Co-Occurrence of Toxins and Taste-and-Odor Compounds in Cyanobacterial Blooms from the Midwestern United States USGS Kansas Water Science Center Algal.

Slides:

Advertisements

Similar presentations

TOXIN TALK Linda Merchant-Masonbrink, Ohio EPA –DSW

Advertisements

CYANOBACTERIA PIGMENTATIONS AND TOXINS Lect 5. Cyanobacteria Pigmentation  Pigments are chemical compounds which reflect only certain wavelengths of.

Jacob Butler. Algal communities and diversity Trends in succession Algal toxins and toxin production Allelopathy and allelochemicals Toxic algae found.

Predicting Taste and Odor Events: Is it Possible? Andrew R. Dzialowski Department of Zoology Oklahoma State University Donald Huggins Central Plains Center.

Lake Erie Algal Source Tracking (LEAST) homas B. Bridgeman, University of Toledo Thomas B. Bridgeman, University of Toledo Cyndee L. Gruden University.

Proposed Solution: Phytoplankton community in Lake Fulmor, CA Proposed Solution: Phytoplankton community in Lake Fulmor, CA Characterization of the phytoplankton.

Comprehensive Watershed Management for the Valley of the Sun David Walker University of Arizona Environmental Research Laboratory

Development of Remote Sensing-based Predictive Models for the Management of Taste and Odor Events in Kansas Reservoirs Dr. Mark Jakubauskas Kansas Biological.

UV Advanced Oxidation for Treatment of Taste and Odor and Algal Toxins

Ian Faurot Elise LaVanaway Scott Paradis Cody Settles.

Molecular Basis for Detection and Cytotoxicity Caused by

Preliminary Assessment of Cyanotoxin Occurrence in Lakes and Reservoirs in the United States Keith A. Loftin, Jennifer L. Graham, Michael T. Meyer, Andrew.

Management of toxic algae in Danish lakes 2. LakePromo Seminar - April 20– Bad Saarow - Germany Mette Bramm - County of North Jutland.

IOOS Application to Harmful Algal Blooms and Ecosystem Health Monitoring Josh Kohut Rutgers University, Institute of Marine & Coastal Science Bob Connell.

Harmful Algal Blooms and Microcystin in the Tidal Fresh James River, Joe Wood, Ph.D. - Chesapeake Bay Foundation *Research performed while at VCU.

Effects of Drought on Lake Almanor Water Quality

Examination of Cyanobacteria (Blue-Green Algae) Microcystin- LR Toxin in Callander Bay Presented by: Jamie Lavigne Supervised by: Dr. Reehan Mirza Department.

Pomme de Terre Lake Water Quality Summary Pomme de Terre Lake Water Quality Summary US Army Corps of Engineers Environmental Resources Section.

Cyanobacterial Blooms: Toxins, Tastes, and Odors

Ecology’s Freshwater Algae Program Lake Steilacoom.

Genetic and environmental factors influencing Microcystis bloom toxicity Juli Dyble NOAA Great Lakes Environmental Research Lab Ann Arbor, MI.

Harmful Algal Blooms The Ohio Response August 14, 2013.

Overview of USGS Groundwater Quality Assessment Activities and Related Data in Alabama 2011 Alabama Water Resources Conference September 9, 2011, Perdido.

Cyanobacteria in Wisconsin: Results of a Multi-Year Statewide Monitoring Program Elisabeth Harrahy, Ph.D., Richard C. Lathrop, Ph.D. Wisconsin Department.

Rapid and Accurate Analysis of Microcystins Using UPLC/MS/MS Yongtao (Bruce) Li, Ph.D. Joshua S. Whitaker Eurofins Eaton Analytical,

Department of the Environment Utilizing a Rapid Laboratory Technique to Assist Public Health Needs Associated with HABs.

Caloosahatchee Watershed Issues and Cyanobacteria Blooms Cyanobacteria Effects Caloosahatchee Cyanos Environmental Controls Temperature Flushing Nutrient.

Barriers Against Cyanotoxins in Drinking Water DVGW-Technology Center Water (TZW) Karlsruhe, Dresden branch TOXIC - EVK TOXIC.

