Chapter 6

Question 1

How many Heme Sites Does Hemoglobin Have?

Answer 1

4

Question 2

How many chains does Globin have that can undergo Mutations?

Answer 2

• Two a Chains
• Two b Chains

Question 3

What is Ferrous Iron? What happens when it is Oxidized?

Answer 3

Ferrous Iron
- Found on Adult hemoglobin A
Oxidized
- Becomes Ferric Iron
- Release of Oxygen to tissue is impaired

Question 4

What does Fetal Hemoglobin F have? What does it help with?

Answer 4

Has
- High Oxygen Affinity
Use
- Helps Fetus tolerate hypoxic environment in Utero

Question 5

What does Dissolved Oxygen Obey?

Answer 5

Henry’s Law

Question 6

What is Henry’s Law?

Answer 6

• The amount of gas dissolved is proportional to the partial pressure

Question 7

What is the ratio of O2 dissolved in 100ml of blood to PO2?

Answer 7

For each mmHg of PO2, 0.003ml O2 dissolved per 100ml of blood.

Question 8

What is the normal arterial O2 Content?

Answer 8

0.3ml O2/100ml

Question 9

What is the amount of dissolved O2 in Normal Arterial Blood with a Q= 50L/min?

Answer 9

0.3ml O2/100ml (normal Arterial Blood)
3ml/1L x 50L/min = 150ml/min O2

Question 10

What is O2 Capacity?

Answer 10

• The maximum amount of O2 that can be combined with Hb.

Question 11

How much O2 can 1g of Hb combine with?

Answer 11

1.39ml O2

Question 12

How much Hb does normal blood have?

Answer 12

• 15g of Hb/ 100ml

Question 13

What is the O2 Capacity of Blood?

Answer 13

• 20.8ml O2/ 100ml blood

Question 14

What is the equation for O2 Saturation of Hb?

Answer 14

O2 Saturation of Hb = ((O2-Hb) / O2 Capacity) x 100

Question 15

What is the normal SaO2 of Arterial Blood?

Answer 15

• 97.5%

Question 16

What is the normal SaO2 of Venous Blood?

Answer 16

• 75%

Question 17

What is the Equation to find the O2 Concentration of Blood (ml O2 / 100ml Blood)?

Answer 17

(1.39 x Hb x Sat/100) + 0.003Po2

Question 18

What are the 5 steps that the Oxygen Transport System Cycles Between?

Answer 18

• Pulmonary Ventilation
• Hemoglobin Concentration
• Blood Volume and Cardiac Output
• Peripheral Blood Flow
• Aerobic Metabolism

Question 19

What is the Equation for identifying VO2? (Oxygen Usage)

Answer 19

VO2 = Q x a-vO2 difference

Question 20

What are the Useful Anchor Points of the Oxygen Dissociation Curve?

Answer 20

1. PO2 40 has a SO2 of 75%
2. PO2 100 has a SO2 of 97%
3. P50 has a PO2 of 27 and SO2 of 50%

Question 21

What causes the Oxygen Dissociation Curve to shift to the Right?

Answer 21

• Increase in Temperature
• Increase in PCO2
• Increase in H+
• Increase in 2,3 DPG

Question 22

What does a Right Shift in the Oxygen Dissociation Curve mean?

Answer 22

• Lower Oxygen Affinity
• Allows for more Oxygen to be delivered to the Tissue

Question 23

What does small additions of CO to blood do to the Oxygen Dissociation Curve?

Answer 23

• Shifts it left (impairs offloading of oxygen)

Question 24

What are the three ways CO2 is transported in the Blood?

Answer 24

• Bicarbonate
• Carbamino
• Dissolved

Question 25

What are the percentages of CO2 carried in Arterial Blood?

Answer 25

• 90% in Bicarbonate (HCO3-)
• 5% in Carbamino
• 5% in Dissolved

Question 26

What are the percentages of CO2 carried in Mixed-Venous Blood?

Answer 26

• 60% in Bicarbonate (HCO3-)
• 30% in Carbamino
• 10% is Dissolved

Question 27

What does the Bicarbonate Reaction depend on?

Answer 27

• Carbonic Anhydrase in the Red Cell (an enzyme)

Question 28

What enhances the CO2 carriage in the form of Carbaminohemoglobin?

Answer 28

• Deoxygenation of the blood

Question 29

How is the CO2 curve shaped in relation to the O2 Curve?

Answer 29

• Steeper and more linear

Question 30

What shifts the CO2 dissociation curve to the right?

Answer 30

• An increase in SO2 (Haldane Effect)

Question 31

What is the Haldane Effect?

