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Fish Physiology: Homeostasis and Toxicology of Essential Metals, Volume 31A [Kõva köide]

Volume editor (University of British Columbia, USA), Volume editor (University of British Columbia, Vancouver, Canada), Volume editor (Dept of Biology, McMaster University, Ontario, Canada)
  • Formaat: Hardback, 520 pages, kõrgus x laius: 229x152 mm, kaal: 870 g
  • Sari: Fish Physiology
  • Ilmumisaeg: 02-Sep-2011
  • Kirjastus: Academic Press Inc
  • ISBN-10: 0123786363
  • ISBN-13: 9780123786364
Teised raamatud teemal:
Fish Physiology: Homeostasis and Toxicology of Essential Metals, Volume 31ASuurem pilt
  • Formaat: Hardback, 520 pages, kõrgus x laius: 229x152 mm, kaal: 870 g
  • Sari: Fish Physiology
  • Ilmumisaeg: 02-Sep-2011
  • Kirjastus: Academic Press Inc
  • ISBN-10: 0123786363
  • ISBN-13: 9780123786364
Teised raamatud teemal:
Püsilink: https://www.kriso.ee/db/9780123786364.html
Märksõnad:

Homeostasis and Toxicology of Essential Metals synthesizes the explosion of new information on the molecular, cellular, and organismal handling of metals in fish in the past 15 years. These elements are no longer viewed by fish physiologists as "heavy metals" that kill fish by suffocation, but rather as interesting moieties that enter and leave fish by specific pathways, which are subject to physiological regulation. The metals featured in this volume are those about which there has been most public and scientific concern, and therefore are those most widely studied by fish researchers. Metals such as Cu, Zn, Fe, Ni, Co, Se, Mo and Cr are either proven to be or are strongly suspected to be essential in trace amounts, yet are toxic in higher doses.

The companion volume, Homeostasis and Toxicology of Non-Essential Metals, Volume 31B, covers metals that have no known nutritive function in fish at present, but which are toxic at fairly low levels, such as Ag, Al, Cd, Pb, Hg, As, Sr, and U. In addition, three chapters in Volumes 31A and 31B on Basic Principles (Chapter 1, 31A), Field Studies and Ecological Integration (Chapter 9, 31A) and Modeling the Physiology and Toxicology of Metals (Chapter 9, 31B) act as integrative summaries and make these two volumes a vital set for readers.

  • All major essential metals of interest are covered in metal-specific chapters
  • Each metal-specific chapter is written by fish physiologists/toxicologists who are recognized authorities for that metal
  • A common format is featured throughout this two volume edition

Arvustused

"This book (actually 2 companion volumes) provides a comprehensive and accessible review of trace metal essentiality, effects of deficiency or excess, homeostatic processes, and toxicology in fishes. The chapters and volumes are constructed with a parallel structure that helps comparisons across the different metals. In addition to the core focus, each chapter includes a brief summary of geochemical speciation, environmental concentrations in natural and polluted areas, environmental quality criteria from different countries, uses, and arguments for and against essentiality. The chapters are all authoritativeThese 2 volumes are likely to stand for some time as the defining compendium on the homeostasis and toxicology of metals in fish. The publisher lists them as the First Edition. Perhaps when the Second Edition is written, it will be feasible to expand the scope to include comparative information on aquatic organisms other than fish." --Integrated Environmental Assessment and Management, Volume 8, Number 4, pp. 768-772

