6.4 Gas exchange

Question 1

What does ventilation maintain?

Answer 1

Ventilation maintains concentration gradients of oxygen and carbon dioxide between air in alveoli and blood flowing in adjacent capillaries

Question 2

What is gas exchange?

Answer 2

The process in which organisms absorb one gas from the environment and release a different one

Question 3

How do humans use gas exchange?

Answer 3

Human absorb oxygen for use in cell respiration and release the carbon dioxide produced by this process

Question 4

Where do gas exchange occur in humans and in terrestrial organisms?

Answer 4

Humans: In small air sacs called alveoli inside the lungs
Terrestrial organisms: exchange gases with the air

Question 5

How does gas exchange happen by?

Answer 5

By diffusion between air in the alveoli and blood flowing in the adjacent capillaries

Question 6

How does the gases only diffuse during gas exchange?

Answer 6

The gases only diffuse because there is a concentration gradient

Question 7

Describe the concentration gradient involving the alveolus and the blood in the capillary?

Answer 7

The air in the alveolus
* higher conc. of oxygen
* Lower conc. of CO2
… compared to the blood in the capillary

Question 8

How do humans maintain the concentration gradient between oxygen and CO2?

Answer 8

• Fresh air must be pumped into the alveoli
• Stale air must be removed
  This process is called ventilation

Question 9

What is the process of maintaining the concentration between oxygen and Co2 called?

Answer 9

Ventilation

Question 10

What are type I pneumocytes?

Answer 10

extremely thin alveolar cells that are adpated to carry out gas exchange

Question 11

What does the lung contain huge numbers of?

Answer 11

Alveoli

Question 12

What is the purpose of having huge numbers of alveoli in the lungs?

Answer 12

For a very large total surface area for diffusion. Diffusion for gas exchange

Question 13

What is the wall of each alveolus consist of?

Answer 13

A thin layer of cells, called the epithelium

Question 14

What type are most of the cells in the epithelium of each alveolus?

Answer 14

Type I pneumocytes

Question 15

What do type I pneumocytes look like?

Answer 15

Flattened cells, with the thickness of only about 0.15 micrometer

Question 16

What do the walls of the adjacent capillaries also consist of?

Answer 16

A single layer of very thin cells
Therefore the air in the alveolus and the blood in the alveolar capillaries are less than 0.5 micrometer apart

Question 17

How does the distance between the air in the alveolus and the blood in the alveolar capillaries affect gas exchange?

Answer 17

The distance over which oxygen and carbon dioide has to diffuse is therefore very small, which is an adaptation to increase the rate of gas exchange

Question 18

What is the adaptation of having a thin layer of cells as the wall for alveolus and capilliaries?

Answer 18

Short diffusion pathways -> increase the rate of gas exchange

Question 19

What are type II pneumocytes?

Answer 19

Rounded cells that occupy about 5% of the alveolar surface area

Question 20

What do type II pneumocytes secrete?

Answer 20

A solution containing surfactant that coats the inner surface of the alveoli

Question 21

What does the film of moisture from the solution secreted by type II pneumocytes allow for?

Answer 21

• Allows oxygen in the alveolus to dissolve and then diffuse to the blood in the alveolar capillaries
• It also provides an area from which carbon dioxide can evaporate into the air and be exhaled

Question 22

What does the fluid secreted by the type II pneumocyte contain?

Answer 22

A pulmonary surfactant

Question 23

What is similar of the molecules in the pulmonary surfactant and phospholipids?

Answer 23

Its molecules have a similar structure with phospholipids in cell membranes .

Question 24

What does the pulmonary surfactant do?

Answer 24

It forms a monolayer on the surface of the moisture lining the alveoli, with the hydrophilic heads facing the water and the hydrophobic tails facing the air.

Question 25

How does surfactant prevent the collapse of the lung?

Answer 25

• reduces the surface tension and prevents the water from causing the sides of the alveoli to adhere when air is exhaled from the lungs
• due to the hydrophilic tails

Question 26

How is the pulmonary surfactant positioned to stop the sides of the alveoli to adhere when air is exhaled from the lung?

Answer 26

The hydrophilic heads facing the water and hydrophobic tails facing the air.

Question 27

What do premature babies suffer from when they are born without insufficient pulmonary surfactant?

Answer 27

Infant respiratory distress syndrome

Question 28

How is infant respiratory distress syndrome treated?

Answer 28

• giving the baby oxygen
• one or more doses of surfactant, extracted from animal lungs

Question 29

Where does air enter the ventilation system?

Answer 29

through the nose or mouth, then passes down the trachea

Question 30

What does the rings of cartilage do in the trachea?

Answer 30

To keep it open even when air pressure inside is low or pressure in surrounding tissues is high

Question 31

What does the trachea divide to form?

Answer 31

Two bronchi, with walls strengthened with cartilage

Question 32

What does one bronchus lead to?

Answer 32

each lung

Question 33

Inside the lung, what do the bronchi do?

Answer 33

They divide repeatedly to form a tree-like strucutre of narrower airways, called bronchioles.

Question 34

What do bronchioles have in their walls?

Answer 34

Smooth muscle fibres, allowing the width of these airways to vary

Question 35

What is found at the end of the narrowest bronchioles?

