Developing Biological ISRU: Implications for Life Support and Space ExplorationMain findings: 1) supplementing very dilute media for cultivation of CB with analogs of lunar or Martian regolith effectively supported the proliferation of CB; 2) O2 evolution by siderophilic cyanobacteria cultivated in diluted media but supplemented with iron-rich rocks was higher than O2 evolution by same strain in undiluted medium; 3) preliminary data suggest that organic acids produced by CB are involved in iron-rich mineral dissolution; 4) the CB studied can accumulate iron on and in their cells; 4) sequencing of the cyanobacterium JSC-1 genome revealed that this strain possesses molecular features which make it applicable for the cultivation in special photoreactors on Moon and Mars. Conclusion: As a result of pilot studies, we propose, to develop a concept for semi-closed integrated system that uses CB to extract useful elements to revitalize air and produce valuable biomolecules. Such a system could be the foundation of a self-sustaining extraterrestrial outpost (Hendrickx, De Wever et al., 2005; Handford, 2006). A potential advantage of a cyanobacterial photoreactor placed between LSS and ISRU loops is the possibility of supplying these systems with extracted elements and compounds from the regolith. In addition, waste regolith may be transformed into additional products such as methane, biomass, and organic and inorganic soil enrichment for the cultivation of higher plants.
Document ID
20100008463
Acquisition Source
Johnson Space Center
Document Type
Extended Abstract
Authors
Brown, I. I. (NASA Johnson Space Center Houston, TX, United States)
Allen, C. C. (NASA Johnson Space Center Houston, TX, United States)
Garrison, D. H. (NASA Johnson Space Center Houston, TX, United States)
Sarkisova, S. A. (NASA Johnson Space Center Houston, TX, United States)
Galindo, C. (NASA Johnson Space Center Houston, TX, United States)
Mckay, David S. (NASA Johnson Space Center Houston, TX, United States)