12 The Transport of O2 and CO2 in the Blood

Question 1

Red blood cells

• Function
• Hemoglobin
• Importance of hemoglobin

Answer 1

• Function
  
  • Transfer of O2 from lungs to tissue and CO2 from tissue to lungs
• Hemoglobin
  
  • A molecule in the RBC used to overcome the poor dissolving capability of O2
  • Necessary to deliver O2
    
    • O2 dissolves poorly in the plasma
• Importance of hemoglobin
  
  • When there’s O2 in the lungs, it diffuses across alveolar capillary membrane into the RBC
  • O2 binds to hemoglobin molecules
  • O2 bound to the hemoglobin molecules is transported through the bloodstream to the tissues
  • In the tissues, where the O2 tension is lower, O2 is released from the hemoglobin
  • O2 diffuses out into the tissues

Question 2

Hemoglobin structure and function

• Structure allows…
• 2 parts
• Synthesis

Answer 2

• Structure allows
  
  • Cooperative binding to bind in the lung and release it in capillaries
• 2 parts
  
  • Heme moiety
    
    • Protoporphyrin ring with an iron atom in center
  • 4 globin chains
    
    • 2 alpha
    • 2 beta
• Synthesis
  
  • Synthesized in the bone marrow and reticulocytes
  • Bone marrow is taken in by cells
  • Transferrin has iron bound to it
  • Some iron is transferred to ferritin
  • Iron is taken into the mitochondria where some molecules are being formed into the protoporphyrin ring
  • Iron binds to the ring and is excreted from the mitochondria in the plasma reticulum
  • Alpha and beta chains are generated in the cytoplasm
  • Chains come together to form hemoglobin

Question 3

Cooperativity

Answer 3

• First oxygen binds to Fe in heme of Hb
  
  • Fe is drawn into the plane of the porphyrin ring
• Conformational changes that are transmitted to adjacent subunits
  
  • “Allosteric regulation”
• Increases adjacent subunits’ affinity for O2

Question 4

Cooperativity and oxyhemoglobin curve

• Cooperativity allows for…
• Oxygen-hemoglobin dissociation curve
• Shifts in the curve
  
  • Normal position of curve depends on…
  • Right shift
  • Left shift

Answer 4

• Cooperativity allows for…
  
  • Rapid loading and unloading of oxygen
• Oxygen-hemoglobin dissociation curve
  
  • Measures cooperativity
  • Sigmoid shape
• Shifts in the curve
  
  • Normal position of curve depends on…
    
    • Concentration of 2,3-DPG
    • H+ ion concentration (pH)
    • CO2 in RBCs
  • Right shift
    
    • Decreased oxygen affinity
    • High 2,3-DPG
    • High H+ (low pH, acidic)
  • Left shift
    
    • Increased oxygen affinity
    • Low 2,3-DPG
    • Low H+ (high pH, basic)

Question 5

Arterial oxygen content

• Major function of the cardiovascular and respiratory systems
• Oxygen is transported in the blood in two ways
• The amount of oxygen carried in each form is dependent on…

Answer 5

• Major function of the cardiovascular and respiratory systems
  
  • Provide an adequate amount of oxygen to the tissues
  • Failure to accomplish this goal results in tissue hypoxia
• Oxygen is transported in the blood in two ways
  
  • (1) In physical solution in the plasma as dissolved oxygen
  • (2) In chemical combination with hemoglobin (HbO2)
• The amount of oxygen carried in each form is dependent on…
  
  • The partial pressure of oxygen (PaO2) to which each medium is exposed

Question 6

Arterial oxygen content:
Dissolved oxygen

• The amount of oxygen transported as dissolved oxygen in blood (at 37OC) is defined by the equation
• The relationship between dissolved oxygen and the partial pressure of oxygen in the blood

Answer 6

• The amount of oxygen transported as dissolved oxygen in blood (at 37OC) is defined by the equation
  
  • Dissolved oxygen (ml O2/100 ml blood) = 0.003 x PaO2
• The relationship between dissolved oxygen and the partial pressure of oxygen in the blood
  
  • Linear
  • Low oxygen carrying capacity
  • That is, the amount of dissolved oxygen is directly proportional to the PaO2, regardless of the value