Use of remote sensing in monitoring algal blooms in inland water bodies Anabel A. Lamaro Fortaleza 1-

Cyanobacteria ~ blue-green algae Ancient, ubiquitous Created world’s oxygen atmosphere Ancestors of green plants Produce ~ 50% of the oxygen in the.

Update on Lake Erie Nutrient and Algal Issues Gail Hesse Ohio Lake Erie Commission March 30, 2012.

Presentation compiled with unvalidated data.. Began in 1991 as a non-profit organization. Purpose: increasing Albertans’ awareness and understanding of.

Cyanobacterial Toxins in Florida’s Freshwater Center for Risk Analysis and Management USF College of Public Health.

Understanding and Monitoring Harmful Algal Blooms in Freshwaters Elena Litchman Michigan State University and Kellogg Biological Station.

USGS Kansas Water Science Center

Introduction Newell Creek Reservoir Data Organization and Algal Bloom Analysis December 11, 2012 City of Santa Cruz Water Department Presented by CSUMB.

Bloomin’ Toxins: What Public Officials Need to Know About Cyanotoxins US Council of Mayors Washington, DC April 30, 2015

SCREENING FOR ALGAL TOXINS IN VOLUNTEER-MONITORED LAKES

LAKE ERIE SOURCE TRACKING OF HARMFUL ALGAL BLOOMS Douglas D. Kane 1, Joseph D. Conroy 2,3,

Blue-green Algae -the basics & -Washington’s monitoring program

Variability of molecular assays Quality-control samples were collected and analyzed for cyanobacterial genes. Fourteen field concurrent replicates were.

CyAN (Cyanobacteria Assessment Network) Project Work Package 1: Field Data Collation/Interpretation Keith Loftin, USGS PI and WP1 team lead.

Research and Other Activities Related To Harmful Algal Blooms (HABs)

Minnesota Drinking Water Designated Use Assessment Workshop Tom Poleck EPA Region 5, Water Quality Branch May 20-21,

Freshwater Harmful Algal Blooms (HABs) in California and SWAMP's Statewide Strategy California’s Surface Water Ambient Monitoring Program (SWAMP) Freshwater.

KDHE’s 2016 HAB Stakeholder Meeting Rex Cox. Past Program Mainly for Recreational Purposes Samples were taken in public access lakes Lake discharge samples.

Harmful Algal Blooms satellites to genomes Timothy Davis Ecosystem Dynamics Place Photo Here.

THE LONG HOT BLUE-GREEN SUMMER Jay Wright ODEQ - SEL.

U.S. Environmental Projection Agency, Office of Research and Development Formation and Control of Cyanobacterial Toxins Thomas Speth, Nicholas Dugan, Joel.

Landscape exports of phosphorus and their effects on aquatic ecosystems Val H. Smith Department of Ecology and Evolutionary Biology University of Kansas.

Influences of environmental factors on the instant removal of Geosmin and 2-MIB by powdered activated carbon Viet Ly Quang a · Sung Kyu Maeng b · Ilhwan.

Eli Asarian Riverbend Sciences Jacob Kann Aquatic Ecosystem Sciences, LLC. Ann St. Amand PhycoTech, Inc. Standardization and Long-term Trends in a Multi-Decadal.

1 The Use of Pigment Pattern for Online Algae Monitoring Detlev Lohse bbe Moldaenke Kiel.

Introduction to Cyanobacteria: Types, Toxins, Bloom Formation Ken Wagner, Ph.D, CLM Water Resource Services, Inc.

Richard Lorenz City of Westerville & The Ohio State University, Stone Laboratory Grand Lake St. Marys. OH IAFP, 2016.

Cyanotoxins: An Emerging Global Issue Kelly A Magurany, M.Sc., DABT Principal Research Scientist- Toxicology August 1st, 2016.

US EPA Drinking Water Health Advisories for Cyanotoxins

Enzo Life Sciences 제품은 매주 목요일 수입발주 진행.

Update on Lake Erie Nutrient and Algal Issues

Lake Elsinore and Canyon Lake TMDL Water Quality Monitoring Update – Summary August 15, 2017.

Algae, Algal Toxins, and Treatment: A Cure for Bad HABits!

