Fast and Robust Optical Flow for Time-lapse Microscopy Using Super-voxels

Overview

Journal Bioinformatics

Publisher Oxford University Press

Specialty Biology

Date 2012 Dec 18

PMID 23242263

Citations 16

Authors

Fernando Amat

Eugene W Myers

Philipp J Keller

Affiliations

Soon will be listed here.

Abstract

Motivation: Optical flow is a key method used for quantitative motion estimation of biological structures in light microscopy. It has also been used as a key module in segmentation and tracking systems and is considered a mature technology in the field of computer vision. However, most of the research focused on 2D natural images, which are small in size and rich in edges and texture information. In contrast, 3D time-lapse recordings of biological specimens comprise up to several terabytes of image data and often exhibit complex object dynamics as well as blurring due to the point-spread-function of the microscope. Thus, new approaches to optical flow are required to improve performance for such data.

Results: We solve optical flow in large 3D time-lapse microscopy datasets by defining a Markov random field (MRF) over super-voxels in the foreground and applying motion smoothness constraints between super-voxels instead of voxel-wise. This model is tailored to the specific characteristics of light microscopy datasets: super-voxels help registration in textureless areas, the MRF over super-voxels efficiently propagates motion information between neighboring cells and the background subtraction and super-voxels reduce the dimensionality of the problem by an order of magnitude. We validate our approach on large 3D time-lapse datasets of Drosophila and zebrafish development by analyzing cell motion patterns. We show that our approach is, on average, 10 × faster than commonly used optical flow implementations in the Insight Tool-Kit (ITK) and reduces the average flow end point error by 50% in regions with complex dynamic processes, such as cell divisions.

Availability: Source code freely available in the Software section at http://janelia.org/lab/keller-lab.

Citing Articles

Tracking cell lineages in 3D by incremental deep learning.

Sugawara K, Cevrim C, Averof M Elife. 2022; 11.

PMID: 34989675 PMC: 8741210. DOI: 10.7554/eLife.69380.

Visualization Method for the Cell-Level Vesicle Transport Using Optical Flow and a Diverging Colormap.

Lee S, Kim H, Higuchi H, Ishikawa M Sensors (Basel). 2021; 21(2).

PMID: 33450927 PMC: 7828387. DOI: 10.3390/s21020522.

Saak Transform-Based Machine Learning for Light-Sheet Imaging of Cardiac Trabeculation.

Ding Y, Gudapati V, Lin R, Fei Y, Packard R, Song S IEEE Trans Biomed Eng. 2020; 68(1):225-235.

PMID: 32365015 PMC: 7606319. DOI: 10.1109/TBME.2020.2991754.

Optical flow analysis reveals that Kinesin-mediated advection impacts the orientation of microtubules in the oocyte.

Drechsler M, Lang L, Al-Khatib L, Dirks H, Burger M, Schonlieb C Mol Biol Cell. 2020; 31(12):1246-1258.

PMID: 32267197 PMC: 7353148. DOI: 10.1091/mbc.E19-08-0440.

3D Hermite Transform Optical Flow Estimation inLeft Ventricle CT Sequences.

Mira C, Moya-Albor E, Escalante-Ramirez B, Olveres J, Brieva J, Vallejo E Sensors (Basel). 2020; 20(3).

PMID: 31973153 PMC: 7038175. DOI: 10.3390/s20030595.

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