Harmful Algal Blooms

A Compendium Desk Reference

Edited by

Sandra E. Shumway

University of Connecticut Groton, CT, USA

JoAnn M. Burkholder

North Carolina State University Raleigh, NC, USA

Steve L. Morton

NOAA National Ocean Service Charleston, SC, USA

Wiley Logo

© 2018 John Wiley & Sons Ltd

All rights reserved. No part of this publication may be reproduced, stored in a retrieval system, or transmitted, in any form or by any means, electronic, mechanical, photocopying, recording or otherwise, except as permitted by law. Advice on how to obtain permission to reuse material from this title is available at http://www.wiley.com/go/permissions.

The right of Sandra E. Shumway, JoAnn M. Burkholder and Steve L. Morton to be identified as the author(s) of the editorial material in this work has been asserted in accordance with law.

Registered Office(s)

John Wiley & Sons, Inc., 111 River Street, Hoboken, NJ 07030, USA

John Wiley & Sons Ltd, The Atrium, Southern Gate, Chichester, West Sussex, PO19 8SQ, UK

Editorial Office

The Atrium, Southern Gate, Chichester, West Sussex, PO19 8SQ, UK

For details of our global editorial offices, customer services, and more information about Wiley products visit us at www.wiley.com.

Wiley also publishes its books in a variety of electronic formats and by print-on-demand. Some content that appears in standard print versions of this book may not be available in other formats.

Limit of Liability/Disclaimer of Warranty

While the publisher and authors have used their best efforts in preparing this work, they make no representations or warranties with respect to the accuracy or completeness of the contents of this work and specifically disclaim all warranties, including without limitation any implied warranties of merchantability or fitness for a particular purpose. No warranty may be created or extended by sales representatives, written sales materials or promotional statements for this work. The fact that an organization, website, or product is referred to in this work as a citation and/or potential source of further information does not mean that the publisher and authors endorse the information or services the organization, website, or product may provide or recommendations it may make. This work is sold with the understanding that the publisher is not engaged in rendering professional services. The advice and strategies contained herein may not be suitable for your situation. You should consult with a specialist where appropriate. Further, readers should be aware that websites listed in this work may have changed or disappeared between when this work was written and when it is read. Neither the publisher nor authors shall be liable for any loss of profit or any other commercial damages, including but not limited to special, incidental, consequential, or other damages.

Library of Congress Cataloging-in-Publication Data

Names: Shumway, Sandra E., editor. | Burkholder, JoAnn M. (JoAnn Marie), editor. | Morton, Steve L., editor.

Title: Harmful algal blooms : a compendium desk reference / edited by Sandra E. Shumway, JoAnn M. Burkholder, Steve L. Morton.

Description: Hoboken, NJ : John Wiley & Sons, 2018. | Includes index. | Identifiers: LCCN 2017040583 (print) | LCCN 2017047559 (ebook) | ISBN 9781118994696 (pdf) | ISBN 9781118994689 (epub) | ISBN 9781118994658 (cloth)

Subjects: LCSH: Toxic algae. | Algal blooms–Toxicology.

Classification: LCC QK568.T67 (ebook) | LCC QK568.T67 H372 2018 (print) | DDC 579.8–dc23

LC record available at https://lccn.loc.gov/2017040583

Cover Design: © Eric Heupel

Cover Image: © Eric Heupel

We dedicate this book to
Robert R.L. Guillard and Theodore J. Smayda,
our esteemed colleagues, friends, and mentors.

List of Contributors

Charles M. Adams

University of Florida

Food and Resource Economics Department

Gainesville, FL

United States

Christine J. Band-Schmidt

CICIMAR-IPN

Depto. de Plancton y Ecología Marina

La Paz, B.C.S.

