Biology
Scientific paper
Dec 2006
adsabs.harvard.edu/cgi-bin/nph-data_query?bibcode=2006agufm.p51d1224a&link_type=abstract
American Geophysical Union, Fall Meeting 2006, abstract #P51D-1224
Biology
5200 Planetary Sciences: Astrobiology, 5215 Origin Of Life
Scientific paper
The results of the Viking experiments suggest that more sensitive methods for the detection and analysis of biomarker compounds are needed for in situ characterization of organic compounds in Martian regolith or on other planetary bodies that may contain trace amounts of organic materials. The extraction methods by which these biomarker molecules are obtained from their native environments are critical to the success of the detection and analysis experiments. For the past few years, we have been developing a front-end system for extraction of these compounds based on subcritical water technology. The operational principles of subcritical water extractor (SCWE) developed in our laboratory are based on the unique property of liquid water to change its dielectric constant as a function of its temperature and pressure. SCWE adjusts water temperature and pressure, so water can be utilized in place of commonly used organic solvents to extract compounds with dissimilar physical and chemical properties (i.e., volatility, polarity, charge and size). We have tested the performance of SCWE in the extraction of amino acids from Atacama Desert soils. Amino acids (alanine, aspartic acid, glycine, glutamic acid, serine and valine) were extracted with subcritical water (T = 30 - 325 C and P = 17.2 - 20.0 MPa). The concentration of amino acids in the exposed duracrust soils samples was in the 1 - 70 parts-per-billion range. The amino acid extraction efficiency was defined by the dielectric constant of water and the rates of the hydrolysis and decomposition reactions, all of which were functions of subcritical water temperature, pressure, and equilibrations time (i.e., the time that subcritical water reacts with the soil samples). The concentrations of aliphatic amino acids increased with increasing subcritical water temperatures, while amino acids with polar side chains, such as glutamic acids, were more stable at significantly lower temperatures. No detectable amounts of amino acids were extracted at 30 C and 17.2 MPa, suggesting that most of the amino acids were strongly bound within the soil matrix. Amino acids were not detected in the extracts collected at 325 C and 20.0 MPa, indicating that amino acids most likely undergo rapid decomposition reactions under these subcritical water conditions. The optimal SCWE extraction conditions for amino acids in the exposed duracrust Atacama soils reported here were 200 C, 17.2 MPa and 10 min equilibration time. Our data demonstrates the successful extraction of trace amounts of amino acids from arid Atacama soils with SCWE. In the Atacama Desert field studies, the operations of SCWE and Mars Organic Analyzer (MOA) were successfully integrated. Laboratory and Atacama field studies were undertaken to support the development of the Urey instrument suite that has been invited to participate on ESA ExoMars mission.
Amashukeli Xenia
Aubrey Andrew D.
Bada Jeffrey L.
Ehrenfreund Pascale
Grunthaner Frank J.
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