Question 7

Arterial oxygen content:
Combined with hemoglobin

• Hemoglobin
• The relationship between the hemoglobin saturation (SaO2) and the PaO2
• The relationship between the partial pressure of oxygen in arterial blood and the saturation of hemoglobin is influenced by…

Answer 7

• Hemoglobin
  
  • Major means of transporting oxygen in the blood
  • When completely saturated with oxygen, one gram of hemoglobin is capable of carrying 1.34 ml of O2
    
    • 1.34 ml O2 / 100 ml blood x [Hgb] x %sat
  • ​High oxygen carrying capacity
• The relationship between the hemoglobin saturation (SaO2) and the PaO2
  
  • Defined by the oxy-hemoglobin association curve shown below
    
    • Non-linear relationship
  • Relatively steep portion between a partial pressure of oxygen in the range of 10-50 mmHg
  • Relatively flat portion in the range > 70 mmHg
• The relationship between the partial pressure of oxygen in arterial blood and the saturation of hemoglobin is influenced by…
  
  • pH
  • Temperature
  • Concentration of inorganic phosphates, such as 2,3-diphosphoglycerate (2,3-DPG)

Question 8

Arterial oxygen content:
Combined with hemoglobin

• Relationship between the partial pressure of oxygen and the hemoglobin saturation is conveniently defined by the P50
• An elevation in temperature…
• More alkaline pH…
• A reduction in the arterial partial pressure of oxygen from a value of 100 mmHg to 70 mmHg…
• Further reductions to the levels typical of tissue oxygen partial pressures (about 40 mmHg) will result in…
• Major form of O2 transport in the blood

Answer 8

• Relationship between the partial pressure of oxygen and the hemoglobin saturation is conveniently defined by the P50
  
  • The PO2 at which hemoglobin is 50% saturated
• An elevation in temperature…
  
  • Shifts the oxyhemoglobin saturation curve to the right
  • Results in an elevation in the P50
• More alkaline pH…
  
  • Shifts the curve to the left
  • Results in a reduction in the P50
• A reduction in the arterial partial pressure of oxygen from a value of 100 mmHg to 70 mmHg…
  
  • Has a minimal impact on the amount of oxygen combined with hemoglobin
• Further reductions to the levels typical of tissue oxygen partial pressures (about 40 mmHg) will result in…
  
  • Significant “unloading” of oxygen at the tissue bed
• Major form of O2 transport in the blood
  
  • Hemoglobin associated O2 transport

Question 9

Oxygen content of arterial blood (CaO2)

• Definition
• Equation
• Ex. a patient with normal body temperature (37OC), a partial pressure of arterial oxygen of 80 mmHg, a corresponding saturation of hemoglobin of 96%, and a blood hemoglobin concentration of 15 g/dl, we can summarize the oxygen content of the blood as follows
  
  • Dissolved oxygen
  • Combined oxygen
  • Total CaO2

Answer 9

• Definition
  
  • Sum of the oxygen carried by hemoglobin and the amount dissolved in plasma
  • Depends mostly on oxygen combined to Hgb
• Equation
  
  • CaO2 (ml O2/dl blood) = [1.34 (ml O2/gram of completely saturated hemoglobin) x Hgb (grams/dl blood) x SaO2/100] + [0.003 (ml O2/mmHg) x PaO2 (mmHg)]
  • CaO2 = Hgb-O2 + dissolved O2 = (1.34 x [Hgb] x % sat) + (0.003 x PO2)
  • CaO2 ≈ 1.34 x [Hgb] x (SaO2 / 100)
• Ex. a patient with normal body temperature (37OC), a partial pressure of arterial oxygen of 80 mmHg, a corresponding saturation of hemoglobin of 96%, and a blood hemoglobin concentration of 15 g/dl, we can summarize the oxygen content of the blood as follows
  
  • Dissolved oxygen
    
    • 80 mmHg x 0.003 ml O2 / mmHg = 0.24 ml O2 / dl blood
  • Combined oxygen
    
    • 1.34 ml of O2 / g Hgb x 15 g Hgb/dl blood x 0.96 = 19.3 ml O2 / dl blood
  • Total CaO2
    
    • 19.54 ml O2 / dl blood

Question 10

Arterial blood oxygen delivery

• The O2 provided to each organ
• Total oxygen delivery (DO2)
• Required to convert CaO2 into ml O2 per liter of blood
• Tissue hypoxia can result from…

