Engineering calcium signaling of astrocytes for neural-molecular computing logic gates

This paper proposes the use of astrocytes to realize Boolean logic gates, through manipulation of the threshold of Ca2+ ion flows between the cells based on the input signals. Through wet-lab experiments that engineer the astrocytes cells with pcDNA3.1-hGPR17 genes as well as chemical compounds, we show that both AND and OR gates can be implemented by controlling Ca2+ signals that flow through the population. A reinforced learning platform is also presented in the paper to optimize the Ca2+ activated level and time slot of input signals T-b into the gate. This design platform caters for any size and connectivity of the cell population, by taking into consideration the delay and noise produced from the signalling between the cells. To validate the effectiveness of the reinforced learning platform, a Ca2+ signalling simulator was used to simulate the signalling between the astrocyte cells. The results from the simulation show that an optimum value for both the Ca2+ activated level and time slot of input signals T-b is required to achieve up to 90% accuracy for both the AND and OR gates. Our method can be used as the basis for future Neural-Molecular Computing chips, constructed from engineered astrocyte cells, which can form the basis for a new generation of brain implants.

Automated summary

This paper proposes using astrocytes to implement Boolean logic gates by controlling Ca2+ ion flows between the cells, and introduces a reinforced learning platform to optimize the activation level and time slot of input signals to the gate. Experimental results show that both AND and OR gates can be achieved through engineered cells, and simulation results indicate that an optimal activation level and time slot value are required for high accuracy.