Toxins and Harmful Algal Blooms Science Team Active
The Team Studies the Factors that Contribute to Algal Toxin Production, Release, and Outbreaks
The Team Identifies Algal Toxins in Surface Waters
Cyanobacterial Bloom on Lake Okeechobee, Florida
The Team Identifies Cyanobacteria Associated with Toxin Production
Gleotrichia shown under a microscope
The Team Advances Method, Sensor, and Model Development
to provide decision support and advanced warning
The Team Improves the Understanding of Algal Toxin Uptake
and if uptake results in adverse effects on wildlife
The Team Develops Advanced Analytical Capabilities
The team develops advanced methods to study factors driving algal toxin production, how and where wildlife or humans are exposed to toxins, and ecotoxicology. That information is used to develop decision tools to understand if toxin exposure leads to adverse health effects in order to protect human and wildlife health.
Algal blooms frequently occur in our Nation's water resources and can cause economic, ecologic, and human health concerns. Algal blooms often contain cyanobacteria and other microorganisms, which can produce natural toxins. Yet, the actual health threats posed to the public, pets, livestock, and wildlife by these toxins in water resources used for recreation and drinking water remain poorly understood. Consequently, in order to be protective from potential health risks, rapid decisions are often made by land managers, public utilities and others to limit access to water resources for recreation or drinking water. These decisions are often based largely on a perception of potential risk.
The U.S. Geological Survey’s (USGS) Toxins and Harmful Algal Blooms Research Team works with multiple stakeholders to quantify toxin exposure and effects, identify hazards and vulnerabilities, develop tools to quantify and forecast toxin occurrence and exposure, and estimate socioeconomic impacts. Knowledge gained is used to identify actual versus perceived health risks posed by natural toxins. The team’s approach for understanding health impacts of algal toxins on humans and wildlife is a sequential process where each step informs the next in the laboratory and in the field. This approach involves teams of USGS scientists working at field sites across the United States, and in collaboration with other scientists to address human and wildlife health concerns.
Current Science Activities
- Toxin Exposure and Effects
- Determining the effects of cyanotoxins in fish and birds, including, cyanotoxin induced endocrine disruption, sublethal effects, and immunomodulation effects
- Determining bioaccessibility of cyanotoxins from ambient waters, finished drinking water, and raw and cooked fish in simulated mammalian digestive systems
- Evaluating the potential exposure risk of cyanotoxins in tap waters in the United States
- Dose-dependent animal toxicity studies for cyanotoxins and in relation to health advisory thresholds
- Biomarkers and cellular response to acute and chronic cyanotoxin exposure and potential proactive response measures
- Cyanotoxin and algal blooms related health impacts on reserved Federal lands and U.S. Trust species
- Potential for cyanotoxin aerosolization and human health effects (collaboration with CDC)
- Causes, Control, and Fate of Toxin Production
- Evaluation of commercial personal drinking water purifiers for toxin removal
- Understanding cyanotoxin production and control dynamics
- The response of harmful algae to atmospheric stimuli and implication for ecosystem and human health
- Advancing Methods and Sensors to Support Toxin Studies
- Validation of a method for simultaneously measuring multiple classes of cyanotoxins and algal toxins in surface waters across the freshwater to marine continuum
- Cyanobacteria Assessment Network (CyAN): Detection of cyanobacterial blooms and potential toxin production in lakes and reservoirs
- Polyphasic identification of toxin producing cyanobacteria
- Assessment of physical and chemical properties of cyanotoxins
- Decision Support
- Identification and quantitation of cyanotoxin socioeconomic effects
Below are other science teams and laboratories associated with this project.
The following are the data releases from this science team’s research activities.
Related publications below.
Satellite remote sensing to assess cyanobacterial bloom frequency across the United States at multiple spatial scales
Pilot-scale expanded assessment of inorganic and organic tapwater exposures and predicted effects in Puerto Rico, USA
The role of behavioral ecotoxicology in environmental protection
Public and private tapwater: Comparative analysis of contaminant exposure and potential risk, Cape Cod, Massachusetts, USA
Cyanotoxin mixture models: Relating environmental variables and toxin co-occurrence to human exposure risk
Toxic cyanobacterial blooms, often containing multiple toxins, are a serious public health issue. However, there are no known models that predict a cyanotoxin mixture (anatoxin-a, microcystin, saxitoxin). This paper presents two cyanotoxin mixture models (MIX) and compares them to two microcystin (MC) models from data collected in 2016–2017 from three recurring cyanobacterial bloom locations in Ka
The tide turns: Episodic and localized cross-contamination of a California coastline with cyanotoxins
Evaluation of a satellite-based cyanobacteria bloom detection algorithm using field-measured microcystin data
Neither microcystin, nor nodularin, nor cylindrospermopsin directly interact with human toll-like receptors
Multiple co-occurring and persistently detected cyanotoxins and associated cyanobacteria in adjacent California lakes
Exploring the potential value of satellite remote sensing to monitor chlorophyll-a for U.S. lakes and reservoirs
Rapid-assessment test strips: Effectiveness forcyanotoxin monitoring in a northern temperate lake
Ecological forecasting—21st century science for 21st century management
Natural resource managers are coping with rapid changes in both environmental conditions and ecosystems. Enabled by recent advances in data collection and assimilation, short-term ecological forecasting may be a powerful tool to help resource managers anticipate impending near-term changes in ecosystem conditions or dynamics. Managers may use the information in forecasts to minimize the adverse ef
Below are news stories associated with this project.
