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Home My WebLink About2012-12-10 PACKET 08.B.City of Cotta Grove Minnesota To: Parks, Recreation and Natural Resources Commission From: Zac Dockter, Parks and Recreation Director CC: Date: December 4, 2012 Subject: State of the Mississippi River Information Staff has included in the Commission packet for review the "State of the River Report ". This report was composed by the Friends of the Mississippi River and the National Park Service. The report discusses the state of the river by focusing on the following characteristics: 1. River Flow 2. Swimming and Recreation 3. Fish and Fishing 4. Ecological Health 5. Other Contaminants of Concern The report is very thorough and aims to give the public an understanding of the quality of the Mississippi River, recommendations for further evaluation and how improving /regulating man -made impacts can ultimately improve the rivers ecosystem. 11 L7 �R E P OO�R�T Mississippi .River ?" A It's a question we get asked quite often and it can be that individuals can take in their home, yard, and hard to know how to respond. community to improve the health of the Mississippi. Th l P ' G 'd t' t d 1 Forty years after the passage of the federal Clean Water Act, the river has come a long way. Gone are the days of sewage and industrial wastes choking the life out of the river. Fish and aquatic species have re- turned. Yet agricultural and urban runoff continues to pollute the resource, invasive species pose new threats, and industrial contaminants — some with frightening potential health risks — are being discovered in the river. I o acy 1r e ff o ers priori h ty ac ions at f e era , state, and local leaders can take for the river. Visit www.stateoftheriver.com to learn more. Clearly, as individuals and as a society, we can make choices that affect the river both for good and ill. While the Mississippi, River has suffered from careless treatment in the past, the big river is also resilient and can heal itself, if given a chance. So, how is the Mississippi River? We wanted to find out how to answer that question accurately, and we knew a lot of people would be interested. So Friends of the Mississippi River (FMR) and the National Park Service teamed up to develop this report. The State of the River Report highlights 13 key indicators of river health so that non - scientists can understand what it means. The report examines the status and trends of each indicator, and highlights key strategies for improve- ment moving forward. We hope to update the report periodically, following these key indicators over time and adding new ones as appropriate. To help readers make use of this information in their communities, we've also created two companion guides. The Stewardship Guide provides practical steps The conservationist Aldo Leopold said, 'A thing is right when it tends to preserve the integrity, stability, and beauty of the biotic community. It is wrong when it tends otherwise." We agree. We believe the long -term health of the Mississippi River is actually, itself, an indi- cator of the health of our community. We hope the State of the River Report can help lead us toward a more healthy and sustainable Mississippi Riv- er, for ourselves and for generations yet to come. For the river, Whitney L. Clark, Executive Director, Friends of the Mississippi River Paul Labovitz, Superintendent, National Park Service, Mississippi National River and Recreation Area STATE of THE RIVER INTRODUCTION Acknowledgments ............................. ............................... page 4 The mighty Mississippi River .......... ............................... page 5 The Mississippi River and Lake Pepin watershed ......... page 6 Mississippi National River and Recreation Area ............page 7 Indicators overview and critical terms ...........................page 8 REPORT FINDINGS RIVER PLOW ............................... ...........................page 10 SWIMMING & RECREATION Bacteria page 14 14 Mr- horns page FISH & FISHING Fish consum Lion page Fish surve ... - Rsian car ... - ECOLOGICAL HEALTH Sediment ... - Nitrate page Mussels page Bald eagles page OTHER CONTAMINANTS OF CONCERN Priclo page Additional contaminants of concern • .. - rya Summary and conclusions ................. ............................... page 45 Sources and notes ............................... ............................... page 46 Authors Trevor A. Russell — Friends of the Mississippi River Lark Weller — National Park Service — Mississippi National River and Recreation Area Maps and design Bob Spaulding — Friends of the Mississippi River Communications consultant Sylvia Bachmann Project funders This report is made possible through the generous support of the McKnight Foundation, the Minnehaha Creek Watershed District, and the Capitol Region Watershed District. These organizations are dedicated to enhancing the health of our water resources, and we thank them for their support. Capitol Region Watershed District Project advisors © A CREEK WATERSHED D DISTRICT QUALITY OF WATER, QUALITY OF LIFE This State of the River Report would not have been possible without the generous assistance of many individuals and organizations, from a wide range of disciplines, whose research forms the basis of the document. "They have given many hours of their time to help us interpret and characterize a variety of river data. These professionals have been unstinting with their time and enthusiastic about the goal of producing a clear and concise report on the status and trends of the Mississippi River in the Twin Cities area. We are grateful to them for their support and cooperation. Science advisory committee John Anfinson — National Park Service — Mississippi National River and Recreation Area Daniel Engstrom —St. Croix Watershed Research Station Steven Heiskary — Minnesota Pollution Control Agency Kent Johnson — Metropolitan Council Environmental Services Sue Magdalene —St. Croix Watershed Research Station Emily Resseger — Metropolitan Council Environmental Services Faye Sleeper — University of Minnesota Water Resources Center Judy Sventek — Metropolitan Council Environmental Services Art Persons — Minnesota Department of Health Michele Ross —Minnesota Department of Health Bill Route — National Park Service Tim Schlagenhaft — Minnesota Department of Natural Resources Norman Senjem — Minnesota Pollution Control Agency (Retired) Carol Sinden — Minnesota Pollution Control Agency Laura Solem — Minnesota Pollution Control Agency Rory Stierler — National Park Service — Mississippi National River and Recreation Area Joel Stiras — Minnesota Department of Natural Resources David VanderMeulen — National Park Service David Wall — Minnesota Pollution Control Agency Dennis Wasley — Minnesota Pollution Control Agency Virginia Yingling — Minnesota Department of Health Technical advisors and agency contributions Mike Davis — Minnesota Department of Natural Resources Deborah Durkin — Minnesota Department of Health Larry Gunderson — Minnesota Pollution Control Agency Paul Hoff — Minnesota Pollution Control Agency Richard Kiesling — United States Geological Survey Len Kremer — Lower Minnesota River Watershed District Kathy Lee — United States Geological Survey Patricia McCann — Minnesota Department of Health Brenda Moraska Lafrancois — National Park Service Barbara Peichel — Minnesota Pollution Control Agency Lastly, a special thank you to former FMR intern Brandon Stephens, whose dedicated work helped bring this project to fruition. The Mississippi River, flowing approximately 2,350 miles from Lake Itasca to the Gulf of Mexico, has long been one of the defining natural features of the United States. The Ojibwe Indians of northern Minnesota called it "Messipi" or The Mississippi River watershed "Big River," and it was also known as the "Mee- zee - see -bee" or the `r sd' 1 A n°v °Ak is "Father of Waters. "' Today, the river drains all or part of 31 states and two Canadian prov- i N inces, or about 41% of the area ❑in e of the lower 48 states. The river \ 4 represents one of the most diverse 5',L° and important natural resources in ANg -- - l ' the U.S., serving as the migratory L s�" g° Yroau i •R� °° �`Y flyway for more than 40% all North , I ParF Ortw MR111. American waterfowl and shorebirds. The river is also home to at least 260 species of fish, A (wturalevhdata <oml. [lOM � 50 mammal species, 145 species of amphibians and reptiles, and 38 species of mussel? The Mississippi River system is a vital public resource, and is es- sential in sustaining our nation's economy. Fifty U.S. cities rely on the Mississippi for daily water supply, including roughly 1,000,000 Minnesotans. The 29 locks and dams on the Mississippi allow for navigation from St. Louis, Mo., to Minneapolis, Minn. To move goods up and down the Mississippi, the U.S. Army Corps of Engineers maintains a 9 -foot shipping channel from Baton Rouge, La. to Minneapolis. Roughly 60% of grain exported from the U.S. is transported and shipped from the Mississippi River, along with billions of dollars' worth of freight each year. Nir.p 4ia � A If J,M1f pAis� - x "The 1Mississi�i is well worth reading about. It is not a commonplace river, but on the contrary is in all ways remarkable. " -Mark Twain, Life on the Mississippi { — _ a _ 6 l T Ulm Lake PE 6o miles downstream of the Twin Uities metropolitan area. Lake Pepin's watershed (drainage area) covers half of Minnesotan land areas (about 50,000 square miles), and in- cludes the upper Mississippi, St. Croix, and Minnesota Rivers, as well as several smaller tributaries. In 2004, Lake Pepin was listed as "impaired" by the State of Minnesota; it has so much excess phosphorus (page 16) that the lake fails to meet state water quality standards, while excess sediment (page 28) continues to threaten the lake. These pollutants affect the lake a number of wa The Lake Pepin watershed • The lake's excess phosphorus negatively impacts aquat- ic life and recreation (by reducing water clarity and depleting oxygen levels), and can lead to massive algae blooms in low -flow periods. • High sediment levels cloud the water and disrupt hab- itat, making it difficult for plants and fish to thrive. At current rates of sedimentation, excess sediment threat- ens to completely fill in the upper third of the lake within a century.' Because Lake Pepin drains such a large portion of Minneso- ta, efforts to clean it up have revived public awareness of the many challenges facing Minnesotas water resources. Several indicators in this report (sediment, phosphorus, and triclosan) reference overall pollution levels in Lake Pepin. Much of the river's sediment settles out in Lake Pepin. Researchers examine that sediment to learn what has been happening in the river upstream over time, and have gained excellent insights into the history and trends of water quality and the ecological health of the Mississippi River. L Upper Mississippi ' - River Map data source: Minnesota Department of Natural Resources K f l t Lake PE 6o miles downstream of the Twin Uities metropolitan area. Lake Pepin's watershed (drainage area) covers half of Minnesotan land areas (about 50,000 square miles), and in- cludes the upper Mississippi, St. Croix, and Minnesota Rivers, as well as several smaller tributaries. In 2004, Lake Pepin was listed as "impaired" by the State of Minnesota; it has so much excess phosphorus (page 16) that the lake fails to meet state water quality standards, while excess sediment (page 28) continues to threaten the lake. These pollutants affect the lake a number of wa The Lake Pepin watershed • The lake's excess phosphorus negatively impacts aquat- ic life and recreation (by reducing water clarity and depleting oxygen levels), and can lead to massive algae blooms in low -flow periods. • High sediment levels cloud the water and disrupt hab- itat, making it difficult for plants and fish to thrive. At current rates of sedimentation, excess sediment threat- ens to completely fill in the upper third of the lake within a century.' Because Lake Pepin drains such a large portion of Minneso- ta, efforts to clean it up have revived public awareness of the many challenges facing Minnesotas water resources. Several indicators in this report (sediment, phosphorus, and triclosan) reference overall pollution levels in Lake Pepin. Much of the river's sediment settles out in Lake Pepin. Researchers examine that sediment to learn what has been happening in the river upstream over time, and have gained excellent insights into the history and trends of water quality and the ecological health of the Mississippi River. L Upper Mississippi ' - River Map data source: Minnesota Department of Natural Resources K I 4 Did you know that the Mississippi River in the Twin Cities is a national park? For 72 miles (from the Crow River confluence in Dayton and Ramsey, to just past the St. Croix River confluence near Hastings and Prescott), the river is so unique that in 1988 Congress des- ignated it a national park: the Mississippi National River and Recreation Area (MNRRA). The river changes character more within this park than it does anywhere else along its entire length. Entering the park as a modest -sized prairie river, it plunges over St. Anthony Falls (the river's only true waterfall) and through a deep, wooded gorge (its only true gorge), emerging in St. Paul as a large floodplain river before flowing downstream to the Gulf of Mexico. The Minnesota River enters the Mississippi about halfway through the park, and the park boundary includes the last four miles of the Minnesota River. The Minnesota drains about 20% of the state,' and plays an important role in the park's water quality. The Minnesota River is discussed throughout this report because of its influence'on the state of the Mississippi River. - .While the National Park Service owns little land within the park, it works with many partners to protect the globally significant resources of the river in this stretch. Its role in protecting water quality is essential to the river's other re- sources, and helping to communicate the state of the river is one important way the park does this. s !i i _92_�m pi River Corridor Critical Area. In order to protect the diverse geological, ecological, historical, and cultural features of the river corridor, the State established c T; the Mississippi River Corridor Critical Area in 1976. The RII L. 1' j Critical Area, which shares the national park's boundaries, GF' _ provides for coordinated planning and management of resources among the communities that share this reach of the river. r 1 Mississippi National River and Recreation Area MINNEAPOL SAINT PAS and Mississippi River Corridor Critical Area $ J i� V- $li _ G6J�E Ht A11 ROVL V r- V h This State of the River Report highlights 13 key indicators of water quality and ecological health in the river. These indicators were selected to portray the state of the river in a way that is easy to understand. These indicators describe river conditions in five categories: RIVER FLOW: ' SWIMMING & RECREATION: FISH & FISHING: ECOLOGICAL HEALTH: iilalTriclosajW PFOS Additionaff contaminants concern For each indicator, we include a brief description, and highlight its role in the river system. We also provide readers with a summary of each indicator's status, and, where possible, include information on history, trends, and manage- ment