NABIR Assessment Element, Expanded Rapid, Comprehensive, Lipid Biomarker Analysis for Subsurface, Community Composition and Nutritional/Physiological Status as Monitors of Remediation and Detoxification Effectiveness
NABIR funding at the University of Tennessee Center for Biomarker Analysis (CBA) has led to several key contributions to the investigation of bioremediation of metals and radionuclides. This lab has played an integral part in assessing microbial communities at the field scale at the ORNL FRC (Istok et al., 2004) and two UMTRA sites (Anderson et al., 2003, Chang et al., 2001). Our work over the period of the grant has resulted in 42-peer reviewed publications, 62 presentations (14 of which were international), and one patent pending. Currently CBA has 2 papers in press. The main objectives relating to the field portion of this program were to provide comprehensive biomarker analysis for NABIR collaborators to enhance the understanding of microbial geo-bioprocesses involved in the effective immobilization of metals (We have worked with and published or currently are publishing with 10 groups of NAIBR investigators). The laboratory portion of our research centered on methods development and has led to three major innovations that could result in a systematic way of evaluating sites for potential bioremediation. The first of these is the development of an in situ sampling device (Peacock et al., 2004, Anderson et al., 2003, Istok et al., 2004) for the collection and concentration of microbial biomass. The second is the development of expanded lipid analysis based on the significantly greater sensitivity and selectivity of the LC/MS/MS that allows the analysis of respiratory quinones, diglycerides, sterols, intact phospholipids, poly-hydroxyalkonates, and potentially archaeol, and caldarchaeols from archea. These new analyses are accomplished more rapidly and with increased sensitivities and resolution than in the past (Lytle et al., 2000a, 2000b, 2001a, Geyer et al., 2004). The third advance is the coupling of lipid analysis with 13C enrichment experiments (Lytle et al., 2001b, Geyer et al. 2005). With this technique it is now possible to follow the active portion of the in situ microbial community with a resolution heretofore not possible. These three advances in technology have been initially demonstrated at the NABIR Field Research Center (FRC) in Oak Ridge, TN and at the UMTRA Old Rifle site in Colorado. Microbial communities are of primary importance in the use of bioimmobilization strategies for metals and radionuclides from contaminated groundwater and sediments. These communities represent a potentially transformable agent that is able to affect virtually all biogeochemical pathways. Microorganisms can alter metal chemistry and mobility through reduction, accumulation, and immobilization and have been shown to be responsible for mineral formation and dissolution. Research is directed to provide collaborating NABIR investigators a rapid, comprehensive, and cost-effective suite of biomarker measurements to quantify microbial community structure, activity, and effectiveness, thereby providing defensible evidence that a desired bioprocess is occurring or may occur at a given site.
- Research Organization:
- The University of Tennessee, Center for Biomarker Analysis, Knoxville, TN 37932
- Sponsoring Organization:
- USDOE Office of Science (SC)
- DOE Contract Number:
- FC02-96ER62278
- OSTI ID:
- 850194
- Report Number(s):
- DOE ER62278; TRN: US0701880
- Country of Publication:
- United States
- Language:
- English
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Related Subjects
12 MANAGEMENT OF RADIOACTIVE WASTES, AND NON-RADIOACTIVE WASTES FROM NUCLEAR FACILITIES
BIOMASS
BIOREMEDIATION
CHEMISTRY
DETOXIFICATION
DISSOLUTION
LIPIDS
MICROORGANISMS
MONITORS
PHOSPHOLIPIDS
QUINONES
RADIOISOTOPES
RESOLUTION
SAMPLING
SEDIMENTS
SENSITIVITY
STEROLS
Methods Development
Bioremediation
In Situ bioimmobilization