- Overview
The team develops advanced methods to study factors driving algal toxin production, how and where wildlife or humans are exposed to toxins, and ecotoxicology. That information is used to develop decision tools to understand if toxin exposure leads to adverse health effects in order to protect human and wildlife health.
Algal blooms frequently occur in our Nation's water resources and can cause economic, ecologic, and human health concerns. Algal blooms often contain cyanobacteria and other microorganisms, which can produce natural toxins. Yet, the actual health threats posed to the public, pets, livestock, and wildlife by these toxins in water resources used for recreation and drinking water remain poorly understood. Consequently, in order to be protective from potential health risks, rapid decisions are often made by land managers, public utilities and others to limit access to water resources for recreation or drinking water. These decisions are often based largely on a perception of potential risk.
The U.S. Geological Survey’s (USGS) Toxins and Harmful Algal Blooms Research Team works with multiple stakeholders to quantify toxin exposure and effects, identify hazards and vulnerabilities, develop tools to quantify and forecast toxin occurrence and exposure, and estimate socioeconomic impacts. Knowledge gained is used to identify actual versus perceived health risks posed by natural toxins. The team’s approach for understanding health impacts of algal toxins on humans and wildlife is a sequential process where each step informs the next in the laboratory and in the field. This approach involves teams of USGS scientists working at field sites across the United States, and in collaboration with other scientists to address human and wildlife health concerns.
Current Science Activities
- Toxin Exposure and Effects
- Determining the effects of cyanotoxins in fish and birds, including, cyanotoxin induced endocrine disruption, sublethal effects, and immunomodulation effects
- Determining bioaccessibility of cyanotoxins from ambient waters, finished drinking water, and raw and cooked fish in simulated mammalian digestive systems
- Evaluating the potential exposure risk of cyanotoxins in tap waters in the United States
- Dose-dependent animal toxicity studies for cyanotoxins and in relation to health advisory thresholds
- Biomarkers and cellular response to acute and chronic cyanotoxin exposure and potential proactive response measures
- Cyanotoxin and algal blooms related health impacts on reserved Federal lands and U.S. Trust species
- Potential for cyanotoxin aerosolization and human health effects (collaboration with CDC)
- Causes, Control, and Fate of Toxin Production
- Evaluation of commercial personal drinking water purifiers for toxin removal
- Understanding cyanotoxin production and control dynamics
- The response of harmful algae to atmospheric stimuli and implication for ecosystem and human health
- Advancing Methods and Sensors to Support Toxin Studies
- Validation of a method for simultaneously measuring multiple classes of cyanotoxins and algal toxins in surface waters across the freshwater to marine continuum
- Cyanobacteria Assessment Network (CyAN): Detection of cyanobacterial blooms and potential toxin production in lakes and reservoirs
- Polyphasic identification of toxin producing cyanobacteria
- Assessment of physical and chemical properties of cyanotoxins
- Decision Support
- Identification and quantitation of cyanotoxin socioeconomic effects
- Toxin Exposure and Effects
- Science
Below are other science teams and laboratories associated with this project.
- Data
The following are the data releases from this science team’s research activities.
- Publications
Related publications below.
