1. Lecture #10 – Animal Circulation and Gas Exchange Systems

2. Key Concepts: Circulation and gas exchange – why?
Circulation – spanning diversity
Hearts – the evolution of double circulation
Blood circulation and capillary exchange
Blood structure and function
Gas exchange – spanning diversity
Breathing – spanning diversity
Respiratory pigments

3. Animals use O2 and produce CO2
All animals are aerobic
Lots of oxygen is required to support active mobility
Some animals use lots of oxygen to maintain body temperature
All animals produce CO2 as a byproduct of aerobic respiration
Gasses must be exchanged
Oxygen must be acquired from the environment
Carbon dioxide must be released to the environment

4. Except……breaking news!
Abstract – 6 April 2010
Background
Several unicellular organisms (prokaryotes and protozoa) can live under permanently anoxic conditions. Although a few metazoans can survive temporarily in the absence of oxygen, it is believed that multi-cellular organisms cannot spend their entire life cycle without free oxygen. Deep seas include some of the most extreme ecosystems on Earth, such as the deep hypersaline anoxic basins of the Mediterranean Sea. These are permanently anoxic systems inhabited by a huge and partly unexplored microbial biodiversity.
Results
During the last ten years three oceanographic expeditions were conducted to search for the presence of living fauna in the sediments of the deep anoxic hypersaline L'Atalante basin (Mediterranean Sea). We report here that the sediments of the L'Atalante basin are inhabited by three species of the animal phylum Loricifera (Spinoloricus nov. sp., Rugiloricus nov. sp. and Pliciloricus nov. sp.) new to science. Using radioactive tracers, biochemical analyses, quantitative X-ray microanalysis and infrared spectroscopy, scanning and transmission electron microscopy observations on ultra-sections, we provide evidence that these organisms are metabolically active and show specific adaptations to the extreme conditions of the deep basin, such as the lack of mitochondria, and a large number of hydrogenosome-like organelles, associated with endosymbiotic prokaryotes.
Conclusions
This is the first evidence of a metazoan life cycle that is spent entirely in permanently anoxic sediments. Our findings allow us also to conclude that these metazoans live under anoxic conditions through an obligate anaerobic metabolism that is similar to that demonstrated so far only for unicellular eukaryotes. The discovery of these life forms opens new perspectives for the study of metazoan life in habitats lacking molecular oxygen.

5. Animals use O2 and produce CO2
Circulation systems move gasses (and other essential resources such as nutrients, hormones, etc) throughout the animal’s body
Respiratory systems exchange gasses with the environment

6. Circulation systems have evolved over time
The most primitive animals exchange gasses and circulate resources entirely by diffusion
Process is slow and cannot support 3-D large bodies
Sponges, jellies and flatworms use diffusion alone

7. Critical Thinking
Why isn’t diffusion adequate for exchange in a 3D large animal???

8. Critical Thinking
Why isn’t diffusion adequate for exchange in a 3D large animal???

9. Critical Thinking
But…..plants rely on diffusion for gas exchange…..how do they get so big???

10. Critical Thinking
But…..plants rely on diffusion for gas exchange…..how do they get so big???

11. Circulation systems have evolved over time
The most primitive animals exchange gasses and circulate resources entirely by diffusion
Process is slow and cannot support 3-D large bodies
Surface area / volume ratio becomes too small
Sponges, jellies and flatworms use diffusion alone

12. Virtually every cell in a sponge is in direct contact with the water – little circulation is required
Diagram of sponge structure

13. Jellies and flatworms have thin bodies and elaborately branched gastrovascular cavities
Again, all cells are very close to the external environment
This facilitates diffusion
Some contractions help circulate (contractile fibers in jellies, muscles in flatworms)
Diagram of jellyfish structure, and photos

14. Circulation systems have evolved over time
Most invertebrates (esp. insects) have an open circulatory system
Metabolic energy is used to pump hemolymph through blood vessels into the body cavity
Hemolymph is returned to vessels via ostia – pores that draw in the fluid as the heart relaxes
Diagram of open circulatory system in a grasshopper

15. Circulation systems have evolved over time
Closed circulatory systems separate blood from interstitial fluid
Metabolic energy is used to pump blood through blood vessels
Blood is contained within the vessels
Exchange occurs by diffusion in capillary beds
Diagram of a closed circulatory system, plus a diagram showing an earthworm circulatory system

16. Open vs. Closed…both systems are common
Open systems….
Use less metabolic energy to run
Use less metabolic energy to build
Can function as a hydrostatic skeleton
Most invertebrates (except earthworms and larger mollusks) have open systems
Closed systems….
Maintain higher pressure
Are more effective at transport
Supply more oxygen to support larger and more active animals
All vertebrates have closed systems
Open – insects!!!

