University of Delaware, Newark - USA
DEIB - Alpha Room (building 24)
June 4th, 2018
5.00 pm
Contacts:
Patrizio Colaneri
Research Area:
Systems and Control
Living cells encode complex networks of interconnected biomolecular components for information processing and reliable decision-making. Recent advances in experimental technologies provide a unique peek into network functioning at the single-cell and single-molecule levels, where system dynamics is inherently stochastic and nonlinear. For example, many biomolecular components (genes, RNAs and proteins, etc.) often occur at low molecular counts, and hence are subject to considerable stochastic fluctuations in copy numbers over time. What control strategies ensure proper functioning of cellular biochemical processes in the face of such randomness is an intriguing fundamental problem that remains poorly understood. I will introduce a Stochastic Hybrid Systems (SHS) framework for modeling complex biomolecular circuits, and illustrate several state-of-the-art computational/analytical tools for analysis, control and inferences of SHS. I will then highlight several collaborative efforts that combine mathematical tools with single-cell data to address emerging medical problems, including cancer drug resistance, HIV dormancy and viral phage therapy.
Electrical and Computer Engineering, Biomedical Enginnering, mathematical Sciences, Center for Bioinformatics and Computational Biology, Evans Hall, Room 315, University of Delaware, Newark, DE, USA.
Research interest: Systems and Synthetic Biology; Instrumentation and Control of Biomedical Systems; Signal Processing; Computational Neuroscience. Systems and Control; Stochastic Processes; Computational Systems Biology; Mathematical Biology.