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Wastewater Chemicals in Colorado’s Streams and …U.S. Department of the Interior U.S. Geological...
Transcript of Wastewater Chemicals in Colorado’s Streams and …U.S. Department of the Interior U.S. Geological...
U.S. Department of the InteriorU.S. Geological Survey
Fact Sheet 2004–3127January 2005Printed on recycled paper
Wastewater Chemicals in Colorado’s Streams and Ground WaterBy Lori A. Sprague and William A. Battaglin
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Figure 1. Chemicals that we use every day in homes, industry, and agriculture can enter Colorado’s streams and ground water with wastewater.
What are wastewater chemicals?Chemicals that we use every day
in homes, industry, and agriculture — including detergents, disinfectants, fragrances, fire retardants, nonprescrip-tion drugs, and pesticides (fig. 1) — can enter Colorado’s streams and ground water with wastewater. These wastewater chemicals can be released to the environ-ment through discharges from industrial facilities, animal feed lots, wastewater treatment plants (WWTPs), individual septic disposal systems (ISDSs), or through runoff from land applications in agricultural and urban areas.
The human health and environmen-tal effects of wastewater chemicals are not well understood, and standards to protect human health or aquatic life have not been established for most of these chemicals. Some chemicals, however, such as the detergent degradation product nonylphenol and the fragrances AHTN and HHCB, have been shown to dis-rupt reproduction and growth in fish by affecting endocrine systems (Thorpe and others, 2001; Schreurs and others, 2004).
Other chemicals, such as the antimicro-bial disinfectant triclosan found in many liquid soaps, dishwasher powders, and plastics, are suspected of increasing the antibiotic resistance of bacteria in the environment (McMurry and others, 1998) or of reducing algae diversity in streams (Wilson and others, 2003). Little is known about the effects of many other individual chemicals or about the potential additive or interactive effects of mixtures of these chemicals.
Until recently, there have been few analytical methods capable of detecting these chemicals at the low concentra-tions found in the environment (Kolpin and others, 2002). The U.S. Geological Survey (USGS) National Water-Quality Laboratory in Denver, Colo., has devel-oped a new analytical method to measure concentrations of 62 wastewater chemi-cals in water (Zaugg and others, 2002). Methods were developed to measure these particular chemicals because they are expected to enter the environment through common wastewater pathways, are used in significant quantities, may have human or environmental health
implications, and can be accurately measured in environmental samples by using available technologies (Kolpin and others, 2002).
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Figure 2. The U.S. Geological Survey has conducted a small number of studies in Colorado examining the occurrence of wastewater chemicals in streams in urban and forested areas and in ground water from domestic and municipal wells.
What do we know about the occurrence of these chemicals in Colorado?
The USGS, through its National Water-Quality Assessment and Toxic Substances Hydrology programs and in cooperation with local agencies, has conducted a small number of studies of the occurrence of wastewater chemicals in streams and ground water in Colorado (fig. 2). This report describes results from four types of sites — streams in urban areas, streams in forested areas, ground water from domestic wells, and ground water from municipal wells — sampled between August 2001 and September 2003. Results for indi-vidual chemicals are grouped into 12 major general-use categories, such as fragrances and disinfectants (fig. 3), as has been done previously (Kolpin and others, 2002). For chemicals having mul-tiple uses or sources, a primary use of the chemical was chosen for categorization purposes. Because sampling was done during separate studies, different num-bers of samples were collected at each type of site. Differences in the number of chemicals detected among site types may be due to differences in the number of samples collected, as well as to differ-ences between site-type characteristics. The total number of samples and the frequency of detection (in percent) are shown along the top of each plot to allow easier comparison between site types. All data shown in figure 3 are available at http://waterdata.usgs.gov/co/nwis/qw/.
Between August 2001 and Septem-ber 2003, 23 samples were collected at 15 sites on urban streams: 10 were in the South Platte River basin, 4 were in the Arkansas River basin, and 1 was in the Upper Colorado River basin. The areas draining to these sites ranged from mod-erately to highly urbanized. Some sites were located immediately downstream from a single large WWTP discharge site, whereas others were located farther downstream from one or more WWTP discharge sites of various sizes. All may have been affected at some point in their upstream drainage area by ISDS leachate or agriculture.
Between October 2002 and Septem-ber 2003, 17 samples were collected at 1 forested stream site. The site was located on the Cache la Poudre River, upstream from its confluence with the
North Fork of the Cache la Poudre River. Most of the drainage area upstream from the site is in either the Roosevelt-Arapahoe National Forest or Rocky Mountain National Park. The river is used for fishing, whitewater rafting, and kayaking, and there are campgrounds and isolated private homes with ISDSs along the river. There is very little urban development and no WWTP discharge site upstream from the study site.
