Spacecraft microbes: Difference between revisions
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===Manned Spacecraft and Space Stations=== | ===Manned Spacecraft and Space Stations=== | ||
Hermetically sealed spacecraft designed for human occupancy provide many opportunities for microbial populations. The same conditions that create an oasis of Earth-like conditions for humans benefit their commensal microbial partners as well. Conditions inside the craft are aerobic, warm, and generally ideal for | Hermetically sealed spacecraft designed for human occupancy provide many opportunities for microbial populations. The same conditions that create an oasis of Earth-like conditions for humans benefit their commensal microbial partners as well. Conditions inside the craft are aerobic, warm, and generally ideal for mesophilic heterotrophs (bioshmars). | ||
The first and probably richest microenvironment inside the craft is the astronauts themselves. The natural human microbiota accompanies them on their journey. | The first and probably richest microenvironment inside the craft is the astronauts themselves. The natural human microbiota accompanies them on their journey (bioshmars). Human bodies provide a rich source of carbon sources and nutrients and the commensal and mutuaistic members of our skin and body cavity microbial ecosystems probably are the most substantial source of inoculation to a craft's interior. However, this of course means that pathogens, particularly opportunistic pathogens, can just as easily enter which has been demonstrated in previous research (bioshmars). | ||
Surfaces of the craft also provide adequate environments for many bacteria. Microbes that colonize the infrastructure and equipment are termed technofiles and can be a serious threat to the craft's integrity (bioshmars). Bacterial-fungal associations will form on polymers to utilize them as a carbon source and release enzymes and acids that further corrode the polymers (bioshmars). Biodegredation of polymers in this way can also release volatile noxious byproducts that can adversely affect air quality (Novikova 2002). Microbes can also exploit organic deposits on metal surfaces and similarly the metal through release of enzymes and organic acids(bioshmars). Polymer and surface corrosion were both observed on the MIR space station (Novikova 2004) and technophile bacterial strains have been detected on the ISS (Novikova 2006). | |||
Another environment for microbes aboard manned spacecraft are life-support systems. This too can lead to dangers if colonization impairs equipment. Water filtration and regeneration systems and coolant lines must be monitored to guard against biofilm formation that can clog up tubing and prevent necessary flow (bioshmars). Despite this it is in life support systems where microbes perhaps show the most promise in occupying a beneficial niche for astronauts in the spaceraft ecosystem. Because microbes play a role in nearly every a major biogeochemical process on Earth they will undoubtedly be a part in establishing artificial biospheres in future spaceflight (Roberts et. al 2004). | |||
Revision as of 18:02, 7 April 2013
Spacecraft Microbiology
Spacecraft represent a unique environment for microbes. Spacecraft are generally classified as either manned or unmanned and this distinction carries profound consequences on the microbial ecology of the crafts. As on Earth, microbial communities can have both positive and negative effects. While they present hazards like degradation of equipment, infection, and contamination they also offer the promise for advanced life support systems.
Spacecraft Environments
As stated the type of environment available to microbes is fundamentally determined by the presence or absence of humans on the mission. Increased radiation exposure and microgravity are common challenges faced by microbes in each environment. Early experiments seemed to show no effect of a microgravity on cells smaller than 10 µm in diameter (Pollard et al 1967), but later experiments demonstrated an indirect lag on the metabolism of nonmotile bacteria due to reduced material exchange with surrounding fluid made more static without gravity (Klaus et al. 2004 and Thevenet 1996). Conversely damage by ionizing radiation is a serious hazard to microbial DNA causing double-stranded breaks, mutations, or irreversible destruction. Bacteria have evolved techniques to deal with genetic damage that include homologous and nonhomologous end-joining and protein-protection in spores (Horneck 2010). Different strains display varying levels of resistance and threshold lethality to radiation-induced damage (Horneck 2010).
Manned Spacecraft and Space Stations
Hermetically sealed spacecraft designed for human occupancy provide many opportunities for microbial populations. The same conditions that create an oasis of Earth-like conditions for humans benefit their commensal microbial partners as well. Conditions inside the craft are aerobic, warm, and generally ideal for mesophilic heterotrophs (bioshmars). The first and probably richest microenvironment inside the craft is the astronauts themselves. The natural human microbiota accompanies them on their journey (bioshmars). Human bodies provide a rich source of carbon sources and nutrients and the commensal and mutuaistic members of our skin and body cavity microbial ecosystems probably are the most substantial source of inoculation to a craft's interior. However, this of course means that pathogens, particularly opportunistic pathogens, can just as easily enter which has been demonstrated in previous research (bioshmars). Surfaces of the craft also provide adequate environments for many bacteria. Microbes that colonize the infrastructure and equipment are termed technofiles and can be a serious threat to the craft's integrity (bioshmars). Bacterial-fungal associations will form on polymers to utilize them as a carbon source and release enzymes and acids that further corrode the polymers (bioshmars). Biodegredation of polymers in this way can also release volatile noxious byproducts that can adversely affect air quality (Novikova 2002). Microbes can also exploit organic deposits on metal surfaces and similarly the metal through release of enzymes and organic acids(bioshmars). Polymer and surface corrosion were both observed on the MIR space station (Novikova 2004) and technophile bacterial strains have been detected on the ISS (Novikova 2006). Another environment for microbes aboard manned spacecraft are life-support systems. This too can lead to dangers if colonization impairs equipment. Water filtration and regeneration systems and coolant lines must be monitored to guard against biofilm formation that can clog up tubing and prevent necessary flow (bioshmars). Despite this it is in life support systems where microbes perhaps show the most promise in occupying a beneficial niche for astronauts in the spaceraft ecosystem. Because microbes play a role in nearly every a major biogeochemical process on Earth they will undoubtedly be a part in establishing artificial biospheres in future spaceflight (Roberts et. al 2004).
Spacecraft represent a unique environment for bacteria.
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