17. All vertebrates have a closed circulatory system
Chambered heart pumps blood
Atria receive blood
Ventricles pump blood
Vessels contain the blood
Veins carry blood to atria
Arteries carry blood from ventricles
Capillary beds facilitate exchange
Capillary beds separate arteries from veins
Highly branched and very tiny
Infiltrate all tissues in the body
We’ll go over these step by step

18. Chambered heart pumps blood
Atria receive blood
Ventricles pump blood
One-way valves direct blood flow
Diagram of a chambered heart

19. Critical Thinking Atria receive blood; ventricles pump
Given that function, what structure would you predict???

20. Critical Thinking Atria receive blood; ventricles pump
Given that function, what structure would you predict???

21. Chambered heart pumps blood
Atria receive blood
Soft walled, flexible
Ventricles pump blood
Thick, muscular walls
One-way valves direct blood flow
Diagram of a chambered heart

22. Vessels contain the blood
Arteries carry blood from ventricles
Always under pressure
Veins carry blood to atria
One-way valves prevent back flow
Body movements increase circulation
Pressure is always low
Diagram showing artery, vein and capillary bed

23. Note that blood vessel names reflect the direction of flow, NOT the amount of oxygen in the blood
Arteries carry blood AWAY from the heart
Arterial blood is always under pressure
It is NOT always oxygenated
Veins carry blood TO the heart
Diagram of blood circulation pattern in humans

24. Capillary beds facilitate exchange
Capillary beds separate arteries from veins
Highly branched and very tiny
Infiltrate all tissues in the body
More later
Diagram showing artery, vein and capillary bed

25. All vertebrates have a closed circulatory system – REVIEW
Chambered heart pumps blood
Atria receive blood
Ventricles pump blood
Vessels contain the blood
Veins carry blood to atria
Arteries carry blood from ventricles
Capillary beds facilitate exchange
Capillary beds separate arteries from veins
Highly branched and very tiny
Infiltrate all tissues in the body

26. Evolution of double circulation – not all animals have a 4-chambered heart
Diagram showing progression from a 1-chambered heart to a 4-chambered heart. This diagram is used in the next 12 slides.

27. Fishes have a 2-chambered heart
One atrium, one ventricle
A single pump of the heart circulates blood through 2 capillary beds in a single circuit
Blood pressure drops as blood enters the capillaries (increase in cross-sectional area of vessels)
Blood flow to systemic capillaries and back to the heart is very slow
Flow is increased by swimming movements

28. Two circuits increases the efficiency of gas exchange = double circulation
One circuit goes to exchange surface
One circuit goes to body systems
Both under high pressure – increases flow rate

29. Amphibians have a 3-chambered heart
Two atria, one ventricle
Ventricle pumps to 2 circuits
One circuit goes to lungs and skin to release CO2 and acquire O2
The other circulates through body tissues
Oxygen rich and oxygen poor blood mix in the ventricle
A ridge helps to direct flow
Second pump increases the speed of O2 delivery to the body

30. Most reptiles also have a 3-chambered heart
A partial septum further separates the blood flow and decreases mixing
Crocodilians have a complete septum
Point of interest: reptiles have two arteries that lead to the systemic circuits
Arterial valves help direct blood flow away from pulmonary circuit when animal is submerged

31. Critical Thinking
What is a disadvantage of a 3 chambered heart???

32. Critical Thinking
What is a disadvantage of a 3 chambered heart???

33. Mammals and birds have 4-chambered hearts
Two atria and two ventricles
Oxygen rich blood is completely separated from oxygen poor blood
No mixing  much more efficient gas transport
Efficient gas transport is essential for both movement and support of endothermy
Endotherms use 10-30x more energy to maintain body temperatures

34. Mammals and birds have 4-chambered hearts
Mammals and birds are NOT monophyletic
What does this mean???

35. Mammals and birds have 4-chambered hearts
Mammals and birds are NOT monophyletic
Phylogenetic tree showing the diversification of vertebrates

36. Mammals and birds have 4-chambered hearts
Mammals and birds are NOT monophyletic
Four-chambered hearts evolved independently
What’s this called???

