Overview
The modern revolution in single-cell technologies and lineage tracing tools has enabled measurements at unprecedented resolution and scale, generating large, high-dimensional datasets that reveal extensive non-genetic variation and “plasticity” driving diverse cellular outcomes. The concepts of “plasticity,” “cell state,” and “fate” have surged in various biological contexts, from developmental biology to disease progression, yet often lack clear consensus definitions.
The concept of “cell states” was first established by Conrad Waddington in 1957 when he described cellular development following an epigenetic landscape shaped by gene expression. Recently, “cell state” has seen liberal use in various contexts, often interchangeably with “cell type” and “cell identity,” resulting in confusion and stalled progress towards the proposed creation of “virtual cells” that can bypass the need for or significantly constrain physical experiments. Moreover, developing robust connections from cell states to eventual fates remains challenging.
Robust regulatory control of these cell-fate decisions is essential in development, homeostasis, and regeneration, as well as during dynamic responses to changing contexts, such as immune responses; however, it gets altered in pathological conditions, such as cancer and autoimmune disease. Recent advances in collecting spatiotemporal data about cellular decision-making have created an urgent need for new mathematical and computational approaches. Tools from dynamical systems theory, information theory, and stochastic processes are now being employed to decode the trajectories that cells traverse during transitions, but significant quantitative challenges remain that require novel mathematical frameworks.
This workshop aims to bring together theoreticians, experimentalists, statisticians, and computational modelers to formalize a unified framework for understanding plasticity and cell state-fate relationships. We will explore novel classification and continuous paradigms inspired by physical principles governing biological systems, reframing traditional machine learning challenges through the lens of physical constraints imposed by biomolecular signaling. This integrated approach offers unique advantages where traditional computational methods face limitations: handling extremely limited data, addressing inherently noisy biological measurements, and maintaining interpretability within mechanistic models.
Participants will engage with both theoretical foundations and practical implementations, gaining insights into how biologically informed computational architectures can yield more robust, efficient, and interpretable systems for analyzing complex biological data and ultimately predicting cell fate decisions.
Schedule
June 29 2026 Monday
12:15-1:45pm
Optimal Transport and Learning Dynamical Systems Equations by Elizabeth Jerison
2:00-3:30;pm
AI Tools/Methodologies to Learn Cell State Transitions From Single Cell Data
Speaker: Samantha Riesenfeld (University of Chicago)
4:00-5:00pm
Poster Session
Participants
Organizers
Yogesh Goyal – Northwestern University
Suri Vaikuntanathan – University of Chicago
Samantha Riesenfeld – University of Chicago
Mohit Kumar Jolly – Indian Institute of Science, Bangalore
Ben Kuznets-Speck – Northwestern University
Speakers
Mohamed Abazeed – Northwestern Unniversity
Shaon Chakrabarti – National Centre for Biological Sciences
Brian Cleary – Boston University
Subhajyoti De – Rutgers Cancer Institute
Jasmine Foo – University of Minnesota
Katie Galloway – Massachusetts Institute of Technology
Sui Huang – Institute for Systems Biology
Herbie Levine – Northeastern University
Jessica Li – Fred Hutchinson Cancer Center
Adam MacLean – University of Southern California
Carsten Marr – Helmholtz Munich
Michael Meers – Washington University
Pankaj Mehta – Boston University
Ian Mellis – Columbia University
Tom Norman – Memorial Sloan Kettering Cancer Center
José Onuchic – Rice University
Lior Pachter – California Institute of Technology
Susanne Rafelski – Allen Institute
Archishman Raju – National Centre for Biological Sciences (NCBS Bangalore)
Vijay Ramani – Gladstone Institutes
Vito Rebecca – Johns Hopkins University
Russell Rockne – Beckman Research Institute, City of Hope
Eric Siggia – Rockefeller University
Peter Sims – Columbia University
Rita Strack – Nature
Julie A. Theriot – University of Washington Seattle
Peter Winter – The Broad Institute of MIT and Harvard
Jianhua Xing – University of Pittsburg