Book contents
- Frontmatter
- Contents
- Editor, Associate Editors, Artistic Consultant, and Contributors
- Preface
- PART I CONTEXT
- 1 The Endothelium in History
- 2 Introductory Essay: Evolution, Comparative Biology, and Development
- 3 Evolution of Cardiovascular Systems and Their Endothelial Linings
- 4 The Evolution and Comparative Biology of Vascular Development and the Endothelium
- 5 Fish Endothelium
- 6 Hagfish: A Model for Early Endothelium
- 7 The Unusual Cardiovascular System of the Hemoglobinless Antarctic Icefish
- 8 The Fish Endocardium: A Review on the Teleost Heart
- 9 Skin Breathing in Amphibians
- 10 Avian Endothelium
- 11 Spontaneous Cardiovascular and Endothelial Disorders in Dogs and Cats
- 12 Giraffe Cardiovascular Adaptations to Gravity
- 13 Energy Turnover and Oxygen Transport in the Smallest Mammal: The Etruscan Shrew
- 14 Molecular Phylogeny
- 15 Darwinian Medicine: What Evolutionary Medicine Offers to Endothelium Researchers
- 16 The Ancestral Biomedical Environment
- 17 Putting Up Resistance: Maternal–Fetal Conflict over the Control of Uteroplacental Blood Flow
- 18 Xenopus as a Model to Study Endothelial Development and Modulation
- 19 Vascular Development in Zebrafish
- 20 Endothelial Cell Differentiation and Vascular Development in Mammals
- 21 Fate Mapping
- 22 Pancreas and Liver: Mutual Signaling during Vascularized Tissue Formation
- 23 Pulmonary Vascular Development
- 24 Shall I Compare the Endothelium to a Summer's Day: The Role of Metaphor in Communicating Science
- 25 The Membrane Metaphor: Urban Design and the Endothelium
- 26 Computer Metaphors for the Endothelium
- PART II ENDOTHELIAL CELL AS INPUT-OUTPUT DEVICE
- PART III VASCULAR BED/ORGAN STRUCTURE AND FUNCTION IN HEALTH AND DISEASE
- PART IV DIAGNOSIS AND TREATMENT
- PART V CHALLENGES AND OPPORTUNITIES
- Index
- Plate section
5 - Fish Endothelium
from PART I - CONTEXT
Published online by Cambridge University Press: 04 May 2010
- Frontmatter
- Contents
- Editor, Associate Editors, Artistic Consultant, and Contributors
- Preface
- PART I CONTEXT
- 1 The Endothelium in History
- 2 Introductory Essay: Evolution, Comparative Biology, and Development
- 3 Evolution of Cardiovascular Systems and Their Endothelial Linings
- 4 The Evolution and Comparative Biology of Vascular Development and the Endothelium
- 5 Fish Endothelium
- 6 Hagfish: A Model for Early Endothelium
- 7 The Unusual Cardiovascular System of the Hemoglobinless Antarctic Icefish
- 8 The Fish Endocardium: A Review on the Teleost Heart
- 9 Skin Breathing in Amphibians
- 10 Avian Endothelium
- 11 Spontaneous Cardiovascular and Endothelial Disorders in Dogs and Cats
- 12 Giraffe Cardiovascular Adaptations to Gravity
- 13 Energy Turnover and Oxygen Transport in the Smallest Mammal: The Etruscan Shrew
- 14 Molecular Phylogeny
- 15 Darwinian Medicine: What Evolutionary Medicine Offers to Endothelium Researchers
- 16 The Ancestral Biomedical Environment
- 17 Putting Up Resistance: Maternal–Fetal Conflict over the Control of Uteroplacental Blood Flow
- 18 Xenopus as a Model to Study Endothelial Development and Modulation
- 19 Vascular Development in Zebrafish
- 20 Endothelial Cell Differentiation and Vascular Development in Mammals
- 21 Fate Mapping
- 22 Pancreas and Liver: Mutual Signaling during Vascularized Tissue Formation
- 23 Pulmonary Vascular Development
- 24 Shall I Compare the Endothelium to a Summer's Day: The Role of Metaphor in Communicating Science
- 25 The Membrane Metaphor: Urban Design and the Endothelium
- 26 Computer Metaphors for the Endothelium
- PART II ENDOTHELIAL CELL AS INPUT-OUTPUT DEVICE
- PART III VASCULAR BED/ORGAN STRUCTURE AND FUNCTION IN HEALTH AND DISEASE
- PART IV DIAGNOSIS AND TREATMENT
- PART V CHALLENGES AND OPPORTUNITIES
- Index
- Plate section
Summary
Fishes are the most phylogenetically ancient vertebrates, and their cardiovascular system presumably resembles the ancestral prototype. Nearly half of all vertebrate species are fishes, and they are also the most physiologically diverse. For example, hagfish have the highest plasma sodium and chloride concentration of any vertebrate (>400 mM), elasmobranchs (sharks skates and rays) adjust plasma osmolarity with 300 mM urea, and bony fishes maintain plasma osmolarity ∼300 mOsm in either saltwater (1,000 mOsm) or freshwater (<1 mOsm). Body temperature varies with the environment and can range from supercooled –1.8°C in Antarctic icefish to 40°C for desert pupfish. Ambient oxygen (O2) varies diurnally, seasonally, and with strata from supersaturation to anoxia, and various mechanisms have evolved to deal with hypoxia; the crucian carp is unaffected by up to 5 days in anoxic water, and many fishes breathe air, either using modified gills or as lungfish with a primitive lung. Hagfish have the lowest blood pressure yet measured in any vertebrate (7 to 10 mm Hg), whereas ventral aortic pressure approaches 90 mm Hg in tuna, similar to mammals. The gill and systemic circulations of fishes are arranged in series thus, unlike most other vertebrates, delicate respiratory tissues are exposed to the highest blood pressures. Also unique to fishes is the apparent lack of a lymphatic system; the impact of this on transcapillary fluid balance is largely unknown.
Despite this variability, the general features of cardiovascular systems in all extant vertebrates are surprising similar (1). Thus, it seems likely that the piscine cardiovascular system can provide clues into the factors that shaped the evolution of the vertebrate cardiovascular system and defined its plasticity.
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- Endothelial Biomedicine , pp. 59 - 65Publisher: Cambridge University PressPrint publication year: 2007