México

Leila Basti

Tokyo University of Marine Science and Technology

Marine Environmental Physiology Laboratory

Department of Ocean Sciences

Tokyo

Japan

Larry E. Brand

University of Miami

Rosenstiel School of Marine and Atmospheric Science

Department of Marine Biology and Ecology

Miami, FL

United States

Margaret H. Broadwater

NOAA National Ocean Service

National Centers for Coastal Ocean Science

Stressor Detection and Impacts Division

Charleston, SC

United States

JoAnn M. Burkholder

North Carolina State University

Department of Applied Ecology

Center for Applied Aquatic Ecology

Raleigh, NC

United States

Allan D. Cembella

Alfred Wegener Institute

Helmholtz Zentrum für Polar- und Meeresforschung

Bremerhaven

Germany

Gregory J. Doucette

NOAA National Ocean Service

National Centers for Coastal Ocean Science

Marine Biotoxins Program

Charleston, SC

United States

Spencer E. Fire

Florida Institute of Technology

Biological Sciences

Melbourne, FL

United States

Kevin J. Flynn

Swansea University

College of Science

Swansea, Wales

United Kingdom

Corinne M. Gibble

University of California

Ocean Science Department

Santa Cruz, CA

United States

Patricia M. Glibert

University of Maryland

Center for Environmental Science

Horn Point Laboratory

Cambridge, MD

United States

Christopher J. Gobler

Stony Brook University

School of Marine and Atmospheric Sciences

Southampton, NY

United States

Lynn M. Grattan

University of Maryland School of Medicine

Department of Neurology

Baltimore, MD

United States

Gustaaf Hallegraeff

University of Tasmania

Institute for Marine and Antarctic Studies (IMAS)

Hobart, Tasmania

Australia

Hélène Hégaret

Institut Universitaire Européen de la Mer

Laboratoire des Sciences de l'Environnement Marin

UMR 6539 CNRS/UBO/IRD/IFREME

Plouzané

France

Philipp Hess

IFREMER

Laboratoire Phycotoxines

France

Porter Hoagland

Woods Hole Oceanographic Institution

Marine Policy Center

Woods Hole, MA

United States

Sailor Holobaugh

University of Maryland School of Medicine

Department of Neurology

Baltimore, MD

United States

Brian A. Hoover

University of California

Graduate Group in Ecology

Davis, CA

United States

Raphael Kudela

University of California, Santa Cruz

Ocean Sciences Department

Institute of Marine Sciences

Santa Cruz, CA

United States

Gregg W. Langlois

California Department of Public Health (retired)

Richmond, CA

United States

Brian E. Lapointe

Florida Atlantic University – Harbor Branch Oceanographic Institute

Marine Ecosystem Health Program

Ft. Pierce, FL

United States

Sherry L. Larkin

University of Florida

Food and Resource Economics Department

Gainesville, FL

United States

Schonna R. Manning

University of Texas at Austin

Department of Molecular Biosciences

Austin, TX

United States

Harold G. Marshall

Old Dominion University

Department of Biological Sciences

Norfolk, VA

United States

Pearse McCarron

National Research Council of Canada

Halifax, Nova Scotia

Canada

Dennis J. McGillicuddy, Jr.

Woods Hole Oceanographic Institution

Department of Applied Ocean Physics and Engineering

Woods Hole, MA

United States

Linda K. Medlin

Marine Biological Association of the United Kingdom

The Citadel

Plymouth

United Kingdom

Steve L. Morton

NOAA National Ocean Service

Marine Biotoxins Program

Charleston, SC

United States

Shauna Murray

University of Technology Sydney

Climate Change Cluster (C3)