solutions for moving forward. Several indicators highlight monitoring results from the 1976 -2011 period. Extensive monitoring efforts over this time provide for an excellent understanding of river trends, and we've made use of this data whenever possible. Crific aR - �ezu -)i.q Throughout this report, we refer to several critical terms that are important to understanding the state of the river. Knowing the meaning of these terms will help you as you read the State of the River Report. If a portion of the river is "impaired," it means that reach of the river fails to meet state or federal standards for one or more pollutants. Some reaches of the river are impaired for multiple pollutants. Pollution "concentration" refers to the amount of a pollutant in a given volume of water. Pollutant concentrations are often used to compare existing pollution levels to water quality standards, and are important when we think of that pollutant's impacts on local river life and health. • . • Pollution "load" refers to the total amount of a pollutant moving intolthrough the river system. Load helps us understand the total quantity of a pollutant, and is especially important when we think of what we send to downstream waters like Lake Pepin or the Gulf of Mexico. The Mississippi River is a complex natural system that can change dramatically from year to year, and even from season to season. So how do we assess the overall state of the river? U F-I 1_4 I This section highlights one indicator, river flow which is the amount of water moving through the river. Changes in rain and snowfall, how we use land, and how we use water and control runoff can result in changes to how much water is in the river. Because of its ability to erode soil and carry pollutants, flow plays an important role in water quality and the health of aquatic habitat. i ? - :•St Flow River flow has increased significantly. T The timing, amount, and intensity of rain and snowfall all impact river flow. Description and impacts. The timing, amounts, and intensity of rain and snowfall can all impact the flow of the Mississippi River, as runoff moves over land and into the river. River conditions can change based on flow conditions. High or low flows can have positive or negative effects. • High flows can cause increased erosion, flooding risk, habitat degradation, and can carry more pollutants into the river system. However, higher flows can also dilute concentrations of some key pollutants, which can reduce their local impacts on the river. Low flows tend to deliver less pollution to the river, and produce fewer flooding events. However, lower flows can contribute to increased algae levels in water. Algae can harm aquatic life and recreation, and have created problems in the lower Minnesota River and Lake Pepin. Figure 1. An example of wetland loss in the Minnesota River basin Graphic: Minnesota River Basin Trends — November 2009 V Flow is an important factor in determining water quality and the health of aquatic habitat. V River flow at Hastings increased by 25% between 1976 and 2005. Sources. In agricultural areas, row crops and artificially drained fields have largely replaced native prairies, forests, and wetlands (Figure 1). Recent studies show that these changes in how we use land result in increased runoff, which typically leads to downstream increases in stream flow.' In cities and towns, hard surfaces such as roads, rooftops, and driveways result in increased runoff that can affect flows in nearby water bodies (Figure 2).' In addition, computer climate models anticipate changes to the frequency and size of runoff - producing rainfalls in many parts of the state, which could alter Mississippi River flows in a variety of ways. This graphic illustrates the loss of 88% of wetlands (shown in blue) in the 7 -Mile Creek watershed (near St. Peter, Minn.) between 1854 and 2003. The addition of extensive artificial agricultural drainage and the loss of so many wetlands have reduced the landscape's ability to retain and evaporate water. This increases downstream river flows in the Minnesota and Mississippi Rivers. 2003 1854 1938 1968 R FLOW • 11 Status. Mississippi River flows were higher than the 30 -year average throughout much of 2011. A rainy fall the previous year left soils full of water and contributed to more runoff in the spring and early summer. Summer rain resulted in higher stream flows throughout the summer and early fall. Later in the year, dry conditions resulted in lower flows throughout the late fall and early winter, and contributed to drought conditions in portions of the state. History and trends River flow has increased over time. Since 1976, median flow has increased by 25% at the Hastings Dam (Figure 3). Flows in the Minnesota River have doubled over the last 70 years." Flow increases may be attributed to several factors, including increased artificial agricultural drainage, increased urban runoff, and changes in rain and snow patterns and climate. Solutions. Rivers, lakes, and streams fare best when runoff infiltrates naturally into the ground. Statewide efforts to restore wetlands and keep more water within agricultural areas are critical to reversing the trends of increased Minnesota and Mississippi River flows. Improved urban runoff controls may also help stabilize local flows by increasing natural infiltration throughout the state. To help maintain a healthy water balance, residents can install rain gardens, rain barrels, pervious pavers, green roofs, and restored prairie landscapes, which are proven strategies for reducing runoff and improving water quality in the Mississippi River. Figure 3. Annual river flow at Hastings Dam 40000 35000 u 30000 o'a a 25000 a� ro 20000 a, lu w 15000 q 10000 v 5000 Data source: Metropolitan Council Environmental Services. Median annual flows for 1976 -2010 were calculated based on flows at the U.S. Geological Survey stream gage in St. Paul plus flows at the Metro Wastewater Treatment Plant, as described in Lafrancois et al. (in prep). Similar flow data were not available for 2011 at the time of publication, and were instead inferred based on their long -term relationship to flow estimates from the U.S. Army Corps of Engineers gage site at the Hastings Dam (Lock and Dam #2). Note: trend analysis only available through 2005. Figure 2. Impacts of how we use the land Hard surfaces increase runoff from the land. 1975 1980 1985 1990 1995 2000 2005 2010 :AxN:AM_VY[1 This section hi two key measures of the quality of the Mississippi River as a swimming and recreation amenity. Bacteria pose a threat to human health and can limit the recreational uses of rivers, lakes, and streams. Phosphorus contributes to algae blooms, and other factors that negatively impact aquatic recreation, life, and health. k Bacteria Parts of the river are impaired with excess bacteria, which can create health concerns for recreational users. V Minnesota uses E. coli data to indicate the potential presence of waterborne pathogens in the river. Bacteria pollution comes from human and animal sources. Description and impacts Escherichia coli (E. coli) is a bacterium indicating the potential presence of wa- terborne pathogens that can be harmful to human health. It typically results from the presence of human and animal fecal waste. To reduce the risk of people getting sick from exposure to these pathogens while recreating, the state has standards for concentrations of E. coli in the water. The river is a significant recreational resource (swimming, boating, or wading) for many Minnesotans. Contact with water with high bacteria concentrations can make recre- ational users sick (nausea, vomiting, fever, headache, and diarrhea). Sources Bacteria pollution can be a problem in rural, suburban, and urban areas. Harmful bacteria originate in the intestines of living creatures, and are generally spread when fecal matter enters the river. Sources of these bacteria include human sources (septic systems, combined storm and sanitary sewer overflows, 13 leaking sanitary sewers), livestock (feedlots, grazing livestock, field - applied manure), pets, and wildlife. In addition, fecal bacteria appear to be able to survive for some time in sediment, so areas with stirred -up sediment may also suffer from elevated river bacteria concentrations. In general, the more runoff an area produces, the more susceptible its surface waters are to bacteria pollution. There is no clear relationship between river bacteria con- centrations and seasonal changes or flow levels. Bacteria in the river seems to come from a mix of local and region- al sources, and can be found at a wide range of flows. Tar- geted monitoring could help determine with more clarity how, when, and where elevated bacteria concentrations are delivered to the river. T A clean -up plan is currently under development to address this pollution problem. The acceptable E. coli limit is exceeded more often on Mississippi River tributaries than on the river itself 16 This indicates that the Mississippi may be "inheriting" some of its elevated bacteria concentrations from its tributaries. In rural areas, fecal waste can travel efficiently to streams and rivers through drain tiles and ditches; in urban areas, it can travel efficiently to streams and rivers via stormwater pipes and hard surfaces like roads. History and trends E. coli data has been con- sistently collected in this portion of the river since 2005, although some stretches were identified as having too much fecal bacteria as early as 1996. Since 1985, efforts by the cities of Minneapolis and St. Paul to separate their sanitary and storm sewers (now large- ly complete) have kept millions of gallons of sewage from contributing bacteria to the river each year. 17 PET WASTE . W TRANSMITS DISEASE LEASH -CURB AND CLEAN UP AFTER YOUR a PET at-1 fi = %%�? .� . .a i. Bacteria impairments through the Twin ` Cities 400 0 350 � O 300 u o WON ^ iritn y 250 not impaired o b) 200 - J impaired 1 «x „ �• � � a, 150 i 00 insufficient data r Imo - loo ., l t� 0 Status. In several reaches ~ ' of this part of the river, average bacteria levels are below the state standard. However, most portions of the river from Coon Rapids Dam to St. Paul have average bacteria concentrations that are too high. These reaches of the river are "impaired" with excess bacteria (see map). Regardless of official "impairment" status, some parts of the river have experienced high bacteria spikes that can exceed the state standard. Figure 1. Bacteria Levels from Lower St. Anthony Falls to the Ford Dam ',kL,;,. PAL „ Bacteria levels vary greatly over time, even at the same location. If enough samples at a site exceed the bacteria standard, that part of the river is classified as "impaired" for having too _ � much bacteria urce: Minnesota Pollution Control Agency GROVE eoTrAC.e i r Ttncrsr c.Ro"'r PostonU11f The river's bacteria concentrations are highest around the Twin Cities metropolitan area. It is recommended that swimming or other recreational contact be limited in "im- paired" sections of the river and that it be avoided every- where on the river within 48 hours of a rainstorm (includ- ing storms upstream), as this is when many pollutants are washed in with stormwater. Recreational users are advised to be especially cautious downstream of storm drain pipes and other places where runoff enters the river. Always rinse off well after swimming. Drinking untreated river water that contains disease - causing bacteria poses a risk for animals as well as for peo- ple. t$ ' " If you allow your dog to swim in the river, do not allow it to drink the water. Solutions. The Minnesota Pollution Control Agency is working with a number of partners to develop a clean- up plan. That plan will identify the potential sources of ti Map data sources: M=esota Pollution Control Agenc (bacteria data) and Minnesota Department of Natural Resources (core geographic elements) bacteria pollution and propose ways to reduce current bacteria levels in the river. This clean-up plan is currently under development and is anticipated to be ready in the next few years. Project information is available at http: / /www.pca. state. mn. us /ktgha48. In the meantime, you can help reduce bacteria pollution in the Mississippi River by cleaning up your pet's waste, making sure septic systems are up -to -date, and taking ac- tion to help reduce stormwater runoff at home and in your community. Stangia , ,126.4ryap . n 1) Q.OmL, III IN 111 11 Jill 111111 -11" 2003 2004 2005 2006 2007 2008 2009 2010 2011 ',kL,;,. PAL „ Bacteria levels vary greatly over time, even at the same location. If enough samples at a site exceed the bacteria standard, that part of the river is classified as "impaired" for having too _ � much bacteria urce: Minnesota Pollution Control Agency GROVE eoTrAC.e i r Ttncrsr c.Ro"'r PostonU11f The river's bacteria concentrations are highest around the Twin Cities metropolitan area. It is recommended that swimming or other recreational contact be limited in "im- paired" sections of the river and that it be avoided every- where on the river within 48 hours of a rainstorm (includ- ing storms upstream), as this is when many pollutants are washed in with stormwater. Recreational users are advised to be especially cautious downstream of storm drain pipes and other places where runoff enters the river. Always rinse off well after swimming. Drinking untreated river water that contains disease - causing bacteria poses a risk for animals as well as for peo- ple. t$ ' " If you allow your dog to swim in the river, do not allow it to drink the water. Solutions. The Minnesota Pollution Control Agency is working with a number of partners to develop a clean- up plan. That plan will identify the potential sources of ti Map data sources: M=esota Pollution Control Agenc (bacteria data) and Minnesota Department of Natural Resources (core geographic elements) bacteria pollution and propose ways to reduce current bacteria levels in the river. This clean-up plan is currently under development and is anticipated to be ready in the next few years. Project information is available at http: / /www.pca. state. mn. us /ktgha48. In the meantime, you can help reduce bacteria pollution in the Mississippi River by cleaning up your pet's waste, making sure septic systems are up -to -date, and taking ac- tion to help reduce stormwater runoff at home and in your community. Phosphorus The metropolitan portion of the Mississippi River sends too much phosphorus pollution downstream to Lake Pepin. V V V Excess phosphorus harms Decreases in river State standards for aquatic life and recreation phosphorus concentrations river phosphorus in water bodies. have been offset by higher are currently under overall flows. development. Description and impacts Phosphorus is a common element in the environment and is essential for plant growth and health. However, excess levels of phos- phorus in waters can harm aquatic life and recreation by reducing water clarity, depleting oxygen levels in the wa- ter, and causing toxic algae blooms. Algae have created problems in the lower Minnesota River and Lake Pepin. Sources Overall, the Minnesota River is the larg- est contributor of phosphorus to Lake Pepin (Figure 1). Major sources of phosphorus pollution include agricultural runoff, urban runoff, and wastewater treatment plants .22 Additional sources include