Your search keyword '"Brusch, Lutz"' showing total 8 results

1. FitMultiCell: Simulating and parameterizing computational models of multi-scale and multi-cellular processes

Author

Alamoudi, Emad, Schälte, Yannik, Müller, Robert, Starruß, Jörn, Bundgaard, Nils, Graw, Frederik, Brusch, Lutz, and Hasenauer, Jan

Abstract

MotivationBiological tissues are dynamic and highly organized. Multi-scale models are helpful tools to analyze and understand the processes determining tissue dynamics. These models usually depend on parameters that need to be inferred from experimental data to achieve a quantitative understanding, to predict the response to perturbations, and to evaluate competing hypotheses. However, even advanced inference approaches such as Approximate Bayesian Computation (ABC) are difficult to apply due to the computational complexity of the simulation of multi-scale models. Thus, there is a need for a scalable pipeline for modeling, simulating, and parameterizing multi-scale models of multi-cellular processes.ResultsHere, we present FitMultiCell, a computationally efficient and user-friendly open-source pipeline that can handle the full workflow of modeling, simulating, and parameterizing for multi-scale models of multi-cellular processes. The pipeline is modular and integrates the modeling and simulation tool Morpheus and the statistical inference tool pyABC. The easy integration of high-performance infrastructure allows to scale to computationally expensive problems. The introduction of a novel standard for the formulation of parameter inference problems for multi-scale models additionally ensures reproducibility and reusability. By applying the pipeline to multiple biological problems, we demonstrate its broad applicability, which will benefit in particular image-based systems biology.AvailabilityFitMultiCell is available open-source athttps://gitlab.com/fitmulticell/fit.Contactjan.hasenauer@uni-bonn.deSupplementary informationSupplementary data are available athttps://doi.org/10.5281/zenodo.7646287online.

Published

2023

2. BioSimulators: a central registry of simulation engines and services for recommending specific tools

Author

Shaikh, Bilal, Smith, Lucian, Vasilescu, Dan, Marupilla, Gnaneswara, Wilson, Michael, Agmon, Eran, Agnew, Henry, Andrews, Steven, Anwar, Azraf, Beber, Moritz, Bergmann, Frank, Brooks, David, Brusch, Lutz, Calzone, Laurence, Choi, Kiri, Cooper, Joshua, Detloff, John, Drawert, Brian, Dumontier, Michel, Ermentrout, G, Faeder, James, Freiburger, Andrew, Fröhlich, Fabian, Funahashi, Akira, Garny, Alan, Gennari, John, Gleeson, Padraig, Goelzer, Anne, Haiman, Zachary, Hellerstein, Joseph, Hoops, Stefan, Ison, Jon, Jahn, Diego, Jakubowski, Henry, Jordan, Ryann, Kalaš, Matúš, König, Matthias, Liebermeister, Wolfram, Mandal, Synchon, Mcdougal, Robert, Medley, J, Mendes, Pedro, Müller, Robert, Myers, Chris, Naldi, Aurélien, Nguyen, Tung, Nickerson, David, Olivier, Brett, Patoliya, Drashti, Paulevé, Loïc, Petzold, Linda, Priya, Ankita, Rampadarath, Anand, Rohwer, Johann, Saglam, Ali, Singh, Dilawar, Sinha, Ankur, Snoep, Jacky, Sorby, Hugh, Spangler, Ryan, Starruss, Jörn, Thomas, Payton, van Niekerk, David, Weindl, Daniel, Zhang, Fengkai, Zhukova, Anna, Goldberg, Arthur, Blinov, Michael, Sauro, Herbert, Moraru, Ion, Karr, Jonathan, and Liebermeister, Wolfram

Subjects

Computational Engineering, Finance, and Science (cs.CE), FOS: Computer and information sciences, Molecular Networks (q-bio.MN), FOS: Biological sciences, [SDV.BC.BC] Life Sciences [q-bio]/Cellular Biology/Subcellular Processes [q-bio.SC], Quantitative Biology - Molecular Networks, Computer Science - Computational Engineering, Finance, and Science, Quantitative Biology - Quantitative Methods, Quantitative Methods (q-bio.QM), [SDV.BIO] Life Sciences [q-bio]/Biotechnology