Ultimo, NSW

Australia

Judith M. O'Neil

University of Maryland Center for Environmental Science

Horn Point Laboratory

Cambridge, MD

United States

Michael L. Parsons

Florida Gulf Coast University

Fort Meyers, FL

United States

Andrew Reich

Bureau of Environmental Health

Florida Department of Health

Tallahassee, FL

United States

J.E. (Jack) Rensel

Rensel Associates Aquatic Sciences

Arlington, WA

United States

Mindy L. Richlen

Woods Hole Oceanographic Institution

Biology Department

Woods Hole, MA

United States

Alison Robertson

University of South Alabama

and

Dauphin Island Sea Laboratory

Dauphin Island, AL

United States

Daniel L. Roelke

Texas A&M University

Department of Wildlife and Fisheries Sciences

College Station, TX

United States

Brian Sancewich

University of Florida

Food and Resource Economics Department

Gainesville, FL

United States

Joe Schumacker

Quinault Department of Fisheries

Taholah, WA

United States

Kevin G. Sellner

Hood College

Center for Coastal and Watershed Studies

Frederick, MD

United States

Sandra E. Shumway

University of Connecticut

Department of Marine Sciences

Groton, CT

United States

Mary Sweeney-Reeves

University of Georgia

Marine Extension Service and Georgia Sea Grant

Athens, GA

United States

Urban Tillmann

Alfred Wegener Institute

Bremerhaven

Germany

Mare Timmons

University of Georgia

Marine Extension Service and Georgia Sea Grant

Savannah, GA

United States

Carmelo R. Tomas

University of North Carolina–Wilmington

Center for Marine Science

Wilmington, NC

United States

Kathryn L. Van Alstyne

Western Washington University

Shannon Point Marine Center

Anacortes, WA

United States

Frances M. Van Dolah

NOAA National Ocean Service

National Centers for Coastal Ocean Science

Stressor Detection and Impacts Division

Charleston, SC

United States

Gary H. Wikfors

NOAA Fisheries Service

Northeast Fisheries Science Center

Milford, CT

United States

Acknowledgments

The production of a multiauthored book is a long and arduous task, and success depends first and foremost upon the efforts and talents of the contributors. The extraordinary talent and patience of the authors are gratefully acknowledged. The project could not have been completed without Noreen Blaschik and Elle Allen, who assisted with numerous and varied tasks, and created organization out of chaos. Eric Heupel designed the food web diagram and provided the cover artwork, and his talents made the mundane aspects of graphics not only functional, but understandable.

This book was made possible by grant #NA14NMF4270023 from the DOC/NOAA/Saltonstall-Kennedy Program to Sandra E. Shumway and Tessa L. Getchis. An executive summary of this book is available:

Getchis, T.L., and S.E. Shumway. (Eds.) 2017. Harmful Algae: An Executive Summary. Connecticut Sea Grant College Program. CTSG-17-08. 16 pp.

Introduction

Toxic microalgae and their associated blooms are regular and natural phenomena and have been recorded throughout history, yet major efforts to study their ecology, physiology, toxins, and impacts have only escalated over the past 4–5 decades as their presence and impacts have expanded globally. Harmful algal blooms (HAB) are caused by a diverse array of microalgal species, and they exert significant negative impacts on human and environmental health, economies, tourism, aquaculture, and fisheries (Figure I.1). The continuing increase in numbers of toxic and harmful algal species worldwide presents a constant threat to these entities, and to the sustainable development of coastal regions. While blooms of toxic algae have been noted in numerous historical documents, dating back centuries, the focus on HAB in North America and their impacts on human health was a relatively new phenomenon in the early 1970s, when the first conference was organized to share information on occurrences predominantly in New England and the Gulf of Mexico (see LoCicero et al., 1975).

Figure depicts the distribution of algal toxins throughout the food web.

Figure I.1

As blooms of toxic phytoplankton have continued to increase in their frequency, concentrations, and geographic distribution in marine, estuarine, and fresh waters, the amount of available literature on the topic has also continued to grow. Of the estimated 3400–4000 known species of phytoplankton, only 1–2% (60–80 species) are known to be harmful or toxic, yet their impacts can be devastating. Benthic microalgae and harmful species that do not typically “bloom” are now emerging as vectors of toxins (Chapter 16).