atmospheric deposition, failing septic systems, and some road salt alternatives. Sediment levels in water also affect phosphorus pollution, as phos- phorus can attach to soil particles as they move through the watershed (see Sediment, page 28). The Metropolitan Wastewater Treatment Plant was a leading source of phosphorus (especially under low -flow conditions), but loads from this plant have greatly dimin- ished since it implemented a new phosphorus reduction process in 2003 (Figure 2). Similar load reductions have taken place at other wastewater treatment plants through- out the Lake Pepin watershed. River status and trends State standards for river phosphorus are currently under development. Without a standard to measure against, we cannot say whether the metropolitan portion of the Mississippi Riv- er is or is not "impaired" due to excess phosphorus. Overall phosphorus concentrations have decreased since 1976. Median annual phosphorus concentrations declined by 28% at the Hastings Dam (Figure 3). On average, each gallon of water flowing through the river contains less phosphorus than in previous years. But with dramatic increases in flow, there are many more gallons of water flowing, meaning the overall "load" (amount of phosphorus moving through the river) has remained fairly steady. Lake Pepin status Unlike the metropolitan portion of the river, Lake Pepin is listed as impaired with excess phosphorus concentrations, and can suffer from severe algae blooms and fish die -offs during low -flow summers such as 1988. Upstream efforts to reduce phosphorus loads will help restore Lake Pepin. Management solutions. Establishing phospho- rus standards for the river is important. Substantial im- provements in agricultural fertilizer and manure manage- ment, along with enhanced septic system maintenance and Figure 1. Sources of phosphorus to Lake Pepin, 2006 Z. 25 %% r� Upper St. Croix River 2% / mississipp Other sources-,'. River 7% Metro Wastewater Treatment Plant Can ton & Vermillion Rivers _ Source: Minnesota Pollution Control Agency29 i Figure 4. Phosphorus concentrations through the Twin Cities E12002-2011 ■ 2011 n.a�tsl�• a h . ! n t_ -- J q/ DAY1'CtN CODA !WM$ C - I,UfPLI, cqol' �]Q e" inspection i6IINNE:1rOlrs SAINT P:\I -':I. and reduced N_ y0 urban stormwa , t,, l�I " " '^' arc ,f ter runoff are vital steps for limiting phosphorus pollution. rn Frz (,I =oti E Because phosphorus can f rnr,,j attach to soil particles, mea- sures that prevent soil erosion --- -- t' are also important. Minnesota banned phosphorus in laundry detergents in 1977, and State law prohibits the use of fertilizers containing phosphorus on lawns and turf, except in a limited number of situations.27, 28 Minnesota residents can help by using lawn chemicals wisely, using phosphorus -free dishwashing detergents and soaps, picking up pet waste, and keeping grass clippings and leaves out of the storm drain. Figure 2. Annual Metro Wastewater Treatment Plant phosphorus loads loon a 900 o ro 800 700 o� �q 600 00 500 ro 400 r 300 KC 200 100 0 0.20 Ci a 0.18 0.16 F o 0.14 y 0.12 Q 0.10 y 1 3 0.08 O q Q 0.06 G 0.04 0.02 0.00 K \ t\"\\", Map data source: Minnesota Department of f - Natural Resources (core geographic elements) Figure 3. Annual phosphorus concentrations at the Hastings Dam 0.40 0.35 0.30 R 0,25 0.20 �A 0.15 CU a q 0.10 vU 0 0.05 t� 0.00 1975 1980 1985 1990 1995 2000 2005 2010 Source: Metropolitan Council Environmental Services Note: trend analysis available only through 2005. 0 © © 0 0 O Monitoring site (corresponds with map) Source: Metropolitan Council Environmental Services 2000 2001 2002 2003 2004 2005 2006 2007 2008 2009 2010 2011 Source: Metropolitan Council Environmental Services section highlights three key measures of quality of the Mississippi River fishery. Fish survey data highlight the abundance and diversity of fish species in the metropolitan portion of the Mississippi River. Fish consumption advisory information provides safe eating guidelines for fish from the river. Asian carp are invasive species threatening to move into the area. Fish consumption Fish from the river are safe and healthy to eat if you follow the state's fish consumption advice. Fish in the river may contain mercury, PCBs, and PFOS. V People who eat fish from the river should consult the state's Site - Specific Eating Guidelines. Background. Both store - bought and locally caught fish may contain contaminants such as mercury or PCBs that can harm human health. As a result, the State of Minnesota has safe eating guidelines to help you make informed decisions about the fish you eat. Statewide Safe Eating Guidelines. The Statewide Safe Eating Guidelines are based on mercury and PCB levels measured in fish through- out Minnesota. While not all waters in Minnesota have been tested for contaminants, the Statewide Safe Eating Guidelines can be used for both tested and untested waters. There are two types of guide- lines: those for mothers and children (more protec- tive), and those for the general population .30 Site - Specific Eating Guidelines. In some of Minnesota's lakes and rivers, test results show that fish contain higher or lower than average levels of certain contaminants. In these cases, the result- ing meal advice may be more or less restrictive than the Statewide Safe Eating Guidelines .31 Figure 1. PCBs in fish, 1970s -2000s ® 1970s ❑ 1980s ® 1990s t - 2000s 10 9 8 7 y � 6 a,o 5 ro �o 4 a 3 2 ro 1 0 Contaminants of concern. Fish are rich in iron, protein and omega -3 fatty acids and are a good choice for a healthy diet. However, fish can contain small amounts of some toxins. The three toxins of concern in this reach of the river are mercury, PCBs, and PFOS. • Mercury is a toxic metal that can impact the nervous system, particularly in children and the developing fetus. • PCB exposure is linked to problems in infant devel- opment and adult immune function. • Perfluorooctane sulfonate (PFOS) is part of a family of man -made chemicals that accumulate in fish, persist in the environment, and can pose potential risks to human health. For more information, see the "Other contaminants of concern" section of this report on page 37. LA Fish consumption guidelines are based on the fish species, who you are, and how often you eat fish. Figure 2. Mercury in fish, 1970s -2000s 3 v U3 N q m .p a g 0.8 0.7 0.6 0.5 0.4 0.3 0.2 0.1 0 ■ 1970s 11 1980s U 1990s 11 2000s St. Anthony Falls Ford Dam to to Ford Dam Hastings Dam Source: Wiener and Sandheinrich 2010 St. Anthony Falls Ford Dam to to Ford Dam Hastings Dam Source: Wiener and Sandheinrich 20 10 33 Fish consumption RA`ASEY r�w+� RiJ'LUS i Anglers should I K 1 , ! j follow Site - Specific Rice 4' Eating Guidelines I for fish from the ' , river. u� ieuth „hq Crerl: { FISH 3c FISHING • 21 Tips for eating fish While mercury and PFOS cannot be removed through cooking or cleaning (they are in the flesh of the fish), you can reduce exposure to contaminants like PCBs by removing fat when you clean and cook fish. cut away � the fat reVskin � i a long the back • cut away the fatty area along the side trim off the of the fish belly fat Source: Minnesota Department of Health Follow these tips when eating fish: 1. Eat smaller fish. 2. Eat more panfish (sunfish, crappies) and fewer predator fish (walleyes, northern pike, lake trout). 3. Trim skin and fat, especially belly fat. Also, eat fewer fatty fish such as carp, EaE,I PA !, catfish, and lake trout. PCBs build up in fish fat. y4 u'icrlr; t, _ J LNVEV f i ` GP.nVG ` i u Map data sources: 11 j Minnesota Department of Health (fish consumption guidelines)' Minnesota Department of Natural Resources (core geographic elements) History and trends. Environmental contamination from PCBs began in the mid - 1930s and peaked in the early 1970s (Figure 1). Concentrations in fish have declined substantially since the manufacture of PCBs was banned nationally in the late 1970s. Mercury pollution to the river peaked in the 1960s. By the early 1990s, annual accumulation rates, as measured in Lake Pepin sed- iment, had decreased by almost 70 %. However, recent research on mercury accumulation in loons and fish shows an increase in recent years, suggesting the need to remain vigilant (Figure 2). For information on PFOS trends, see page 40 of this report. Status. There are site - specific eating guidelines in place for the metropolitan portion of the river. Some of these guide- lines are more restrictive than the Statewide Safe Eating Guidelines. People who eat fish from the river should con- sult the Site - Specific Eating Guidelines. More information is available through the Minnesota Department V 7 of Health at http: / /wwwhealth.state. mn.us /divs /eh /fish /eating /sitespecific. html. Solutions. The Minnesota Pollution Control Agency recently approved a statewide mercury reduction plan that calls for a 76% reduction in mercury air emissions by 2025. Achieving these goals will require major reductions from a range of sources, including coal -fired power plants, ferrous mining operations, and other for- eign and domestic sources. PCB manufacture was banned in the U.S. in the late 1970s. As a result, PCB concentrations in the river have decreased dramatically. PFOS clean -up work is under- way; see page 40 to learn more. �s Fish survey Anglers have embraced the metropolitan portion of the Mississippi River as a world -class fishery. V There has been an increase in the Catch - and - release River managers lack data diversity and quality of the river's regulations are in on fish populations; few fishery, particularly smallmouth bass place for portions of regular fish surveys have and walleye fisheries, since the 1970s. the river. been conducted. Background. Early settlers and explorers found abun- dant fish and wildlife throughout this reach of the river. Pre - settlement fish populations are estimated to have included nearly 120 native species below St. Anthony Falls and approximately 60 species above the falls, which historically served as a natural migration barrier. Unfortunately, fish populations declined dramatically following European settlement. By 1926, fish survey data showed only two living fish in the 25 miles down- stream of St. Anthony Falls. Sewage and industrial contamination contributed to high pollution levels, while subsequent dam construction altered river flow patterns (converting free - flowing water to more stagnant pools) and increased sediment accumulation in the water (smothering important fish habitat). Since then, improvements in regional and federal waste- water management, including substantial reductions in pollution following passage of the 1972 Clean Water Act, along with other factors, have resulted in improved fish populations in the river. In addition, lock and dam installation has aided fish migration upstream as far as the Coon Rapids Dam, which now acts as the primary fish migration barrier in the metropolitan portion of the river (the other metro -area dams have locks through which fish can pass). Status. Today, the river supports a high quality fishery for several trophy species, including smallmouth bass, catfish, and walleye. Between the Ford Dam and the Hastings Dam, the walleye fishery is one of the highest quality urban fisheries in the U.S. The smallmouth bass fishery upstream of the Coon Rapids Dam is considered word- class. It is estimated that more than 127 species of fish (119 native, eight introduced) currently live in the river up to the Coon Rapids Dam, including some, like trout - perch, that are sensitive to pollution. An estimated 75 species (65 native, 10 introduced) are now found above the Coon Rapids Dam. Some of these would not naturally be found there, and are present due to human actions or because they have been able to pass the dam during floods. Despite these encouraging numbers, it is difficult to accurately estimate fish populations, and much remains unknown about the overall diversity and abundance of fish in the river. There have been few consistent surveys of aquatic life in this reach of the river, and fishery managers lack data to adequately manage the river's fishery. Fishing catch - and - release rules. There are catch - and - release regulations for the river between the Figure L Walleye catches between Ford and Hastings Dams o walleye < 20 inches long t ) walleye >_ 20 inches long b) 8 G N 7 0 6 a 5 a 4 0 � 3 a 2 U 1 Source: Minnesota Department of Natural Resources 1979 1980 2003 2008 Catch - and - release regulations 6. FISH do FISHING • 23 Figure 2. Smallmouth bass catches above Coon Rapids Dam ■ smallmouth bass ? 12 inches long * smallmouth bass < 12 inches long F i11ISLY F;PID5 -- ElattCPt,I' I �uti gas 1 i_ Ford and Hastings c� Dams for walleye, sauger, largemouth bass, SN and smallmouth bass. A These fish may be caught, but must be returned alive to the water. These guidelines were estab- lished in 1993 to protect and maintain high quality populations. 180 t)) 160 140 120 V w 100 0 80 ti 60 v 40 v Ci 20 0 Source: Minnesota Department of Natural Resources SA IN'l JA L f ` 1 ' E ' I C Hi S 'tiE1GHS I;A •Er. ..� GF<7t'E HEIGM'� Emerging threats. The Department of Natural Resources (DNR) is actively pursuing in- formation and management strategies for two emerging threats to fish populations in the Mississippi River. Asian carp: These large invasive fish can destabilize the aquatic food web and outcompete native fish for food. Monitoring for the presence of Asian carp in the river is ongoing (see Asian carp, page 24). VHS: Viral Hemorrhagic Septicemia (VHS) is a deadly virus that threatens a number of fish spe- cies in the river. The DNR has been testing for the presence of VHS in the metropolitan portion of the river. To date, no fish have tested positive. Ford Dam to Hastings Dam: catch - and - release regulations for walleye, sauger, smallmouth bass, and largemouth bass cC" ra(;E are in place here GRO`,'E Map data source: Minnesota Department of Natural Resources (fishing regulation data & core geographic elements) r� While the fishery as a whole appears healthy, fishery managers lack clear data on species abundance and habitat condition throughout this reach of the river. Regular and consistent fish survey data are needed in order to establish "baseline" fish population informa- tion. The DNR is allocating additional resources to this work. Once baseline information exists for the river's fish populations, strategic management options can be more effectively identified. Management tools and outcomes. Several im- In addition to habitat restoration and water quality portant fishery management tools, including commercial enhancement, the DNR is actively working to address and recreational angling regulations, and catch - and -re- overharvesting of protected species, and to prevent the lease rules, are currently in place. spread of both VHS and Asian carp. 1974 2000 2001 2002 2003 2004 2005 2006 2007 2008 Asian carp Asian carp are moving into the metropolitan portion of the Mississippi River. Asian carp are invasive fish that pose a serious threat to river recreation and ecosystem health. V Grass, bighead and silver carp have reached Minnesota; eDNA tests suggest potential migration as far as the Coon Rapids Dam. About Asian carp. Asian carp are a group of invasive fish consisting of four species: bighead, black, grass and silver carp. The largest species, bighead carp, can grow to 111 pounds. With