37. Mammals and birds have 4-chambered hearts
Mammals and birds are NOT monophyletic
Four-chambered hearts evolved independently

38. Review: evolution of double circulation

39. Blood Circulation Blood vessels are organs Arteries have thicker walls
Outer layer is elastic connective tissue
Middle layer is smooth muscle and elastic fibers
Inner layer is endothelial tissue
Arteries have thicker walls
Capillaries have only an endothelium and basement membrane

40. Critical Thinking Arteries have thicker walls than veins
Capillaries have only an endothelium and basement membrane
What is the functional significance of this structural difference???

41. Critical Thinking Arteries have thicker walls than veins
Capillaries have only an endothelium and basement membrane
What is the functional significance of this structural difference???

42. Form reflects function…
Arteries are under more pressure than veins
Capillaries are the exchange surface
Diagram showing artery, vein and capillary bed

43. Blood pressure and velocity drop as blood moves through capillaries
Graph showing relationships between blood pressure, blood velocity, and the cross-sectional area of different kinds of blood vessels – arteries to capillaries to veins. This same graph is on the next 3 slides.

44. Total cross-sectional area in capillary beds is much higher than in arteries or veins; slows flow

45. Velocity increases as blood passes into veins (smaller cross-sectional area); pressure remains dissipated

46. One-way valves and body movements force blood back to right heart atrium

47. Critical Thinking
What makes rivers curl on the Coastal Plain???

48. Critical Thinking
What makes rivers curl on the Coastal Plain???

49. Emphasize the difference between velocity and pressure
Emphasize the difference between velocity and pressure!!! Velocity increases in the venous system; pressure does NOT

50. Capillary Exchange
Gas exchange and other transfers occur in the capillary beds
Muscle contractions determine which beds are “open”
Brain, heart, kidneys and liver are generally always fully open
Digestive system capillaries open after a meal
Skeletal muscle capillaries open during exercise
etc…

51. Bed fully open Bed closed, through-flow only Note scale – capillaries are very tiny!!
Diagram showing sphincter muscle control over capillary flow. Micrograph of a capillary bed.

52. Capillary Transport Processes:
Endocytosis  exocytosis across membrane
Diffusion based on electrochemical gradients
Bulk flow between endothelial cells
Water potential gradient forces solution out at arterial end
Reduction in pressure draws most (85%) fluid back in at venous end
Remaining fluid is absorbed into lymph, returned at shoulder ducts

53. Capillary Transport Processes:
Endocytosis  exocytosis across membrane
Diffusion based on concentration gradients
Bulk flow between endothelial cells
Water potential gradient forces solution out at arterial end
Reduction in pressure draws most (85%) fluid back in at venous end
Remaining fluid is absorbed into lymph, returned at shoulder ducts

54. Bulk Flow in Capillary Beds
Remember water potential: Ψ = P – s
Remember that in bulk flow P is dominant
No membrane
Plus, in the capillaries, s is ~stable (blood proteins too big to pass)
P changes due to the interaction between arterial pressure and the increase in cross-sectional area

55. Bulk Flow in Capillary Beds Remember: Ψ = P – s
Diagram showing osmotic changes across a capillary bed

56. Capillary Transport Processes:
Endocytosis  exocytosis across membrane
Diffusion based on concentration gradients
Bulk flow between endothelial cells
Water potential gradient forces solution out at arterial end
Reduction in pressure draws most (85%) fluid back in at venous end
Remaining fluid is absorbed into lymph, returned at shoulder ducts

57. Blood structure and function
Blood is ~55% plasma and ~45% cellular elements
Plasma is ~90% water
Cellular elements include red blood cells, white blood cells and platelets

58. Blood Components
Chart listing all blood components – both liquid and cellular

59. Plasma Solutes – 10% of plasma volume
Inorganic salts that maintain osmotic balance, buffer pH to 7.4, contribute to nerve and muscle function
Concentration is maintained by kidneys
Proteins
Also help maintain osmotic balance and pH
Escort lipids (remember, lipids are insoluble in water)
Defend against pathogens (antibodies)
Assist with blood clotting
Materials being transported
Nutrients
Hormones
Respiratory gasses
Waste products from metabolism

60. Cellular Elements Red blood cells, white blood cells and platelets
Red blood cells carry O2 and some CO2
White blood cells defend against pathogens
Platelets promote clotting

61. Red Blood Cells Most numerous of all blood cells
5-6 million per mm3 of blood!
25 trillion in the human body
Biconcave shape
No nucleus, no mitochondria
They don’t use up any of the oxygen they carry!
250 million molecules of hemoglobin per cell
Each hemoglobin can carry 4 oxygen molecules
More on hemoglobin later…
Produce ATP by glycolysis