Consumption of contaminated seafood and exposure to contaminated water and aerial-borne toxins lead to seafood safety issues and human health hazards (Chapter 11). These episodes also impact the local economies (Chapter 10) and can cause large-scale ecological disturbances including fish and shellfish die-offs, and mortalities of marine mammals and birds. A conservative, dated estimate of societal costs associated with HAB in the United States is nearly a half-billion U.S. dollars, about half of which is linked to public health effects (Anderson et al., 2000; also see Adams and Larken, 2013; Hamilton et al., 2014; Bingham et al., 2015).

Traditionally, the vectors for toxin transfer were limited to consideration of filter-feeding bivalve molluscs (e.g., oysters, clams, scallops, and mussels), but over time they have grown to include gastropods (snails, limpets, and abalone), cephalopods (squid and octopus), crustaceans (crabs, shrimp, and lobsters), and echinoderms (sea urchins and sea cucumbers) (Chapter 5). Fish and many of these nontraditional food items have been incorporated in routine algal toxin-monitoring programs (Chapter 12) for the most common toxic syndromes such as paralytic shellfish poisoning (PSP), amnesic shellfish poisoning (ASP), neurotoxic shellfish poisoning (NSP), and diarrheic shellfish poisoning (DSP), and emerging toxins such as azaspiracids, palytoxins, yessotoxins, and pectenotoxins.

Aquaculture is the fastest growing component of the food production sector globally, and the possible contamination of aquaculture and fishery products due to microalgal toxins is a major concern for managers charged with guaranteeing safe products for human and animal consumption. This has in turn led to concerted efforts to develop more sensitive, efficient, and affordable tests for algal toxins.

Since the first international conference focused on toxic algae in 1974, there have been 16 international conferences, each of which has produced a volume of contributed papers that provide invaluable information, often at local levels that might not otherwise be made available to the community at large. Bibliographic information for these volumes is provided in the “References and Further General Reading” at the end of this Introduction.

The topic is very well studied, and there are numerous comprehensive reviews and volumes available (see “References”). The volume of published material and the exponential growth of the field over the past four decades are the impetus for the current volume – to distill the information into a useable format for managers, newcomers to the field, and those who are not familiar with the scientific literature or do not have easy or affordable access.

The worldwide number of phycotoxin-induced intoxications per year is about 60,000 cases (Gerssen et al., 2010), and, even with the advent of new and improved technologies for detection and monitoring programs, human illnesses still occur on a regular basis. An excellent summary of illnesses and deaths attributed to harmful algae is provided by Picot et al. (2011). The greatest threats are with regard to novel species and outbreaks, or areas where monitoring is not routine or does not include all edible species. As new toxins are identified and better technologies developed, monitoring programs continue to evolve. These monitoring programs are also a valuable source of long-term data sets that are currently being used in modeling efforts to predict the presence and impacts of blooms (see Chapter 3). The high variability in toxin levels between individual animals demands a comprehensive monitoring program (see Chapter 12). The increase in blooms has resulted in development of new and more cost-effective technologies for toxin detection. Among the greatest strides in recent years have been the development of “dipstick tests,” which are now routinely used in many areas as preliminary screening tools; the automatized detection of harmful species with specific molecular probes; and the migration from mouse assays to instrumental analyses (see Chapter 2). Successful management and monitoring programs have minimized cases of illnesses associated with toxic algae, and they continue to be refined.

Control, prevention, and mitigation remain topics of considerable interest, and new technologies, especially with regard to manipulated clay, continue to be pursued (Chapter 14), as do efforts to minimize the severity of economic and ecological impacts as well as to reduce threats to human health. The development of educational and outreach materials that promote public understanding and especially those targeted at focused audiences where language may be a barrier (Chapter 13) has been a major factor in engaging the general public and making them more aware of the perils and avoidance means when faced with local harmful and toxic algal blooms.

