Your search keyword '"Mindek, Peter"' showing total 3 results

1. Modeling in the Time of COVID-19: Statistical and Rule-based Mesoscale Models.

Author

Nguyen, Ngan, Strnad, Ondrej, Klein, Tobias, Luo, Deng, Alharbi, Ruwayda, Wonka, Peter, Maritan, Martina, Mindek, Peter, Autin, Ludovic, Goodsell, David S., and Viola, Ivan

Subjects

COVID-19, BIOLOGICAL models, VIRAL transmission, SARS-CoV-2, MACROMOLECULES

Abstract

We present a new technique for the rapid modeling and construction of scientifically accurate mesoscale biological models. The resulting 3D models are based on a few 2D microscopy scans and the latest knowledge available about the biological entity, represented as a set of geometric relationships. Our new visual-programming technique is based on statistical and rule-based modeling approaches that are rapid to author, fast to construct, and easy to revise. From a few 2D microscopy scans, we determine the statistical properties of various structural aspects, such as the outer membrane shape, the spatial properties, and the distribution characteristics of the macromolecular elements on the membrane. This information is utilized in the construction of the 3D model. Once all the imaging evidence is incorporated into the model, additional information can be incorporated by interactively defining the rules that spatially characterize the rest of the biological entity, such as mutual interactions among macromolecules, and their distances and orientations relative to other structures. These rules are defined through an intuitive 3D interactive visualization as a visual-programming feedback loop. We demonstrate the applicability of our approach on a use case of the modeling procedure of the SARS-CoV-2 virion ultrastructure. This atomistic model, which we present here, can steer biological research to new promising directions in our efforts to fight the spread of the virus. [ABSTRACT FROM AUTHOR]

Published

2021

2. Multi-Scale Procedural Animations of Microtubule Dynamics Based on Measured Data.

Author

Klein, Tobias, Viola, Ivan, Groller, Eduard, and Mindek, Peter

Subjects

MICROTUBULES, CELL morphology, CYTOSKELETON, DATABASES, MULTISCALE modeling, EUKARYOTIC cells

Abstract

Biologists often use computer graphics to visualize structures, which due to physical limitations are not possible to image with a microscope. One example for such structures are microtubules, which are present in every eukaryotic cell. They are part of the cytoskeleton maintaining the shape of the cell and playing a key role in the cell division. In this paper, we propose a scientifically-accurate multi-scale procedural model of microtubule dynamics as a novel application scenario for procedural animation, which can generate visualizations of their overall shape, molecular structure, as well as animations of the dynamic behaviour of their growth and disassembly. The model is spanning from tens of micrometers down to atomic resolution. All the aspects of the model are driven by scientific data. The advantage over a traditional, manual animation approach is that when the underlying data change, for instance due to new evidence, the model can be recreated immediately. The procedural animation concept is presented in its generic form, with several novel extensions, facilitating an easy translation to other domains with emergent multi-scale behavior. [ABSTRACT FROM AUTHOR]

Published

2020

3. Visualization Multi-Pipeline for Communicating Biology.

Author

Mindek, Peter, Kouril, David, Sorger, Johannes, Toloudis, Daniel, Lyons, Blair, Johnson, Graham, Groller, M. Eduard, and Viola, Ivan

Subjects

SCIENTIFIC visualization, BIOLOGICAL databases, RENDERING (Computer graphics), PLURIPOTENT stem cells, HETEROGENEOUS computing

Abstract

We propose a system to facilitate biology communication by developing a pipeline to support the instructional visualization of heterogeneous biological data on heterogeneous user-devices. Discoveries and concepts in biology are typically summarized with illustrations assembled manually from the interpretation and application of heterogenous data. The creation of such illustrations is time consuming, which makes it incompatible with frequent updates to the measured data as new discoveries are made. Illustrations are typically non-interactive, and when an illustration is updated, it still has to reach the user. Our system is designed to overcome these three obstacles. It supports the integration of heterogeneous datasets, reflecting the knowledge that is gained from different data sources in biology. After pre-processing the datasets, the system transforms them into visual representations as inspired by scientific illustrations. As opposed to traditional scientific illustration these representations are generated in real-time - they are interactive. The code generating the visualizations can be embedded in various software environments. To demonstrate this, we implemented both a desktop application and a remote-rendering server in which the pipeline is embedded. The remote-rendering server supports multi-threaded rendering and it is able to handle multiple users simultaneously. This scalability to different hardware environments, including multi-GPU setups, makes our system useful for efficient public dissemination of biological discoveries. [ABSTRACT FROM PUBLISHER]

Published

2018