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Experimental Mechanics

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05-08-2020 | Sp Iss: Experimental Advances in Cardiovascular Biomechanics

A Method for Markerless Tracking of the Strain Distribution of Actively Contracting Cardiac Muscle Preparations

Authors: M.L. Cheuk, E.J. Lam Po Tang, A. HajiRassouliha, J.-C. Han, P.M.F. Nielsen, A.J. Taberner

Published in: Experimental Mechanics | Issue 1/2021

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Abstract

Background

Current techniques for tracking the displacement and strain patterns within contracting cardiac specimens often require ‘invasive’ markers to be fixed on the sample, offer only modest spatial resolution, and are computationally inefficient.

Objective

We present a new technique for determining, without requiring the addition of markers, the dynamic displacement and strain distribution within isolated cardiac muscle samples.

Methods

We use an accurate and robust new digital image correlation algorithm to measure deformations from a stitched-together time-series of images of a contracting trabecula, and a video recording of a contracting myocyte, captured by an optical transmission microscope.

Results

This technique yielded a 2D map of local deformation and strain throughout each specimen, over the time-course of a twitch, at a spatial resolution far exceeding that of previous techniques. In the trabecula we examined, our method enabled us to quantify its non-uniform strain and sarcomere length dynamics even when it was contracting with its length fixed. We noted the non-uniform relaxation of the specimen, where part of the trabecula appeared to be in contraction while the rest was in extension. The images of the myocyte revealed a strain distribution that ranged from −7% to −18%.

Conclusion

By applying this method, it is now possible to accurately quantify internal deformation in isolated muscle samples to subpixel resolution, which is essential for interpreting any motion-dependent measurements such as sarcomere length and change in cross-sectional area, all of which are preparation-specific.

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Title: A Method for Markerless Tracking of the Strain Distribution of Actively Contracting Cardiac Muscle Preparations
Authors: M.L. Cheuk
E.J. Lam Po Tang
A. HajiRassouliha
J.-C. Han
P.M.F. Nielsen
A.J. Taberner
Publication date: 05-08-2020
Publisher: Springer US
Published in: Experimental Mechanics / Issue 1/2021
Print ISSN: 0014-4851
Electronic ISSN: 1741-2765
DOI: https://doi.org/10.1007/s11340-020-00646-w

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Abstract

Background

Objective

Methods

Results

Conclusion

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