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One Welfare, a Framework to Improve Animal Welfare and Human Well-being

Name: One Welfare, a Framework to Improve Animal Welfare and Human Well-being
Brand: Global Vet & Co
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Preface (p.5)
Contents (p.6)
Contributors (p.8)
References (p.11)
1 Introduction (p.13)
2 Blood Oxygen Transport and Transfer Across the Gill (p.13)
3 Blood Carbon Dioxide Transport and Transfer Across the Gill (p.13)
4 Sensing of Respiratory Gases at the Gill (p.13)
5 Ammonia Excretion (p.13)
References (p.13)
1 Introduction (p.51)
2 Regulation of pH in the Blood and Extracellular Space (p.51)
3 Environmental Hypercarbia (p.51)
4 Acid–Base Compensation During Exposure to Hypercarbia (p.51)
5 Limitations to Extracellular pH Compensation During Hypercapnia (p.51)
6 Novel Patterns of pH Regulation in Response to Hypercarbia in Pleisiomorphic and Air-Breathing Fishes (p.51)
7 Conclusions and Speculations (p.51)
References (p.51)
1 Introduction (p.72)
2 The Problem of Buoyancy (p.72)
3 Buoyancy Devices in Teleosts and Elasmobranchs (p.72)
4 Diving Reptiles and Birds (p.72)
5 Buoyancy in Mammals (p.72)
6 Conclusions (p.72)
References (p.72)
1 Introduction (p.106)
References (p.106)
1 Introduction (p.127)
2 Cardiac Output, Heart Rate, and Stroke Volume (p.127)
3 In vitro Cardiac Performance (p.127)
References (p.127)
1 Introduction (p.167)
2 How Advanced is the Lungfish Lung? (p.167)
3 Regulation of Acid–Base Status and Oxygen Levels (p.167)
4 Respiratory Control in Lungfish Compared to Amphibians and Other Land Vertebrates (p.167)
5 Focus on the South American Lungfish L. paradoxa (p.167)
6 Focus on the African Lungfish Protopterus sp (p.167)
7 Focus on the Australian Lungfish Neoceratodus Forsteri (p.167)
8 Aestivation (p.167)
References (p.167)
1 Introduction to Aestivation (p.184)
References (p.184)
1 Introduction (p.195)
2 Aquatic Water Breathers: Interaction of Respiratory, Cardiovascular, Locomotor and Nutritional Faculties (p.195)
3 Aquatic Air Breathers (p.195)
4 Terrestrial Air Breathers (p.195)
References (p.195)
1 Introduction (p.207)
2 Temperature (p.207)
3 Pressure (p.207)
4 Hypoxia (p.207)
5 Conclusions and Future Directions (p.207)
References (p.207)
1 Introduction (p.242)
2 Lesion Studies (p.242)
3 Putative Mediators Within the NI (p.242)
4 Locus Coeruleus (p.242)
5 Final Remarks and Perspectives (p.242)
References (p.242)
1 Introduction (p.263)
2 Comparative Hypoxia Tolerance of Cardiac Function (p.263)
3 Cellular Energy Metabolism During Hypoxia/Anoxia (p.263)
4 Cellular Energy State and Contractile Force (p.263)
5 Cardiac Excitation–Contraction (E, C) Coupling (p.263)
6 Factors Influencing Cardiac Contractility During Anoxia (p.263)
7 Conclusion (p.263)
References (p.263)
1 Introduction (p.285)
2 Efferent Innervation of the Vertebrate Heart (p.285)
3 Cardiorespiratory Interactions (p.285)
4 The Neural Basis of Cardiorespiratory Interactions (p.285)
5 Fish (p.285)
6 Elasmobranchs (p.285)
7 Teleosts (p.285)
8 Amphibians (p.285)
9 Reptiles (p.285)
10 Mechanisms of Phasic Vagal Control of the Heart (p.285)
References (p.285)
1 Introduction (p.316)
2 Basic Cold-Blooded Vertebrate Heart (p.316)
3 Catecholamines (p.316)
4 Natriuretic Peptides (p.316)
5 Chromogranin-A (p.316)
6 The Renin–Angiotensin-System (p.316)
7 Other Cardiac Endocrine/Paracrine/Autocrine Substances (p.316)
8 A Major Autocrine/Paracrine Sensor-Integrator:The NOS–NO System (p.316)
9 Concluding Remarks (p.316)
References (p.316)
1 Introduction (p.379)
2 Pathways of Fuel Oxidation (p.379)
3 Metabolic Rates During Flight (p.379)
4 The Supply of Oxygen (p.379)
5 Fuel Use During Flight: The Sucrose Oxidation Cascade (p.379)
6 In Vitro, In Vivo and Beyond (p.379)
7 Concluding Remarks (p.379)
References (p.379)
1 Introduction (p.393)
2 Ontogeny of the Control of the Heart Via the Autonomic Nervous System (p.393)
3 Ontogeny of the Control of Vascular Contractility (p.393)
4 Functional Integration of Autonomic Cardiovascular Regulation (p.393)
5 Effects of Humoral and Local Effectors: Angiotensin, Endothelin-1 and Natriuretic Peptides (p.393)
References (p.393)
1 Introduction (p.424)
2 Efferent Innervation of the Vertebrate Heart (p.424)
3 Cardiorespiratory Interactions (p.424)
4 The Neural Basis of Cardiorespiratory Interactions (p.424)
5 Fish (p.424)
6 Elasmobranchs (p.424)
7 Teleosts (p.424)
8 Amphibians (p.424)
9 Reptiles (p.424)
10 Mechanisms of Phasic Vagal Control of the Heart (p.424)
References (p.424)
1 Introduction (p.444)
2 Characteristics of Peripheral Chemoreceptor Tissue (p.444)
3 Natural Stimuli of Peripheral Chemoreceptors (p.444)
4 Mechanism of Hypoxia Chemotransduction (p.444)
5 Conclusions (p.444)
References (p.444)
1 Introduction (p.467)
2 Organismal Chemosensitive Responsesto Environmental or Metabolic Stimuli (p.467)
3 Altered Chemosensitivity in Disease (p.467)
4 Development of the Organismal ChemosensitiveResponse (p.467)
5 Central Chemosensitivity (p.467)
6 Multiple Chemosensitive Regions in the Brainstem? (p.467)
7 Development of Central Chemoreception (p.467)
8 Central Vs Peripheral Chemoreception (p.467)
9 Cellular Chemosensitive Signaling (p.467)
10 Summary (p.467)
References (p.467)
1 Introduction (p.493)
2 Skeletal Muscles (p.493)
3 Metabolic Demand (p.493)
4 Static and Dynamic Work (p.493)
5 Energy Requirements and Cardiorespiratory Limitations (p.493)
6 Endocrine and Metabolic Responses (p.493)
7 Ventilation (p.493)
8 Blood Lactate (p.493)
9 The Heart Rate Response (p.493)
10 Blood Pressure (p.493)
11 Regional Blood Flow (p.493)
12 Peripheral Gas Exchange (p.493)
13 Brain (p.493)
14 Diving Response (p.493)
15 Altitude (p.493)
16 Heat and Cold (p.493)
17 Genetic Influence (p.493)
18 Health (p.493)
References (p.493)
Index (p.532)
... and 23 more chapters