Filter Total Items: 69Satellite remote sensing to assess cyanobacterial bloom frequency across the United States at multiple spatial scales
Cyanobacterial blooms can have negative effects on human health and local ecosystems. Field monitoring of cyanobacterial blooms can be costly, but satellite remote sensing has shown utility for more efficient spatial and temporal monitoring across the United States. Here, satellite imagery was used to assess the annual frequency of surface cyanobacterial blooms, defined for each satellite pixel asAuthorsMegan M. Coffer, Blake Schaeffer, Wilson B. Salls, Erin Urquhart, Keith Loftin, Richard P. Stumpf, P. Jeremy Werdell, John A. DarlingPilot-scale expanded assessment of inorganic and organic tapwater exposures and predicted effects in Puerto Rico, USA
A pilot-scale expanded target assessment of mixtures of inorganic and organic contaminants in point-of-consumption drinking water (tapwater, TW) was conducted in Puerto Rico (PR) to continue to inform TW exposures and corresponding estimations of cumulative human-health risks across the US. In August 2018, a spatial synoptic pilot assessment of than 524 organic, 37 inorganic, and select microbioloAuthorsPaul M. Bradley, Ingrid Y. Padilla, Kristin M. Romanok, Kelly Smalling, Michael J. Focazio, Sara E. Breitmeyer, Mary C. Cardon, Justin M. Conley, Nicola Evans, Carrie E Givens, James L. Gray, L. Earl Gray, Phillip C. Hartig, Michelle Hladik, Christopher P. Higgins, Luke R. Iwanowicz, Rachael F. Lane, Keith Loftin, R. Blaine McCleskey, Carrie A. McDonough, Elizabeth Medlock-Kakaley, Shannon M. Meppelink, Christopher P. Weis, Vickie S. WilsonThe role of behavioral ecotoxicology in environmental protection
For decades, we have known that chemicals affect human and wildlife behavior. Moreover, due to recent technological and computational advances, scientists are now increasingly aware that a wide variety of contaminants and other environmental stressors adversely affect organismal behavior and subsequent ecological outcomes in terrestrial and aquatic ecosystems. There is also a groundswell of concerAuthorsAlex T. Ford, Marlene Ågerstrand, Bryan W. Brooks, Joel Allen, Michael G. Bertram, Tomas Brodin, Zhichao Dang, Sabine Duquesne, René Sahm, Frauke Hoffmann, Henner Hollert, Stefanie Jacob, Nils Klüver, James M. Lazorchak, Mariana Ledesma, Steven D. Melvin, Silvia Mohr, Stephanie Padilla, Gregory G. Pyle, Stefan Scholz, Minna Saaristo, Els Smit, Jeffery Steevens, Sanne van den Berg, Werner Kloas, Bob B.M. Wong, Michael Ziegler, Gerd MaackPublic and private tapwater: Comparative analysis of contaminant exposure and potential risk, Cape Cod, Massachusetts, USA
BackgroundHumans are primary drivers of environmental contamination worldwide, including in drinking-water resources. In the United States (US), federal and state agencies regulate and monitor public-supply drinking water while private-supply monitoring is rare; the current lack of directly comparable information on contaminant-mixture exposures and risks between private- and public-supplies underAuthorsPaul M. Bradley, Denis R. LeBlanc, Kristin M. Romanok, Kelly Smalling, Michael J. Focazio, Mary C. Cardon, Jimmy Clark, Justin M. Conley, Nicola Evans, Carrie E Givens, James L. Gray, L. Earl Gray, Phillip C. Hartig, Christopher P. Higgins, Michelle Hladik, Luke R. Iwanowicz, Keith Loftin, R. Blaine McCleskey, Carrie A. McDonough, Elizabeth Medlock-Kakaley, Christopher P. Weis, Vickie S. WilsonByEcosystems Mission Area, Water Resources Mission Area, Contaminant Biology, Environmental Health Program, Toxic Substances Hydrology, California Water Science Center, Eastern Ecological Science Center, New England Water Science Center, New Jersey Water Science Center, South Atlantic Water Science Center (SAWSC), Upper Midwest Water Science Center, National Water Quality LaboratoryCyanotoxin mixture models: Relating environmental variables and toxin co-occurrence to human exposure risk
Toxic cyanobacterial blooms, often containing multiple toxins, are a serious public health issue. However, there are no known models that predict a cyanotoxin mixture (anatoxin-a, microcystin, saxitoxin). This paper presents two cyanotoxin mixture models (MIX) and compares them to two microcystin (MC) models from data collected in 2016–2017 from three recurring cyanobacterial bloom locations in Ka
AuthorsVictoria Christensen, Erin A. Stelzer, Barbara C. Scudder Eikenberry, Hayley T. Olds, Jaime F. LeDuc, Ryan P. Maki, Jack E. Norland, Eakalak KhanThe tide turns: Episodic and localized cross-contamination of a California coastline with cyanotoxins