The current body of knowledge on HAB and their impacts is vast and no longer easily accessible, or understandable, to those not actively engaged in specific research arenas. The present volume is not intended to be a comprehensive review of all topics, but rather to provide basic information to those who are confronted with seemingly boundless sources of information, some conflicting or confusing, or who simply don't know where to begin searching for the information they need. These issues become more urgent when faced with unexpected blooms or known or unknown algal species and the associated risks to human health and trophic consequences in marine and aquatic habitats.

The aim of the current volume is to provide an accessible source of information and references for further investigation for individuals who may not be familiar with the scientific literature, but are in need of technical information when faced with unexpected or unknown harmful algal events.

References and Further General Reading

The available published literature on harmful algal blooms and their impacts is vast and can no longer be covered in any single publication. The goal of this book is to provide an overview for managers and newcomers to the field, and the following list provides an overview of recent publications.

  1. Adams, C.M., and S.L. Larken. 2013. Economics of Harmful Algal Blooms: Literature Review. Report to the Gulf of Mexico Alliance. Food and Resource Economics Department, University of Florida, Gainesville: 32 p. Available at: http://www.fred.ifas.ufl.edu/pdf/Adams-Larkin-LitRev-April2013.pdf.
  2. Anderson, C., S.K. Moore, M.C. Tomlinson, J. Silke, and C.K. Cusack. 2015. Living with harmful algal blooms in a changing world: strategies for modeling and mitigating their effects in coastal marine ecosystems. In: Coastal and Marine Hazards, Risks, and Disasters. J.F. Shroder, J.T. Ellis, and D.J. Sherman (Eds.). Elsevier Science, Amsterdam: 592 p.
  3. Anderson, D.M., S.F.E. Boerlage, and M. Dixon (Eds.). 2017. Harmful Algal Blooms (HABs) and Desalination: A Guide to Impacts, Monitoring and Management. Intergovernmental Oceanographic Commission, Paris: 493 p.
  4. Anderson, D.M., Y. Kaoru, and A.W. White. 2000. Estimated Annual Economic Impacts from Harmful Algal Blooms (HABs) in the United States. Technical Report WHOI-2000-11. Woods Hole Oceanographic Institute, Woods Hole.
  5. AOAC International. 2012. Official Methods of Analysis of AOAC International, 19th ed. Official Method 2011.27. AOAC International, Gaithersburg.
  6. Bailey, S.A. 2015. An overview of thirty years of research on ballast water as a vector for aquatic invasive species to freshwater and marine environments. Aquatic Ecosystem Health and Management, 18: 261–268.
  7. Berdalet, E., L.E. Fleming, R. Gowen, K. Davison, P. Hess, L.C. Backer, S.K. Moore, P. Hoagland, and H. Enevoldsen. 2016. Marine harmful algal blooms, human health and wellbeing: challenges and opportunities in the 21st century. Journal of the Marine Biological Association of the United Kingdom, 96: 61–91.
  8. Bingham, M., S.K. Sinha, and F. Lupi. 2015. Economic Benefits of Reducing Harmful Algal Blooms in Lake Erie. Report. Environmental Consulting and Technology, Inc.: 66 p. Available at: http://ijc.org/files/tinymce/uploaded/Publications/Economic-Benefits-Due-to-Reduction-in-HABs-October-2015.pdf.
  9. Brooks, B.W., J.P. Grover, and D.L. Roelke. 2011. Prymnesium parvum, an emerging threat to inland waters. Environmental Toxicology and Chemistry, 30: 1955–1964.
  10. Burkholder, J.M. 1998. Implications of harmful microalgae and heterotrophic dinoflagellates in management of sustainable fisheries. Ecological Applications, 8: S37–S62.
  11. Burkholder, J.M. 2002. Cyanobacteria. In: Encyclopedia of Environmental Microbiology. G. Bitton (Ed.). John Wiley & Sons, New York: p. 952–982.
  12. Burkholder, J.M. 2009. Harmful algal blooms. In: Encyclopedia of Inland Waters. Vol. 1 G.E. Likens (Ed.). Elsevier, Oxford: p. 264–285.
  13. Deeds J.R., J.H. Landsberg, S.M. Etheridge, G.C. Pitcher, and S.W. Longan. 2008. Non-traditional vectors for paralytic shellfish poisoning. Marine Drugs, 6: 308–348.
  14. Etheridge, S.M. 2010. Paralytic shellfish poisoning: seafood safety and human health perspectives. Toxicon, 56: 108–122.