Muu info

A comprehensive synthesis of information on both the physiology and toxicology of specific essential metals in fish
Contributors for Volume 31B xv
Preface xvii
1 Silver
Chris M. Wood
1 Introduction
2(1)
2 Sources of Silver and Occurrence in Natural Waters
3(2)
3 Speciation in Freshwater
5(1)
4 Speciation in Seawater
6(2)
5 Environmental Situations of Concern
8(1)
6 Acute and Chronic Ambient Water Quality Criteria in Freshwater and Seawater
8(2)
7 Waterborne Silver Toxicity in Freshwater
10(19)
8 Waterborne Silver Toxicity in Saltwater
29(6)
9 Essentiality or Non-Essentiality of Silver
35(1)
10 Potential for Bioconcentration and/or Biomagnification of Silver
35(1)
11 Characterization of Uptake Routes
36(9)
12 Characterization of Internal Handling
45(7)
13 Characterization of Excretion Routes
52(1)
14 Behavioral Effects of Silver
53(1)
15 Molecular Characterization of Silver Transporters, Storage Proteins, and Chaperones
53(1)
16 Genomic and Proteomic Studies
54(1)
17 Interactions with Other Metals
54(1)
18 Knowledge Gaps and Future Directions
54(14)
2 Aluminum
Rod W. Wilson
1 Introduction
68(1)
2 Chemical Speciation in Freshwater and Seawater
69(5)
3 Sources (Natural and Anthropogenic) of Aluminum and Economic Importance
74(1)
4 Environmental Situations of Concern
75(2)
5 Ambient Water Quality Criteria in Freshwater
77(2)
6 Mechanisms of Toxicity
79(15)
7 Non-Essentiality of Aluminum
94(1)
8 Potential for Bioconcentration and/or Biomagnification of Aluminum
95(1)
9 Characterization of Uptake Routes
95(2)
10 Characterization of Internal Handling
97(1)
11 Characterization of Excretion Routes
98(1)
12 Behavioral Effects of Aluminum
98(5)
13 Molecular Characterization of Aluminum Transporters, Storage Proteins, and Chaperones
103(1)
14 Genomic and Proteomic Studies
103(1)
15 Interactions with Other Metals
104(1)
16 Knowledge Gaps and Future Directions
104(22)
3 Cadmium
James C. McGeer
Som Niyogi
D. Scott Smith
1 Introduction
126(1)
2 Chemical Speciation in Freshwater and Seawater
127(4)
3 Sources (Natural and Anthropogenic) of Cadmium and Economic Importance
131(4)
4 A Survey of Acute and Chronic Ambient Water Quality Criteria
135(3)
5 Mechanisms of Toxicity
138(10)
6 Essentiality of Cadmium
148(1)
7 Potential for Bioconcentration and Biomagnification of Cadmium
148(4)
8 Characterization of Uptake Routes
152(6)
9 Characterization of Internal Handling
158(3)
10 Characterization of Excretion Routes
161(1)
11 Behavioral Effects of Cadmium
162(2)
12 Molecular Characterization of Cadmium Transporters and Storage Proteins
164(2)
13 Genomic and Proteomic Studies
166(1)
14 Interactions with Other Metals
167(1)
15 Knowledge Gaps and Future Directions
168(18)
4 Lead
Edward M. Mager
1 Chemical Speciation in Freshwater and Seawater
186(5)
2 Sources (Natural and Anthropogenic) of Lead and Economic Importance
191(3)
3 Environmental Situations of Concern
194(2)
4 A Survey of Acute and Chronic Ambient Water Quality Criteria in Various Jurisdictions in Freshwater and Seawater
196(2)
5 Mechanisms of Toxicity
198(6)
6 Non-Essentiality of Lead
204(1)
7 Potential for Bioconcentration and Biomagnification of Lead
204(3)
8 Characterization of Uptake Routes
207(5)
9 Characterization of Internal Handling
212(6)
10 Characterization of Excretion Routes
218(2)
11 Behavioral Effects of Lead
220(1)
12 Molecular Characterization of Lead Transporters, Storage Proteins, and Chaperones
221(1)
13 Genomic Studies
222(1)
14 Interactions with Other Metals
223(2)
15 Knowledge Gaps and Future Directions
225(13)
5 Mercury
Karen Kidd
Katharina Batchelar
1 Introduction
238(1)
2 Chemical Speciation in Freshwater and Seawater
239(1)
3 Sources of Mercury and Economic Importance
240(1)
4 Environmental Situations of Concern
241(1)
5 A Survey of Acute and Chronic Ambient Water Quality Criteria for Freshwater and Seawater
242(1)
6 Mechanisms of Toxicity
242(19)
7 Essentiality or Non-Essentiality of Mercury
261(1)
8 Potential for Bioconcentration and Biomagnification of Mercury
261(1)
9 Characterization of Uptake Routes
262(8)
10 Characterization of Internal Handling
270(7)
11 Characterization of Excretion Routes
277(5)
12 Behavioral Effects of Mercury
282(1)
13 Molecular Characterization of Mercury Transporters, Storage Proteins, and Chaperones
283(1)
14 Genomic and Proteomic Studies
284(1)
15 Knowledge Gaps and Future Directions
284(14)
6 Arsenic
Dennis O. McIntyre
Tyler K. Linton
1 Chemical Speciation in Freshwater and Saltwater
298(5)
2 Sources (Natural and Anthropogenic) of Arsenic and Economic Importance
303(1)
3 Environmental Situations of Concern
304(1)
4 A Survey of Acute and Chronic Ambient Water Quality Criteria in Various Jurisdictions in Freshwater and Saltwater
304(2)
5 Mechanisms of Toxicity
306(15)
6 Essentiality or Non-Essentiality of Arsenic
321(1)
7 Potential for Bioaccumulation and/or Biomagnification (or Biodiminution) of Arsenic
321(5)
8 Characterization of Uptake, Internal Handling, and Excretion
326(8)
9 Detoxification and Mechanisms for Tolerance
334(1)
10 Behavioral Effects of Arsenic
335(1)
11 Molecular Characterization of Metal Transporters, Storage Proteins, and Chaperones
336(1)
12 Interactions with Other Metals