Answer 10

• The O2 provided to each organ is the product of…
  
  • The arterial oxygen content
  • The blood flow to that individual organ
• Total oxygen delivery (DO2)
  
  • The product of arterial oxygen content and cardiac output.
  • DO2 (ml O2/min) = CaO2 (ml O2/dl blood) x CO (L/min) x 10 (dl/L)
    
    • ​DO2 = O2 delivery
    • CaO2 = O2 content of arterial blood
    • CO = cardiac output
  • DO2 ≈ CaO2 x CO ≈ 1.34 x [Hgb] x (SaO2 / 100) x CO
• Required to convert CaO2 into ml O2 per liter of blood
  
  • Multiplying by 10
• Tissue hypoxia can result from…
  
  • A reduction in the arterial oxygen content
  • A decrease in tissue blood flow

Question 11

The effects of a 50% reduction in the individual variables associated with tissue oxygen delivery

• Normal
  
  • Tissue oxygen delivery = 1020
  • PaO2 = 100
  • SaO2 = 100
  • Hgb = 15
  • CO = 50
• PaO2 –> 50
• Hgb –> 7.5
• CO –> 25

Answer 11

• Tissue oxygen delivery = 1020
  
  • PaO2 = 100
  • SaO2 = 100
  • Hgb = 15
  • CO = 50
• PaO2 –> 50
  
  • SaO2 –> 87
  • Tissue oxygen delivery –> 882
• Hgb –> 7.5
  
  • Tissue oxygen delivery –> 518
• CO –> 25
  
  • Tissue oxygen delivery –> 510

Question 12

Transport of CO2 in the blood:
The transport of carbon dioxide from actively metabolizing cells to the lungs for excretion involves a number of processes

• In the tissues, CO2 diffuses…
• Once in the blood…
  
  • The majority of the CO2…
  • The remainder…
• CO2 transport in arterial vs. venous blood

Answer 12

• In the tissues, CO2 diffuses along its partial pressure gradient into the plasma
  
  • Diffusion of CO2 from tissue cells
  • 20x more soluble than O2
• Once in the blood…
  
  • The majority of the CO2 enters the red blood cell
  • The remainder stays in the plasma
  • Chemical reactions in the plasma and in RBCs
• CO2 transport in arterial vs. venous blood
  
  • ​Arterial
    
    • Most CO2 is transported as HCO3-
    • ​Very little CO2 is transported as carbamino or dissolved CO2
  • ​Venous
    
    • ​​Still a lot of CO2 is transported as HCO3
    • But a lot more is transported as carbamino or dissolved CO2

Question 13

Transport of CO2 in the blood:
In the plasma, CO2 can be transported in 1 of 3 ways

Answer 13

• Like oxygen, the amount of CO2 dissolved in plasma is relatively small
  
  • Each dl of plasma will carry about 0.067 ml of CO2 for each mmHg PCO2
  • Dissolved carbon dioxide (ml CO2/dl blood) = 0.067 (ml CO2/ mmHg) x PaCO2 (mmHg)
• CO2 can be bound by reactions with plasma proteins to form carbamino compounds
• CO2 can be hydrated in the following reaction:
  
  • CO2 + H2O ⇔ H2CO3 ⇔ H+ + HCO3-
  • This reaction in plasma is relatively slow, since the critical enzyme, carbonic
    anhydrase, is not present

Question 14

RBC CO2 transport

• RBC
• Hydration
• NH2 groups

Answer 14

• CO2 is dissolved in RBC
• Hydration
  
  • ​H2O + CO2 <–> H2CO3 <–> H+ + HCO3-
  • H+ buffered by Hgb / O2 unloaded
  • Bohr effect
  • HCO3- may be carried in the plasma
• NH2 groups of Hg form carbamino groups
  
  • R-NH2 + CO2 <–> R-NHCOO- + H+

Question 15

Transport of CO2 in the blood:
Fates of CO2

• Majority of CO2
• A small quantity of CO2
• Haldane effect
• Bohr effect

Answer 15

• Majority of CO2
  
  • Enters the RBC
• A small quantity of CO2
  
  • Dissolved within the RBC
• Haldane effect
  
  • CO2 can combine directly with hemoglobin to form carbamino groups
  • Formation of these compounds is enhanced by the presence of unsaturated hemoglobin
• Bohr effect
  
