Real-time reconstruction and visualisation towards dynamic feedback control during time-resolved tomography experiments at TOMCAT

Buurlage, Jan‐Willem; Marone, Federica; Pelt, Daniël M.; Palenstijn, Willem Jan; Stampanoni, Marco; Batenburg, Kees Joost

doi:10.1038/s41598-019-54647-4

Cited by 25 publications

(17 citation statements)

References 24 publications

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“…In contrast, OVSS requires an order-less data i.e., about 180 images and reatively less memory (few tens of MBs). So the availability of fast computing engines and an order-less sectional 2D data may enable volume reconstruction in real-time 52 , 53 .…”

Section: Discussionmentioning

confidence: 99%

Fluorescence based rapid optical volume screening system (OVSS) for interrogating multicellular organisms

Basumatary

Ara

Mukherjee

et al. 2021

Sci Rep

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Continuous monitoring of large specimens for long durations requires fast volume imaging. This is essential for understanding the processes occurring during the developmental stages of multicellular organisms. One of the key obstacles of fluorescence based prolonged monitoring and data collection is photobleaching. To capture the biological processes and simultaneously overcome the effect of bleaching, we developed single- and multi-color lightsheet based OVSS imaging technique that enables rapid screening of multiple tissues in an organism. Our approach based on OVSS imaging employs quantized step rotation of the specimen to record 2D angular data that reduces data acquisition time when compared to the existing light sheet imaging system (SPIM). A co-planar multicolor light sheet PSF is introduced to illuminate the tissues labelled with spectrally-separated fluorescent probes. The detection is carried out using a dual-channel sub-system that can simultaneously record spectrally separate volume stacks of the target organ. Arduino-based control systems were employed to automatize and control the volume data acquisition process. To illustrate the advantages of our approach, we have noninvasively imaged the Drosophila larvae and Zebrafish embryo. Dynamic studies of multiple organs (muscle and yolk-sac) in Zebrafish for a prolonged duration (5 days) were carried out to understand muscle structuring (Dystrophin, microfibers), primitive Macrophages (in yolk-sac) and inter-dependent lipid and protein-based metabolism. The volume-based study, intensity line-plots and inter-dependence ratio analysis allowed us to understand the transition from lipid-based metabolism to protein-based metabolism during early development (Pharyngula period with a critical transition time, $$\tau _c = 50$$ τ c = 50 h post-fertilization) in Zebrafish. The advantage of multicolor lightsheet illumination, fast volume scanning, simultaneous visualization of multiple organs and an order-less photobleaching makes OVSS imaging the system of choice for rapid monitoring and real-time assessment of macroscopic biological organisms with microscopic resolution.

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Section: Discussionmentioning

confidence: 99%

Fluorescence based rapid optical volume screening system (OVSS) for interrogating multicellular organisms

Basumatary

Ara

Mukherjee

et al. 2021

Sci Rep

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“…The synchronization possibilities offered at TOMCAT (see Sections "Rotation Stage" and "Data Acquisition") at least partially mitigate this data deluge. The 3D preview currently under development (Buurlage et al, 2019) opens up new opportunities for an active experimental feedback and should enable smarter experiment control, thereby significantly reducing the amount of acquired data while maximizing its information content.…”

Section: Discussion and Outlookmentioning

confidence: 99%

“…Although 2D X-ray projections of the sample already provide very insightful information to control and steer the experiment, for several applications they are unfortunately not sufficient to detect subtle but important changes indicating for instance the onset of a particular event. To expand the controlling and steering options, a previewing tool outputting selected arbitrarily oriented tomographic slices on-the-fly is currently being developed (Buurlage et al, 2019). This tool enables the optimization of the beamline and of experimental parameters as well as for instance the real-time selection of a region of interest in a larger volume, an operation often very difficult to achieve from 2D projections only.…”

Section: Data Previewmentioning

confidence: 99%

Time Resolved in situ X-Ray Tomographic Microscopy Unraveling Dynamic Processes in Geologic Systems

et al. 2020

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Sub-Second X-Ray Tomographic Microscopy coalescence in volcanological material. With the integration of a rheometer, information on bubble deformation could also be gained. In the near future, upgrades of most large-scale synchrotron radiation facilities to diffraction-limited storage rings will create new opportunities, for instance through sub-second tomographic imaging capabilities at sub-micron length scales.

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“…There is now a strong demand for improving data handling, analysis workflows and documentation of the results obtained from these techniques to truly enable correlative microscopy and material behavior characterization at multiple length scales. Furthermore, performing real-time reconstructions and segmentation of dynamically evolving features/classes in microstructures during an in situ experiment is gaining significant interest [28]. This capability would give the user complete knowledge of the dynamic evolution of the specimen under a stimulus (mechanical stresses, electrochemical environments etc.)…”

Section: Segmentation and Analysismentioning

confidence: 99%

Computational Imaging in 3D X-Ray Microscopy: Reconstruction, Image Segmentation and Time-Evolved Experiments

Niverty

Torbatissaraf

Никитин

et al. 2021

2021 IEEE International Conference on Image Processing (ICIP)

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Time-dependent X-ray Microscopy (XRM) is an excellent technique to develop a fundamental mechanistic understanding of material behavior. Computational imaging plays a critical role in XRM, in a variety of ways. 2D projections are acquired and the resulting datasets are reconstructed using a filtered back projection algorithm. Several imaging artifacts are typically present, such as beam hardening, misalignment of the data, drift during time-evolved experiments (particularly at high temperatures and/or nanometer resolution scans), etc. Minimizing and removing these artifacts is, thus, very important. This is all the more important, because image segmentation is then done to quantify the statistics of the microstructure (often, as a function of time). The efficiency and accuracy of image segmentation is directly proportional to the quality of the initial reconstructed data. Thus, there is a need to develop efficient, robust algorithms that can handle large datasets obtained by 4D, time-dependent x-ray microscopy. In this paper, we will describe the challenges associated with computation imaging during x-ray microscopy. The use of Convolutional Neural Network (CNN) architectures based on a deep learning approach, as means of automating and handling x-ray microscopy data sets, in both lab-scale and synchrotron, will be discussed. The use of CNN techniques to robustly process ultra-large volumes of data in relatively small-time frames can exponentially accelerate tomographic data analysis, opening up novel avenues for performing 4D characterization experiments.

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Real-time reconstruction and visualisation towards dynamic feedback control during time-resolved tomography experiments at TOMCAT

Cited by 25 publications

References 24 publications

Fluorescence based rapid optical volume screening system (OVSS) for interrogating multicellular organisms

Fluorescence based rapid optical volume screening system (OVSS) for interrogating multicellular organisms

Time Resolved in situ X-Ray Tomographic Microscopy Unraveling Dynamic Processes in Geologic Systems

Computational Imaging in 3D X-Ray Microscopy: Reconstruction, Image Segmentation and Time-Evolved Experiments

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