336(1)
13 Knowledge Gaps and Future Directions
337(15)
7 Strontium
M. Jasim Chowdhury
Ronny Blust
1 Chemical Speciation in Freshwater and Seawater
352(2)
2 Sources and Economic Importance of Strontium
354(2)
3 Environmental Situations of Concern
356(1)
4 Acute and Chronic Ambient Water Quality Criteria in Various Jurisdictions in Freshwater and Seawater
357(1)
5 Mechanisms of Toxicity
358(4)
6 Non-Essentiality of Strontium
362(1)
7 Potential for Bioconcentration and Biomagnification of Strontium
362(4)
8 Characterization of Uptake Routes
366(8)
9 Characterization of Internal Handling
374(5)
10 Characterization of Excretion Routes
379(1)
11 Behavioral Effects of Strontium
380(1)
12 Molecular Characterization of Strontium Transporters, Storage Proteins, and Chaperones
380(1)
13 Genomic and Proteomic Studies
381(1)
14 Interactions with Other Metals
382(1)
15 Knowledge Gaps and Future Directions
382(10)
8 Uranium
Richard R. Goulet
Claude Fortin
Douglas J. Spry
1 Chemical Speciation in Freshwater and Seawater
392(6)
2 Sources of Uranium and its Economic Importance
398(1)
3 Environmental Situations of Concern
399(2)
4 A Survey of Acute and Chronic Ambient Water Quality Criteria in Various Jurisdictions in Freshwater and Seawater
401(2)
5 Mechanisms of Toxicity
403(5)
6 Water Chemistry Influences on Bioavailability and Toxicity
408(4)
7 Non-Essentiality of Uranium
412(1)
8 Potential for Bioaccumulation of Uranium
412(1)
9 Characterization of Uptake Routes
413(3)
10 Characterization of Internal Handling
416(1)
11 Characterization of Excretion Routes
417(1)
12 Behavioral Effects of Uranium
417(1)
13 Genomic and Proteomic Studies
418(1)
14 Interactions with Other Metals
418(1)
15 Knowledge Gaps and Future Directions
418(12)
9 Modeling the Physiology and Toxicology of Metals
Paul Paquin
Aaron Redman
Adam Ryan
Robert Santore
1 Introduction
430(2)
2 Model Frameworks for Evaluating Metal Accumulation
432(15)
3 Models Relating Metal Accumulation to Effects
447(20)
4 Regulatory Applications
467(3)
5 Future Model Development Needs
470(15)
Index 485(20)
Other Volumes in the Fish Physiology Series 505
Dr. Tony Farrell is a Professor Emeritus in the Department of Zoology & Faculty of Land and Food Systems at the University of British Columbia and a Fellow of the Royal Society of Canada. His research had provided an understanding of fish cardiorespiratory systems and has applied this knowledge to salmon migratory passage, fish stress handling and their recovery, sustainable aquaculture and aquatic toxicology. He has over 490 research publications in peer-reviewed scientific journals and an h-factor of 92. He has co-edited of 30 volumes of the Fish Physiology series, as well as an award-winning Encyclopedia of Fish Physiology. As part of his application of physiology to aquaculture, he has studied the sub-lethal impacts of sea lice and piscine orthoreovirus on the physiology of juvenile salmon. Dr. Farrell has received multiple awards, including the Fry Medal, which is the highest honour to a scientist from the Canadian Society of Zoologists, the Beverton Medal, which is the highest honour to a scientist from the Fisheries Society of the British Isles, the Award of Excellence, which is the highest honour of the American Fisheries Society and the Murray A. Newman Awards both for Research and for Conservation from the Vancouver Marine Sciences Centre. He is a former President of the Society of Experimental Biologists and a former Editor-in-Chief for the Journal of Fish Biology. He served as a member of the Ministers Aquaculture Advisory Committee on Finfish Aquaculture for British Columbia and was a member of the Federal Independent Expert Panel on Aquaculture Science. Dr. Colin Brauner was educated in Canada at the University of British Columbia (Ph D), followed by a Post-doctoral fellowship at Aarhus University and the University of Southern Denmark, and was a Research Associate at McMaster University. He is a Professor of Zoology, UBC and Director of the UBC Aquatics Facility. He has been a Co-Editor of the Fish Physiology series since 2006. His research investigates environmental adaptations (both mechanistic and evolutionary) in relation to gas-exchange, acid-base balance and ion regulation in fish, integrating responses from the molecular, cellular and organismal level. The ultimate goal is to understand how evolutionary pressures have shaped physiological systems among vertebrates and to determine the degree to which physiological systems can adapt/acclimate to natural and anthropogenic environmental changes. This information is crucial for basic biology and understanding the diversity of biological systems, but much of his research conducted to date can also be applied to issues of aquaculture, toxicology and water quality criteria development, as well as fisheries management. His achievements have been recognized by the Society for Experimental Biology, UK (Presidents medal) and the Canadian Conference for Fisheries Research (J.C. Stevenson Memorial Lecturer) and the Vancouver Marine Sciences Centre (Murray A. Newman Award for Aquatic Research). He is a former President of the Canadian Society of Zoologists.