large appetites and no natural predators, these voracious feeders can severely disrupt aquatic ecosystems as they out - compete native fish species. In addition, Asian carp also threaten boating, fishing and other river recreation activities. Silver carp, which can grow to 60 pounds and leap as high as 10 feet from the water when disturbed, have injured boaters and damaged property in other states. History and background. Asian carp were originally imported to the southern U.S. from China to control aquatic vegetation and parasites in fish farms. The carp escaped to the Mississippi River and its tributaries in the 1970s, and populations were well established in southern river states by the 1980s. Their population and range have increased dramatically in recent years, and the fish have reached the Mississippi and Missouri River watersheds in Illinois, Missouri, Iowa and southern Wisconsin. In 2012, over 80 bighead and 50 silver carp were caught by commercial fisherman in Lake Okoboji in V Federal and state agencies and nongovernmental organizations are working to prevent additional Asian carp migration. northwest Iowa, near the Minnesota border . In portions of the Illinois River where the infestation is extreme, 60% of the river's fish biomass is now Asian carp. Status. In 2011 and 2012, bighead carp were caught in the St. Croix River (Prescott, Wisc.) and on the Mississippi River near Winona. Silver and grass carp were also caught near Winona. About a dozen bighead and silver carp have been caught in the St. Croix and Mississippi Rivers along Minnesota's eastern border since 1996. While no established populations of bighead or silver carp are known to exist in Minnesota, recent data suggests the fish may be present in the Mississippi River above Red Wing and in the lower St. Croix River. Environmental DNA (eDNA) testing in 2011 found genetic evidence of silver carp above and below the Coon Rapids Dam, between the Lower St. Anthony Falls Lock and Dam and the Ford Dam (Lock and Dam #1), and below the Hastings Dam (Lock and Dam #2). In addition, eDNA was found in the St. Croix River below the dam at Taylor's Falls, and on the Minnesota River upstream of the continues on page 26 ► confluence with the Mississippi (see map, page 26). s F The march of Asian carp up the M_ ississippi River a� r l KEY ` Carp abundant by species -- no finding rare A mm- uncommo: ow-s*occasiona Owma .*--*abundant lock and c (number) Prefer zooplankton but also eat phytoplankton - the base of the aquatic a° food web. Identifying features: silver color • no y z scales on head • no barbels on nose, unlike common carp • downward slanting mouth (frown) • low set eyes • keel extends F s partway along belly Gti Map data sources: B lack carp p 'Xn carp data compiled National Park Service; M Y 10 p har yng O On ICeI1S geographic data : , som from USGS, NOAH and Natural Earth ''; iti "� , •;! >; ;naturalearthdata.com) .. Black carp eat and threaten native mussels and snails. They take away food sources for native fish, waterfowl, and SIN a vertebrates. There is no evidence of r established populations in x Green Bay 9 the upper Mississippi, but the USGS has reports of individuals caught as far north as Lock and / a Dam 24, 100 miles north of St. Louis. zlw U Identifying features: M eis n darker color • large scales • no — scales on head • pointy shaped face • teeth that look like human molars C . Peorer carp are the kind that S, I i famously jump up to ten out of the water when urbed by passing boats, S p ri sing injury to passing boaters. ...ltrp Ctenopharyngo d on idella Grass carp eat massive amounts of vegetation, destroying habitat needed for other wildlife. �m Identifying features: silver color • small scales, but no scales on head • no barbels on nose, unlike F carp • downward slanting mouth (frown) • low set eyes • keel that extends to throat s Silver carp Hypophthalmich ysmolitrix Identifying features: green -gray back • rounded snout • over - hanging upper lip • no barbels on nose, unlike common carp • covered with larger scales lam' Silver carp eDNA sample locations, 2011 All locations tested positive for silver carp DNA Samples for bighead carp were collected - -� at the same time in the same locations; those samples all came back negative. Additional long -term testing and monitoring is , needed to fully assess the range and population of Asian carp in the Mississippi River. Solutions. Federal, state and local agencies, through an ad -hoc Asian Carp Task Force, are actively pursuing management solutions to prevent the further spread of Asian carp into Minnesota. This task force has developed and is working to implement an action plan to prevent the establishment of Asian carp in the state. The Asian Carp Coalition, a group of nongovernmental organizations collaborating to raise awareness about Asian carp, recommends a three -step strategy: • Stop the spread of Asian carp through targeted lock closure, especially at the Upper St. Anthony Falls Lock and Dam and the Ford Dam. • Slow the spread of Asian carp by reducing recreational traffic through locks and dams, limiting overall lockage hours, and installing fish "bubble" and electric barriers. The Minnesota Legislature has approved funding for the installation of Asian carp barriers at the Ford Dam. • Control established Asian carp populations with the development of new technologies to biologically control carp. Enhance monitoring and research in partnership with the newly - established Aquatic Invasive Species Research Center at the University of Minnesota. Bay,.» rARK T ( t f f r- In addition, improvements to water quality and aquatic habitat in the river will support healthy native fish populations and are among the best ways to prevent aggressive Asian carp infestation throughout the Minnesota, St. Croix, and upper Mississippi River watersheds. To learn more, visit www.asiancarp.us, or www.stopcarp.org. 0 rK I i i N Q S7i1 hJ:AT5' - S A FN PA 4 )am e Hast: Da VW Map data sources: Environmental DNA °R "z Solutions, 2011 (eDNA sample results); Minnesota & Wisconsin Departments - ;5 of Natural Resources (core geographic elements) R.r VID', Samples for bighead carp were collected - -� at the same time in the same locations; those samples all came back negative. Additional long -term testing and monitoring is , needed to fully assess the range and population of Asian carp in the Mississippi River. Solutions. Federal, state and local agencies, through an ad -hoc Asian Carp Task Force, are actively pursuing management solutions to prevent the further spread of Asian carp into Minnesota. This task force has developed and is working to implement an action plan to prevent the establishment of Asian carp in the state. The Asian Carp Coalition, a group of nongovernmental organizations collaborating to raise awareness about Asian carp, recommends a three -step strategy: • Stop the spread of Asian carp through targeted lock closure, especially at the Upper St. Anthony Falls Lock and Dam and the Ford Dam. • Slow the spread of Asian carp by reducing recreational traffic through locks and dams, limiting overall lockage hours, and installing fish "bubble" and electric barriers. The Minnesota Legislature has approved funding for the installation of Asian carp barriers at the Ford Dam. • Control established Asian carp populations with the development of new technologies to biologically control carp. Enhance monitoring and research in partnership with the newly - established Aquatic Invasive Species Research Center at the University of Minnesota. Bay,.» rARK T ( t f f r- In addition, improvements to water quality and aquatic habitat in the river will support healthy native fish populations and are among the best ways to prevent aggressive Asian carp infestation throughout the Minnesota, St. Croix, and upper Mississippi River watersheds. To learn more, visit www.asiancarp.us, or www.stopcarp.org. 0 rK I i i N Q S7i1 hJ:AT5' - S A FN PA 4 )am e Hast: Da VW A n lJ This section highlights the ecological health of the Mississippi River, including the status and trends of four key measures of water quality and aquatic life in the metropolitan portion of the Mississippi River. Sediment and nitrate are important measures of water quality that affect aquatic life and habitat throughout the Mississippi River watershed. Bald eagles and mussels are key treasures of the health and vitality of the river. A �F Sediment The river is impaired with excess sediment below the confluence with the Minnesota River. Excess sediment can harm About 75% of the river's Lake Pepin is filling in aquatic plants and habitat sediment comes from the with sediment at 10 for fish and other wildlife. Minnesota River basin. times its natural rate. Description and impacts Sediment pollution includes tiny particles of soil and organic matter that are suspended in the river's water. Excess sediment makes the water "turbid" or cloudy, harming aquatic plants and habi- tat for fish and other wildlife. In addition, other pollutants, like phosphorus, can attach to sediment and be carried downstream. Excess sediment is also rapidly filling in Lake Pepin, a natural lake on the Mississippi River, where exten- sive sediment research provides valuable long -term data. Sources On average, about 75% of the sediment load flowing into the metropolitan portion of the riv- er comes from the Minnesota River basin, where river banks, bluffs, and farm fields are the primary sources of sediment pollution. 12 The rest of the sediment comes from the upper Mississippi River basin, along with the Can- non River and other smaller tributaries. Metro -area urban runoff contributes roughly 6% of the total sediment load, while the relatively clean St. Croix River contributes very little sediment to the river. Figure 1. Total sediment contribution Pounds per acre, per year TA Mississippi River Ba in St. Croix Z River . _ I. Basin 43 1V�innesota River' !' -- Basin { 134 - On average, sediment loss in the Minnesota River basin is far greater than in the Mississippi or St. Croix River basins. Sources: Engstrom & Almendinger, 2000, Nater & Kelley, 1998 via Minnesota River Trends - November 2009 Total sediment loads to the river and Lake Pepin are greatly influenced by increased river flows, as large volumes of water move more sediment through the river system. History and trends Current sediment loads to Lake Pepin are roughly 10 times pre- European settlement rates. 14 From the 1930s to 1960s, sediment loads to Lake Pepin roughly doubled, from 300,000 to 700,000 metric tonnes per year (Figure 2). This period coincides with the Figure 2. Sediment loading to Lake Penin 1000 900 a 800 — N m 700 o a 500 to 0 400 N m 300 N 0 200 100 Source: Minnesota Pollution Control Agency 1500 1600 1700 1800 1850 1900 1950 2008 {{ f RA"45LY -� 1 DAYTON f � i_i_�UN IL4PIpti C 79"il'LI'`i j BRCS 1N 1 PAKK 1 11 , a 4 100 o 90 80 70 0 big 60 0 50 ti 40 m 30 u 20 to a' _- y _0 Figure 3. Average sediment concentrations • Sites above Minnesota River confluence (sites 1 & 2) • Sites below Minnesota River confluence (sites 4, 5 & 6) ■ FINE ■ _ I■ IN immmm Ir So N N ... � . II ■ ■ ■ rrS'�■ r° 2002 2003 2004 2005 2006 2007 2008 2009 2010 2011 iMINNrarOI is s -�i n' P ..i; _ This graphic illustrates sediment concentrations in "' " " - "'", .l' the river above and below - the confluence with the , nc TA Minnesota River. widespread loss of wet- �c uwr.a *32 ppm site - specific standard to the o lands and intensification N1 south -metro P GROVE cOTTACh ap p ortion of I>TIc}r�z GROVE o the river (including sites 4, 5, and 6). d of agriculture, along with Source: Metropolitan Council 5 Environmental Services ditching of farmlands, and -- increased urban development.", 57 Sediment loads peaked in the early RCKEhtJUVT 1990s (when river flows were especially t high) and have since leveled off at approxi- mately 850,000 tonnes /year. Changes in hydrology, particularly agricultural drain- age and wetland loss, have increased river flow (see Flow, page 10). Median Minnesota River flows near Jordan have doubled over the past 70 years, and its tributary flows have increased by similar magnitudes 6 Increased flows have in turn amplified Minnesota River basin stream bank, ravine, and bluff erosion, which are now the prima- ry sources of sediment to the Mississippi River and Lake Pepin.' Status. The river is currently impaired with excess sedi- ment below the confluence with the Minnesota River (Fig- ure 3). Sediment levels in this reach of the river frequently exceed the state standard of 32 parts per million (ppm). As a result, the river has too much sediment for healthy aquatic plant growth, or for fish and wildlife to thrive. Solutions. The Minnesota Pollution Control Agency recently drafted a clean -up plan for excess sediment in the river. The plan calls for major reductions in sediment Map data source: Minnesota Department of Natural Resources (core geographic elements) loads, including 50 -60% reductions from the Minnesota River, 20% from the upper Mississippi River, and 25% from metro -area urban runoff. Achieving these goals will require substantial changes in how we use land as well as increased water retention throughout the Mississippi River watershed. Improved agricultural conservation and water retention, urban runoff controls, and in -river restoration such as island building, are important steps in reducing sediment and restoring aquatic life in the river. Nitrate The river currently meets drinking water standards for nitrate, but overall nitrogen pollution to the Gulf of Mexico remains a serious problem. V Excess nitrate poses threats to human health and aquatic life, and is a primary contributor to the Gulf "dead zone." V Nitrate concentration in the river increased by 47% from 1976 -2005. Description and impacts. Nitrate is an im- portant form of nitrogen for plant and animal life, but too much in waters can be detrimental. Like most nitrogen compounds, nitrate easily dissolves in water. Excess nitrate can quickly enter surface waters and groundwater, where it presents two primary challenges: • Human health. Nitrate in drinking water at levels above federal and state standards (10 parts per million) can pose health risks, including a potentially fatal condition known as "blue baby syndrome" in infants. • Hypoxia and the Gulf dead zone. Further downstream, surplus nitrate contributes to the seasonal dead zone in the Gulf of Mexico. Excess nitrogen feeds massive algae blooms each spring. When the algae die off, their decomposition robs the water of oxygen (a condition called "hypoxiZ), suffocating all marine life that is unable to escape. Sources. U.S. Geological Survey researchers have doc- umented the overall sources of nitrogen pollution to the Gulf of Mexico (Figure 1). Total nitrate loads to the river are related to flow, as large volumes of water can move T A drinking water nitrate standard exists to protect humans, but no nitrate standard exists to protect aquatic life. That standard is under development in Minnesota. Status. Locally, the river (above the confluence with the Minnesota River) is used directly for drinking water. As a result, the drinking water standard (10 parts per million) applies to that reach of the river. The river meets the current standard. However, the state does not yet have a nitrate standard for the protection of aquatic life in the river. That