62. Critical Thinking
Tiny size and biconcave shape do what???

63. Critical Thinking
Tiny size and biconcave shape do what???

64. White Blood Cells All function in defense against pathogens
We will cover extensively in the chapter on immune systems

65. Platelets Small fragments of cells Formed in bone marrow
Function in blood clotting at wound sites

66. The Clotting Process
Diagram showing the clotting process

67. Blood Cell Production
Blood cells are constantly digested by the liver and spleen
Components are re-used
Pluripotent stem cells produce all blood cells
Feedback loops that sense tissue oxygen levels control red blood cell production
Diagram showing blood cell production from stem cells in bone marrow
Fig 42.16, 7th ed

68. Key Concepts: Circulation and gas exchange – why?
Circulation – spanning diversity
Hearts – the evolution of double circulation
Blood circulation and capillary exchange
Blood structure and function
Gas exchange – spanning diversity
Breathing – spanning diversity
Respiratory pigments

69. Hands On Dissect out the circulatory system of your rat
Start by clearing the tissues around the heart
Be especially careful at the anterior end of the heart – this is where the major blood vessels emerge
Trace the aorta, the vena cava, and as many additional vessels as possible – use your manual and lab handout for direction!

70. Hands On Feel and describe the texture of the atria vs. the ventricles
Take cross sections of the heart through both the atria and the ventricles
Examine under the dissecting microscope
Do the same with aorta and vena cava
Try for a thin enough section to look at under the compound microscope too

71. Gas Exchange Gas Exchange ≠ Respiration ≠ Breathing
Gas exchange = delivery of O2; removal of CO2
Respiration = the metabolic process that occurs in mitochondria and produces ATP
Breathing = ventilation to supply the exchange surface with O2 and allow exhalation of CO2

72. Diagram showing indirect links between external environment, respiratory system, circulatory system and tissues.

73. Gas Exchange Occurs at the Respiratory Surface
Respiratory medium = the source of the O2
Air for terrestrial animals – air is 21% O2 by volume
Water for aquatic animals – dissolved O2 varies base on environmental conditions, especially salinity and temperature; always lower than in air

74. Gas Exchange Occurs at the Respiratory Surface
Respiratory surface = the site of gas exchange
Gasses move by diffusion across membranes
Gasses are always dissolved in the interstitial fluid
Surface area is important!

75. Evolution of Gas Exchange Surfaces
Skin
Must remain moist – limits environments
Must maintain functional SA / V ratio – limits 3D size
Gills
Large SA suspended in water
Tracheal systems
Large SA spread diffusely throughout body
Lungs
Large SA contained within small space

76. Skin Limits
Sponges, jellies and flatworms rely on the skin as their only respiratory surface

77. Evolution of Gas Exchange Surfaces
Skin
Must remain moist – limits environments
Must maintain functional SA / V ratio – limits 3D size
Gills
Large SA suspended in water
Tracheal systems
Large SA spread diffusely throughout body
Lungs
Large SA contained within small space

78. Invertebrate Gills Dissolved oxygen is limited
Behaviors and structures increase water flow past gills to maximize gas exchange
Diagrams and photos of gills in different animals.
Fig 42.20, 7th ed

79. Countercurrent Exchange in Fish Gills
Direction of blood flow allows for maximum gas exchange – maintains high gradient
Diagram of countercurrent exchange in fish gills
Fig 42.21, 7th ed

80. How countercurrent flow maximizes diffusion
Figure showing countercurrent vs co-current flow effects on diffusion

81. Evolution of Gas Exchange Surfaces
Skin
Must remain moist – limits environments
Must maintain functional SA / V ratio – limits 3D size
Gills
Large SA suspended in water
Tracheal systems
Large SA spread diffusely throughout body
Lungs
Large SA contained within small space

82. Tracheal Systems in Insects
Air tubes diffusely penetrate entire body
Small openings to the outside limit evaporation
Open circulatory system does not transport gasses from the exchange surface
Body movements ventilate
Diagram and micrograph of insect tracheal system.

