Statistical Inference from Multiscale Biological Data: theory, algorithms, applications

MSCA (Marie Skłodowska-Curie)HORIZON-TMA-MSCA-SEID: 101131463
EC Contribution
€7,406
Consortium Size
8 orgs
Start Year
2023
Summary

The last two decades have witnessed giant experimental breakthroughs in different areas of the life sciences, from genomics to epidemiology. Thanks to modern high-throughput techniques, biological systems across multiple scales from single molecules up to entire populations can now be probed quantitatively at high spatial and temporal resolutions. Besides enhancing our basic knowledge of a systems constituents, these data potentially encode a plethora of information about the functional constraints that govern its evolution and the physical constraints that limit its performance, as well as about levels of organization, dynamical constraints or design principles that would be hard to identify from low-throughput data. Extracting this information is also crucial for applications ranging from the design of proteins with a desired functionality to the reconstruction of contacts during an epidemics. Inverse statistical mechanics attempts to do it by inferring generative models (Boltzmann distributions) from data using methods from the physics of disordered and random systems. Specific characteristics of biological data however, like strong undersampling and heterogeneity, limit the effectiveness of these tools. SIMBAD aims at developing a class of statistical inference techniques capable of overcoming these issues. In SIMBAD, theoretical work will supply concepts and methods to address four pressing problems (learning protein sequence landscapes, inverse modeling metabolic networks, inferring contact networks from epidemiological data, and improving survival analysis models), which in turn will guide the theory towards integration with the existing standards of each field. This effort promises to open new pathways for basic research to impact economic, technological and societal issues; the high- profile cross-disciplinary expertise represented in SIMBAD ensures instead for measurable and achievable objectives, placing SIMBAD in an ideal position to achieve its goals

Consortium (8)

Project Results (12)

Source: CORDIS, the EU research results database.

Publications (9)
Cross-feeding percolation phase transitions of intercellular metabolic networks
Science Advances· 2025DOI
Luís C. F. Latoski, Andrea De Martino, Daniele De Martino
Decoding cancer dynamics: Hypergraph analysis of stem cell marker interactions through O-information and community detection
Physical Review E· 2025DOI
David H. Margarit, Marcela V. Reale, Gustavo Paccosi, Lilia M. Romanelli
Evolutionary emergent metabolic interactions in cell cultures: A statistical mechanics point of view
Physical Review E· 2025DOI
A. R. Batista-Tomás, C. Díaz-Faloh, R. Mulet
Metabolic coordination and phase transitions in spatially distributed multi-cellular systems
Communications Physics· 2025DOI
Krishnadev Narayanankutty, José Antonio Pereiro-Morejon, Arián Ferrero-Fernández, Valentina Onesto, Stefania Forciniti, Loretta L. del Mercato, Roberto Mulet, Andrea De Martino, David S. Tourigny, Daniele De Martino
Nonequilibrium steady-state dynamics of Markov processes on graphs
SciPost Physics· 2025DOI
Stefano Crotti, Thomas Barthel, Alfredo Braunstein
Practical debiasing with the Covariant Prior in the proportional regime when <i>p</i> < <i>n</i>
Journal of Physics Communications· 2025DOI
Emanuele Massa, Anthony C C Coolen
SYSTEM VARIABLE REDUCTION AND GLOBAL SENSITIVITY ANALYSIS FOR A COMPLEX MODEL OF CANCER CELL DIFFERENTIATION
Journal of Biological Systems· 2025DOI
DAVID H. MARGARIT, GUSTAVO PACCOSI, ANDREA PAGNANI, MARCELA V. REALE, ARIEL F. SCAGLIOTTI, LILIA M. ROMANELLI
Unveiling cancer stem cell marker networks: A hypergraph approach
Computational Biology and Chemistry· 2025DOI
David H. Margarit, Gustavo Paccosi, Marcela V. Reale, Lilia M. Romanelli
The advantage of periodic over constant signalling in microRNA-mediated regulation
Nucleic Acids ResearchDOI
Elsi Ferro, Candela L Szischik, Alejandra C Ventura, Carla Bosia
Deliverables (3)
Data Management Plan
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