Living cells are able to produce a wide variety of biological responses when subjected to biochemical stimuli. It has become apparent that these biological responses are regulated by complex chemical reaction networks (CRNs). Unravelling the function of these circuits is a key topic of both systems biology and synthetic biology. Recent progress at the interface of chemistry and biology together with the realisation that current experimental tools are insufficient to quantitatively understand the molecular logic of pathways inside living cells has triggered renewed interest in the bottom-up development of CRNs. This builds upon earlier work of physical chemists who extensively studied inorganic CRNs and showed how a system of chemical reacti...
Oscillators are essential to fuel autonomous behaviours in molecular systems. Artificial oscillators...
State-of-the-art biochemical systems for medical applications and chemical computing are application...
Oscillators are essential to fuel autonomous behaviours in molecular systems. Artificial oscillators...
Living cells are able to produce a wide variety of biological responses when subjected to biochemica...
Living cells are able to produce a wide variety of biological responses when subjected to biochemica...
Living cells are able to produce a wide variety of biological responses when subjected to biochemica...
Living cells are able to produce a wide variety of biological responses when subjected to biochemica...
A new discipline of “systems chemistry” is emerging, which aims to capture the complexity observed i...
Until very recently, synthetic chemistry has focussed on the creation of chemical entities with desi...
The signal-response characteristics of a living cell are determined by complex networks of interacti...
Biochemical systems have been influenced, altered, and engineered to produce a myriad of complex beh...
This chapter addresses the issue of generating target behaviors in <i>in vitro</i> chemical systems ...
Biochemical interactions in systems and synthetic biology are often modeled with chemical reaction n...
Readily programmable chemical networks are important tools as the scope of chemistry expands from in...
The use of abstract chemical reaction networks (CRNs) as a modelling and design framework for the im...
Oscillators are essential to fuel autonomous behaviours in molecular systems. Artificial oscillators...
State-of-the-art biochemical systems for medical applications and chemical computing are application...
Oscillators are essential to fuel autonomous behaviours in molecular systems. Artificial oscillators...
Living cells are able to produce a wide variety of biological responses when subjected to biochemica...
Living cells are able to produce a wide variety of biological responses when subjected to biochemica...
Living cells are able to produce a wide variety of biological responses when subjected to biochemica...
Living cells are able to produce a wide variety of biological responses when subjected to biochemica...
A new discipline of “systems chemistry” is emerging, which aims to capture the complexity observed i...
Until very recently, synthetic chemistry has focussed on the creation of chemical entities with desi...
The signal-response characteristics of a living cell are determined by complex networks of interacti...
Biochemical systems have been influenced, altered, and engineered to produce a myriad of complex beh...
This chapter addresses the issue of generating target behaviors in <i>in vitro</i> chemical systems ...
Biochemical interactions in systems and synthetic biology are often modeled with chemical reaction n...
Readily programmable chemical networks are important tools as the scope of chemistry expands from in...
The use of abstract chemical reaction networks (CRNs) as a modelling and design framework for the im...
Oscillators are essential to fuel autonomous behaviours in molecular systems. Artificial oscillators...
State-of-the-art biochemical systems for medical applications and chemical computing are application...
Oscillators are essential to fuel autonomous behaviours in molecular systems. Artificial oscillators...