Particle retracking algorithm capable of quantifying large, local matrix deformation for traction force microscopy

Samuel E. Haarman; Sue Y. Kim; Tadamoto Isogai; Kevin M. Dean; Sangyoon J. Han

doi:10.1371/journal.pone.0268614

Particle retracking algorithm capable of quantifying large, local matrix deformation for traction force microscopy

Samuel E. Haarman, Sue Y. Kim, Tadamoto Isogai, Kevin M. Dean, Sangyoon J. Han

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

Abstract

Deformation measurement is a key process in traction force microscopy (TFM). Conventionally, particle image velocimetry (PIV) or correlation-based particle tracking velocimetry (cPTV) have been used for such a purpose. Using simulated bead images, we show that those methods fail to capture large displacement vectors and that it is due to a poor cross-correlation. Here, to redeem the potential large vectors, we propose a two-step deformation tracking algorithm that combines cPTV, which performs better for small displacements than PIV methods, and newly-designed retracking algorithm that exploits statistically confident vectors from the initial cPTV to guide the selection of correlation peak which are not necessarily the global maximum. As a result, the new method, named ‘cPTV-Retracking’, or cPTVR, was able to track more than 92% of large vectors whereas conventional methods could track 43–77% of those. Correspondingly, traction force reconstructed from cPTVR showed better recovery of large traction than the old methods. cPTVR applied on the experimental bead images has shown a better resolving power of the traction with different-sized cell-matrix adhesions than conventional methods. Altogether, cPTVR method enhances the accuracy of TFM in the case of large deformations present in soft substrates. We share this advance via our TFMPackage software.

Original language	English (US)
Article number	e0268614
Journal	PloS one
Volume	17
Issue number	6 June
DOIs	https://doi.org/10.1371/journal.pone.0268614
State	Published - Jun 2022

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@article{5622b1cbddea4835bc54721f1eba6f05,

title = "Particle retracking algorithm capable of quantifying large, local matrix deformation for traction force microscopy",

abstract = "Deformation measurement is a key process in traction force microscopy (TFM). Conventionally, particle image velocimetry (PIV) or correlation-based particle tracking velocimetry (cPTV) have been used for such a purpose. Using simulated bead images, we show that those methods fail to capture large displacement vectors and that it is due to a poor cross-correlation. Here, to redeem the potential large vectors, we propose a two-step deformation tracking algorithm that combines cPTV, which performs better for small displacements than PIV methods, and newly-designed retracking algorithm that exploits statistically confident vectors from the initial cPTV to guide the selection of correlation peak which are not necessarily the global maximum. As a result, the new method, named {\textquoteleft}cPTV-Retracking{\textquoteright}, or cPTVR, was able to track more than 92% of large vectors whereas conventional methods could track 43–77% of those. Correspondingly, traction force reconstructed from cPTVR showed better recovery of large traction than the old methods. cPTVR applied on the experimental bead images has shown a better resolving power of the traction with different-sized cell-matrix adhesions than conventional methods. Altogether, cPTVR method enhances the accuracy of TFM in the case of large deformations present in soft substrates. We share this advance via our TFMPackage software.",

author = "Haarman, {Samuel E.} and Kim, {Sue Y.} and Tadamoto Isogai and Dean, {Kevin M.} and Han, {Sangyoon J.}",

note = "Funding Information: This work was funded by National Institutes of Health (https://www.nih.org/) R15GM135806 (S.J.H.) and F32GM117793 (K.M. D.). The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript. We acknowledge Jiri Vejrazka (Institute of Chemical Process Fundamentals ASCR, Prague, Czech Republic), an author of PIV Suite, Nobuhito Mori (Kyoto University, Japan) and Kuang-An Chang (Texas A&M University), authors of mpiv, Qingzong Tseng (EMBL, Germany), an author of Tseng{\textquoteright}s PIV and Mohak Patel and Christian Franck (UW Madison), authors of T-PT for their software to be compared with our cPTVR method. We also thank Alex Groisman (UCSD) for providing soft substrates for experimental TFM experiments. Publisher Copyright: {\textcopyright} 2022 Haarman et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.",

year = "2022",

month = jun,

doi = "10.1371/journal.pone.0268614",

language = "English (US)",

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AU - Haarman, Samuel E.

AU - Kim, Sue Y.

AU - Isogai, Tadamoto

AU - Dean, Kevin M.

AU - Han, Sangyoon J.

N1 - Funding Information: This work was funded by National Institutes of Health (https://www.nih.org/) R15GM135806 (S.J.H.) and F32GM117793 (K.M. D.). The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript. We acknowledge Jiri Vejrazka (Institute of Chemical Process Fundamentals ASCR, Prague, Czech Republic), an author of PIV Suite, Nobuhito Mori (Kyoto University, Japan) and Kuang-An Chang (Texas A&M University), authors of mpiv, Qingzong Tseng (EMBL, Germany), an author of Tseng’s PIV and Mohak Patel and Christian Franck (UW Madison), authors of T-PT for their software to be compared with our cPTVR method. We also thank Alex Groisman (UCSD) for providing soft substrates for experimental TFM experiments. Publisher Copyright: © 2022 Haarman et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

PY - 2022/6

Y1 - 2022/6

N2 - Deformation measurement is a key process in traction force microscopy (TFM). Conventionally, particle image velocimetry (PIV) or correlation-based particle tracking velocimetry (cPTV) have been used for such a purpose. Using simulated bead images, we show that those methods fail to capture large displacement vectors and that it is due to a poor cross-correlation. Here, to redeem the potential large vectors, we propose a two-step deformation tracking algorithm that combines cPTV, which performs better for small displacements than PIV methods, and newly-designed retracking algorithm that exploits statistically confident vectors from the initial cPTV to guide the selection of correlation peak which are not necessarily the global maximum. As a result, the new method, named ‘cPTV-Retracking’, or cPTVR, was able to track more than 92% of large vectors whereas conventional methods could track 43–77% of those. Correspondingly, traction force reconstructed from cPTVR showed better recovery of large traction than the old methods. cPTVR applied on the experimental bead images has shown a better resolving power of the traction with different-sized cell-matrix adhesions than conventional methods. Altogether, cPTVR method enhances the accuracy of TFM in the case of large deformations present in soft substrates. We share this advance via our TFMPackage software.

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Particle retracking algorithm capable of quantifying large, local matrix deformation for traction force microscopy

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