquisition. We perform fully-automatic adaptive cell tracking on multiple datasets, to identify optimal time step intervals for data acquisition, while at the same time demonstrating the performance of the computer cell tracking algorithms.

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KW - directed cell migration

KW - fully-automated cell tracking

KW - microscope data acquisition

KW - optimal time step intervals

KW - particle tracking

KW - phase-contrast microscopy

KW - segmentation

KW - tracking accuracy

U2 - 10.3390/JIMAGING6070066

DO - 10.3390/JIMAGING6070066

M3 - Article

AN - SCOPUS:85091558884

SN - 2313-433X

VL - 6

JO - Journal of Imaging

JF - Journal of Imaging

IS - 7

M1 - 66

ER -

Investigating optimal time step intervals of imaging for data quality through a novel fully-automated cell tracking approach

Abstract

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Keywords

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