83. Tracheal Systems in Insects Rings of chitin Look familiar???

84. Critical Thinking
Name 2 other structures that are held open by rings

85. Name 2 other structures that are held open by rings
Critical Thinking
Name 2 other structures that are held open by rings

86. Evolution of Gas Exchange Surfaces
Skin
Must remain moist – limits environments
Must maintain functional SA / V ratio – limits 3D size
Gills
Large SA suspended in water
Tracheal systems
Large SA spread diffusely throughout body
Lungs
Large SA contained within small space

87. Lungs in Spiders, Terrestrial Snails and Vertebrates
Large surface area restricted to small part of the body
Single, small opening limits evaporation
Connected to all cells and tissues via a circulatory system
Dense capillary beds lie directly adjacent to respiratory epithelium
In some animals, the skin supplements gas exchange (amphibians)

88. Mammalian Lungs
Highly branched system of tubes – trachea, bronchi, and bronchioles
Each ends in a cluster of “bubbles” – the alveoli
Alveoli are surrounded by capillaries
This is the actual site of gas exchange
Huge surface area (100m2 in humans)
Rings of cartilage keep the trachea open
Epiglottis directs food to esophagus

89. Figure and micrograph of lung and alveolus structure.

90. Mammalian Lungs
Highly branched system of tubes – trachea, bronchi, and bronchioles
Each ends in a cluster of “bubbles” – the alveoli
Alveoli are surrounded by capillaries
This is the actual site of gas exchange
Huge surface area (100m2 in humans)
Rings of cartilage keep the trachea open
Epiglottis directs food to esophagus

91. Figure of vascularized alveolus

92. Mammalian Lungs
Highly branched system of tubes – trachea, bronchi, and bronchioles
Each ends in a cluster of “bubbles” – the alveoli
Alveoli are surrounded by capillaries
This is the actual site of gas exchange
Huge surface area (100m2 in humans)
Rings of cartilage keep the trachea open
Epiglottis directs food to esophagus

93. Breathing Ventilates Lungs
Positive pressure breathing – amphibians
Air is forced into trachea under pressure
Mouth and nose close, muscle contractions force air into lungs
Relaxation of muscles and elastic recoil of lungs force exhalation

94. Breathing Ventilates Lungs
Positive pressure breathing – amphibians
Air is forced into trachea under pressure
Mouth and nose close, muscle contractions force air into lungs
Relaxation of muscles and elastic recoil of lungs force exhalation
Negative pressure breathing – mammals
Air is sucked into trachea under suction
Circuit flow breathing – birds
Air flows through entire circuit with every breath

95. Negative Pressure Breathing
Diagram of negative pressure breathing

96. Breathing Ventilates Lungs
Positive pressure breathing – amphibians
Air is forced into trachea under pressure
Mouth and nose close, muscle contractions force air into lungs
Relaxation of muscles and elastic recoil of lungs forces exhalation
Negative pressure breathing – mammals
Air is sucked into trachea under suction
Circuit flow breathing – birds
Air flows through entire circuit with every breath

97. Flow Through Breathing
No residual air left in lungs
Every breath brings fresh O2 past the exchange surface
Higher lung O2 concentration than in mammals
Diagram of circuit flow breathing in birds

98. Critical Thinking
What is the functional advantage of flow-through breathing for birds???

99. Critical Thinking
What is the functional advantage of flow-through breathing for birds???

100. Respiratory pigments – tying the two systems together
Respiratory pigments are proteins that reversibly bind O2 and CO2
Circulatory systems transport the pigments to sites of gas exchange
O2 and CO2 molecules bind or are released depending on gradients of partial pressure

101. Partial Pressure Gradients Drive Gas Transport
Atmospheric pressure at sea level is equivalent to the pressure exerted by a column of mercury 760 mm high = 760 mm Hg
This represents the total pressure that the atmosphere exerts on the surface of the earth
Partial pressure is the percentage of total atmospheric pressure that can be assigned to each component of the atmosphere

102. Atmospheric pressure at sea level is equivalent to the pressure exerted by a column of mercury 760 mm high = 760 mm Hg (29.92” of mercury)

103. Partial Pressure Gradients Drive Gas Transport
Atmospheric pressure at sea level is equivalent to the pressure exerted by a column of mercury 760 mm high = 760 mm Hg
This represents the total pressure that the atmosphere exerts on the surface of the earth
Partial pressure is the percentage of total atmospheric pressure that can be assigned to each component of the atmosphere

104. Partial Pressure Gradients Drive Gas Transport
Each gas contributes to total atmospheric pressure in proportion to its volume % in the atmosphere
Each gas contributes a part of total pressure
That part = the partial pressure for that gas
The atmosphere is 21% O2 and 0.03% CO2
Partial pressure of O2 is 0.21x760 = 160 mm Hg
Partial pressure of CO2 is x760 = 0.23 mm Hg

