Litcius/Paper detail

Recurrent neural networks in synthetic cells: a route to autonomous molecular agents?

Michele Braccini, Ethan Collinson, Andrea Roli, Harold Fellermann, Pasquale Stano

2023Frontiers in Bioengineering and Biotechnology18 citationsDOIOpen Access PDF

Abstract

Prompted by recent advancements in synthetic biology, we highlight the possible use of bio-chemical reactivity to generate tools and strategies for a genuinely new AI in the wetware domain. Chemical neural networks (CNNs) could be realized inside synthetic cells by employing elements of bacterial two-component signaling systems. The major novelty of CNNs, when compared to neural networks, consists in the embodiment of the network nodes and links: these network elements are no more logical entities but physical ones, whose behavior is subjected to the physico-chemical laws. Moreover, the results of network computation (i.e., molecules) belong to the same domain as the network elements, the physical domain. Building on this, we illustrate a viable way for implementing recurrent links in CNNs, making them able to have an internal state, i.e. a memory. This capability makes it possible to endow CNNs with some sort of autonomy, as they can take decisions also on the basis of their state and not just as a consequence of the computation of the inputs. At a more fundamental level, synthetic cell technology can be a platform for crucial investigations of theoretical biology principles. For instance, autonomy can be seen as a prerequisite for agency and other more complex characteristics of living beings.

Topics & Concepts

Computer scienceArtificial intelligenceComputational biologyBiologyGene Regulatory Network AnalysisPhotoreceptor and optogenetics researchMolecular Communication and Nanonetworks