One sample was collected from each of 75 domestic wells between September 2001 and August 2003 (Brendle, 2004; Ortiz, 2004a and b). The wells were completed in the fractured-rock and sedimentary aquifers in Park County, Colo., about 30 miles southwest of Denver. Increasing development in Park County has led to an increase in the number of ISDSs in the region. Depend-ing on the permeability of the aquifer, the distance from the ISDS to the well, and the rate of water flow in fractures, ISDS effluent potentially can reach shallow ground water before concentrations of contaminants are reduced substantially.
One sample was collected from each of 12 municipal wells in Arapahoe, Douglas, and Elbert Counties, Colo., between March and October 2003. The wells were completed in the Dawson aquifer, the uppermost aquifer of the Denver Basin aquifer system. The north-ern part of the Dawson aquifer is located in the southern metropolitan area of Den-ver, and along with the three underlying aquifers of the Denver Basin, it is used primarily for drinking water and lawn irrigation (Robson, 1987). In the south-ern metropolitan area of Denver, where ground water is an important source of drinking water, urban development could make the water supply in the Dawson aquifer more vulnerable to contamina-tion.
The few data currently (2004) avail-able indicate that urban streams were the most vulnerable to contamination, with one or more wastewater chemicals being found in 100 percent of samples from urban streams, and with 57 of the 62 wastewater chemicals being detected in at least 1 sample from these sites. Con-centrations also tended to be highest in urban streams compared to the other site types, with total concentrations above 1 microgram per liter (µg/L or part per billion) occurring in 8 of the 12 general-use categories (antioxidants, detergent
metabolites, disinfectants, fire retardants, fragrances/flavors, nonprescription drugs, PAHs, and steroids) and total concentra-tions above 10 µg/L occurring in 3 of the 12 general-use categories (detergent metabolites, fire retardants, and nonpre-scription drugs).
Samples from the domestic wells gen-erally had a lower number of wastewater chemicals detected and at lower concen-trations compared to the urban streams sampled. However, a wide variety of chemicals also were detected (34 of 62) in the domestic wells. Total concentra-tions above 1 µg/L occurred in 7 of the 12 general-use categories (detergent metabolites, disinfectants, fire retardants, fragrances/flavors, plasticizers, solvents, and steroids).
The forested stream had fewer waste-water chemicals detected (11 of 62) and at lower concentrations compared to the urban streams and domestic wells sampled. Total concentrations above 1 µg/L occurred in only one general-use category (detergent metabolites).
The municipal wells sampled had the fewest wastewater chemicals detected (6 of 62) and the lowest concentrations measured of the four site types. Total concentrations were below 1 µg/L in all general-use categories.
No concentrations of individual chemicals exceeded currently (2004) established drinking-water standards in any of the samples; however, no stan-dards have been established for most of these chemicals (U.S. Environmental Protection Agency, 2004). Concentra-tions of caffeine, DEET, nonylphenol, and triclosan, four of the more commonly detected chemicals at each site type, are shown in figure 4. The U.S. Environ-mental Protection Agency is develop-ing aquatic-life criteria for nonylphenol because of its potential for endocrine disruption (U.S. Environmental Protec-tion Agency, 2003), and triclosan is of concern because it may increase the anti-biotic resistance of bacteria in the envi-ronment. Both chemicals were frequently detected in urban stream samples; tri-closan also was present in samples from domestic and municipal wells.
Wastewater chemicals were detected more frequently and generally at higher concentrations in samples from urban streams and domestic wells than in samples from the forested stream and municipal wells. The results indicate
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that urban streams and domestic wells in Colorado may be vulnerable to contami-nation by wastewater chemicals. How-ever, the detection of low concentrations of wastewater chemicals in the forested stream and deeper municipal wells indi-cates that these chemicals can be found in streams or ground water even in areas where there are no obvious sources of waste contamination nearby.
Where do we go from here?Although data are available from only
a limited number of sites in Colorado at this time, these results indicate that mix-tures of wastewater chemicals are present at low concentrations at numerous, and sometimes unexpected, locations in the State. Other USGS studies have found hormones, antibiotics, and prescription drugs in urban streams receiving WWTP effluent across the Nation, including parts of the South Platte River (Kolpin and others, 2002; Barnes and others, 2002). The laboratory methods for measuring hormones, antibiotics, and prescription drugs in water are being developed and are nearing approval for general use by the USGS. Laboratory methods for the detection of wastewater chemicals in bio-solids — solid or semi-solid residue gen-erated during the treatment of domestic sewage and recycled as surface-applied fertilizer — also are being developed by the USGS.