105. Partial Pressure Gradients Drive Gas Transport
Each gas contributes to total atmospheric pressure in proportion to its volume % in the atmosphere
Each gas contributes a part of total pressure
That part = the partial pressure for that gas
The atmosphere is 21% O2 and 0.03% CO2
Partial pressure of O2 is 0.21x760 = 160 mm Hg
Partial pressure of CO2 is x760 = 0.23 mm Hg

106. Partial Pressure Gradients Drive Gas Transport
Atmospheric gasses dissolve into water in proportion to their partial pressure and solubility in water
Dynamic equilibriums can eventually develop such that the PP in solution is the same as the PP in the atmosphere
This occurs in the fluid lining the alveoli

107. Critical Thinking
If a dynamic equilibrium exists in the alveoli, will the partial pressures be the same as in the outside atmosphere???

108. Critical Thinking
If a dynamic equilibrium exists in the alveoli, will the partial pressures be the same as in the outside atmosphere???

109. Inhaled air PP’s = atmospheric PP’s
Diagram showing partial pressures of gasses in various parts of the body. This diagram is used in the next 3 slides.
Inhaled air PP’s = atmospheric PP’s
Alveolar PP’s reflect mixing of inhaled and exhaled air
Lower PP of O2 and higher PP of CO2 than in atmosphere

110. O2 and CO2 diffuse based on gradients of partial pressure
Blood PP’s reflect supply and usage
Blood leaves the lungs with high PP of O2
Body tissues have lower PP of O2 because of mitochondrial usage
O2 moves from blood to tissues

111. Same principles with CO2
Blood leaves the lungs with low PP of CO2
Body tissues have higher PP of CO2 because of mitochondrial production
CO2 moves from tissues to blood

112. When blood reaches the lungs the gradients favor diffusion of O2 into the blood and CO2 into the alveoli

113. Oxygen Transport Oxygen is not very soluble in water (blood)
Oxygen transport and delivery are enhanced by binding of O2 to respiratory pigments
Diagram of hemoglobin structure and how it changes with oxygen loading. This diagram is used in the next 3 slides.
Fig 42.28, 7th ed

114. Oxygen Transport Increase is 2 orders of magnitude!
Almost 50 times more O2 can be carried this way, as opposed to simply dissolved in the blood

115. Oxygen Transport
Most vertebrates and some inverts use hemoglobin for O2 transport
Iron (in heme group) is the binding element

116. Oxygen Transport
Four heme groups per hemoglobin, each with one iron atom
Binding is reversible and cooperative

117. Critical Thinking Binding is reversible and cooperative
What does that mean???

118. Critical Thinking Binding is reversible and cooperative
What does that mean???

119. Oxygen Transport Reverse occurs during unloading
Release of one O2 induces shape change that speeds up the release of the next 3

120. Oxygen Transport
More active metabolism (ie: during muscle use) increases unloading
Note steepness of curve
O2 is unloaded quickly when metabolic use increases
Graph showing how hemoglobin oxygen saturation changes with activity.

121. Oxygen Transport – the Bohr Shift
Graph showing the Bohr Shift
More active metabolism also increases the release of CO2
Converts to carbonic acid, acidifying blood
pH change stimulates release of additional O2
Fig 42.29, 7th ed

122. Carbon Dioxide Transport
Figure showing how carbon dioxide is transported from tissues to lungs. This figure is used in the next 3 slides.
Red blood cells also assist in CO2 transport
7% of CO2 is transported dissolved in plasma
23% is bound to amino groups of hemoglobin in the RBC’s
70% is converted to bicarbonate ions inside the RBC’s

123. Carbon Dioxide Transport
CO2 in RBC’s reacts with water to form carbonic acid (H2CO3)
H2CO3 dissociates to bicarbonate (HCO3-) and H+

124. Carbon Dioxide Transport
Most H+ binds to hemoglobin
This limits blood acidification
HCO3- diffuses back into plasma for transport

125. Carbon Dioxide Transport
Reverse occurs when blood reaches the lungs
Conversion back to CO2 is driven by diffusion gradients as CO2 moves into the lungs

126. REVIEW – Key Concepts: Circulation and gas exchange – why?
Circulation – spanning diversity
Hearts – the evolution of double circulation
Blood circulation and capillary exchange
Blood structure and function
Gas exchange – spanning diversity
Breathing – spanning diversity
Respiratory pigments

127. Hands On Dissect out the respiratory system of your rat
Trace the trachea into the lungs
Examine trachea and lungs under the dissecting microscope
Try for thin enough sections to also examine with the compound microscope