standard is under development. Figure 1. Sources of nitrogen to the Gulf of Mexico, 2006 atmospheric deposition 16% urban 9% natural land 4 -ko pasture and range 5% other crops 14% corn and soybean crops 52% Source: Alexander, et. al." Figure 2. Median nitrate concentrations through the Twin Cities ■ 2011 11 10 -year average It�,n -ISet! � CiAt fCrr. COON RAPIDS PRO 1111N -� ] P,at:_ Ficr Cr ^k a - 1� " f _J 5.0 4.5 �^ 4.0 3.5 3.0 N 2.5 g 2.0 1.5 1.0 0.5 0.0 stwX 1 I' V. i© I 9 Nationally, excess nitrogen pollution re -` trVz ; mains a serious problem for GROVI , t t the Gulf of Mexico. History and trends Overall nitrate concentrations in the river in- creased by 47% from 1976 -2005 (Figure 3). Further downstream near Clinton, Iowa, river nitrate concentrations have increased by 76% since 1980. Multiple factors are linked to these increases, including increased agricultural production, fertilizer application, artificial drainage, and overall river flows. Other factors, including population increases, changes in how wastewater is managed, and urban development, also impact river nitrate levels. Solutions. Establishing a state nitrate standard to protect aquatic life is an important first step in mini- mizing the impacts of excess nitrate in Minnesota. The state is conducting a thorough study of nitrate condi- tions in Minnesota's rivers, including sources, trends, and solutions. The study will be completed in 2013. Considering the overall sources to the Gulf of Mexico, substantial reductions in nitrogen loads from agricul- tural sources are an important part of the solution. In addition, reductions in urban runoff, wastewater treatment plant contributions, and air emissions are important components of protecting the river and restoring the Gulf of Mexico for future generations. Source: Metropolitan Council Environmental Services 0, Map data sources: Minnesota Metropolitan Council Environmental Services (nitrate data), and Department of Natural Resources (core geographic elements) 0 Figure 3. Nitrate concentrations at the Hastings Dam 5.0 0 4.0 m 3.0 �ro Q, ` 2.0 �o ro•� '8 m 1.0 v U O u 0.0 1975 0 © 0 0 1980 1985 1990 1995 2000 2005 2010 Note: trend analysis only available through 2005. Source: Metropolitan Council Environmental Services Mussels Some mussel populations are gradually being re- established in the river. The presence of mussels Mussel habitat is degraded Species diversity and is a good biological below the confluence with abundance have not fully indicator of river health. the Minnesota River. recovered to historical levels. About mussels. The presence of mussels is a good biological indicator of overall river health. Minnesota's native mussels perform important functions in lakes and streams, and are considered ecosystem engineers because they enhance habitat for other organisms. Mussels filter solid material (like plant debris and soil runoff) from the water, incorporate it into their bodies and shells, and excrete nutrients usable by plants and other animals back to the river. The physical presence of both living mussels and their discarded shells creates habitat for other life, including fish, amphibians, and insects. There are about 50 species of mussel that are native to Minnesota, some of which can live for more than 100 years. Health and lifecycle. Mussels spend their lives partially or fully buried in mud, sand, or gravel in lakes, rivers, and streams. They require a stable surface, dis- solved oxygen, and a food supply of organic matter to filter from the water passing over them. Since mussels can't swim away to escape, they are directly impacted by river contaminants and habitat conditions. Mussels reproduce by releasing larvae that attach to a host animal, usually fish (Figure 1). Once attached to their host, the larvae metamorphose into adult form, leave the host, and take up life in the river bottom. Not just any fish host will do: some mussel species are only able to utilize a sin- gle species of fish, while others are adapted to use several different species. History and trends. Historically, St. Anthony Falls represented an important migration barrier that lim- ited the distribution of mussels and fish. As a result, fewer species of mussel (nine) were historically present above the falls, while many more species (43) were historically present in the lower portions of the river (Figure 2). Figure 2. Mussel species richness above and below St. Anthony Falls Figure 1. The lifecycle of a mussel -+ fish host 4 _ glochidia k ' , juvenile larvae mussels adult mussel Source: Water Resources Center at Minnesota State University, Mankato 50 45 y 40 35 y 30 'F3 25 R 20 15 10 c Above St. Anthony Falls* n Below St. Anthony Falls *The construction of the St. Anthony Falls Locks and Dams aided fish and mussel passage upstream to the Coon Rapids Dam. Sources: Minnesota Department of Natural Resources pre -1900 1900 1972 2000 - present Condition of mussel habitat i the Twin Cities 3 E 4 y� �5 ae c� ac R�ti \151:1' D:AN70% a i:i.HJN RAPIDS ttanmu_ ORWKUYN Rice Cr I Y` < tJULE � 0 i cry I'M _ _rot A few of the many mussels found locally in the Mississippi: the fragile paper mussel (top), fat mucket (right), plain pocket (bottom), and the endangerd Higgins eye (left). Figure 3. Mussel abundance in the Twin Cities, 2000 -2001 160 140 120 C 100 4 80 60 U ` 40 20 -- © Above Coon Rapids Dam (CRD) © CRD to St. Anthony Falls (SAF) Q SAF to Ford Dam ,,, • 0 Ford Dam to Minnesota River © Minnesota River to I -494 Bridge 0 I -494 Bridge to Hastings Dam INA ER ftCIGtMS GlopA'F By the early 1900s, pollution had eliminated the river's mussel populations below St. Anthony Falls. Prior to 1938, human and other waste was discharged directly to the river, greatly reducing oxygen in the water and increasing toxic ammonia levels in the sediments where mussels live. Mussel populations have responded favorably to improved sewage treatment, storm sewer sep- aration, and other water quality improvements, as year - round oxygen levels have increased and ammonia levels have decreased dramatically since the early 1980s. Status. Water quality and habitat for mussels in the upper portions of the river are good. From Dayton to the Coon Rapids reservoir, seven of nine historical native species are present. Below Coon Rapids Dam, improved water quality and the lock and dam system have allowed for greater upstream fish passage, resulting in more mussel species and larger populations. Unfortunately, mussel habitat below the confluence with the Minnesota River is degraded due to high sediment and pollutant loads. Source: I {elver and Davis, 2008 Map data sources: Department of Natural Resources (mussel data and core geographic elements) However, some mussel species have re- turned and this lower reach of the river now supports 28 of the original 43 native mussel species. Management solutions Reducing pollution is the most important step we can take to improve mussel habitat in the river. Efforts to remove fish migration barri- ers (such as dams) would also benefit mussel populations, but these measures are at odds with efforts to control the spread of Asian carp. Presently, re- colonization of many historically present mussel species is largely dependent on human reintroduction. O © © O 4 4 Bald eagles The bald eagle population along the river has made a dramatic comeback; the river is now home to one of the densest populations in the Midwest. Eagles along the river are highly productive, averaging two young per nest each year. V The dramatic increase in the bald eagle population is evidence of a healthier river compared to the 1960s, attributed to habitat protection and bans on certain chemicals. Background The bald eagle in North America has made an extraordinary recovery since 1963, when only 417 pairs were known to be nesting in the lower 48 states. Protections offered by the Bald Eagle Act (1940), the Clean Water Act (1972), national bans on DDT and PCBs (1970s), and the Endangered Species Act (1973) helped the population to rebound. Today, nearly 10,000 pairs nest in the lower 48 states, including 1,300 in Min - nesota. Eagles feed primarily on aquatic prey, and can easi- ly accumulate contaminants present in fish and other wildlife. Young bald eagles ( "nestlings" or "eaglets ") are particularly susceptible to these contaminants, and are good indicators of overall ecosystem health. The National Park Service (NPS) began intensively monitoring bald eagle nestlings along the river in 2006 to assess the levels of several environmental contaminants, including lead, mercury, the pesticide DDT, PCBs, and PFCs (including PFOS). See Figure 3 on page 36. Population status NPS data indicate there are approximately 36 active nesting sites along this reach of the river, indicating a strong and stable bald eagle popu- lation. From 2006 through 2011, the NPS visited up to 30 nests each year, assessed the health of 124 nestlings, and took blood samples to measure their levels of targeted contaminants. The findings indicate a well- nourished and productive eagle population, averaging about two nestlings per nest each year (Figure 1). The reproductive rate has varied over the years, but remains high relative to other areas monitored by the National Park Service. W a 2.0 a� a 1.5 a 0 1.0 0.5 0.0 V The National Park Service is monitoring levels of man -made chemicals in bald eagles along the river. This helps evaluate how contaminants impact fish, wildlife, and humans. Figure 1. Nestlings per occupied nest Source: National Park Service, 2012 Eaglet health status As a general trend, levels of a number of contaminants have declined over the last six years. Monitoring data indicates that overall levels of PFOS have declined (Figure 2), and levels of PCBs and DDT are generally below values considered critical for ea- gle health. Combined with nestling population data, these trends indicate an overall positive outlook for eagle health along the Mississippi River. However, contamination concerns persist for this reach of the river. PFOS contamination remains elevated in por- tions of the river between the Ford Dam and the conflu- ence with the St. Croix continues on page 36 Poo- 2006 2007 2008 2009 2010 2011 Eaale nest loc Figure 2. Average PFOS levels in eagle nestling blood samples 1,800 - - - 1600 - - - -- -- - -- - - 1,400 'q 1,200 m R 1,000 - - R 800 - - - - -- - -- -- - -- - - 0 600 I - - - -- - - - -- - -- - -- - 0. 400 IL- -- 200 r - 0 2006 2007 2008 2009 2010 2011 Source: National Park Service, 2012 O )� :voor. J G u iGr 0 — GROVE I-1LllSi , 0 • nesting locations study area Natural Resources (core geographic elements) Map data sources: National Park Service (eagle data), and Minnesota Department of River. One nestling from Durham Island (in Minneap- olis) had record -high DDT levels in 2009; the contam- inant source is unknown.$ have been multiple instances of high lead exposure in nestlings from Pigs Eye Lake (in St. Paul) .117 Recent research on mercury accumulation in loons and fish shows an increase in re- cent years, suggesting the need to remain vigilant.$$ °" In addition, the loss of critical habitat along the river poses potential long -term threats to the eagle population. Management solutions. Continued monitor- ing of PFCs (including PFOS and its substitutes) in the south -metro portion of the river is highly recommended to assess whether PFOS continues to decline, and how long (and where) PFOS and its substitutes may linger. Additional research on record levels of DDT at the Durham Island nesting site, and high lead levels in the Pigs Eye Lake area, is recommended, as it appears that there may be local sources responsible for these high concentrations. Action should be taken to address the lack of regener- ation of cottonwoods and other nesting trees along the river. Planning now to phase in succession plantings can help avoid significant loss of large trees necessary for eagle nesting and perching. Figure 3. Contaminants being monitored in the park's eagle population Six man -made contaminants are being monitored in bald eagle nestlings in the MNRAA corridor. sourc Marninant -A Primary - Concern Coal- burning power plants, mining, and Mercury Neurotoxin; cause for fish consumption advisory degradation of products containing mercury. in the river. Lead Past and current industrial uses, fishing tackle, Neurotoxin; especially harmful and ammunition. to children. Banned in North America. Used in the past as Causes tumors in fish, implicated an industrial lubricant and coolant. Can also be in crossed -bills in fish - eating PCBs formed by incomplete burning of plastics and birds; known to cause cancer. by chemical reactions in the environment. Cause for fish consumption advisory in the river. Banned in North America. DDT and DDD were The metabolite DDE was the DDT used as a pesticides; DDE is a breakdown primary cause of egg -shell (including product of DDT. DDT still used in other countries thinning that caused declines in DDE & DDD) and is occasionally used illegally in North bald eagles, osprey and other America. predators. Emissions from manufacturing and the Highest levels found in infants; PBDEs degradation of textiles, plastics, electronic chemically similar to PCBs; linked circuitry, and building materials containing to impaired liver and thyroid these flame retardants. function; possible carcinogen. High levels in infants; possible PFCs (including Emissions from manufacturing and degradation links to obesity, diabetes, and PFOA, PFOS) of products such as coated fabrics, coated early menopause in women. paper, and cookware. Cause for fish consumption advisory in the river. Source: National Park Service fj 14AI IF A This section highlights two primary contaminants of concern for this reach of the river, and includes an overview of some additional pollutants of concern. Triclosan can affect public health and aquatic life in a variety of ways. PFOS contamination affects fish consumption in the south -metro portion of the river. Additional contaminants, including PAHs, PDBEs, pharmaceuticals, and endocrine disrupting compounds, may also negatively impact the ecological health of the Mississippi River, and raise public health concerns as well. b eiclosan 6,PFOS Triclosan Triclosan contamination in Lake Pepin sediment is increasing. 0 V V Triclosan is an antimicrobial Triclosan is present Triclosan- derived dioxins have product used in a wide in 75% of Americans increased by 200 -300% in variety of household items. over age five. Lake Pepins sediment. Background. Triclosan is an antimicrobial product developed in the 1960s and introduced in 1972 for use in health care facilities. Triclosan has since been added to a wide variety of household products including liquid hand soap, toothpaste and toothbrushes, deodorant, fabrics, toys, and cosmetics. Risks. While additional research is required, numerous studies indicate that there are three primary risks associated with triclosan: • River environment. As triclosan moves through the wastewater treatment process and into the river, it is exposed to sunlight and chemicals such as chlorine, which can cause it to degrade into potentially harmful dioxins and other carcinogens, some of which can persist in our environment for long periods of time. 91 These contaminants pose a risk to aquatic life, and have been shown to interfere with the thyroid system and have other endocrine- disrupting effects in laboratory animals. 