Title :
On biological pattern formation by contact inhibition
Author_Institution :
Dept. of Electr. Eng. & Comput. Sci., Univ. of California, Berkeley, CA, USA
Abstract :
Many patterning events in multi-cellular organisms rely on cell-to-cell contact signaling. We study a model which employs a graph to describe which cells are in contact, and examine its spatio-temporal dynamics. We first give an instability condition for the homogeneous steady-state. We then show that, for bipartite graphs, this instability condition also guarantees the existence and asymptotic stability of steady-states that exhibit a pattern of alternating high and low values in adjacent cells. Finally, we establish a strong monotonicity property of this model for bipartite graphs, which implies that almost every bounded solution converges to a steady-state.
Keywords :
asymptotic stability; cellular biophysics; graph theory; pattern formation; asymptotic stability; biological pattern formation; bipartite graphs; cell-to-cell contact signaling; contact inhibition; homogeneous steady-state; instability condition; monotonicity property; multicellular organisms; spatio-temporal dynamics; Asymptotic stability; Bipartite graph; Eigenvalues and eigenfunctions; Nickel; Pattern formation; Stability analysis; Steady-state;
Conference_Titel :
American Control Conference (ACC), 2012
Conference_Location :
Montreal, QC
Print_ISBN :
978-1-4577-1095-7
Electronic_ISBN :
0743-1619
DOI :
10.1109/ACC.2012.6315209
