Free Form Deformation-Based Image Registration Improves Accuracy of Traction Force Microscopy

Traction Force Microscopy (TFM) is a widespread method used to recover cellular tractions from the deformation that they cause in their surrounding substrate. Particle Image Velocimetry (PIV) is commonly used to quantify the substrate's deformations, due to its simplicity and efficiency. Howeve...

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Bibliographic Details
Published in:PloS one 2015-12, Vol.10 (12), p.e0144184-e0144184
Main Authors: Jorge-Peñas, Alvaro, Izquierdo-Alvarez, Alicia, Aguilar-Cuenca, Rocio, Vicente-Manzanares, Miguel, Garcia-Aznar, José Manuel, Van Oosterwyck, Hans, de-Juan-Pardo, Elena M, Ortiz-de-Solorzano, Carlos, Muñoz-Barrutia, Arrate
Format: Article
Language:English
Subjects:
Algorithms
Analysis
Biomechanics
Computer simulation
Deformation
Deformation mechanisms
Endothelial cells
Extracellular matrix
Finite element method
Formability
Free form
Image registration
Imaging, Three-Dimensional - methods
Mechanical engineering
Microscopy
Microscopy, Atomic Force - methods
Models, Theoretical
Particle image velocimetry
Pathological physiology
Recovery
Registration
Substrates
Traction
Traction force
Velocity measurement
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Summary:Traction Force Microscopy (TFM) is a widespread method used to recover cellular tractions from the deformation that they cause in their surrounding substrate. Particle Image Velocimetry (PIV) is commonly used to quantify the substrate's deformations, due to its simplicity and efficiency. However, PIV relies on a block-matching scheme that easily underestimates the deformations. This is especially relevant in the case of large, locally non-uniform deformations as those usually found in the vicinity of a cell's adhesions to the substrate. To overcome these limitations, we formulate the calculation of the deformation of the substrate in TFM as a non-rigid image registration process that warps the image of the unstressed material to match the image of the stressed one. In particular, we propose to use a B-spline -based Free Form Deformation (FFD) algorithm that uses a connected deformable mesh to model a wide range of flexible deformations caused by cellular tractions. Our FFD approach is validated in 3D fields using synthetic (simulated) data as well as with experimental data obtained using isolated endothelial cells lying on a deformable, polyacrylamide substrate. Our results show that FFD outperforms PIV providing a deformation field that allows a better recovery of the magnitude and orientation of tractions. Together, these results demonstrate the added value of the FFD algorithm for improving the accuracy of traction recovery.
ISSN:1932-6203
1932-6203
DOI:10.1371/journal.pone.0144184