  15. Flynn, K.J., M. St. John, J.A. Raven, D.O.F. Skibinski, J.I. Allen, A. Mitra, and E.E. Hofmann. 2015. Acclimation, adaptation, traits and trade-offs in plankton functional type models: reconciling terminology for biology and modelling. Journal of Plankton Research, 37: 683–691.
  16. Granéli, E., B. Edvardsen, D.L. Roelke, and J.A. Hagström. 2012. The ecophysiology and bloom dynamics of Prymnesium spp. Harmful Algae, 14: 260–270.
  17. Hallegraeff G.M., D.M. Anderson, and A.D. Cembella. 1995. Manual on Harmful Marine Microalgae. IOC Manuals and Guides, Vol. 33 Intergovernmental Oceanographic Commission of UNESCO, Paris: 551 p.
  18. Hamilton, D.P., S.A. Wood, D.R. Dietrich, and J. Puddick. 2014. Costs of harmful blooms of freshwater cyanobacteria. In: Cyanobacteria: An Economic Perspective. N.K. Sharma, A.K. Rai, and L.J. Stal (Eds.). John Wiley & Sons, Hoboken: p. 247–256.
  19. Landsberg, J. 2002. The effects of harmful algal blooms on aquatic organisms. Reviews in Fisheries Science, 10: 113–390.
  20. Landsberg, J.H., K.A. Lefebvre, and L.J. Flewelling. 2014. Effects of toxic microalgae on marine organisms. In: Toxins and Biologically Active Compounds from Microalgae. Vol. 2 G.P. Rossini (Ed.). CRC Press, Boca Raton: p. 379–449.
  21. Landsberg, J., F. Van Dolah, and G. Doucette. 2005. Marine and estuarine harmful algal blooms: impacts on human and animal health. In: Oceans and Health: Pathogens in the Marine Environment. S. Belkin and R.R. Colwell (Eds.). Springer, New York: p. 165–215.
  22. Lassus, P., P. Bourdeau, C. Marcaillou, and P. Soudant. 2014. Phycotoxins: seafood contamination, detoxification, and processing. In: Toxins and Biologically Active Compounds from Microalgae. Vol. 2 G. Rossini (Ed.). Taylor and Francis Group, Boca Raton: p. 453–501.
  23. Lassus, P., N. Chomerat, P. Hess, and E. Nezan. 2016. Toxic and Harmful Microalgae of the World Ocean. IOC Manuals and Guides, Vol. 68 Intergovernmental Oceanographic Commission of UNESCO, Paris: 528 p.
  24. Lawrence, J., H. Loreal, H. Toyofuku, P. Hess, I. Karunasagar, and L. Ababouch. 2011. Assessment and Management of Biotoxin Risks in Bivalve Molluscs. FAO Fisheries and Aquaculture Technical Paper No. 551. FAO, Rome: 337 p.
  25. Matsuyama, Y., and S.E. Shumway. 2009. Impacts of harmful algal blooms on shellfisheries and aquaculture. In: New Technologies in Aquaculture: Improving Production Efficiency, Quality and Environmental Management. G. Burnell and G. Allan (Eds.). Woodhead Publishing, Oxford: p. 580–609.
  26. Picot, C., T.A. Nguyen, A.C. Roudout, and D. Parent-Massin. 2011. A preliminary risk assessment of human exposure to phycotoxins in shellfish: a review. Human and Ecological Risk Assessment, 17: 328–366.
  27. Richardson, K. 1997. Harmful or exceptional phytoplankton blooms in the marine ecosystem. Advances in Marine Biology, 31: 301–385.
  28. Roelke, D.L., A. Barkoh, B.W. Brooks, J.P. Grover, K.D. Hambright, J.W. La Claire II, P.D.R. Moeller, and R. Patino. 2016. A chronicle of a killer algae in the west: ecology, assessment and management of Prymnesium parvum blooms. Hydrobiologia, 764: 29–50.
  29. Shumway, S.E. 1990. A review of the effects of algal blooms on shellfish and aquaculture. Journal of the World Aquaculture Society, 21: 65–104.
  30. Shumway, S.E. 1995. Phycotoxin-related shellfish poisoning: bivalve molluscs are not the only vectors. Reviews in Fisheries Science, 3: 1–31.
  31. Shumway, S.E., S.M. Allen, and P.D. Boersma. 2003. Marine birds and harmful algal blooms: sporadic victims or under-reported events? Harmful Algae, 2: 1–17.
  32. Smayda, T.J. 1992. Global epidemic of noxious phytoplankton blooms and food chain consequences in large ecosystems food chain consequences in large ecosystems. In: Food Chains, Yields, Models and Management of Large Marine Ecosystems. K. Sherman, L.M. Alexander, and B.D. Gold (Eds.). Westview Press, Boulder: p. 275–307.
  33. Smayda, T.J. 1997. What is a bloom? A commentary. Limnology and Oceanography, 42: 1132–1136.
  34. Tomas, C. 1997. Identifying Marine Phytoplankton. Academic Press, San Diego: 858 p.
  35. Van Dolah, F.M. 2000. Marine algal toxins: origins, health effects, and their increased occurrence. Environmental Health Perspectives, 108: 133–141.
  36. Zingone, A., and H.O. Enevoldsen. 2000. The diversity of harmful algal blooms: a challenge for science and management. Ocean and Coastal Management, 43: 725–748.