12 • Health. Humans can be exposed to triclosan via consumer products through skin contact, inges- tion, or inhalation, as well as through contaminat- ed drinking water. 93 Numerous studies indicate that triclosan exposure can lead to allergy suscepti- bility in humans. Human triclosan exposure is now common; a recent survey found the chemical present in the urine of 75% of Americans over age five, and overall levels of triclosan in the U.S. population increased by 50% between 2004 and 2009. • Bacterial Resistance. The Minnesota antibacterial products in most home applications because they may contribute to the emergence of resistant strains of bacteria. Sources. Triclosan is used in a wide variety of house- hold products and enters the environment primarily through the municipal wastewater treatment system. While wastewater treatment systems remove most of the triclosan, some of it is discharged directly to the river. Wastewater treatment byproducts are sometimes spread on agricultural fields for use as fertilizer, exposing near- by waters to triclosan- contaminated runoff, sometimes months after its application. In addition, triclosan can be released to surface waters and groundwater through wastewater from septic systems. Status. Since 1963, triclosan- derived dioxins have increased by 200 to 300% in Lake Pepin sediments, while levels of all other dioxins have decreased by 73 to 90% (Figure 1). This increase in triclosan- derived dioxins is consistent with increased use of triclosan in household products since its introduction. Triclosan- derived dioxins now represent as much as 31% of the total mass of diox- insin Lake Pepin."' Drinking water and public health. While several recent studies have detected triclosan in surface water and tap water, concentrations were well below the Minnesota Department of Health's 2010 "Health Based Values" for drinking water and no adverse health effects are anticipated. Triclosan has not been detected in ground- water samples in Minnesota. 102 Consumer solutions. Consumers should follow the recommendations of both the Minnesota Depart- ment of Health and the American Medical Association Department of Health recommends against using by avoiding the use of triclosan products for household applications. The U.S. Food and Drug Administration (FDA) has found that household use of antibacterial soap provides no health benefits over plain soap and water. If a cosmetic contains triclosan, it will be included in the ingredient list on the product label. If an over - the - counter drug contains triclosan, it will be listed as an ingredient on the label, in the "Drug Facts" box. Some product manu- facturers have recently announced plans to phase -out the use of triclosan in their consumer products. For information on products that contain triclosan, visit www.ewg.org /skindeep /ingredient /706623 /TRICLOSAN. Figure 1. Triclosan- derived dioxin trends in Lake Pepin % change in triclosan- derived dioxins vs. non - triclosan derived dioxins in Lake Pepin sediment cores since the 1960s 350% 300% 250% 200% M 150% 100% 50% a 0% -50% -100 q A H v A a A U U U U A U A w x x O a, x x O g H t~ dioxin not derived triclosan- from triclosan derived dioxins Source: Buth et. a1. How to avoid triclosan Be on the lookout for triclosan on the ingredient lists of soaps, facial cleansers, toothpaste, cosmetics, deodorant, and other personal care products. .AWV ingredlw►t e� Jrddosan % .... . Us ® fo r hand washing te, itmings When looking for triclosan in plastics or fabrics, watch out for products that are marketed as containing Microban or Biofresh Some examples of products that contain triclosan: Neutrogena deep clean body scrub bar Lever 2000 special moisture response bar soap, anti - bacterial+ CVS antibacterial hand soap Dial liquid soap, antibacterial Ajax hand soap Softsoap antibacterial liquid Right Guard hand soap Cetaphil gentle antibacterial cleansing bar Clearasil daily face wash Clean & Clear oil -free foaming facial cleanser Dawn complete antibacterial dish liquid Ajax antibacterial dish liquid Colgate total toothpaste Right Guard sport deodorant Old Spice red zone, high endurance and classic deodorants Vaseline intensive care antibacterial hand lotion Source: Food and Water Watch and Beyond Pesticides" Ali PFOS A portion of the river is impaired with PFOS based on its presence in fish tissue. T This compound is part of a family of man-made chemicals used in nonstick cookware, stain - resistant fabric, food packaging and fire - fighting foam. V PFOS levels in fish contribute to a site - specific fish consumption advisory in part of the river. Description and impacts. PFOS (perHuo- rooctane sulfonate) is part of a family of synthetic com- pounds known as PFCs, and is used in nonstick cookware, stain- resistant fabric, food packaging, fire - fighting foam, insecticides, and manufacturing processes. PFCs are extremely stable, persist in the environment, and can be found in the blood of animals and humans worldwide. Health concerns. While the health impacts of human exposure to PFOS are not fully known, lab animal studies reveal that exposure to high concentrations can result in altered development, immune suppression, en- docrine disruption, decreased organ health, and increased sensitivity to other chemicals. 1 I While the Minnesota De- partment of Health (MDH) has determined that exposure to PFOS through swimming is not a concern, ' PFOS concentrations in fish tissue and drinking water could pose potential risks to human health if ingested. 117 Status. The river from the Ford Dam to the Hastings Dam is impaired with PFOS contamination in fish tis- sue. Fish in this reach of the river are more likely to contain PFOS levels that exceed state guidelines (Figure 1), Anglers should review MDH Site - Specific Eating Guide- lines (see Fish consumption, page 20) and Minnesota Department of Natural Resources catch -and release regula- tions (see Fish survey, page 22) in this reach of the river. Elevated levels of PFOS have also been found in bald eagle populations throughout the river (see Bald eagles, page 34). Sources. PFOS was originally manufactured in Minne- sota by 3M at its Cottage Grove facility. Production began around 1950 and was phased out in 2002. During that pe- riod, PFOS was released into the river via 3M's wastewater V The state, 3M, and others are actively engaged in restoring the fishery to health. treatment plant. In addition, production waste from this facility was disposed of onsite, as well as at three disposal sites in the east metro area (see map). The 3M- Oakdale and 3M Woodbury disposal sites have groundwater pump- ing systems that were installed in the 1970s and 1980s that ultimately discharge to the river. PFOS is common in numerous household and industri- al products, and can enter our environment in a variety of ways including landfills, wastewater treatment plants, stormwater runoff, and household activities. PFOS contam- Figure 1. PFOS in fish species between the Ford and Hastings Dams Green box indicates 25 -75% percentile range of sample values 0. 1000 0 n, 100 ro Ln O 10 Sources: Minnesota Depatment of Natural Resources, Minnesota Department of Health, and Minnesota Pollution Control Agency bluegill common freshwater white sunfish carp drum bass Distribution of PFOS in ground ater CLF.!U a Mu•;P!1:.AVOIJ 3M Oakdale PP Disposal Site Pigs Eye Dump 1 ♦ a ., / .0 00 ♦ 40 V ination has been identified in soil, surface waters, ground- water, and river sediment in multiple locations in the east metro area, as well as other sites throughout the state."' Where PFOS is present in groundwater adjacent to the river, it will discharge into the Mississippi River over time. PFOS and drinking water. The MDH is responsible for setting limits for contaminants in drink- ing water. PFOS is present in groundwater in some areas (see map), and the MDH has set a Health Risk Limit (HRL) for PFOS in drinking water of 0.3 parts per billion (ppb) . 112 Although some Oakdale city wells and a number of private water supply wells exceed the HRL, filtration systems paid for by 3M and installed by the city and Minnesota Pollution Control Agency (MPCA) ensure the drinking water in the affected communities meets the HRL. 113 MDH biomonitoring shows decreasing PFOS exceeds health limits (> 10ppb) ■ PFOS exceeds health limits (1 -10 ppb) ■ PFOS exceeds health limits (0.3 -0.99 ppb) ■ PFOS 75 -100% of health limits (0.23 -0.3 ppb) PFOS 50 -75% of health limits (0.15 -0.23 ppb) PFOS 25 -50% of health limits (.075 -.15 ppb) PFOS < 25% of health limits (0.015 -0.075 ppb) PFOS not detected, but sampling performed No sampling for PFOS performed (outside affected area) Source: Minnesota Department of Health, 2012 (PFOS data); Minnesota Department of Natural Resources (core geographic elements) Contractors for 3M use dredges to remove PFC- contaminated sediment from a small river cove in Cottage Grove. Excavation was completed in April 2012. concentrations of PFOS and other PFCs in the blood of residents following the installation of filter systems to city and private water supplies.''' For more information on PFOS and public health, visit the MDH website ( http : / /www.health.state.mn.us /divs/ eh /hazardous /topics /pfcsheAth.html) . Management solutions. 3M completed addi- tional clean-up at its disposal sites in early 2012. The for- mer Washington County Landfill has also been successful- ly cleaned up. Additional work remains on containing, pumping and treating PFC - contaminated groundwater, and monitoring treatment effectiveness over time."' The MPCA is currently reviewing additional data and collecting additional samples of PFOS in fish tissue in the river between the Ford and Hastings Dams. 1;r>A MI 0s1.::a;n Additionalcontann"nants OOR a�(�i)M(7s7m Additional contaminants of concern may negatively impact the health of the Mississippi River and its watershed. 0 Some compounds can disrupt human and animal hormone function and present potentially serious health risks. 0 PCBs and mercury are present in fish tissue in the Mississippi River. Background Additional contaminants of concern for this reach of the river include a number of chemicals and their byproducts that are highly persistent in our envi- ronment and may accumulate in fish, wildlife and humans over time. These pollutants pose unique risks, as many can have effects even at very low levels. Little is known about what happens when these contaminants of concern mix and interact in nature. Some of these chemicals may also act as endocrine disrupting compounds (EDCs). EDCs mimic or alter hormone systems and can interfere with re- productive, developmental, and other biological functions and can lead to reproductive mutations in aquatic organ- isms."' A recent U.S. Geological Survey (USES) study found 73% of smallmouth bass at a site in Lake Pepin showed signs of mutated sexual organs. 1 I Additional research is required to fully understand the extent of the presence and impacts of these contaminants in this reach of the river. PCBs PCBs (polychlorinated biphenyls) are a class of man -made industrial chemicals manufactured domestical- ly from 1929 until they were banned by the U.S. Envi- ronmental Protection Agency (EPA) in the late 1970s. PCBs do not easily break down in the environment, and have remained in water and sediments for years. PCBs are classified by the EPA as probable human carcinogens, 121 and can affect the human immune, reproductive, ner- vous, and endocrine systems. Although PCB levels in Minnesota waters are slowly decreasing, they are still found in fish throughout Min- nesota, including the Mississippi River. 121 While Minne- sotans can still eat fish from the river, they should follow V Additional research is needed to fully understand the impacts of these pollutants. Minnesota Department of Health Site - Specific Eating Guidelines (see Fish consumption, page 20). Pharmaceuticals In the U.S., about four billion prescriptions were dispensed in 201 L" Unused medi- cation in human waste, along with expired or unwant- ed prescription and over - the - counter medications, are often disposed of down the drain. Wastewater treatment systems are not specifically designed to remove pharma- ceuticals, many of which are discharged back into surface waters after treatment. 12s A nationwide USGS study done in 2000 found low levels of drugs such as antibiotics, hor- mones, contraceptives, and steroids in 80% of the rivers and streams tested. 126 Wastewater treatment systems are not specifically designed to remove pharmaceuticals. I s ::.., :;;, s w. iiM r =1 1 s. Pharmaceuticals can have impacts on fish and other aquatic wildlife, including feminization of male fish exposed to estrogen in human waste and birth control medications. Other drugs, such as anti - depressants and beta - blockers, reduce fertility or affect spawning in certain aquatic organisms. 127 Unwanted or expired medi- cations should never be flushed down the drain. For more information on household hazardous wastes and collec- tion programs, contact your county solid waste office or the Minnesota Pollution Control Agency. PAHs and coal tar sealants. PAHs (polycy- dic aromatic hydrocarbons) are a group of compounds that can cause tumors, organ abnormalities, and disrupt immune and reproductive system function in fish and aquatic life. Seven PAH compounds are classified as probable human carcinogens. 129 Coal tar sealants (coal by- products used to seal asphalt surfaces since the 1960s) are a major source of PAH pollution. PAH concentra- tions in coal tar sealants are about 1000 times higher than concentrations in asphalt -based sealant alternatives. ' Over time, the sealants wear down and are carried into the environment by wind and rain, allowing PAHs to contaminate rivers, lakes, wetlands, and stormwater ponds. While little is known about PAH contamination in Mississippi River sediment, projected clean up costs for stormwater ponds contaminated with PAH runoff could approach $1 to $5 billion in the Twin Cities metropolitan area alone. As of August 2012, 24 Minnesota communities have coal tar sealant restrictions of some kind, and the State has its own restrictions for state agencies. 132 For more informa- tion on coal tar sealants, contact the Minnesota Pollution Control Agency. Mercury. Mercury is a naturally occurring element that can damage the central nervous system of animals and people, especially children and fetuses. 133 About 70% of the mercury in the air is the result of emissions from coal combustion, mining, incineration of mercury-con- taining products and other human sources. 131 The vast majority of mercury in Minnesota's environment comes from out -of -state sources. 131 Over time mercury can build up in fish and pose risks for human consumption (see Fish consumption, page 20). Mercury can be found in Mississippi River fish, as well as most fish tested from Minnesota lakes. 116 While Minne- sotans can still eat fish from the river, they should follow Minnesota Department of Health Site - Specific Eating Guidelines. Minnesota established a statewide mercury clean -up goal in 2007. This goal calls for reducing emissions from exist- ing Minnesota sources to safe levels by 2025.137 Pesticides and herbicides. Pesticides and herbicides are used to control unwanted insects, plants, rodents, fungi, mold, or bacteria. They can be carried into the environment by wind and rain, 138 and can accu- mulate in both rural and urban waters. While there are many products in use, atrazine and acetochlor are two herbicides of particular concern. Atrazine, used in corn production, has possible links to prostate and other cancers in humans and to repro- ductive deformities in frogs. 