Für den Inhalt der Angaben zeichnet die Projektleitung verantwortlich.
This project is one of the five winners of the call 2016 «Microbials – Direct Use of Micro-Organisms».
Project partners: ETH Zurich
Förderbeitrag: CHF 450'000
Dauer: 01.2017 - 12.2019
Handlungsfeld: Microbials, seit 2016
Prof. Dr. Jan Wendelin Stark
Dept of Chemistry and Applied Sciences
HCI E 107, Vladimir-Prelog-Weg 1
8093 Zürich (Schweiz)
- wendelin.stark@chem. ethz. ch
Microorganisms are very good at sensing their environment – can we use this capability in a technical or medical sensor? In this project, we intent to build a biosensor platform based on so called living materials, i.e. combinations of materials and organisms, accessible to a sampling area or liquid. The central element is an enclosed, optionally genetically engineered microorganisms. They cannot escape the material, but are still able to communicate with their environment (e.g. sensing and quantifying analytes). In a second part, the sensor platform shall be implemented as an easy, user-friendly readout device.
Our concept of living material was inspired by natural living surfaces such as lichens, and bacterial or fungal biofilms and further developed by adding the sensing function. We have already shown that oligosaccharides (e.g., lactose, galactose) in complex samples can be quantified based in such systems. Minimal equipment requirements and availability to untrained users outside of a laboratory environment make such systems attractive for developing countries.
The objective of this project is to build an inexpensive and fast microorganism-based biosensor platform and additionally tackle questions of storability, biosafety, multiplexing and experimenting with different organisms and reporter systems.
Was ist das Besondere an diesem Projekt?
Generally the project aims at an easy use of optionally genetically modified microorganisms to enable an untrained user to exploit their enormous sensing capabilities. Analysis tasks could for example involve the assessment of water and soil quality and food contamination within a complex sample.
Recent work in the field of whole-cell biosensors will be considered and integrated into the new biosensor platform. Innovation comes by combining established biotechnological platforms with modern engineering and cutting edge product development tools resulting in an integrated system.
Previous work by our research group was based on the bacterium E. coli as a reporter organism. In a first step to move from a living material to a sensor chip, we have switched to use the spore-forming Bacillus subtilis as sensing organism. The change to B. subtilis enabled us to move towards the milestone of finding a material suitable for cell embedding. A mechanically stable polymer hydrogel was identified and tested as a sensor matrix first without and later with cells. Progress is also reported on prototyping a readout system. With 3D-printing as a rapid prototyping method first drafts of a chip suitable for smartphone-readout were built.
The current focus is to combine the material with the sensor-microorganisms, optimize the quantification and move towards a user-friendly sensor platform.
Programmable living material containing reporter micro-organisms permits quantitative detection of oligosaccharides
, Biomaterials, 2015Incorporating microorganisms into polymer layers provides bioinspired functional living materials
, PNAS, 2012; featured as Editor’s Choice: Carnivorous Cloth, Science, January 20th 2012, Vol. 335, Issue 6066, pp. 264. Incorporation of Penicillin-Producing Fungi into Living Materials to Provide Chemically Active and Antibiotic-Releasing Surfaces
, Angewandte Chemie, 2012; featured in Nature Chemistry, 4, 960, 2012.
Am Projekt beteiligte Personen
Letzte Aktualisierung dieser Projektdarstellung 28.11.2018