Organic chemistry pioneered a synthetic approach to understanding chemical reactions and mechanisms through synthesis of novel and biochemical compounds.
Since the early 80's at the MPI GöttingenMcCaskill(and since the early 90's BioMIP) has been pursuing a synthetic approach to understanding the physico-chemical basis of biological systems. This field could be entitled organic physics: since it employs techniques from the area of chemical physics to aid the synthetic approach to chemical systems, which extends organic chemistry to the next higher level of integration : i.e. systems chemistry. This field has a clear relation both to organic computing and synthetic biology (terms coined more recently by von der Malsburg and Endy), and is more process oriented than supramolecular chemistry.
At the IMB in Jena in the 90's, we developed synthetic biochemical evolving systems and built artificial spatial environments using microflluidics to control their evolution. We also built reconfigurable hardware to simulate molecular evolution as strings of bits diffusing in massively parallel electronic hardware, which we could reconfigure to represent different systems. We used the same FPGA technology to control novel single molecule detection hardware for monitoring real synthetic biochemical systems, and to test automata theories of evolutionary self-organization.
At the National Research Lab for IT (GMD), around the turn of the millenium, we investigated bootstrapping self-organization (in the spirit of John von Neumann) and began designing "wet" DNA processing systems, benchmarking our progress in programming such systems using the combinatorially hard problem of Maximal Clique. We integrated a light programmable selection module working in a continuous flow microsystem using magnetic beads, and showed how it could be used to design programmable biochemical systems and for directed evolution. We also perfected our reconfigurable hardware platform (MereGen) and developed analytical models of stochastic spatial evolutionary self-organization (PRESS).
In 2004, we joined the Ruhr University (after a brief interim hosted by the Fraunhofer Gesellschaft in the multidisciplinary labs we built up at the GMD) to take the next step in integrating self-organization with information processing, by designing microsystems for bridging the gap to the first chemical living systems. Since then, we have developed the concepts of individual cell micro-complementation and electronic genomes for artificial cells and have been working on designing an omega machine to program the self-organization of combinatorially complex chemical systems towards living cells. At the same time we have been developingnovel simulation techniquesto studymesoscale self-assembly and self-organizationand have investigated thepower of self-assemblyforevolutionary problem solution. We are applying ourmesoscale simulation toolsto complex combinatorialprotein sortingin theendocytosis of liver cells, which represent another grand challenge to understanding rich spatial chemical self-organization. Recently we have begun to apply our microfluidic technology with parallel confocal fluorescence detection towards both artificial and live cell control, closing the loop back to synthetic systems science.