Error analysis of surface-distribution and non-deformation of fluorescent beads for the IC-GN2 DVC algorithm
•The inverse compositional Gauss-Newton DVC algorithm with the second-order shape function (IC-GN2 DVC algorithm), which has high accuracy and efficiency, is introduced.•The influence of the non-deformation and surface-distribution of fluorescent beads on the accuracy of the IC-GN2 DVC algorithm is...
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| Veröffentlicht in: | Optics and lasers in engineering Jg. 140; S. 106541 |
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| Hauptverfasser: | , , , , , , , |
| Format: | Journal Article |
| Sprache: | Englisch |
| Veröffentlicht: |
Elsevier Ltd
01.05.2021
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| Schlagworte: | |
| ISSN: | 0143-8166, 1873-0302 |
| Online-Zugang: | Volltext |
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| Zusammenfassung: | •The inverse compositional Gauss-Newton DVC algorithm with the second-order shape function (IC-GN2 DVC algorithm), which has high accuracy and efficiency, is introduced.•The influence of the non-deformation and surface-distribution of fluorescent beads on the accuracy of the IC-GN2 DVC algorithm is studied.•The speckle-surface-distributed experimental method, which has far less scanning time and hence can reduce the phototoxicity, is proposed.
Digital volume correlation (DVC) method is extensively used for the internal displacement measurement. In biomechanical experiments, fluorescent beads are used, instead of traditional speckles (or microstructure of materials), as the information feature of the volume image for DVC algorithm. The traditional experimental method and DVC algorithm, together, provide an effective measurement method for the cell deformation. Nevertheless, the aforesaid method has three limitations, viz., (1) low accuracy for complex displacement and poor efficiency for traditional second-order forward additive Gauss-Newton (FA-GN2) algorithm, (2) shape function mismatch induced by the non-deformation of fluorescent beads, and (3) the extreme phototoxicity caused by the long scanning time. To tackle these issues, we introduce the inverse compositional Gauss-Newton DVC algorithm with the second-order shape function (IC-GN2 DVC algorithm) to achieve higher accuracy and establish the four speckle volume image models to analyze the influence of the distribution and non-deformation of fluorescent beads on the results of calculation of DVC method. Henceforth, we propose an experimental method, considering that fluorescent beads are only distributed on the surface of the gel substrate (cells are also placed on the surface of gel substrate) enabling short scanning time (termed speckle-surface-distributed experimental method). The results from the analysis by numerical simulations show that the proposed IC-GN2 DVC algorithm has a very high accuracy (local error < 0.1 voxel). The error analysis of the four models shows that the non-deformation of fluorescent beads will induce significant error into the calculation results, whereas the surface-distribution of fluorescent beads induces little error, which prove the reliability of the speckle-surface-distributed experimental method. The noise robustness of the IC-GN2 DVC algorithm with the speckle-surface-distributed experimental method is also studied. Finally, the migration and deformation of the living cell is analyzed using the IC-GN2 DVC algorithm and the speckle-surface-distributed experimental method. |
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| ISSN: | 0143-8166 1873-0302 |
| DOI: | 10.1016/j.optlaseng.2021.106541 |