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Team:Tsinghua-A/Safety/HP
From 2011.igem.org
Safety Section
Background
The ideas of electronic circuit based design have long been a part of the fundamental research since the very beginning of synthetic biology. However, as the scale of designs becomes larger and larger, researchers start to find it difficult to adapt those ideas of circuits to the biological system, in which two main properties bottleneck the realization of these ideas.
First, biological reactions are considerably much slower, when compared with circuits, thus less possible to analogize the electronic components.
Second, synthetic biology fails to get the concept ‘wire’ introduced, due to the liquid environment of biological reaction, which decrease both the quality and the quantity of signals.
In this passage, we, with the consideration of the basic analysis method in information science, try to propose some new perspectives on the combination of synthetic biology and electronics.
Bottom-up Method
In modern electronics, people rarely focus on the detail of a particular component when designing systems, for these single components have already been well-characterized and standardized. All that requires is innovating rather than just repeating. When it comes to biology, we are surprised to find that some basic parts, such as AND gate, register and toggle switch, have been applied to genetic machines. While, there is still a far way to go.
Reaction rate
Usually, the reactions of protein expressing cost a period on the scale of hours, which is disappointing when thinking in an electronic way. Fortunately, the rate of protein-protein interaction (PPI) is relatively fast, which makes us feel optimistic. The potential of these ‘high-speed’ reactions is to be explored.
On the other side, a low rate does make a difference in some aspects, especially in those need delay. Capacitors is widely used in sequential circuits like oscillator and trigger in order to realize delay, correspondingly, the low rate in biological reaction shows its preeminence in forming delay, thus easy to establish a inertia system.
Independent signals
To overcome the interference of signals in liquid and simulate the function of wires in circuits, we put forward some solutions. Different populations of bacteria communicate under a variety of signal molecules, each independent with others. Whereas, it’s not as easy when the amount of signals increases, for that molecules should maintain orthogonality.
In our further research, we try to utilize microfluidical chips, which aim at separating signals and transmitting information through physical isolation, to achieve the independence of biological reactions.
