Deployment of a Fully-Automated Green Fluorescent Protein Imaging System in a High Arctic Autonomous Greenhouse

Higher plants are an integral part of strategies for sustained human presence in space. Space-based greenhouses have the potential to provide closed-loop recycling of oxygen, water and food. Plant monitoring systems with the capacity to remotely observe the condition of crops in real-time within the...

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Bibliographic Details
Published in:Sensors
Main Authors: Alain Berinstain, Rita Noumeir, Stephen Braham, Thomas Graham, Anna-Lisa Paul, Matthew Bamsey, Talal Abboud, Robert Ferl
Format: Article in Journal/Newspaper
Language:English
Published: MDPI AG 2013
Subjects:
green fluorescent protein
remote sensor
telemetry
plant health
life support
mars
astrobiology
analogue environments
imaging
Chemical technology
TP1-1185
Arctic
Online Access:https://doi.org/10.3390/s130303530
https://doaj.org/article/227252fa3ef94c6da3e507f46f201022
Description
Summary:Higher plants are an integral part of strategies for sustained human presence in space. Space-based greenhouses have the potential to provide closed-loop recycling of oxygen, water and food. Plant monitoring systems with the capacity to remotely observe the condition of crops in real-time within these systems would permit operators to take immediate action to ensure optimum system yield and reliability. One such plant health monitoring technique involves the use of reporter genes driving fluorescent proteins as biological sensors of plant stress. In 2006 an initial prototype green fluorescent protein imager system was deployed at the Arthur Clarke Mars Greenhouse located in the Canadian High Arctic. This prototype demonstrated the advantageous of this biosensor technology and underscored the challenges in collecting and managing telemetric data from exigent environments. We present here the design and deployment of a second prototype imaging system deployed within and connected to the infrastructure of the Arthur Clarke Mars Greenhouse. This is the first imager to run autonomously for one year in the un-crewed greenhouse with command and control conducted through the greenhouse satellite control system. Images were saved locally in high resolution and sent telemetrically in low resolution. Imager hardware is described, including the custom designed LED growth light and fluorescent excitation light boards, filters, data acquisition and control system, and basic sensing and environmental control. Several critical lessons learned related to the hardware of small plant growth payloads are also elaborated.

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