MAŠKA, Martin, Pavel MATULA, Arrate MUÑOZ-BARRUTIA and Carlos ORTIZ-DE-SOLÓRZANO. Fast Tracking Algorithm of GFP-Transfected Living Cells Based on the Chan-Vese Model. 2011.
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Basic information
Original name Fast Tracking Algorithm of GFP-Transfected Living Cells Based on the Chan-Vese Model
Name in Czech Rychlý algoritmus na sledování pohybu živých buněk transfekovaných pomocí GFP založený na Chan-Vese modelu
Authors MAŠKA, Martin (203 Czech Republic, guarantor, belonging to the institution), Pavel MATULA (203 Czech Republic, belonging to the institution), Arrate MUÑOZ-BARRUTIA (724 Spain) and Carlos ORTIZ-DE-SOLÓRZANO (724 Spain).
Edition 2011.
Other information
Original language English
Type of outcome Conference abstract
Field of Study 10201 Computer sciences, information science, bioinformatics
Country of publisher Germany
Confidentiality degree is not subject to a state or trade secret
RIV identification code RIV/00216224:14330/11:00051908
Organization unit Faculty of Informatics
Keywords in English object tracking; Chan-Vese model; level set framework; coherence-enhancing diffusion
Tags cbia-web
Tags International impact, Reviewed
Changed by Changed by: doc. RNDr. Martin Maška, Ph.D., učo 60734. Changed: 13/4/2011 10:32.
Abstract
We present a general, robust, and fast approach for tracking GFP-transfected living cells in time-lapse series acquired using a confocal fluorescence microscope. The proposed tracking scheme involves two steps. First, the coherence-enhancing diffusion filtering is applied on each frame in order to reduce the noise and enhance flow-like structures. Second, enhanced cell boundaries are detected through a minimization of the Chan-Vese model that divides an image domain into two possibly disconnected regions of minimal variance. To speed up the second step, final contours from the previous frame are taken as seeds in the next one. The minimization of the Chan-Vese model is implemented using a fast level set-like algorithm (Maška et al. 2010) achieving near real-time performance in 2D. Furthermore, this algorithm has been integrated with a topology-preserving constraint based on the simple point concept from digital geometry in order to preserve known topology from the first frame throughout the entire time-lapse series. Such constraint provides a simple and inherent mechanism for keeping the boundaries of two cells separated even if the cells get touched in subsequent frames. The potential and preliminary results of the proposed tracking algorithm are demonstrated on 2D as well as 3D time-lapse series. The image data used in our experiments was acquired using a Zeiss Cell Observer Spinning Disk confocal microscope equipped with a 20x Plan Apo (0.85 NA) objective lens. The execution time of the proposed tracking algorithm is about 0.55 seconds per a 2D frame of the size 512x512 pixels and about 30 seconds per a 3D frame of the size 512x512x42 voxels.
Abstract (in Czech)
Příspěvek pojednává o rychlém algoritmu na sledování pohybu živých buněk
Links
LC535, research and development projectName: Dynamika a organizace chromosomů během buněčného cyklu v normě a patologii
Investor: Ministry of Education, Youth and Sports of the CR, Dynamika a organizace chromosomů během buněčného cyklu v normě a patologii
MSM0021622419, plan (intention)Name: Vysoce paralelní a distribuované výpočetní systémy
Investor: Ministry of Education, Youth and Sports of the CR, Highly Parallel and Distributed Computing Systems
MUNI/A/0914/2009, interní kód MUName: Rozsáhlé výpočetní systémy: modely, aplikace a verifikace (Acronym: SV-FI MAV)
Investor: Masaryk University, Category A
2B06052, research and development projectName: Vytipování markerů, screening a časná diagnostika nádorových onemocnění pomocí vysoce automatizovaného zpracování multidimenzionálních biomedicínských obrazů (Acronym: Biomarker)
Investor: Ministry of Education, Youth and Sports of the CR, Determination of markers, screening and early diagnostics of cancer diseases using highly automated processing of multidimensional biomedical images
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