For more than 100 years, the USGS has been successfully partnering with State and local agencies to fund water-resources studies through the Cooperative Water Program. These initial findings
on wastewater chemicals in Colorado’s streams and ground water, along with the new analytical methods being developed by the USGS, provide a starting point for further investigation into the occurrence, fate, and environmental effects of waste-water chemicals in Colorado and across the Nation.
References cited
Barnes, K.K., Kolpin, D.W., Meyer, M.T., Thurman, E.M., Furlong, E.T., Zaugg, S.D., and Barber, L.B., 2002, Water-quality data for pharmaceuticals, hormones, and other organic wastewater contaminants in U.S. streams, 1999–2000: U.S. Geological Sur-vey Open-File Report 02–94, 7 p.
Brendle, D.L., 2004, Potential effects of individual sewage disposal system density on ground-water quality in the fractured-rock aquifer in the vicinity of Bailey, Park County, Colorado, 2001–2002: U.S. Geo-logical Survey Fact Sheet 2004–3009, 5 p.
Kolpin, D.W., Furlong, E.T., Meyer, M.T., Thurman, E.M., Zaugg, S.D., Barber, L.B., and Buxton, H.T., 2002, Pharmaceuticals, hormones, and other organic wastewater contaminants in U.S. streams, 1999–2000 — A national reconnaissance: Environmen-tal Science and Technology, v. 36, no. 6, p. 1202–1211.
McMurry, L.M., Oethinger, M., and Levy, S.B., 1998, Over-expression of marA, soxS, or acrAB produces resistance to triclosan in laboratory and clinical strains of Esch-erichia coli: FEMS Microbiology Letters, v. 166, no. 2, p. 305–309.
Ortiz, R.F., 2004a, Ground-water quality of alluvial and sedimentary-rock aqui-fers in the vicinity of Fairplay and Alma, Park County, Colorado, September–October 2002: U.S. Geological Survey Fact Sheet 2004–3065, 6 p.
Ortiz, R.F., 2004b, Ground-water quality of granitic- and volcanic-rock aquifers in southeastern Park County, Colorado, July–August 2003: U.S. Geological Survey Fact Sheet 2004–3066, 6 p.
Robson, S.G., 1987, Bedrock aquifers in the Denver Basin, Colorado — A quantitative water resources appraisal: U.S. Geological Survey Professional Paper 1257, 73 p.
Schreurs, R.M., Legler, J., Artola-Garicano, E., Sinnige, T.L., Lanser, P.H., Seinen, W., and Van Der Burg, B., 2004, In vitro and in vivo antiestrogenic effects of polycyclic musks in zebrafish: Environmental Science and Technology, v. 38, no. 4, p. 997–1002.
Thorpe, K.L., Hutchinson, T.H., Hetheridge, M.J., Scholze, M., Sumpter, J.P., and Tyler, C.R., 2001, Assessing the biological potency of binary mixtures of environmen-tal estrogens using vitellogenin induction in juvenile rainbow trout (Oncorhynchus mykiss): Environmental Science and Tech-nology, v. 35, no. 12, p. 2476–2481.
U.S. Environmental Protection Agency, 2004, 2004 edition of the drinking water standards and health advisories: U.S. Environmental Protection Agency Report 822–R–04–005, 13 p.
U.S. Environmental Protection Agency, 2003, Ambient aquatic life water qual-ity criteria for nonlyphenol — draft: U.S. Environmental Protection Agency Report 822–R–03–029, 71 p.
Wilson, B.A., Smith, V.H., Denoyelles, F., Larive, C.K., 2003, Effects of three pharmaceutical and personal care products on natural freshwater algal assemblages: Environmental Science and Technology, v. 37, no. 9, p. 1713–1719.
Zaugg, S.D., Smith, S.G., Schroeder, M.P., Barber, L.B., and Burkhardt, M.R., 2002, Methods of analysis by the U.S. Geological Survey National Water-Quality Labora-tory — Determination of wastewater compounds by polystyrene-divinylbenzene solid-phase extraction and capillary-column gas chromatography/mass spectrometry: U.S. Geological Survey Water-Resources Investigations Report 01–4186, 37 p.
For more information about waste-water studies in Colorado, please contact:
District ChiefWater Resources DisciplineU.S. Geological SurveyP.O. Box 25046, MS 415Lakewood, CO 80225303-236-4882
http://co.water.usgs.gov