The contamination of coastal ecosystems from a variety of toxins of marine algal origin is a common and well-documented situation along the coasts of the United States and globally. The occurrence of toxins originating from cyanobacteria along marine coastlines is much less studied, and little information exists on whether toxins from marine and freshwater sources co-occur regularly. The current sAuthorsAvery O. Tatters, Jayme Smith, Raphael M. Kudela, Kendra Hayashi, Meredith D. A. Howard, Ariel Donovan, Keith Loftin, David A. CaronEvaluation of a satellite-based cyanobacteria bloom detection algorithm using field-measured microcystin data
Widespread occurrence of cyanobacterial harmful algal blooms (CyanoHABs) and the associated health effects from potential cyanotoxin exposure has led to a need for systematic and frequent screening and monitoring of lakes that are used as recreational and drinking water sources. Remote sensing-based methods are often used for synoptic and frequent monitoring of CyanoHABs. In this study, one such aAuthorsSachidananda Mishra, Richard P. Stumpf, Blake Schaeffer, P. Jeremy Werdell, Keith Loftin, Andrew MeredithNeither microcystin, nor nodularin, nor cylindrospermopsin directly interact with human toll-like receptors
Various stressors including temperature, environmental chemicals, and toxins can have profound impacts on immunity to pathogens. Increased eutrophication near rivers and lakes coupled with climate change are predicted to lead to increased algal blooms. Currently, the effects of cyanobacterial toxins on disease resistance in mammals is a largely unexplored area of research. Recent studies have suggAuthorsJohn Hansen, Keith Loftin, Zachary Laughrey, Ondrei AdamovskyMultiple co-occurring and persistently detected cyanotoxins and associated cyanobacteria in adjacent California lakes
The global proliferation of toxin producing cyanobacterial blooms has been attributed to a wide variety of environmental factors with nutrient pollution, increased temperatures, and drought being three of the most significant. The current study is the first formal assessment of cyanotoxins in two impaired lakes, Canyon Lake and Lake Elsinore, in southern California that have a history of cyanobactAuthorsMeredith D. A. Howard, Raphael M. Kudela, Kendra Hayashi, Avery O. Tatters, David A. Caron, Susanna Theroux, Stuart Oehrle, Miranda Roethler, Ariel Donovan, Keith Loftin, Zachary LaughreyExploring the potential value of satellite remote sensing to monitor chlorophyll-a for U.S. lakes and reservoirs
Assessment of chlorophyll-a, an algal pigment, typically measured by field and laboratory in situ analyses, is used to estimate algal abundance and trophic status in lakes and reservoirs. In situ-based monitoring programs can be expensive, may not be spatially, and temporally comprehensive and results may not be available in the timeframe needed to make some management decisions, but can be more aAuthorsMichael Papenfus, Blake Schaeffer, Amina Pollard, Keith LoftinRapid-assessment test strips: Effectiveness forcyanotoxin monitoring in a northern temperate lake
Precise and rapid methods of determining toxin levels are needed in lakes used for recreation and drinking water to facilitate a quick risk assessment during cyanobacteria blooms. Therefore, we evaluated rapid-assessment test strips, a newer technology for estimating the toxicity of cyanobacterial blooms, in Kabetogama Lake, a popular recreational area of Voyageurs National Park in northern MinnesAuthorsJaime F. LeDuc, Victoria Christensen, Ryan P. MakiEcological forecasting—21st century science for 21st century management
Natural resource managers are coping with rapid changes in both environmental conditions and ecosystems. Enabled by recent advances in data collection and assimilation, short-term ecological forecasting may be a powerful tool to help resource managers anticipate impending near-term changes in ecosystem conditions or dynamics. Managers may use the information in forecasts to minimize the adverse ef
AuthorsJohn B. Bradford, Jake Weltzin, Molly L. McCormick, Jill Baron, Zack Bowen, Sky Bristol, Daren Carlisle, Theresa Crimmins, Paul C. Cross, Joe DeVivo, Mike Dietze, Mary Freeman, Jason Goldberg, Mevin Hooten, Leslie Hsu, Karen Jenni, Jennifer L. Keisman, Jonathan Kennen, Kathy Lee, David P. Lesmes, Keith Loftin, Brian W. Miller, Peter S. Murdoch, Jana Newman, Karen L. Prentice, Imtiaz Rangwala, Jordan Read, Jennifer Sieracki, Helen Sofaer, Steve Thur, Gordon Toevs, Francisco Werner, C. LeAnn White, Timothy White, Mark T. WiltermuthByEcosystems Mission Area, Water Resources Mission Area, Science Synthesis, Analysis and Research Program, Contaminant Biology, Environmental Health Program, Science Analytics and Synthesis (SAS) Program, Eastern Ecological Science Center, Fort Collins Science Center, Kansas Water Science Center, Maryland-Delaware-D.C. Water Science Center, National Wildlife Health Center, New Jersey Water Science Center, Pacific Island Ecosystems Research Center, Southwest Biological Science Center, Upper Midwest Environmental Sciences Center, Upper Midwest Water Science Center - News
Below are news stories associated with this project.