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Biomathematics

In biology and the medical sciences, complexity and detail prevail. Many branches of mathematics may be employed to great detail to provide biological insight. The biomathematics group is active in the following areas.

The research interests in dynamical systems encompass various domains:

  • Mathematical Neuroscience: Our research interests are in modeling, simulation, and statistical analysis of neuronal activity. We analyze deterministic and stochastic models of brain activity at various scales, from single neurons to networks of coupled oscillators, neural masses, and continuum neural fields to gain insights into neural dynamics. We develop statistical methods and perform statistical analysis of brain signals obtained by functional magnetic resonance imaging (fMRI), electroencephalography (EEG), and magnetoencephalography (MEG). We also develop numerical methods with provable accuracy that predict activity, quantify uncertainties in models with random data, and infer model inputs from data.
  • Statistics for Big Biomedical Data: We work on statistical methodology, ranging from parameter estimation, inference, prediction to class discovery, to learn from high-throughput experiments on the cell. This methodology aids, for instance, in the analysis of oncogenomic studies. Such studies characterize the expression levels of many genes simultaneously in a limited set of cancer patients. The methodology then enables the identification of genes predictively associated with the clinical outcome of the patients. Alternatively, we develop methods for the reconstruction of the cancer cell's gene-gene interaction network from longitudinal in vitro studies.
  • Dynamics of Cellular Processes: The department also has a long-standing collaboration with systems biologists. Here, we try to develop dynamical models of cellular processes and behaviour. How does a single cell sense its environment and deal with stochastic information? How does it decide whether to invest into growth processes or instead mount stress responses? Understanding such broad questions, relevant for all of unicellular life, requires both stochastic and deterministic modeling, formal analysis of ODE and PDE models, and optimization and control theory.
  • Networks and Topology: Graphs and hypergraphs are common topological models to understand a variety of biological systems, including gene expression, protein-protein interaction, phylogeny, neural networks and metabolic networks. We are interested in developing the mathematical foundations of network theory and extending topological methods while exploring applications to biology. For example, how do topological properties of the network of interactions between neural oscillators shape emergent synchronization and, thus, neural function?

Researchers and their interests

  • Daniele Avitabile. Numerical bifurcation analysis, mathematical neuroscience.

    My research interests include: numerical bifurcation analysis, mathematical neuroscience, multi-scale dynamics, numerical methods, localised states, coherent structures, nonlinear media, reaction-diffusion systems, and nonlocal models.

    Webpage:

  • Christian Bick. Network dynamical systems.

    My research interests focus on dynamical systems and networks. This includes dynamical phenomena in the dynamics of coupled oscillator networks, network dynamical systems with generalized, higher-order, and adaptive interactions, and the dynamics of asynchronous networks.

    Website:

  • Mathisca de Gunst . Statistics for Life Sciences.

    My research is in the area of stochastic modeling and statistical analysis of biological processes, and comprises development, assessment and application of statistical models and tools. I use mathematical models ranging from (non)linear regression, Markov and hidden Markov models to non-Markovian counting processes, and frequentist as well as Bayesian estimation techniques. My main interest is in statistical models for networks with a special focus on neuroscience applications.

  • Rikkert Hindriks. Statistical inference for EEG/MEG and fMRI.

    My expertise is in statistical inference, computational and inverse modeling of hemodynamic and electrophysiological brain signals, with particular focus on functional connectivity. My current interests include inference for non-Gaussian and higher-order functional connectivity and classification of invariant connectivity measures.

  • Renee Hoekzema. Manifold topology and applications of topology in bioscience.

    On the one hand, I work on theoretical questions in algebraic topology, in particular, the study of manifold invariants in arbitrary dimensions, cobordism categories, and topological quantum field theories. On the other hand, I work on applications of topology within (bio)science, such as the development of analysis methods for single-cell data and models for coevolution.

    Webpage:

  • Joost Hulshof. Nonlinear partial differential equations, applications in physics and biology.

    I work on a variety of nonlinear partial differential equations, e.g., those describing thin films, porous media, turbulence and combustion. I also have a keen interest in problems from systems biology, such as metabolism, growth rate optimisation and control theory.

    Website:

  • Raffaella Mulas. Graphs and hypergraphs, spectral theory.

    My research focuses on the study of graphs and hypergraphs. In particular, I am mainly interested in spectral theory, combinatorics, non-backtracking operators, and applications to network science.

    Website:

  • Bob Planqué. Mathematical biology, ordinary differential equations, optimization.

    I'm interested in a wide variety of problems in mathematical biology, with an emphasis on systems biology and microbial physiology. My main expertise is in ordinary differential equations, but the applications often require other techniques, such as optimization, control theory, and nonlinear maps.

    Website:

  • Wessel van Wieringen. High-dimensional data and regularized learning.

    My primary interest is in modeling data stemming from complex phenomena that have been characterized in xof the model's parameters from the high-dimensional data, how this learning may benefit from existing knowledge present in related domains, and inference regarding this parameter within this setting.

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