Abstract

Computational models have great potential to accelerate bioscience, bioengineering, and medicine. However, it remains challenging to reproduce and reuse simulations, in part, because the numerous formats and methods for simulating various subsystems and scales remain siloed by different software tools. For example, each tool must be executed through a distinct interface. To help investigators find and use simulation tools, we developed BioSimulators (https://biosimulators.org), a central registry of the capabilities of simulation tools and consistent Python, command-line, and containerized interfaces to each version of each tool. The foundation of BioSimulators is standards, such as CellML, SBML, SED-ML, and the COMBINE archive format, and validation tools for simulation projects and simulation tools that ensure these standards are used consistently. To help modelers find tools for particular projects, we have also used the registry to develop recommendation services. We anticipate that BioSimulators will help modelers exchange, reproduce, and combine simulations., Comment: 6 pages, 2 figures

Published

2022

3. Die virtuelle Leber

Author

Zerial, Marino, Meyer, Kirstin, Ostrenko, Oleksandr, Bourantas, Georgios, Morales-Navarrete, Hernan, Porat-Shliom, Natalie, Segovia-Miranda, Fabian, Nonaka, Hidenori, Ghaemi, Ali, Verbavatz, Jean-Marc, Brusch, Lutz, Sbalzarini, Ivo F., Kalaidzidis, Yannis, and Weigert, Roberto

Published

2018

4. Supplementary Information from A dynamically diluted alignment model reveals the impact of cell turnover on the plasticity of tissue polarity patterns

Author

Hoffmann, Karl B., Voss–Böhme, Anja, Rink, Jochen C., and Brusch, Lutz

Abstract

Supplementary Information to Hoffmann, Voss-Böhme, Rink and Brusch 2017: “A Dynamically Diluted Alignment Model Reveals the Impact of Cell Turnover on the Plasticity of Tissue Polarity Patterns” with detailed derivations of equations that are used in the main text, a table summarising all variable names and notations and additional results in 7 supplementary figures: Fig.S1, Lattice size effects. Fig.S2, Effects of de-novo polarisation rate beta on the time of minimal order. Fig.S3, Statistical robustness of time of minimal order. Fig.S4, Bistability of mean-field ODE system for very high neighbour coupling strength. Fig.S5, Time of minimal order for vanishing neighbour coupling strength. Fig.S6, Time of minimal order collapses to linear function of the effective neighbour coupling strength. Fig.S7, Effects of coupling strength to global signal epsilon_s on the time of minimal order.

Published

2017

5. Fold-Hopf Bursting in a Model for Calcium Signal Transduction

Author

Brusch, Lutz, Lorenz, Wolfram, Or-Guil, Michal, Bär, Markus, and Kummer, Ursula

Subjects

Molecular Networks (q-bio.MN), FOS: Biological sciences, Quantitative Biology - Molecular Networks, Quantitative Biology::Cell Behavior

Abstract

We study a recent model for calcium signal transduction. This model displays spiking, bursting and chaotic oscillations in accordance with experimental results. We calculate bifurcation diagrams and study the bursting behaviour in detail. This behaviour is classified according to the dynamics of separated slow and fast subsystems. It is shown to be of the Fold-Hopf type, a type which was previously only described in the context of neuronal systems, but not in the context of signal transduction in the cell., Comment: 13 pages, 5 figures

Published

2003

6. Biosimulation of drug metabolism—A yeast based model

Author

Brusch Lutz, Wechler Kerstin, Ines Pieper, Sørensen Preben Graae, Mensonides Femke, Bertau Martin, and Katzberg Michael

Subjects

Biochemistry, General Medicine, Biology, Biosimulation, Toxicology, Yeast, Drug metabolism

Published

2009

7. Modelling and Analysis of Chevron Formation in the Fish Myotome

Author

Rost, Fabian, Brusch, Lutz, and Oates, Andrew Charles

Abstract

Myotomes of adult teleost have a folded shape often referred to as chevron shape. The chevron shape has been proposed to be optimal for the alternating body bending during swimming. Much less is known about which processes underly the ontogenetic development of the myotome shape. As far as we know, the only study that deals with this topic was done by Van Raamsdonk et al.(1974, 1977, 1979). They conclude” that the lateral body movements have both a shape determining and a shape-stabilizing role during the early stages of somite morphogenesis. We aim to shed new light on the mechanisms that shape the my- otome chevrons by developing and analysing a mathematical model of the interactions between muscle fibres and somite boundaries.