139 It has been found in groundwater and surface waters across Minnesota."' Farm operators may not apply atrazine within 66 -feet of waterbodies. Acetochlor, used primarily in corn and soybean pro- duction, was introduced in 1994, and is classified as a "probable human carcinogen." 142 In Minnesota, the LeSueur River and Little Beauford Ditch (both in Blue Earth County) are classified as "impaired" due to high acetochlor levels in the water. 143 Farm operators are encouraged not to apply acetochlor within 66 -feet of waterbodies. In 2011, the Minnesota Department of Agriculture detected the presence of both acetochlor and atrazine at their river monitoring site (Grey Cloud Island, south of St. Paul); however both were present at levels well below the State's Health Risk Limit. 116 PBDEs. PBDEs (polybrominated diethyl ethers) are a family of compounds used as flame - retardants in many household products including electronics, furnishings, motor vehicles, and plastics. PBDEs have been found to accumulate in river sediment and fish tissue, 147 as well as human tissue and breast milk, 14' and are found in higher levels in children than adults. PBDEs are found in river sediments, though additional testing is needed to fully understand any possible effects on the river. 149 PBDEs have been found in the blood of all bald eagles sampled along the river. "O Some research indicates that exposure to very small doses of PBDEs at critical points in development can damage reproductive systems and cause deficits in motor skills, learning, memory and hearing, as well as changes in be- havior. Additional evidence suggests that these chem- icals may cause liver, thyroid, and neurodevelopmental toxicity.' 52 U.S. manufacture and import of some forms of PBDE were phased out in 2004. Another form of PBDE (DecaBDE) is banned in European electronics"' and is restricted in some U.S. states. Domestic manufactur- ers are now voluntarily phasing out production, though import of DecaBDE products continues."' The Mississippi River is a complex natural system, with many factors affecting its overall health and vitality. In this report, we've selected 13 indicators that can illustrate the state of the river. So, how is the Mississippi River? It's a river that has improved in both water quality and ecological health over time, but there are also some distressing trends and emerging concerns. • Positive trends in our bald eagles, mussels, and fish population indicators are signs of a restored river that is once again home to healthy and abundant wildlife. As pollution has been cleaned up and habitat restored over the past 40 years, bald eagle, mussel, and fish populations have rebounded. These are symbols of our shared ability to rejuvenate and restore our Mississippi River — and are an inspiration for future success. • Other indicators remain causes for concern. Excess sediment and phosphorus degrade aquatic habitat and recreation in the Mississippi River, including downstream in Lake Pepin. Some portions of the river are im- paired with excess bacteria, while site - specific fish consumption guidelines are in place throughout the river due to elevated levels of PFOS, mercury, and PCBs. While we remain optimistic that these issues can be solved, it is clear that much more work remains to prevent these indicators from becoming larger problems. Several indicators are cause for serious concern moving forward. River flows have multiplied to worrisome levels, destabilizing the watershed and flushing large amounts of pollution into the river. Nitrate concentra- tions are increasing at an alarming rate, with disasterous impacts on the Gulf of Mexico. Asian carp contin- ue to move upstream, with potentially devastating consequences to aquatic life and recreation throughout the state. And emerging contaminants, like triclosan, PAH compounds, and others present risks to the river that we do not yet fully understand. The solutions to these problems require new tools and decisive public action before they move beyond our reach. While the challenges facing the river are complex and daunting, it is clear that this is a resource worthy of resto- ration. Forty years after the passage of the Clean Water Act, 24 years after the river became a national park, and 19 years after concerned citizens formed Friends of the Mississippi River, we have made great strides in protecting and preserving this unique natural resource. We remain hopeful that with strong leadership and vocal support from river lovers across our state and nation, we can pass a cleaner, healthier and more vibrant Mississippi River on to future generations. To learn more about what you can do in your home, yard, and community to help protect the Mississippi River, consult the Stat of the River Report Stewardship Guide. You can also learn more about priority actions that federal, state, and local�eaders can The mighty Mississippi River 1. National Park Service. Mississippi River Facts. Available at http: //Nv v.nps.gov /miss/ rive&cts.htm 2. ibid 3. ibid 4. ibid The Mississippi River and Lake Pepin watershed 5. Minnesota Pollution Control Agency. 2012. South metro Mississippi River total suspp solids total maximum daily load available at: http://wtvsvpca.state.mn.us/index.phplview- document.html ?gid =15794. 6. Engstrom, D.E., J.E. A] mendinger and J.A. Wolin. 2009. Historical changes in sediment and phosphorus loading in the upper Mississippi River: Mass balance reconstructions from the sediments of Lake Pepin. J. Paleolininology 41: 563 -588. Mississippi National River and Recreation Area 7. Minnesota Pollution Control Agency. 2012. Minnesota River TMDL project for turbidity: Document wq- b3 -33. Available at http: / /%vw%v.pm.state.mn.us /indu.php /view- document. html ?gid =8093. Flow 8. Lenhart, C., H. Peterson, J Nieber. 2011. Increased streamflow in agricultural watersheds of the midwest: Implications for management. lVaterrhed Science Bulletin (April): 25 -31. 9. United States Environmental Protection Agency. 2003. Managing Urban Runoff. Pointer No. 7 EPA841 -F -96 -004. Available at http: / /water.epa.gov /pol% a telnps /outreach /point7.cfm. 10. Manoj, J., J.G. Arnold, P.W. Gassman, R. Go. 2004. Climate charge sensitivity assessment on Upper Mississippi River basin streamflows using SWAT. Available at http: / /vvtvw.card. iasLate.edu/publicatioiis/dbs/pdffiles/04Nvp353.pdf. 11. Minnesota Pollution Control Agency. 2012. Draft south metro Mississippi River total suspended solids total maximum daily' load. Publication wq- iw9 -12b. Available at http: // wsvNv.pca.state.mn.us/index.php/vieiv-document.html?gid=15794. Bacteria 12. Minnesota Pollution Control Agency. 2008. Bacteria: Sources, types, impact on water quality-a general overview. Publication wq- iw3 -20. Available at http: / /wtvvvpca.state.mn.us/ index. php /view- document.html ?gid =8543. 13. Combined Sanity/Sewer overflows: Sewers that collect runoff, domestic sewage, and industrial wastewater in the same pipe (combined sewers) can exceed the capacity during heavy rainfalls and discharge excess wastewater directly to nearby streams, rivers, or other water bodies. For more information, see http: / /cfpub.epa.gov /npdes /home.cfm ?program_id =5. 14. Minnesota Pollution Control Agency, Minnesota Department of Health, and EOR, Inc. 2009. Upper Mississippi River bacteria'I'MDL: Data analysis, source assessment, and monitoringg recommendations. Available at http://wsv%v..pcastate.mn.us/index.php/vinv- document.html ?gid =8200. 15. ibid. 16. ibid. 17. Metropolitan Council Environmental Services. 2005. 100+ years ofwater quality improvements in the Twin Cities. Available at http: /by vw.merrocouncd.org/environment/ AboutMCFS /do cat ments/ 100 - year- brochu re. pdf. 18. United States International Boundary Water Commission and Paso del Norte Watershed Council. 2010. Bacteria in the Rio Grande basin: what you need to know for recreation and health. Available at http: / /wwteibNvc.state. ov /CRP /documents /EcoliFactSheeL final.pdf. 19. NVayside Animal Hospital. 2012. NVater safety for dogs. July 9 press release. Available at http: // wtvty ..knowpickens.com/pressrelease .asp ?PressReleme =1148. 20. A monthly geometric mean tends to dampen the effect of very high or very low values. This is helpful when analyzing bacteria concentrations because levels may vary dramatically over a given period. Phosphorus 21. Minnesota Pollution Control Agency. 2004. Detailed assessment of phosphorus sources to Minnesota watersheds. Prepared by Barr Engineering. Available at http: / /proteus.pm.state. mn.us/hot/legislature/reports/phosphoms-reporr.html. 22. Minnesota Pollution Control Agency. 2007. Phosphorus: Sources, forms, impact on water quality - a general overview. Available at http: / /wsvw.pca.state.mn.us /index.php /view- document.html ?gid =8547. 23. Heiskary, S., R. W Bouchard Jr., and H. Markus. 2010. Draft- Minnesota nutrient criteria for rivers. Minnesota Pollution Control Agency, St. Paul, MN, USA. 24. Metropolitan Council Environmental Services. 2012. Data request: Median annual phosphorus concentrations (mg/L) at Lock & Dam #2 (Hastings) from 1976 -2005. 25. Lafrancois, B. M., S. Magdalene, D.K. Johnson, D. Engstrom, D. VanderMeulen. Water quality conditions and trends in the Mississippi National River and Recreation Area, 1976- 2005. In preparation. 26. Minnesota Pollution Control Agency. 2007. Phosphorus: Sources, forms, impact on water quality -A general overview. Available at http: / /vAvw.pca.state.mn.us /index.php /view- documenehtml ?gid =8547. 27. Litke, D.W 1999. Review of phosphorus control measures in the United States and their effects on water quality. . United States Geological Survey. Water- Resources Investigations Report 99 -4007. Available at pubs. uses. gov/ wri /Nvri994007 /pdf /tvri99- 4007.pdf. 28. Minnesota Department of Agriculture. Phosphors lawn fertilizer law. Available at http: // www.mcla.statc.inn.us/phoslaw. 29. Minnesota Pollution Control Agency. 2009. Presentation: The Lake Pepin T1v1DL - What's New? Available at: http: //N"v v.pm. state. mn .us /index.php/Nvaterhvater -types- and - programs/ minnesotas - impaired- waters- and - tmdls /tmdl- projects /lower -mi ssissippi- river - basin -tmdl- projects /project - lake- pepin- watershed- eutrophication- rrbidity-i mpai rments.html. Fish consumption 30. Minnesota Department of Health. 2012. Safe eating guidelines. Available at http: / /wtsnv. heaith.scate.mn.us/divs/eh/fish/cating/index.html. 31. ibid. 32. Minnesota Department of Health. 2012. Frequently asked questions. What are the health risks of eating contaminated fish? Available at http: //% s"v.healtli.state.mn.us /divs /eh /fish /faq. html #hmlthrisks. 33. Wiener, J. G. Sandheinrich, M. B. 2010. Contaminants in the Upper Mississippi River: Historic trends, responses to regulatory controls, and emerging concerns. Hydrobiologia (640): 49- 70.ibid. 34. ibid. 35. ibid. 36. ibid. 37. Monson, B. A., Trend Reversal of Mercury Concentrations in Piscivorous Fish from Minnesota Lakes: 1982 -2006. Environmental Science and Technology 2009, 43, (6), 1750- 1755. 38. Meyer, M. W, P.W. Rasmussen, C.J. Waters, B.M Fevold, and K.P. Know. 2011. Biphasic trends in mercury concentrations in blood of Wisconsin common loons during 1992 -2010. Ecotoxicology (2011): 1 -10. 39. NIN Pollution Control Agency. 2009. Implementation plan for Minnesotas statewide mercury Total Maximum Daily Load. Available at http:/ /W%vw.pm.state.ma.uslindex.php/ view -doc ument. html?gi d= 11481. 40. Minnesota Department ofHealth: http://N"v%v.liealth.state.mn.us/divs/eh/fisli/cating/tips. hurl. Fish survey 41. Stiras, J. 2012. Minnesota Department of Natural Resources. Personal communication. 42. Hart, E. 2009. ?fie neighborhood by the falls: A look back at life in Longfellow. Longfellow Community Council: Minneapolis. 125 pages. 43. Stiras, J. 2012. Minnesota Department of Natural Resources. Personal communication. 44. Hatch, J.T. and K. Schmidt. 2004. Fishes of Minnesota: Distribution in 8 major drainage basins. Available at http: / /Iiatcli.cehd.mmi.edu /researdi /fish /fishes /distribution_table.hnnl. Asian carp 45. United States Geological Survey -Upper Midwest Environmental Sciences Center. Asian carp. Available at http: / /mvw.umesc.usgs.gov/ invasive _species /asian carp.html. 46. Koel, T.M., K.S. Irons, and E. Ratcliff. 2000. Asian carp invasion of due Upper Mississippi River system. U.S. Geological Survey PSR 2000 -05. Available at http://Nvv%v.umesc.usgs.gov/ reports_ publications /psrs /psr_2000_05.htm I. 47, Anfinson, J. and T. Schlagenhaft. 2012. The threat of Asian carp: History of issue, impacts on recreation and habitat, management strategies. Presentation to Mississippi Makeover. 48. Garvey, J.E., G.G. Sass, J. Trushenski, D. Glover, EM. Charlebois, J. I"engood, B. Roth, G. Whidedge, B.C. Small, S.J. Tripp, and S. Secchi. 2012. Fishing down the bighead and silver carps: Reducing the risk of invasion to the Great Ickes. Research summary available online at http: / /asimmrp.m /documents /EXECCARP2011.pdf. 49. Minnesota Department of Natural Resources. 2012. Bighead caught in St. Croix underscores urgency around Asian carp. News release. Available at http: / /nms.dncstate. mn.us /2012 /04/24 /bighead- caught- in- st-croix- underscores - urgency- around -mian- carp /. 50. 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Publication wq- iw9 -126. Available at: http: //vvwwpca, state.mn.us/index.php/vieNv-document.htrnl?gid=15794. 56. ibid. 57. Musser, K., S. Kudelka, R. Moore. 2009. Minnesota River basin trends. Available at http: // mrbdc.=s u.edu /sites /mrbdc.mn su.edu /files /public /mnbasin /trends /pdfs /trends_full.pdf 58. Minnesota Pollution Control Agency. Undated. Life support for the South Metro Mississippi. Available at: http: / /tvww.pca.state.mn.us/ index .php /view- document.html ?gid= 15805. 59. Lenhart, C., H. Peterson, J. Nieber. 2011. Increased streamflow in agricultural watersheds of the midwest: Implications for management. Rvatersbed Science Bulletin (April): 25 -31. 60. Minnesota Pollution Control Agency. 2012. South metro Mississippi River total suspended solids TMDL (Public Notice Draft). Publication wq- iw9 -12b. Available at: http: //w v.pca. state.mn.us /index.php /view- document.html ?gid = 15794. 61. ibid. 62. ibid. 63. ibid. Nitrate 64. United. 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Available at http: //N s vpca. state.mn.m/ index. php / component /option,com_do cman /task,doc- view /gid,15398. 69. Sprague L.A., R.M. Hirsch, B.T. Aulenbaeh. 2011 Nitrate in the Mississippi River and its tributaries, 1980 to 2008: Are we making progress? Environ Sci Technol. 45(17): 7209 -7216. 70. David, M.B., L.E. Drinkwate , G.F. Mclsaac. 2010: Sources of nitrate yields in the Mississippi River basin. j. Environ. Qual. 39:1657 -1667. 71. Wall, D. Minnesota Pollution Control Agency. 2012. Personal communication. 72. Mississippi River Gulf of Mexico Watershed Nutrient Task Force. 