Title :
A computational framework for modelling multicellular biochemistry
Author :
Montagna, Sara ; Viroli, Mirko
Author_Institution :
ALMA MATER STUDIORUM-Univ. di Bologna, Cesena
Abstract :
A state-of-the-art problem in Computational Systems Biology is to provide suitable tools to model and predict the behaviour of multicellular systems (tissues, embryos) where biological interactions occur both inside and between cells (or compartments in general). Starting from existing computational models and languages such as stochastic pi-calculus, Petri Nets, mobile ambients, and membrane computing, we developed a new computational framework based on (i) a compositional model for biological compartments, and (ii) an enhanced model of chemical rules addressing also biomechanical actions such as substances diffusion across membranes or compartments splitting. We tested a fragment of the framework using a case study based on spatial pattern formation in embryogenesis, where the interplay between cells´ internal dynamics and cell-to-cell interactions has a central role.
Keywords :
Petri nets; biochemistry; biocomputing; biology computing; cellular biophysics; pi calculus; Petri net; biological interaction; cell-to-cell interaction; chemical rules; computational framework; computational languages; computational model; computational systems biology; embryogenesis; membrane computing; mobile ambients; multicellular biochemistry; multicellular systems; spatial pattern formation; stochastic pi-calculus; Biochemistry; Biological interactions; Biological system modeling; Biological tissues; Biology computing; Biomembranes; Computational modeling; Computational systems biology; Embryo; Predictive models;
Conference_Titel :
Evolutionary Computation, 2009. CEC '09. IEEE Congress on
Conference_Location :
Trondheim
Print_ISBN :
978-1-4244-2958-5
Electronic_ISBN :
978-1-4244-2959-2
DOI :
10.1109/CEC.2009.4983218