Conference Proceedings Series

  1. Anderson, D.M., A.W. White, and D.G. Baden (Eds.). 1985. Toxic Dinoflagellates. Proceedings of the 3rd International Conference on Toxic Dinoflagellate Blooms. Elsevier Science, New York: 561 p.
  2. Granéli, E., B. Sundstrom, L. Edler, and D.M. Anderson (Eds.). 1990. Toxic Marine Phytoplankton. Proceedings of the 4th International Conference on Toxic Dinoflagellate Blooms. Elsevier Science, New York: 554 p.
  3. Hallegraeff, G.M., S.I. Blackburn, C.J. Bolch, and R.J. Lewis (Eds.). 2001. Harmful Algal Blooms 2000. Proceedings of the 9th International Conference on Harmful Algal Blooms. Intergovernmental Oceanographic Commission of UNESCO, Paris: 518 p.
  4. Ho, K.-C., M.J. Zhou, Y.Z. Qi, and V. Kai (Eds.). 2010. Harmful Algae 2008. Proceedings of the 13th International Conference on Toxic Dinoflagellate Blooms. International Society for the Study of Harmful Algae. Environmental Publication House, Hong Kong.
  5. Kim, H.G., B. Reguera, G.M. Hallegraeff, C.K. Lee, M.S. Han, and J.K. Choi (Eds.). 2014. Harmful Algae 2012. Proceedings of the 15th International Conference on Harmful Algae. International Society for the Study of Harmful Algae, 246 p.
  6. Lassus, P., G. Arzul, E. Erard-Le Denn, P. Gentien, and C. Marcaillou-Le Baut (Eds.). 1995. Harmful Marine Algal Blooms. Proceedings of the 6th International Conference on Toxic Dinoflagellate Blooms. Lavoisier Publishing, Paris: 878 p.
  7. LoCicero, V., L.A. Loeblich, and A.R. Loeblich (Eds.). 1975. Proceedings of the 1st International Conference on Toxic Dinoflagellate Blooms. Massachusetts Science and Technology Foundation, Wakefield: 541 p.
  8. Mackenzie, A.L. (Ed.). 2015. Marine and Freshwater Harmful Algae. Proceedings of the 16th International Conference on Harmful Algae. Cawthron Institute, Nelson, New Zealand, and International Society for the Study of Harmful Algae, Wellington, New Zealand: 289 p.
  9. Okaichi, T., D.M. Anderson, and T. Nemoto (Eds.). 1989. Red Tides: Biology, Environmental Science, and Toxicology. Proceedings of the 1st International Symposium on Red Tides. Elsevier/ North Holland, New York: 505 p.
  10. Pagou, K.A., and G.M. Hallegraeff (Eds.). 2012. Proceedings of the 14th International Conference on Harmful Algae. International Society for the Study of Harmful Algae and Intergovernmental Oceanographic Commission of UNESCO, Paris.