Binding affinity and Toxicity of Microcystin congeners

Preliminary Assessment of Cyanotoxin Occurrence in Lakes and Reservoirs in the United States Keith A. Loftin, Jennifer L. Graham, Michael T. Meyer, Andrew.

SoE Guidance – Biological reporting sheets

Lakes - Central GIG progress report July 2004

Water & Wastewater Equipment Manufacturers Association March 22, 2017

Proactive and Multi-Barrier Treatment Approach for Taste-and-Odor Compounds and UCMR4 Cyanotoxins: The Lafourche Parish Water District Experience Amlan.

Isabella Sanseverino, Lorna Fewtrell and

Lake Water Quality PLA Meeting August 17, 2019.

Harmful Algal Blooms “Red and Green…” What Does It All Mean?

Presentation transcript:

Co-Occurrence of Toxins and Taste-and-Odor Compounds in Cyanobacterial Blooms from the Midwestern United States USGS Kansas Water Science Center Algal Toxin Team Jennifer L. Graham, Keith A. Loftin, Michael T. Meyer, and Andrew C. Ziegler North American Lake Management Society November 12, 2008

Overview Historical Studies Study Design and Approach Results Summary Limnological Conditions Phytoplankton Community Structure Toxin Occurrence Microcystin Variants Toxin and Taste-and-Odor Co-Occurrence Concentrations Relations among compounds Summary

Microcystin is Common in the Midwest and May Reach Concentrations Great Enough to Cause Human Health Concerns Sampling Integrated photic zone samples during summer Lakes were sampled multiple times (n=3-26) Microcystin measured by ELISA Results 78% of lakes (n=359) had detectable concentrations of microcystin at least once Total concentrations ranged from <0.1 to 52 µg/L 1999-2006 Studies After Graham and others 2004 and 2006

2006 USGS Midwestern Cyanotoxin Reconnaissance – Objectives Document the occurrence and co-occurrence of cyanobacterial toxins and taste-and-odor compounds in the Midwest Identify the microcystin variants that commonly occur in the Midwest

2006 USGS Midwestern Cyanotoxin Reconnaissance – Design Targeted Sampling During August 2006 Lakes and reservoirs (n=23) with a history of late summer cyanobacterial blooms Blooms and surface accumulations USGS Cyanobacteria Sampling Guidelines: http://pubs.usgs.gov/sir/2008/5038/

2006 USGS Midwestern Cyanotoxin Reconnaissance– Analyses Toxins – Total by Freeze/Thaw Extraction ELISA: microcystins (ADDA), cylindrospermopsins, saxitoxins LC/MS/MS: 7 microcystins (LR, RR, YR, LW, LA, LF, LY), Nodularin, Anatoxin-a, Cylindrospermopsin, Deoxycylindrospermopsin, Lyngbyatoxin-a Taste-and-Odor Compounds SPME GC/MS: Geosmin, 2-methylisoborneol (MIB) Phytoplankton Community Composition Chlorophyll In Situ Water-Quality Measurements

A Wide Range of Lake Types and Conditions Were Included in the 2006 USGS Midwestern Cyanotoxin Reconnaissance Physical Characteristics Surface Area (Ha): 15-4,512 Volume (Ha m-1 ): 41-25,800 Mean Depth (m): 0.8-6.5 Maximum Depth (m): 1.5-15.0 Drainage Area (Ha): 89-289,000 Water Quality Secchi Depth (m): 0.1-0.9 Temperature (ºC): 25.5-30.7 Specific Conductance (µS/cm): 197-694 Dissolved Oxygen (mg/L): 4.1-16.0 Turbidity (FNU): 7-179 CHLOROPHYLL (µg/L): 28-187,000 Chlorophyll = 28 µg/L Chlorophyll = 187,000 µg/L

Cyanobacterial Communities Were Dominated by Anabaena, Aphanizomenon, and/or Microcystis Blooms with Taxa Present (%) Blooms with Taxa Dominant/ Co-Dominant (%) Potential Toxins and Taste-and-Odor Compounds Common Toxigenic Genera Anabaena 96 26 Anatoxin, Cylindrospermopsin, Geosmin, Microcystin, Saxitoxin Aphanizomenon 43 Aphanocapsa 30 4 Microcystin Cylindrospermopsis 22 Cylindrospermopsin, Saxitoxin Microcystis Pseudanabaena 48 Anatoxin, MIB, Microcystin Planktothrix 35 9 Anatoxin, Geosmin, Lyngbyatoxin, MIB, Microcystin, Saxitoxin

All Blooms Had Detectable Microcystins by Either ELISA or LC/MS/MS and 30% Had Detectable Anatoxin; Saxitoxins, Cylindrospermopsins, and Nodularin Were Less Common Microcystin was detected by both ELISA and LC/MS/MS in 96% of blooms. Cylindrospermopsin was detected by ELISA but not LC/MS/MS.

