D.6 gas transport

Question 1

Haemoglobin

Answer 1

Is a protein in red blood cells

Haemoglobin is composed of four polypeptide chains, each with an iron-containing heme group that reversibly binds oxygen

As each O2 molecule binds, it alters the conformation of haemoglobin, making subsequent binding easier

Question 2

Oxygen affinity

Answer 2

Affinity = the attraction between two things
Represented by dissasociation curve

The more O2 attatched to the haemoglobin, the easier it gets for another one to bind
=> As each O2 molecule binds, it alters the conformation of haemoglobin, making subsequent binding easier

Question 3

Oxygen dissasociation curve

Answer 3

The highest oxygen affinity is in the lungs

Question 4

How is Co2 transported between the lungs and the tissue?

Answer 4

1. Some is bound to haemoglobin to form HbCO2 (binds with globin, NOT heme)
2. A very small fraction gets dissolved in water and is carried in solution
3. 75% diffuses into the erythrocyte and gets converted into carbonic acid

Question 5

Co2 transported as Carbonic Acid

Answer 5

1. Co2 entres erythrocyte and combines with H2O to form carbonic acid (H2CO3)
2. Carbonic acid breaks dissasociates to form H+ and bicarbonate (HCO3–)
3. Bicarbonate is pumped out and chlorine is pumped in
4. Bicarbonate binds with sodium to form sodium bicarbonate, which travels to the lungs
5. H+ makes the erythrocyte more acidic
6. Therefore the haemoglobin releases its O2 and takes H+
7. When the erythrocyte goes back to lungs for reoxygenation, the bicarbonate ions replace the H+
8. Process is then reversed

Question 6

The Bohr Shift

Answer 6

pH alters the release of O2 by Haemogrobin

Carbon dioxide lowers the pH of the blood which causes haemoglobin to release its oxygen
- This is known as the Bohr effect

More Co2 = less pH

Question 7

Chemoreceptors

Answer 7

Chemoreceptors in the carotid bodies and in the brain provide sensory information for the Breathing and Cardiovascular functioning.

Chemoreceptors are highly sensitive to changes in PCO2 and in the pH
- Therfore can cause large increases in respiration

When Chemoreceptors sense a change in PCO2 or a pH
- The body responds by regulating blood flow and breathing

Question 8

Carotid bodies

Answer 8

The point where the carotid artery splits in two, there’s a tiny organ known as the carotid body (CB).

Question 9

PCO2

Answer 9

Measure of carbon dioxide (CO2) within arterial or venous blood.

Question 10

Expiratory movements

Answer 10

The process of an organism’s breath leaving it

Question 11

Inspiratory movements

Answer 11

Air from the outside environment enters the lungs during inspiration

Question 12

Ventral respiratory group

Answer 12

Frequently assumed to have the vital circuitry responsible for producing the basic breathing rhythm.

Stimulates expiratory movements

Question 13

Dorsal respiratory group

Answer 13

Located in the distal part of the medulla.

Peripheral chemoreceptors and other types of receptors provide input to it. Responsible for the basic breathing rhythm.

stimulates inspiratory movements

Question 14

Intercostal Muscles

Answer 14

The muscle groups that run between the ribs and support the formation and movement of the chest wall.

External = contract for inspiration
Internal = contract for expiration

Question 15

Medulla oblongata

Answer 15

Responds to stimuli from chemoreceptors in order to control ventilation

Increases the the frequency of nerve impulses that are sent to the diaphragm and intercostal muscles

Question 16

Ventilation changes due to exercise

Answer 16

1. Metabolism increases during exercise with a build up of carbon dioxide, and reduction of oxygen. Causing pH levels to decrease.
2. These changes are detected by chemoreceptors
3. An impulse is sent to the respiratory control centre in the brainstem (medulla)
4. A signal is then sent to the diaphragm and intercostal muscles from the medulla
5. This increases ventilation
6. As ventilation increases, Co2 levels drop and O2 levels rise
7. This causes pH to raise and restore
8. Long term effects of continual exercise may lead to improved and increased vital capacity

Question 17

Ventilation changes due to exercise

Answer 17

1. Metabolism increases during exercise with a build up of carbon dioxide, and reduction of oxygen. Causing pH levels to increase
2. These changes are detected by chemoreceptors
3. An impulse is sent to the respiratory control centre in the brainstem
4. A signal is then sent to the diaphram and intercostal muscles
5. This increases ventilation
6. As ventilation increases, Co2 levels drop and O2 levels rise
7. This causes pH to raise and restore
8. Long term effects of continual exercise may lead to improved and increased vital capacity

Question 18

Outline the location and role of chemoreceptors that help regulate the ventilation rate.

Answer 18

Chemoreceptors are in the medulla.

They detect lowered body pH from increased respiration, and trigger an increase in ventilation to remove CO2 from the body restoring pH.

Question 19

List the neural structures that control the rate of ventilation.

Answer 19

Medulla oblongata, brain stem

Question 20

Outline the feedback loop that regulates the rate of ventilation, including the role of stretch receptors.

Answer 20

Intercostal nerves make intercostal muscles contract

phrenic nerves stimulate the diaphragm to contract

stretch receptors respond to the lung expanding to send signals that lead to the signal telling the muscles to contract to stop.

Question 21

Describe the relationship between carbon dioxide concentration and blood pH.

Answer 21

Increased CO2 causes Bicarbonate (HCO3-) and H+ ions to form, and H+ ions lower pH. Therefore, higher carbon dioxide concentrations lead to a lower blood pH.