Answer 31

Haldane Effect
- Deoxygenated Hemoglobin can carry more CO2

Question 32

How much more soluble is CO2 than O2?

Answer 32

20x

Question 33

What are the steps in CO2 being changed to Bicarbonate?

Answer 33

CO2 + H20 –(CA)– H2CO3 — H+ + HCO3-
1. Slow, in Plasma. Fast in Red Blood Cell because of Carbonic Anhydrase (CA) enzyme.
2. Dissociation of Carbonic Acid, Fast without enzyme

Question 34

What happens when Ions Rise within the RBC?

Answer 34

• HCO3- diffuses out, but H+ cannot.

Question 35

How does the RBC maintain electrical Neutrality after CO2 converts to Bicarbonate?

Answer 35

– Cl- ions move into the cell from plasma to offset the H+ buildup
– Called the Chloride Shift

Question 36

How does the product of H+ from the CO2 to Bicarbonate reaction help with CO2 offloading?

Answer 36

• H+ ions bind to hemoglobin and reduce it
• Reduced hemoglobin contributes to the Haldane Effect, which helps with offloading of CO2

Question 37

What is the Reaction that causes CO2 to become part of a Carbamino Compound?

Answer 37

Hb.NH2 + CO2 — Hb.NH.COOH
- CO2 combines with a Terminal Amine Group of Blood PRotein

Question 38

Describe the Reaction of CO2 and a Terminal Amine Group of Blood Protein.

Answer 38

• Product is a Carbamino Compound
• Occurs rapidly without an enzyme
• Reduced Hb can bind with more CO2 as Carbamino-hemoglobin than with HbO2
• Unloading of O2 in peripheral capillaries facilitates the loading of CO2, whereas oxygenation has the opposite effect

Question 39

What are the 4 Causes of Primary Acid-Base Abnormalities?

Answer 39

• Respiratory Acidosis
• Respiratory Alkalosis
• Metabolic Acidosis
• Metabolic Alkalosis

Question 40

What are the Causes of Respiratory Acidosis?

Answer 40

• Opiate Overdose
• Severe Chronic Obstructive Pulmonary Disease
• Neuromuscular Disease
• Obesity Hypoventilation Syndrome

Question 41

What are the Causes of Respiratory Alkalosis?

Answer 41

• Anxiety Attack
• High Altitude
• Hypoxemic Lung Disease

Question 42

Metabolic Acidosis

Answer 42

• Lactic Acidosis
• Diabetic, Starvation, or Alcoholic Ketoacidosis
• Uremia
• Renal Tubular Acidosis
• Severe Diarrhea

Question 43

What are the Causes of Metabolic Alkalosis?

Answer 43

• Vomiting
• Loop Diuretics
• Excess Alkali Ingestion
• Hyperaldosteronism

Question 44

What is the Henderson-Hasselbatch Equation?

Answer 44

CO2 + H2O –(CA)– H2CO3 – H+ + HCO3-
- Ka = [H+][A-] / [HA]
- HA = molar concentration of weak acid
- A- = molar concentration of the acid’s conjugate base
- HA = H2CO3
- A-= HCO3-
- pH = pKa + log([HCO3-]/0.03PCO2)

Question 45

What are the physiological changes that cause Respiratory Acidosis?

Answer 45

• Increase in PCO2, which reduces the HCO3-/PCO2 ratio
• Depresses pH
• Body Conserves HCO3- to help stabilize ratio

Question 46

What are the Physiological changes that cause Respiratory Alkalosis?

Answer 46

• Decrease in PCO2
• Increases HCO3-/PCO2 ratio
• Elevates pH
• Body Excretes HCO3- to stabilize ratio (pH)

Question 47

What are the physiological changes that result in Metabolic Acidosis?

Answer 47

• Ratio of HCO3- to PCO2 falls
• Depresses pH
• Body increases VE to lower PCO2 and stabilize pH

Question 48

How does the body regulate Acid-Base ratio?

Answer 48

• Chemical Buffers
• Pulmonary Ventilation
• Renal Function

Question 49

What are some Chemical Buffers used to regulate body pH?

Answer 49

H+ + Buffer — H-Buffer
- Bicarbonate Buffer
- Phosphate Buffer
- Protein Buffer

Question 50

How does the body regulate pH using Ventilation?

Answer 50

Ventilatory Buffer
- increase in ventilation reduces PACO2, which causes CO2 to be blown off, which will accelerate H+ + HCO3-

Question 51

How does the body use kidneys to regulate pH?

Answer 51

• Excretion of H+ by kidneys