ALCYONE

Autonomous Living Cell analYsis ON-chip for Evaluation of space Environment Effects: low-power integrated lab-on-chip for the assessment of radiation damage on living systems in nanosatellite missions

Abstract

The project aims at the design and realization of a new analytical platform implementing a series of innovative technologies able to provide a highly-integrated solution for the analysis in-situ of the effects of the space environment on model biological systems and for the evaluation of shielding technologies combined with radioprotective agents. The main objective of the project will be achieved through the development of a lab-on-chip device with integrated thin-film sensors and actuators that will implement an extremely compact cell-incubator capable to sample the status of the cell culture during a space mission using real-time monitoring techniques based on bioluminescence. Genetically modified microorganisms will be designed in order to monitor specific stress responses based on a luciferase-based reporter system. An electronic system will be integrated in the platform for the characterization of the radiation environment allowing to evaluate the correlation between observed biological effects and radiation exposure. The main features of the proposed technology include low power consumption, extreme compactness, high data efficiency and full automation making it suitable for cubesat missions. In particular, a complete cubesat payload will be designed to address and solve any integration issue and to provide a test bench for a preliminary set of experiments to be carried out on ground facilities simulating the deep space environment. The proposed system will therefore represent a key element to pave the route toward deep space human mission as it offers the possibility to test the effects of long term exposure to the space environment on model biological systems using simple platforms as cubesats. This opens new scenarios where minor effort will be required to plan multiple low-cost missions for improving the risk modeling and for testing new countermeasures in a continuous-improvement scheme.

Project details

Unibo Team Leader: Mara Mirasoli

Unibo involved Department/s:
Dipartimento di Chimica "Giacomo Ciamician"

Coordinator:
"Sapienza" Universita' Di Roma(Italy)

Other Participants:
ALMA MATER STUDIORUM - Università di Bologna (Italy)

Total Eu Contribution: Euro (EUR) 1.570.263,75
Project Duration in months: 36
Start Date: 01/01/2023
End Date: 31/12/2025

Cordis webpage

This project has received funding from the European Union’s Horizon Europe research and innovation programme under grant agreement No 101082679 This project has received funding from the European Union’s Horizon Europe research and innovation programme under grant agreement No 101082679