NOMIS Fellowship Program at ISTA: Enabling high-risk research across disciplinary borders

April 12, 2022

The research of NOMIS Fellows Maayan Levy and David Brückner have been profiled in an article on the Institute of Science and Technology Austria’s website. The institute recently announced a new call for proposals for the NOMIS Fellowship Program at ISTA.

The NOMIS Fellowship enables multidisciplinary connections in science.

Many problems in modern science require researchers to think beyond the borders of their discipline. Together, neuroscience and computer science investigate how the human brain works and information theory paired with physics might help to shed light on how cells make decisions. However, science is still usually organized into departments and research fields. The NOMIS Fellowship at the Institute of Science and Technology Austria wants to support scientists in bringing disparate fields together.

To draw new connections and gain insights, scientists often need to employ a multidisciplinary approach. This is exactly what the NOMIS Fellowship at the Institute of Science and Technology Austria (ISTA) offers. Established in 2021, this program has been made possible by the partnership between ISTA and the NOMIS Foundation.

Scientists that join this postdoc program are supervised by two experienced group leaders from different fields, building a bridge between the teams and bringing together differing perspectives and approaches. They have access to ISTA’s state-of-the-art research facilities, scientific leadership trainings, and career development support. This fully funded three-year position enables the fellows to pursue high-risk ideas that push at the very frontiers of scientific knowledge. Currently, there are four scientists who hold NOMIS Fellowships at ISTA.

Thinking Networks

One of the NOMIS fellows is Maayan Levy, who wants to understand the physical phenomena underlying processes in the human brain – like memory formation. Researchers cannot yet simulate the human brain’s tens of billions of neurons and their connections – the synapses – on a computer, but they can use smaller networks to gain insights. Levy is programming virtual networks of about 10,000 neurons with biologically realistic parameters and circuit architecture. These networks help her understand how changes in just a small number of synapses can produce a memory. Similar to traditional neural networks in machine learning, Levy’s networks can be trained to recognize simple images. However, hers are not aimed at network-wide optimization but try to closely mimic real biological functions using only local changes on the level of synapses. Levy’s work brings together many different fields ranging from neuroscience and biophysics to chemistry and computer science. At this intersection of disciplines, she is supported by Tim Vogels from the Computational Neuroscience and Neurotheory group and Peter Jonas from the Cellular Neuroscience group. These two groups bring together their expertise on the physical characteristics and plasticity of cells and machine learning applied to neuronal systems.

Simulation of neurons. A succession of simulations of biologically realistic neurons with different cell types and realistic morphology. In each iteration of the simulation, only a small number of synapses are allowed to change and the network is trained and tested for the formation of memories. When a network succeeds, the next networks in the simulation start with a similar configuration. ©Maayan Levy

Decision-making Cells

Another NOMIS Fellow is David Brückner, who studies the way cells in your body make decisions about where to go and what to develop into. Cells can migrate to heal wounds and fight pathogens. Stem cells can even differentiate into all sorts of cell types. While scientists already understand many of the biological processes involved, the fundamental principles of how cells use complex external inputs to make decisions remain unknown.

To do this, Brückner is looking at large experimental data sets of hundreds of cell movements and develops algorithms to pierce through the noisy movement data. He wants to find the underlying patterns hidden in the data, like a needle in the haystack.

Brückner is being supported by Edouard Hannezo from the Physical Principles in Biological Systems group and Gašper Tkačik from the Information Processing in Biological Systems group. These teams investigate, on the one hand, the biomechanics of cells and their movement, and on the other, tackle the problem of understanding biological systems from the perspective of information theory.

David Brückner (Photo: Max Hofstetter)

Continue to this ISTA release

Read more about the latest call for proposals at ISTA