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"EMERGING" POLLUTANTS, AND COMMUNICATING THE SCIENCE OF ENVIRONMENTAL CHEMISTRY AND MASS SPECTROMETRY: PHARMACEUTICALS IN THE ENVIRONMENT
Citation:
Daughton, C G. "EMERGING" POLLUTANTS, AND COMMUNICATING THE SCIENCE OF ENVIRONMENTAL CHEMISTRY AND MASS SPECTROMETRY: PHARMACEUTICALS IN THE ENVIRONMENT. JOURNAL OF THE AMERICAN SOCIETY FOR MASS SPECTROMETRY 12(10):1067-1076, (2001).
Impact/Purpose:
The research focused on in the subtasks is the development and application of state-of the-art technologies to meet the needs of the public, Office of Water, and ORD in the area of Water Quality. Located In the subtasks are the various research projects being performed in support of this Task and more in-depth coverage of each project. Briefly, each project's objective is stated below.
Subtask 1: To integrate state-of-the-art technologies (polar organic chemical integrative samplers, advanced solid-phase extraction methodologies with liquid chromatography/electrospray/mass spectrometry) and apply them to studying the sources and fate of a select list of PPCPs. Application and improvement of analytical methodologies that can detect non-volatile, polar, water-soluble pharmaceuticals in source waters at levels that could be environmentally significant (at concentrations less than parts per billion, ppb). IAG with USGS ends in FY05. APM 20 due in FY05.
Subtask 2: Coordination of interagency research and public outreach activities for PPCPs. Participate on NSTC Health and Environment subcommittee working group on PPCPs. Web site maintenance and expansion, invited technical presentations, invited articles for peer-reviewed journals, interviews for media, responding to public inquiries.
Subtask 3: To apply state-of-the-art environmental forensic techniques to the recognition and characterization of emerging pollutants in the aquatic environment. There is a need for high sensitivity and for a powerful method of structural characterization, advanced mass spectrometric and chromatographic techniques to be employed to meet the challenge of emerging pollutants, including pharmaceuticals and personal care products, agents of sabotage, and explosives. Ongoing efforts continue to identify previously unrecognized pollutants from a range of problematic samples having importance to regional and state contacts.
Subtask 4: To provide the Agency with a set of practical analytical methods for the selective and sensitive determination of selenium species (organic, inorganic, volatile and non volatile forms) in multiple media to accurately assess and if necessary control the risk of selenium exposure to organisms. This includes development of optimal extraction, digestion, separation and detection approaches.
Subtask 5: To develop and apply an analytical method that can extract and detect synthetic musks. The extent of exposure may be determined by measuring levels of synthetic musks from their potential source (communal sewage effluent). This subtask ends in FY05 with the deliverable of APM 21. Future applications to biosolids will be covered in subtask 6.
Subtask 6: Application, and improvement, of previously in-house developed sensitive, robust, and green, methodologies regarding the use of urobilin and sterols as a possible markers of sewage contamination.
Subtask 7: Adaptation and improvement of previously developed in-house methods, for PPCPs (e.g., antibiotics and musks) to solid materials (e.g. biosolids, sediments).
Subtask 8: Study of the presence of personal care products, incombustible organic compounds from the direct-piping of small engines exhaust in Lake Tahoe, and lake deposition of airborne pollutants from industrial activity
Description:
This paper weaves a rnulti-dimensioned perspective of mass spectrometry as a career against the backdrop of mass spectrometry's key role in the past and future of environmental chemistry. Along the way, some insights are offered for better focusing the spotlight on the discipline of mass spectrometry.
A Foundation for Environmental Science-Mass Spectrometry Historically fundamental to our understanding of environmental processes and chemical pollution is mass spectrometry. This branch of analytical chemistry is the workhorse which supplies much of the definitive data to environmental scientists and engineers for identifying the molecular compositions, and ultimately the structures, of chemicals. This is not to ignore the complementary and critical roles played by the adjunct practices of sample enrichment (e.g., to lower method detection limits via any of various means of selective extraction) and analyte separation (e.g., to lessen contaminant interferences via the myriad forms of chromatography and electrophoresis).
While the power of mass spectrometry has long been highly visible to the practicing environmental chemist, it borders on continued obscurity to the lay public and most non-chemists. Even though mass spectrometry has played a long, historic and Largely invisible role in establishing or undergirding our existing knowledge about environmental processes and pollution, what recognition it does enjoy is usually relegated to that of a tool. It is usually the relevance or significance of the knowledge acquired from the application of the tool that has ultimate meaning to the public and science at large, not how the knowledge was acquired.
Communicating Science - Mass Spectrometry and the Risk- Paradigm
Protecting human and ecological health from chemical hazards is rooted in assessing and managing/controlling chemical risks, a process requiring data from many aspects of the risk Paradigm. Comprising this Paradigm are a series of inter-related steps or activities, such as identifying sources, establishing environmental occurrence, elucidating fate and transport, verifying exposure or effects (eg., bio-markers), and developing remediation/control technologies. Mass spectrometry plays a critical, direct role in all of them, except the actual step of assessing risk (Figure 1). Mass spectrometry is essential to obtaining data required for establishing environmental source/origin, occurrence (identities concentrations), fate and transport including that for all associated transformation products), exposure (including measurement of biomarkers), effects (including receptor interactions and metabolites).