2012. Hyppoxia in the news. Available at http: / /water. epa. gov /type/ watersheds / named /msbmin /gulfnews /cfn #2011zone. Mussels 73. Vaughn, C. C., K. B. Gido, and D. E. Spooner. 2004. Ecosystem processes performed by mtionid mussels in stream mesocosms: species roles and effects of abundance. Hydrobiologia 527: 35-47. 74. Minnesota Department of Natural Resources. 2012. Mussels of Minnesota. Available at http://Nvw%v.dnr.state.mn.us/mussels/index.htn-A. 75. Vaughn, C.C. and C. C. Hakenkamp. 2001. The functional role of burrowing bivalves in freshwater ecosystems. Freshwater Biology 46: 1431 -1446, 76. Minnesota Department of Natural Resources. 2012. Mussels of Minnesota. Available at http: //N wsv.dnr.state.mn.us /mussels /index.html. 77. Minnesota Department of Natural Resources. 2000. Mussel bound in Minnesota. Available at http: //N t"v.dnrstate.mn.us/ young - naturalists /mussels / index.html. 78. Davis, M. 2012. Minnesota Department of Natural Resources. Personal communication. 79. Harder, E ca. 1908. Unpublished memoirs. The history of the freshwater clam or mussel shell. Red Wing, MN. 80. Stoddard, A., J. Harcum, J. Simpson, J.R- Pagenkopf, and R.K. Bastian. 2002. Municipal wastewater treatment: Evaluating improvements in national water quality. Chapter 12: Upper Mississippi River Case Study. John Wiley & Sons, Inc. 672 pages. 81. Metropolitan Council Environmental Services. 2005. 100+ years of water quality improvements in the Tivin Cities. Available at http:// ws vw .metrocouncil.org/environment/ AboutMCES /documents/ 100 - year- brochure.pdf 82, Kelne, D., and M. Davis. 2008. Mussel (bivalvia: unionidae) survey of the Mississippi National River and Recreation Area Corridor, 2000 -2001. Natural resource technical report. NPS /GLKN /NRTR- 2008/137. National Park Service: Fort Collins, Colo. Available at: http: // science.nature.nps.gov /im/ unit s / GLKN / reports / miss %20mussel %20inventory pdf. Bald eagles 83. National Park Service- Mississippi National River and Recreation Area. Eagle nest survey. Available at http: / /%"v .nps.gov /miss /parknews /news- eaglesurveyhtm. 84. Route, B., E Rasmussen, R. Key, M. Meyer, and M. Martell. 2011. Spatial patterns of persistent contaminants in bald eagle nestlings at three national parks in the upper Midwest: 2006 -2009. Natural Resource Technical Report NPS /GLKN /NRTR - 2011/431. National Park Service, Fort Collins, Colorado. 85. ibid. 86. ibid. 87. ibid. 88. Monson, B. A. 2009. Trend reversal of mercury concentrations in piscivorous fish from Minnesota lakes: 1982 -2006. Environmental Science and Technology. 43(6): 1750 -1755. 89. Meyer, M.W., P.W. Rasmussen, C.J. Watras, B.M. Fevold, K.E Kenow. 2011. Bi- phasic trends in mercury concentrations in blood of Wisconsin common loons during 1992 -2010. Ecotoxicology (2011): 1 -10. Triclosan 90. Buth J., E Steen, C Sueper, D. Blumentritt, E Vokelans, W. Arnold, K. McKneill. 2010. Photoproducts of triclosan and its chlorinated derivatives in sediment cores. Environ. Sri. Technol. (44): 4545 -4551. 91. Includes: 2,8- Dichlorodibenzo -p- dioxin (2,8- DCDD), 2,4- Dichlomphenol (2,4 -dCP), 2,4,6- trichlorophenol (2,4,6 -TCP), Chloroform, and Methyl Triclosan. 92. Martin, A. 2011. Antibacterial chemical raises safety issues. August 19. New York Times. Available at http://Nvwwnytimes.com/ 2011 /08/201 business /triclosan -an- antibacterial- chemical- intonsumer- products- raises - safety- issues.html ?pagewanted =all. 93. Minnesota Department of Health. 2010. Triclosan exposure and toxicity summary. Available at http: / /wwsv hcalth.state.mn.us /divs /eh/ risk /guidance /dwec /sumtriclosan.pdf. 94. J.H. Savage, E.C. Matsui, R.A. Wood, C.A. Keet. 2012. Urinary levels of triclosan and parabens are associated with aeroallergen and food sensitization. Die journal ofAllergy and Clinicallmmtmology 130 (2): 453- 460.e7. Available at http: / /wsvw.jacionline.org/arricle/ 50091- 6749(12)00779 -8 /abstract. 95. Martin, A. 2011. Antibacterial chemical raises safety issues. August 19. New York Times. Available at http: //www.ny[im es.com/ 2011 /08/20 /business/ triclosan -an- antibacterial- chemical- i n- consumer - products - raises - safety- issues.hunPliagewanted =all. 96. Centers for Disease Control and Prevention. 2009. National report on human exposure to environmental chemicals. 97. Minnesota Department of Health. 2010. Triclosan exposure and toxicity summary. Available at http: / /www.health.state. mn.m /divs /eh/ risk /guidance /dwec /sumtriclosan.pdf 98. Centers for Disease Control and Prevention. 2009. National report on human exposure to environmental chemicals. 99. Buth J., E Steen, C Sueper, D. Blumentritt, E Vokelans, XV. Arnold, K. McKneill. 2010. Photoproducts of triclosan and its chlorinated derivatives in sediment cores. Environ. Sci. Technol. (44): 4545 -4551. 100. ibid. 101. Minnesota Department of Health. 2010. Triclosan exposure and toxicity summary. Available at http: //xvww.health. state. mn.us /divs /eh/ risk /guidance /dwec /sumtriclos -.pdf. 102. ibid. 103. 'Thomas, K. 2012. Johnson & Johnson announces new safety plan. August 16. RocbesterPost Bulletin. Available at http: / /postbufetin. com /news /stories /display.php ?id = 1505396. PFOS 104. Minnesota Department of Health. 2010. Overview of perfluorochemicals and health. Available at http: //% w v.health. state. mn. us /divs /eh/ hazardous /topics/pfcs /healthlinks.html. 105. Minnesota Pollution Control Agency Leadership Update. 2011. 3M consent decree accomplishments. 106. Minnesota Department of Health. 2011. Overview ofperfluorochemicals and health. Available at http: /hvvv%v.health. state. mn. us / divs /eh /hazardous /topics /pfcshealth.ht nl. 107. Minnesota Pollution Control Agency. 2007 Perfluorochemirais past, present and futuue actions. Available atw tvw.pca.state.mn.us /index.php /view- document.html ?gid =2883. 108. Metropolitan Council Environmental Services. 2011. Facts about PFOS. Available at www. metrocouncil.org/news /201 I /PFOS.pdf. 109. Minnesota Pollution Control Agency. 2007. Perfluorochemicals past, ppresent and future actions. Available at tv v.pca. state. mn. us /index.php /view- document.html ?gid =2883. 110. Yingling, Virginia. 2012Minnesota Department of Health. Personal communication. 111. Minnesota Department of Health. 2011. Overview of perfluorocltenticals and health. Available at http: //wsvw.health.state.mn.us /divs /eh/ hazardous /topics /pfcshealth.ht -1. 112. Minnesota Department of Health. 2008. Health risk limits for perfluorochemicals. Report to the Minnesota legislature. Available at http: / /Nvww.hmlth. state .mn.us /divs /eh /hazardous /topics/ pfcs /final reporto 11508.pdf 113, Minnesota Department of Health. 2011. Health guidelines for perfluorodtemicals - PFCs in drinking water. Available at http://wsvw.health.state.mn.us/divs/eh/hazardous/topics /pfcs/ drinkingwater.html. 114. Minnesota Department of Health. 2012. East metro PFC biomonitoring follow -up project. Available at http:// wsvw.health.state.mn.m/tracking/ biomonitoring /projects /eastmcuopfc.html. 115. Minnesota Pollution Control Agency. 2011. Leadership update: 3M consent decree accomplishments. 116. Yingling, Virginia. 2012. Minnesota Department of Health. Personal communication. 117. Minnesota Pollution Control Agency. 2010. Mississippi River pool intensive study of perfluorochemicals in fish and water, 2009. Available at wsvw.pca.state.mn.us /index.php /view- document.html ?gid= 15527. Additional contaminants of concern 118. United States Environmental Protection Agency. What are endocrine disruptors? Available at http:/ /wtvw.epa.govloscpmont /oscpendo /pubs /edspoverview /whatarc.bttn. 119. Hiuck, J.E., V.S. Blazer, C.J. Schmitt, D.M. Papoulias and D.E. Tillitt. 2009. Widespread occurrence of intersex in black basses (Micropterus spp.) from U.S. rivers, 1995 -2004. Aquatic Toxicology 95(1): 60 -70. 120. United States Environmental Protection Agency. 1979. EPA bans PCB manufacture; phases out uses. April 19. Press Release. Available at http: //N w .epa.gov /history/topics /pcbs /Ol.ht". 121. Minnesota Pollution Control Agency. Glossary: PCBs. Available at http: / /ww%vpca.state.mn.ml index.php/glossary/glossar) 122. United States Environmental Protection Agency. Polychlorinated Biphenyls (PCB): Basic information. Available at http : / /wwwepa.gov /osw /hazard/tsd /pcbs /pubs /about.htm. 123. Minnesota Department of Health. 2012. Fish consumption: Frequently asked questions. Available at htip://%vwv.heatch.SEace.mn.us/divs/cli/fish/faq.huni. 124. IMS Institute for Health Care Informatics. 2011. The use of medicines in the United States: Review of 2011. Available at http: //Nvw%v imshealth. com /imshealth /Global/Content /IMS9o20 Institute /Doc uments /I HII- UseOlMed- report%ZO.pdf. 125. Metropolitan Council Environmental Services. 2010. 2009 River and stream water quality assessment report. Available at http:// www. metrocouncil .orglenvironment/Nvater/reports/ WaterReporti0.pdf 126. New York Department of Environmental Conservation. 2012. Dmgs in New York's waters: How drugs get into our waters and why DEC is concerned. Available at http: / /wsvw dec. 127. try, ggov /chemical /45083.html. go"/chemical/45083.html. Mahler, B., EC. Van Metre, J.L. Crane, A.W. Watts, M Scoggins, and E.S. Williams. 2012. Coal- tar -based pavement sealcoar and PAHs: Implications for the environment, human health, and stormwater management. Environmental Science and Technology 46(6): 3039 -3045. 129. ibid. 130. Minnesota Pollution Control Agency. 2009. Coal tar -based sealcoat: Environmental concerns. Publication wq- sam4 -12. Available at http: / /Nv%vsepca.st ate. mn.us /index.php /view - document. html ?gid= 11857. 131. Berger, D. 2011. Minnesota Pollution Control Agency cost estimates for Minnesota stormwater collection systems. 132. Coal Tar Free America. Coal tar sealant bans. Available at http : / /coaltarfreeamerica.blogspot. com /p /bans.html. 133. United States Environmental Protection Agency. Mercury. Health effects. Available at http: // www.epa.gov /hg /effeets.htm. 134. Minnesota Department of Health. 2012. Fish consumption: Frequently asked questions. Available at http: / /ivww.health. state . mn.us /divs /eh /fish /faq.html. 135. Minnesota Pollution Control Agency. 2012. About environmental mercury. Available at http: // www.pca.state.mn.us /index.php /topics/ mercury/ about - environmental- mercury.html. 136. Minnesota Department of Health. 2012. Fish consumption: Site - specific meal advice for tested lakes and rivers. Available at http: /hvwt¢health.state.mn.us /divs /eh /fish /eating /sitespecific. broil. 137. Minnesota Pollution Control Agency. 2009. Implementation plan for Minnesotas statewide mercury Total Maximum Daily Load. Available at http://Nvww.pm.state.mn.uslindex.php/view- document.html ?gid= 11481. 138. Capel, ED., M. Lin, P.J. Wotzka. 1998. Wet atmospheric deposition of pesticides in Minnesota, 1989 -94. U.S. Geological Survey Water Resources Investigations Report 97 -4026. Available at http: / /Iibraryusgs.gov. 139. Minnesota Department of Agriculture. 2005. Atrazine summary information. Available at http: / /wtvtv.mda. state. mn. us /GlobaVMDADou /chemfertlothers /summary aspx. 140. ibid. 141. Minnesota Department of Agriculture. 2010. Water quality and agricultural pesticide use - 2010 season. Available at http: //Nvww.mda.state.mn.us / -/ media /Files /chemicals /pesticides/ pmu2010mailing.ashx. 142. United States Environmental Protection Agency. 2007. Acetochlor. Document EPA -HQ OPP- 2007 -0725 -0002. Available at http: / /wt v.regulations.gov/#!documentDetail;D-EPA- HQ-OPP-2007-0725-0002. 143. Minnesota Department of Agriculture. 2012. Acetochlor information. Available at http: / /tvwsv. mda.state.mn.us/chemicals/pesticides/acetochlorl.aspx#current. 144. Minnesota Department of Agriculture. 2010. Water quality and agricultural pesticide use: 2010 season. Available at http: //w v..mda.state.mn.m / -/ media /Files /chemicals /pesticides/ pmu2010mailing.ashx. 145. Minnesota Department of Agriculture. 2012. 2011 Water quality monitoring report. Available at http: / /wwtv.mda. state. mn. us /chemicals/ pesticides /- /media/Files /chemicals/ wqm /201 I wpm rpt- app5.ashx. 146. Minnesota Department of Health. 2011. Human health -based water guidance table. Available at http: / /wtvty health. state. mn. us / divs /eh /risk/guidance /gw /table.html. 147. Minnesota Pollution Control Agency. 2007. Annual Pollution Report to the Legislature. 148. Minnesota Pollution Control Agency. 2012. Annual Pollution Report to the Legislature. Available at http: / /w%v%v.pca.state.mn.ml index. php /view- document.htral ?gid = 17613. W. Wiener, J. and M Sandheinrich. 2010. Contaminants in the Upper Mississippi River: Historic trends, responses to regulatory controls, and emerging concerns. Hydrobiologia 640: 49 -70. 150. Route, B., P. Rasmussen, R Key, M. Meyer, and M. Martell. 2011. Spatial patterns of persistent contaminants in bald eagle nestlings at three national parks in the upper Midwest: 2006 -2009. Natural Resource Technical Report NPS /GLKN /NRTR- 2011/431. National Park Service, Fort Collins, Colorado. 151. Lunder, S. and A. Jacob 2008: Fire retardants in toddlers and their mothers: Levels three times higher in toddlers than moms. Environmental Working Group. Available at http: / /w- mveNvg. org /reports /pbdesintoddlers. 152. United States Environmental Protection Agency. Polybrominated diphenylethers (PBDEs): Significant New Use Rules (SNUR). Available at http: / /mvw.epa.gov /oppt /existingchemicals/ pubs /ganda.html. 153. Umwelr Bundes Ante 2008. Ban on DecaBDE flame retardant in electronic and electrical equipment in effect on 1 July 2008. Press release. Available at http: //N s vumweltbundesamr. de/uba-info-prase-e/2008/peOS-05O.htm. 154. Environmental Working Group. 2012. Fire retardants in toddlers and their mothers: Government and industry actions to phase out PBDEs. Available at http: / /W%"v.ewg.org/ reports / pbdesintoddlers/Governmentand%20lndustrytoPhaseOutPBDEs. 155. Wilson, A. 2010. Industry agrees to phase out DecaBDE flame retardant. Environmental Building News 19(2). Available at http: / /w%vwbuildinggreen .com /auth /article.cfin /2010/2/l/ Industry- Agrees -to- Phase - Out - DecaBDE - Flame- Retardant /. Additional notes & credits • Cover photo: Friends of the Mississippi River • Background theme for Swimming & Recreation section, pages 13 through 17: courtesy Donald Lee Pardue under CC BY 2.0 license. • Background theme for Fish & Fishing section, pages 19 through 26: courtesy New Brunswick Tourism under CC BY 2,0 license. • Background theme for Ecological Health, pages 27 through 36, courtesy Joost A. Baker under CC BY 2.0 license. • Background theme for Other contaminants of concern section, pages 37 through 44 courtesy Metropolitan Design Center Image Bank. Copyright ©Regents of the University of Minnesota. All rights reserved. Used with permission. • Microban is a registered trademark of Microban Internation, Ltd. • Biofresh is a registered trademark of F- Matic, Inc. Use of any photo in this document does not imply agreement of the artist with the content of this report. �. MCI "any'- -, _ - • Friends of the Mississippi River Mississippi National River and Recreation Area 360 North Robert Street, Suite 400 111 Kellogg Boulevard East, Suite 105 Saint Paul, MN 55101 Saint Paul, MN 55101 www.nps.gov /miss (651) 222 -2193 (651) 290 -4160 '