Question 22

State the effect of exercise on CO2 production.

Answer 22

Exercise results in more CO2 production.

Question 23

Outline the relationship between CO2 production and blood pH.

Answer 23

When more CO2 is produced, there is more H+ ions, which lowers the blood pH.

Question 24

Explain how and why hyperventilation occurs in response to exercise.

Answer 24

When exercising, the pH is lowered because of the increased respiration. When pH is low, ventilation increases, resulting in hyperventilation.
- Steps of exercise and relationship to ventilation changes

Question 25

Fetal haemoglobin Vs Adult haemoglobin

Learning Outcome: Fetal haemoglobin is different from adult haemoglobin allowing the transfer of oxygen in the placenta onto the fetal haemoglobin

Answer 25

Fetal. has a different molecular composition than adult haemoglobin

Fetal. has a higher affinity for oxygen
- this ensures that oxygen is transferred from the mother to the fetus across the placenta

Fetal. Is replaced by adult haemoglobin after birth through cycling of RBC

Question 26

Mutation on adult hemoglobin

Answer 26

Fetal haemoglobin production can be pharmacologically induced in adults to treat diseases such as sickle cell anaemia

Sickle cell anemia is on the adult haemoglobin, so fetal haemoglobin is induced to treat the disease

Question 27

Partial pressure

Learning Outcome: Consequences of high altitude for gas exchange

Answer 27

the pressure exerted by a single type of gas when it is found within a mixture of gases

Determined by:
- The concentration of the gas within the mixture
- The total pressure of the mixture

At high altitudes, air pressure is lower and hence there is a lower partial pressure of oxygen

= P(gas)
PO2
PCo2 etc.

Question 28

At higher altitude why is it harder for haemoglobin to take up and transport O2

Answer 28

At higher altitude there is less air pressure;
Therefore → less PO2 for the haemoglobin

Therefore → respiring tissue will receive less oxygen – leading to symptoms such as fatigue, headaches and rapid pulse (acute mountain sickness) (AMS)

Question 29

How does the body adapt to lower oxygen levels?

Answer 29

• increase in red blood cell production (to increase oxygen uptake)
• higher hemoglobin count in RBC (causing a higher oxygen affinity)
• increased vital capacity (improving rate of gas exchange)
• increased myoglobin production and vascularisation in muscles
• kidneys secrete more alkaline urine (removal of excess bicarbonates improves buffering of blood pH)
• people living at higher altitudes have higher lung surface area and chest size (higher SA for absorption)

Question 30

Ideal altitude for althetes training to gain benefits

Answer 30

1500m - 3000m

Question 31

How the body maintains a blood pH of 7.35 to 7.45

Learning Outcome: pH of blood is regulated to stay within the narrow range of 7.35 to 7.45

Answer 31

maintained by plasma proteins that acts as buffers

The buffering solutions resists changes to pH by removing excess H+ ions (↑ acidity) or OH– ions (↑ alkalinity)

Amino acids may have both a positive and negative charge and hence can buffer changes in pH
→ The amine group may take on H+ ions while the carboxyl group may release H+ ions (forms water with OH– ions)

Question 32

Pneumocytes

Answer 32

• Inner surface of the alveolus

Type I: very thin -> mediate gas exchange (via diffusion)

Type II: secretion of pulmonary surfactant -> reducing surface tension

Question 32

Pneumocytes

Answer 32

• Inner surface of the alveolus

Type I: very thin -> mediate gas exchange (via diffusion)

Type II: secretion of pulmonary surfactant -> reducing surface tension

Question 33

Capillary endothelium cells

Answer 33

Surrounded by a dense network of capillaries -> transporting respiratory gases to and from the lungs

Question 34

Blood Cells

Answer 34

Carry oxygen through the bloodstream to the body

Question 35

Electron Micrograph of Lung Tissue

Answer 35

Question 36

Light Micrograph of Lung Tissue

Answer 36

Question 37

Electron Micrograph of Lung Tissue

Answer 37

Question 38

Light Micrograph of Lung Tissue

Answer 38

Question 39

Analyzing a Oxygen Dissociation Curve

Answer 39

Myoglibin has a higher affinity than haemoglobin because it is formed by only one peptide

There is no allosteric effect in the molecule.

Question 40

Emphysema

Answer 40

a lung condition where damage to the alveolar walls causes the the walls of the alveoli to lose their elasticity

Question 41

Emphysema

Answer 41

a lung condition where damage to the alveolar walls causes the the walls of the alveoli to lose their elasticity

Question 42

Cause of Emphysema

Answer 42

Most cases smoking, or caused by a rare hereditary deficiency of elastase due to a gene mutation

Question 43

Smoking leading to emphysema

Could also ask for formation of Pulmonary Bullae

Answer 43

1. Chemical irritants harm the tissue of the alveolar walls
2. Damaged lung tissue triggers phagocytes to the region which produce the elastase
3. Elastase breaks down elastic fibres in the alveolar walls
4. Alveoli become abnormally enlarged due to the loss of elasticity
5. Leading to a lower total surface area for gas exchange
6. Degradation of the alveolar walls causes holes to develop. Alveoli can end up merging into pulmonary bullae

Question 44

Treatments of Emphysema

Answer 44

There is NO cure
* Bronchodilators (puffer)
* Corticosteroids (pill medication)
* Enzyme inhibitor
* Oxygen Supplement - later stage
* Surgery - extreme cases