Determination of the positions and orientations of concentrated rod-like colloids from 3D microscopy data

T. H. Besseling; M. Hermes; A. Kuijk; B. de Nijs; T-S Deng; A. Imhof; A. van Blaaderen; Marjolein Dijkstra

doi:10.1088/0953-8984/27/19/194109

Determination of the positions and orientations of concentrated rod-like colloids from 3D microscopy data

T. H. Besseling^*, M. Hermes, A. Kuijk, B. de Nijs, T-S Deng, A. Imhof, A. van Blaaderen, Marjolein Dijkstra

^*Corresponding author for this work

Research output: Contribution to journal › Article › Academic › peer-review

Abstract

Confocal microscopy in combination with real-space particle tracking has proven to be a powerful tool in scientific fields such as soft matter physics, materials science and cell biology. However, 3D tracking of anisotropic particles in concentrated phases remains not as optimized compared to algorithms for spherical particles. To address this problem, we developed a new particle-fitting algorithm that can extract the positions and orientations of fluorescent rod-like particles from three dimensional confocal microscopy data stacks. The algorithm is tailored to work even when the fluorescent signals of the particles overlap considerably and a threshold method and subsequent clusters analysis alone do not suffice. We demonstrate that our algorithm correctly identifies all five coordinates of uniaxial particles in both a concentrated disordered phase and a liquid-crystalline smectic-B phase. Apart from confocal microscopy images, we also demonstrate that the algorithm can be used to identify nanorods in 3D electron tomography reconstructions. Lastly, we determined the accuracy of the algorithm using both simulated and experimental confocal microscopy data-stacks of diffusing silica rods in a dilute suspension. This novel particle-fitting algorithm allows for the study of structure and dynamics in both dilute and dense liquid-crystalline phases (such as nematic, smectic and crystalline phases) as well as the study of the glass transition of rod-like particles in three dimensions on the single particle level.

Original language	English
Article number	194109
Number of pages	13
Journal	Journal of physics. Condensed matter
Volume	27
Issue number	19
DOIs	https://doi.org/10.1088/0953-8984/27/19/194109
Publication status	Published - 20 May 2015

Funding

The authors thank E Weeks, K Desmond, T Vissers and A Gantapara for useful discussion, H Bakker, C Kennedy and B Liu for useful feedback on the algorithm and H Meeldijk for help with the electron microscopy data. This research was carried out partially (THB) under project number M62.7.08SDMP25 in the framework of the Industrial Partnership Program on Size Dependent Material Properties of the Materials innovation institute (M2i) and the Foundation of Fundamental Research on Matter (FOM), which is part of the Netherlands Organisation for Scientific Research (NWO). Part of the research leading to these results has received funding from the European Research Council under the European Unions Seventh Framework Programme (FP/2007-2013)/ERC Grant Agreement no. [291667].

Keywords

rod-like particles
image processing
3D reconstructions
CONFOCAL MICROSCOPY
ROTATIONAL DIFFUSION
VIDEO MICROSCOPY
HARD-SPHERE
TRANSLATIONAL DIFFUSION
DIRECT VISUALIZATION
PHASE-BEHAVIOR
SILICA RODS
TRACKING
PARTICLES

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title = "Determination of the positions and orientations of concentrated rod-like colloids from 3D microscopy data",

abstract = "Confocal microscopy in combination with real-space particle tracking has proven to be a powerful tool in scientific fields such as soft matter physics, materials science and cell biology. However, 3D tracking of anisotropic particles in concentrated phases remains not as optimized compared to algorithms for spherical particles. To address this problem, we developed a new particle-fitting algorithm that can extract the positions and orientations of fluorescent rod-like particles from three dimensional confocal microscopy data stacks. The algorithm is tailored to work even when the fluorescent signals of the particles overlap considerably and a threshold method and subsequent clusters analysis alone do not suffice. We demonstrate that our algorithm correctly identifies all five coordinates of uniaxial particles in both a concentrated disordered phase and a liquid-crystalline smectic-B phase. Apart from confocal microscopy images, we also demonstrate that the algorithm can be used to identify nanorods in 3D electron tomography reconstructions. Lastly, we determined the accuracy of the algorithm using both simulated and experimental confocal microscopy data-stacks of diffusing silica rods in a dilute suspension. This novel particle-fitting algorithm allows for the study of structure and dynamics in both dilute and dense liquid-crystalline phases (such as nematic, smectic and crystalline phases) as well as the study of the glass transition of rod-like particles in three dimensions on the single particle level.",

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author = "Besseling, {T. H.} and M. Hermes and A. Kuijk and {de Nijs}, B. and T-S Deng and A. Imhof and {van Blaaderen}, A. and Marjolein Dijkstra",

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AU - Besseling, T. H.

AU - Hermes, M.

AU - Kuijk, A.

AU - de Nijs, B.

AU - Deng, T-S

AU - Imhof, A.

AU - van Blaaderen, A.

AU - Dijkstra, Marjolein

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AB - Confocal microscopy in combination with real-space particle tracking has proven to be a powerful tool in scientific fields such as soft matter physics, materials science and cell biology. However, 3D tracking of anisotropic particles in concentrated phases remains not as optimized compared to algorithms for spherical particles. To address this problem, we developed a new particle-fitting algorithm that can extract the positions and orientations of fluorescent rod-like particles from three dimensional confocal microscopy data stacks. The algorithm is tailored to work even when the fluorescent signals of the particles overlap considerably and a threshold method and subsequent clusters analysis alone do not suffice. We demonstrate that our algorithm correctly identifies all five coordinates of uniaxial particles in both a concentrated disordered phase and a liquid-crystalline smectic-B phase. Apart from confocal microscopy images, we also demonstrate that the algorithm can be used to identify nanorods in 3D electron tomography reconstructions. Lastly, we determined the accuracy of the algorithm using both simulated and experimental confocal microscopy data-stacks of diffusing silica rods in a dilute suspension. This novel particle-fitting algorithm allows for the study of structure and dynamics in both dilute and dense liquid-crystalline phases (such as nematic, smectic and crystalline phases) as well as the study of the glass transition of rod-like particles in three dimensions on the single particle level.

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KW - DIRECT VISUALIZATION

KW - PHASE-BEHAVIOR

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JF - Journal of physics. Condensed matter

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M1 - 194109

ER -

Determination of the positions and orientations of concentrated rod-like colloids from 3D microscopy data

Abstract

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Keywords

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