Microcystin-LR Was the Most Common Variant, But It Was Not Detected in ALL Blooms With Detectable Microcystin Microcystin-RR, -YR, and –LY also were relatively common. 91% of blooms had two or more microcystin variants present. 17% of blooms had all seven measured microcystin variants present.

48% of Blooms Had Co-occurring Toxins and 87% Had Co-occurring Toxins and Taste-and-Odor Compounds Microcystin and geosmin co-occurred in 83% of blooms. When present, anatoxin always co-occurred with geosmin. When present, cylindrospermopsin always co-occurred with saxitoxin. When present, MIB co-occurred with geosmin in all blooms but one. Nodularin was the only compound that was detected with no known cyanobacterial producer present.

The Majority of Blooms Had At Least Two Measured Compounds Present, and 91% Had At Least Two Different Classes of Compounds

Microcystin Concentrations Ranged From <0 Microcystin Concentrations Ranged From <0.01 µg/L to 19,000 µg/L, and 17% of Blooms (n=4) Had Concentrations Exceeding the World Health Organization Recreational Guideline of 20 µg/L All Data (n=23) MC (ELISA): <0.1-13,000 µg/L (median=2.8) Summed MC (LC/MS/MS): <0.01-19,000 µg/L (median=1.8) MC Congeners: MC-LA: <0.01-54 µg/L (median=0.02) MC-LF: <0.01-51 µg/L (median<0.01) MC-LR: <0.01-2,100 µg/L (median=1.1) MC-LW: <0.01-56 µg/L (median<0.01) MC-LY: <0.01-200 µg/L (median=0.02) MC-RR: <0.01-16,000 µg/L (median=0.6) MC-YR: <0.01-240 µg/L (median=0.03) Detections Only 20 µg/L LC/MS/MS Detection Limit

Concentrations of Other Classes of Compounds Were Orders of Magnitude Less Than Microcystin All Data (n=23) Anatoxin: <0.01-10 µg/L (median<0.01) Cylindrospermopsin: <0.04-0.1 µg/L (med<0.04) Geosmin: <0.005-0.9 µg/L (med=0.01) MIB: <0.005-0.06 µg/L (med<0.005) Nodularin: <0.04-0.2 µg/L (med<0.04) Saxitoxin: <0.02-0.2 µg/L (med<0.02) Detections Only LC/MS/MS Detection Limit

Although Toxins and Taste-and-Odor Compounds Frequently Co-Occurred Concentrations Were Not Linearly Related

Summary Microcystin was detected in all Midwestern blooms sampled and 17% had concentrations great enough to cause human health concerns. The most commonly occurring microcystin variant was microcystin-LR. Anatoxin was also relatively common (30% detection) in Midwestern blooms. Multiple toxin classes co-occurred in 48% (n=11) of blooms and toxins and taste-and-odor compounds co-occurred in 87% (n=20). All blooms with detectable taste-and-odor compounds also had detectable toxins, but toxins also occurred without taste-and-odor compounds. Although toxin and taste-and-odor compounds frequently co-occurred concentrations were not linearly related.

Additional Information Available on the Web: USGS Cyanobacteria Research - http://ks.water.usgs.gov/Kansas/studies/qw/cyanobacteria Cheney Reservoir Project - http://ks.water.usgs.gov/Kansas/studies/qw/cheney Organic Geochemistry Research Laboratory - http://ks.water.usgs.gov/researchlab.html Olathe Reservoir Project - http://ks.water.usgs.gov/Kansas/studies/qw/olathe Real-Time Water-Quality Monitoring - http://ks.water.usgs.gov/Kansas/rtqw/index.shtml