8. Data-driven Modeling of Cell Behavior, Morphogenesis and Growth in Regeneration and Development

Author

Rost, Fabian, Brusch, Lutz, Chara, Osvaldo, Deutsch, Andreas, Tanaka, Elly M., and Technische Universität Dresden

Subjects

developmental biology, sytems biology, developmental biology, regeneration, hippocampus, ddc:570, regeneration, biophysics, Systembiologie, Entwicklungsbiologie, Regeneration, axolotl, zebrafish, mathematical model

Abstract

The cell is the central functional unit of life. Cell behaviors, such as cell division, movements, differentiation, cell death as well as cell shape and size changes, determine how tissues change shape and grow during regeneration and development. However, a generally applicable framework to measure and describe the behavior of the multitude of cells in a developing tissue is still lacking. Furthermore, the specific contribution of individual cell behaviors, and how exactly these cell behaviors collectively lead to the morphogenesis and growth of tissues are not clear for many developmental and regenerative processes. A promising strategy to fill these gaps is the continuing effort of making developmental biology a quantitative science. Recent advances in methods, especially in imaging, enable measurements of cell behaviors and tissue shapes in unprecedented detail and accuracy. Consequently, formalizing hypotheses in terms of mathematical models to obtain testable quantitative predictions is emerging as a powerful tool. Tests of the hypotheses involve the comparison of model predictions to experimentally observed data. The available data is often noisy and based on only few samples. Hence, this comparison of data and model predictions often requires very careful use of statistical inference methods. If one chooses this quantitative approach, the challenges are the choice of observables, i.e. what to measure, and the design of appropriate data-driven models to answer relevant questions. In this thesis, I applied this data-driven modeling approach to vertebrate morphogenesis, growth and regeneration. In particular, I study spinal cord and muscle regeneration in axolotl, muscle development in zebrafish, and neuron development and maintenance in the adult human brain. To do so, I analyzed images to quantify cell behaviors and tissue shapes. Especially for cell behaviors in post-embryonic tissues, measurements of some cell behavior parameters, such as the proliferation rate, could not be made directly. Hence, I developed mathematical models that are specifically designed to infer these parameters from indirect experimental data. To understand how cell behaviors shape tissues, I developed mechanistic models that causally connect the cell and tissue scales. Specifically, I first investigated the behaviors of neural stem cells that underlie the regenerative outgrowth of the spinal cord after tail amputation in the axolotl. To do so, I quantified all relevant cell behaviors. A detailed analysis of the proliferation pattern in space and time revealed that the cell cycle is accelerated between 3–4 days after amputation in a high-proliferation zone, initially spanning from 800 µm anterior to the amputation plane. The activation of quiescent stem cells and cell movements into the high-proliferation zone also contribute to spinal cord growth but I did not find contributions by cellular rearrangements or cell shape changes. I developed a mathematical model of spinal cord outgrowth involving all contributing cell behaviors which revealed that the acceleration of the cell cycle is the major driver of spinal cord outgrowth. To compare the behavior of neural stem cells with cell behaviors in the regenerating muscle tissue that surrounds the spinal cord, I also quantified proliferation of mesenchymal progenitor cells and found similar proliferation parameters. I showed that the zone of mesenchymal progenitors that gives rise to the regenerating muscle segments is at least 350 µm long, which is consistent with the length of the high-proliferation zone in the spinal cord. Second, I investigated shape changes in developing zebrafish muscle segments by quantifying time-lapse movies of developing zebrafish embryos. These data challenged or ruled out a number of previously proposed mechanisms. Motivated by reported cellular behaviors happening simultaneously in the anterior segments, I had previously proposed the existence of a simple tension-and-resistance mechanism that shapes the muscle segments. Here, I could verify the predictions of this mechanism for the final segment shape pattern. My results support the notion that a simple physical mechanism suffices to self-organize the observed spatiotemporal pattern in the muscle segments. Third, I corroborated and refined previous estimates of neuronal cell turnover rates in the adult human hippocampus. Previous work approached this question by combining quantitative data and mathematical modeling of the incorporation of the carbon isotope C-14. I reanalyzed published data using the published deterministic neuron turnover model but I extended the model by a better justified measurement error model. Most importantly, I found that human adult neurogenesis might occur at an even higher rate than currently believed. The tools I used throughout were (1) the careful quantification of the involved processes, mainly by image analysis, and (2) the derivation and application of mathematical models designed to integrate the data through (3) statistical inference. Mathematical models were used for different purposes such as estimating unknown parameters from indirect experiments, summarizing datasets with a few meaningful parameters, formalizing mechanistic hypotheses, as well as for model-guided experimental planning. I venture an outlook on how additional open questions regarding cell turnover measurements could be answered using my approach. Finally, I conclude that the mechanistic understanding of development and regeneration can be advanced by comparing quantitative data to the predictions of specifically designed mathematical models by means of statistical inference methods.

Published

2017