  • Since RBCs contain the enzyme carbonic anhydrase, CO2 is readily hydrated to form H+ and HCO3-
  • Most of the bicarbonate moves from the RBC into the plasma, and chloride shifts into the RBCs to maintain electrical neutrality
    
    • This is the main mechanism for CO2 transport in the blood
  • Hemoglobin combines with or buffers the free H+ generated, and this results in a conformational change, which decreases the affinity of hemoglobin for oxygen

Question 16

Bohr effect

Answer 16

• Describes the effect of PCO2 on the affinity of hemoglobin for O2
  
  • In the tissues, PCO2 rises, thereby lowering pH and decreasing the affinity of hemoglobin for O2
  • In the lungs, the reverse occurs as PCO2 falls
• This facilitates the loading of O2 in the lungs and the release of O2 in the tissues

Question 17

Haldane effect

Answer 17

• Describes the effect of PO2 on the affinity of hemoglobin for CO2
• That is, deoxygenated hemoglobin has a greater affinity for CO2 than does oxyhemoglobin
• This results from the enhanced ability of deoxygenated hemoglobin to both form carbamino compounds and to accept the H+ released by the hydration of CO2
• This enhances the ability to load CO2 in the tissues and release it in the lungs

Question 18

Relationship between the Bohr and Haldane effects

• Both
• RBC
  
  • Haldane
  • Bohr
• Tissue
  
  • Haldane
  • Bohr

Answer 18

• Both
  
  • Important reactions that are complimentary and facilitate oxygen and carbon dioxide exchange in the tissues and the lungs
• RBC
  
  • Haldane
    
    • Hgb oxygenation facilitates CO2 unloading
  • Bohr
    
    • Decreased CO2 facilitates O2 loading
• Tissue
  
  • Haldane
    
    • Unoxygenated Hgb facilitates CO2 loading
  • Bohr
    
    • Increased CO2 facilitates O2 unloading

Question 19

O2 vs. CO2 carrier systems

• O2 carrier system
• CO2 carrier system
• PaCO2 and CO2

Answer 19

• The oxygen carrier system (hemoglobin) is readily saturated once a critical partial pressure of oxygen is achieved (> 60 mm Hg)
• In contrast, the multiple carrier systems for CO2 in the blood assure that saturation of the carrier system does not occur even in the presence of significant anemia
• PaCO2 and CO2 content are nearly linearly related over the entire physiologic range

Question 20

Clinical applications:
Hemoglobin saturation

Answer 20

• Main way we can figure out how much O2 content there is
• O2 + Hgb <–> Hgb-O2
• Measured by ABG and optical sensors
• Calculation
  
  • (O2 combined with Hgb) / (O2 capacity to combine with Hgb) x 100

Question 21

Pulse oximeter

Answer 21

• Absorption spectra of oxyhemoglobin and deoxyhemoglobin differ
• Oxyhemoglobin
  
  • Lower absorption of the 660 nm wavelength
  • Higher absorption of the 940 nm wavelength
• Ratio of absorption at these different wavelengths is used for measurement

Question 22

Clinical applications of SaO2

• Diagnostically
• Safety monitoring

Answer 22

• Diagnostically
  
  • Sleep apnea
  • Screen for lung or cardiac disease
• Safety monitoring
  
  • Hospital - ICU and operating rooms
  • At home - monitor chronic disease

Question 23

Physiologic examples

• Exercise at sea level
• Breathing at 12,000 ft

Answer 23

• Exercise at sea level
  
  • Muscle generate acid –> rightward shift in the curve
  • Oxygen released more effectively at the tissues
• Breathing at 12,000 ft
  
  • ~490 torr –> PAO2 ~43
  • What do you do
    
    • Hyperventilate –> decrease CO2
    • Alkalosis –> shifts O2 dissociation curve to the left
      
      • Allows saturation of hemoglobin at lower PaO2 levels

Question 24

Key points

• Hemoglobin allows for…
• DO2 ≈
• CO2 transport depends mostly on…
• Bohr and Haldane effects explain…

Answer 24

• Hemoglobin allows for enriched carrying capacity of oxygen in the blood
• DO2 ≈ 1.34 X Hgb X (SaO2/100) X CO
• CO2 transport depends mostly on the erythrocyte
• **Bohr and Haldane effects explain the interaction between O2 / CO2 transport **