Synchronization is a fundamental mechanism in biological networks: examples include networks of neurons in the circadian pacemaker and the insulin-secreting cells of pancreas. In this paper we examine the problem of finding conditions for constructing a network of synthetic biological oscillators that synchronize
Synthetic biology aims to engineer biological systems and components, ultimately for applications as...
Abstract—This paper provides synchronization conditions for networks of nonlinear systems. The compo...
Diverse biochemical rhythms are generated by thousands of cellular oscillators that somehow manage t...
Synchronization is a fundamental mechanism in biological networks: examples include networks of neur...
Abstract: This paper is concerned with a novel algorithm to study networks of biological clocks. A n...
Abstract: This paper is concerned with a novel algorithm to study networks of biological clocks. A n...
Synthetic biology seeks to understand and engineer biological networks that perform a quantitative d...
Synthetic biology has recently provided functional single-cell oscillators. With a few exceptions, h...
Engineering artificial networks from modular components is a major challenge in synthetic biology. I...
Networks of interacting biomolecules carry out many essential functions in living cells, but the ‘de...
We define a subclass of timed automata, called oscillator timed automata, suitable to model biologic...
Genetic oscillators that arrive from the dynamic interaction of molecular components have been shown...
Many biological systems consisting of a population of oscillators exhibit self-synchronization. In s...
Living organisms often display rhythmic and oscillatory behavior. We investigate here a challenge in...
AbstractWe define a subclass of timed automata, called oscillator timed automata, suitable to model ...
Synthetic biology aims to engineer biological systems and components, ultimately for applications as...
Abstract—This paper provides synchronization conditions for networks of nonlinear systems. The compo...
Diverse biochemical rhythms are generated by thousands of cellular oscillators that somehow manage t...
Synchronization is a fundamental mechanism in biological networks: examples include networks of neur...
Abstract: This paper is concerned with a novel algorithm to study networks of biological clocks. A n...
Abstract: This paper is concerned with a novel algorithm to study networks of biological clocks. A n...
Synthetic biology seeks to understand and engineer biological networks that perform a quantitative d...
Synthetic biology has recently provided functional single-cell oscillators. With a few exceptions, h...
Engineering artificial networks from modular components is a major challenge in synthetic biology. I...
Networks of interacting biomolecules carry out many essential functions in living cells, but the ‘de...
We define a subclass of timed automata, called oscillator timed automata, suitable to model biologic...
Genetic oscillators that arrive from the dynamic interaction of molecular components have been shown...
Many biological systems consisting of a population of oscillators exhibit self-synchronization. In s...
Living organisms often display rhythmic and oscillatory behavior. We investigate here a challenge in...
AbstractWe define a subclass of timed automata, called oscillator timed automata, suitable to model ...
Synthetic biology aims to engineer biological systems and components, ultimately for applications as...
Abstract—This paper provides synchronization conditions for networks of nonlinear systems. The compo...
Diverse biochemical rhythms are generated by thousands of cellular oscillators that somehow manage t...