Technological Evolution of Synergy Between Physicochemical and Living Systems

Project: Research

Project Details

Description

We will develop artificial, technological evolution and use it to design functional ecosystems consisting of up to three forms of living technology, namely, artificial chemical life, living microorganisms, and complex chemical reaction networks for the purpose of improved treatment and cleanup of wastewater for energy generation. The goals of this project are i) develop a general, robotic platform, which by using artificial evolution can optimize the performance of a physicochemical or microbial system and its environment and ii) use the robotic platform to evolve improved microbial fuel cells in terms of robustness, longevity, or adaptability. The robot evolutionary platform will take the form of an open-source 3D printer extended with functionality for handling liquids and
reaction vessels, and for obtaining feedback from the reaction vessels either using computer vision or task-specific sensors in real-time. The robot platform will optimize parameters such as the environment, hydraulics or real-time interaction with experiments (for instance, timing of injection of nutrients, removal of metabolic products, stirring, etc.) to maximize a desired functionality. Initially, we investigate processes such as fluid-structure-interaction driving bio-aggregate structure and in turn metabolic activity as well as the interaction of nanoparticles and bacterial cells by analyzing the outcome of the evolutionary process using state-of-the-art imaging techniques. We then seek to exploit synergies between these technologies to significantly improve the ability of the living technology, in the form of optimized microbial fuel cells, to cleanup wastewater. Overall, this is a crossdisciplinary project involving state-of-the-art chemistry, imaging, robotics, artificial life, microbiology and bioenergy harvesting for the purpose of enhancing our understanding of living technologies and how to best design and exploit groundbreaking bio-hybrid systems.
AcronymEVOBLISS
StatusFinished
Effective start/end date01/02/201431/01/2018

Collaborative partners

  • IT University of Copenhagen (lead)
  • University of the West of England
  • Karlsruher Institut für Technologie
  • University of Glasgow
  • University of Southern Denmark

Funding

  • European Commission: DKK19,042,036.00

Fingerprint

Explore the research topics touched on by this project. These labels are generated based on the underlying awards/grants. Together they form a unique fingerprint.
  • A ROBOT AND A METHOD OF CONTROLLING A ROBOT

    Støy, K. (Inventor), Faina, A. (Inventor) & Nejatimoharrami, F. (Inventor), 21 Sept 2017, IPC No. B25J9/16, Patent No. WO2017157402 (A1) ― 2017-09-21, Priority date 17 Mar 2016, Priority No. DKPA201670155 20160317

    Research output: Patent