  11. Reguera, B., J. Blanco, M.L. Fernández, and T. Wyatt (Eds.). 1998. Harmful Algae. Proceedings of the 8th International Conference on Harmful Algae. Xunta de Galicia and Intergovernmental Oceanographic Commission of UNESCO, Grafisant, Santiago de Compostela.
  12. Smayda, T., and Y. Shimizu (Eds.). 1993. Toxic Phytoplankton Blooms in the Sea. Proceedings of the 5th International Conference on Toxic Dinoflagellate Blooms. Elsevier Science, Amsterdam: 952 p.
  13. Steidinger, K.A., J.H. Landsberg, C.R. Tomas, and G.A. Vargo (Eds.). 2002. Harmful Algae 2002. Proceedings of the 10th International Conference on Harmful Algae. Florida Fish and Wildlife Conservation Commission, Florida Institute of Oceanography and Intergovernmental Oceanographic Commission of UNESCO, St. Petersburg: 573 p.
  14. Taylor, D.L., and H.H. Seliger (Eds.). 1978. Toxic Dinoflagellate Blooms. Proceedings of the 2nd International Conference on Toxic Dinoflagellate Blooms. Elsevier/North Holland: New York.
  15. Yasumoto, T., Y. Oshima, and Y. Fukuyo (Eds.). 1996. Harmful and Toxic Algal Blooms. Proceedings of the 7th International Conference on Toxic Phytoplankton. Intergovernmental Oceanographic Commission of UNESCO, Paris: 586 p.

Special Focused Issues of Harmful Algae

  1. Doucette, G.J., and C. Lee (Eds.). 2008. Recent progress on the research and management of Cochlodinium blooms: workshop of recent progress on the research and management of Cochlodinium blooms. Harmful Algae, 7: 259–378.
  2. Glibert, P.M., and J.M. Burkholder (Eds.). 2006. Ecology of Pfiesteria. Harmful Algae, 5: 339–480.
  3. Glibert, P.M., and K.G. Sellner (Eds.). 2005. Ecology and physiology of Prorocentrum minimum. Harmful Algae, 4: 447–650.
  4. Gober, C.J., and T.W. Davis (Eds.). 2016. Global expansion of harmful cyanobacterial blooms: diversity, ecology, causes, and controls. Harmful Algae, 54: 1–238.
  5. Grattan, L., and V. Trainer (Eds.). 2016. Harmful algal blooms and public health. Harmful Algae, 57: 1–56.
  6. Jeong, H.J. (Ed.). 2013. Red tides in Korea. Harmful Algae, 30: S1–S144.
  7. O'Neil, J.M., and C.A. Heil (Eds.). 2014. Nutrient dynamics of Karenia brevis red tide blooms in the eastern Gulf of Mexico. Harmful Algae, 38: 1–140.
  8. Shumway, S.E., and T. Smayda (Eds.). 2004. Brown tides. Harmful Algae, 3: 273–246.
  9. Veldhuis, M.J.W., and P. Wassmann (Eds.). 2005. Bloom dynamics and biological control of Phaeocystis: a HAB species in European coastal waters. Harmful Algae, 4: 805–964.