Answer 35

A group of alveoli, where gas exchange occurs

Question 36

What happens to the pressure when the volume increases or decreases?

Answer 36

Increase volume = decrease pressure
Decreased volume = increased pressure

Question 37

If a gas is free to move, where will it flow from and to?

Answer 37

It will always flow from regions of higher pressure to regions of lower pressure

Question 38

During ventilation, what causes the pressure inside the thorax to drop below atmospheric pressure?

Answer 38

Muscle contractions

Question 39

What is the consequence of muscle contractions during ventilation?

Answer 39

The contraction of respiratory muscles changes the volume of the thoracic cavity (i.e. the chest)

Question 40

What happens when the volume of the thoracic cavity increases and decreases?

Answer 40

Increase = pressure in the thorax decreases
Decrease = pressure in the thorax increases

Question 41

What effect does muscle contractions have during expiration?

Answer 41

They cause the pressure inside the thorax to rise above atmospheric, so air is forced out from the lungs to the atmosphere

When the pressure in the chest is greater than the atmospheric pressure, air will move out of the lungs (expiration)

Question 42

What effect does muscle contractions have during inspiration?

Answer 42

Cause the pressure inside the thorax to drop below atmpspheric pressure and air is drawn into the lungs from the atmosphere

When the pressure in the chest is greater than the atmospheric pressure, air will move out of the lungs (expiration)

Question 43

What effect does muscle contractions have during inspiration?

Answer 43

Cause the pressure inside the thorax to drop below atmpspheric pressure and air is drawn into the lungs from the atmosphere

When the pressure in the chest is greater than the atmospheric pressure, air will move out of the lungs (expiration)

Question 44

Compare the pressure during inspiration and expiration?

Answer 44

• When the pressure in the chest is less than the atmospheric pressure, air will move into the lungs (inspiration)
• When the pressure in the chest is greater than the atmospheric pressure, air will move out of the lungs (expiration)

Question 45

What two states can muscles be in?

Answer 45

Contracting and relaxing

Question 46

How do muscles do work?

Answer 46

When they contract by exerting a pulling force (tension) that causes a particular movement. They become shorter when they do this

Question 47

What happens to muscles when they are relaxing?

Answer 47

Muscles lengthen passively when relaxing - they do not lengthen themselves.
* Most muscles are pulled into an elongated state by the contraction of another muscle - they do no exert a pushing force (compression) while relaxing

Question 48

Why can muscles only cause movement in one direction?

Answer 48

Because the opposite movement is required by a second muscle contracting while the other one relaxes.

Question 49

if movement in opposite directions is needed at different times, what is needed?

Answer 49

Two muscles will be required

Question 50

What is an antagonistic pair of muscles?

Answer 50

When muscles work together for two opposite movements.
* When one muscle contracts and causes a moement, the second muscle relaxes and is elongated by the first.
* The opposite movement is caused by the second muscle contracting while the first relaxes.

Question 51

How are antagonistic pair of muscles related to gas exchange?

Answer 51

Inspiration and expiration involve opposite movements, so different muscles are required, working as antagonistic pairs

Question 52

What are the examples of antagonisitic muscle action in ventilation?

Answer 52

• External and internal intercoastal muscles
• Diaphram and abdominal muscles

Question 53

What do ventilation need two pairs of opposite movements for?

Answer 53

to change the volume. andtherefore the pressure inside the thorax

Question 54

What happens to the diaphram and ribcage during inspiration and expiration?

Answer 54

Question 55

How does volume and pressure change during inspiration and expiration?

Answer 55

Question 56

How does the diaphragm and abdomen wall muscles influence the movement of the diaghragm during inspiration and expiration?

Answer 56

inspiration on left column and expiration on the right

Question 57

How does the external and internal intercostal muscles influence the movement of the ribcage during inspiration and expiration?

Answer 57

inspiration on the left column and expiration on the right

Question 58

What does tobacco smoke contain lots of?

Answer 58

Mutagenic chemicals

Question 59

How does passive smoking cause 3% of lung cancer cases?

Answer 59

This happens when non-smokers inhale tobacco smoke exhaled by smokers

Question 60

How does air pollution probably cause about 5% of lung cancers?

Answer 60

The sources of air pollution that are most significant are diesel exhaust fumes, nitrogen oxides from all vehicles exhaust fumes and smoke from bruning coal, wood or other organic matter

Question 61

How does Radon gas cause significant number of cases?

Answer 61

Radon gas is a radioactive gas that leaks out of certain rocks such as granite.
It accumulates in badly ventilated buildings and people then inhale it

Question 62

How does Asbestos, silica and some other solid cause lung cancer?

Answer 62

If dust or other particles of them are inhaled. This usually happens on construction sites or in quarries, mines or factories

Question 63

What are some symptoms of lung cancer?

Answer 63

• difficulties with breathing
• persistent coughing
• coughing up blood
• chest pain
• loss of appetite
• weight loss
• general fatigue

Question 64

What is emphysema?

Answer 64

a lung condition whereby the walls of the alveoli lose their elasticity due to damage to the alveolar walls

Question 65

How does the alveoli of emphysema patients compare to a healthy lung?

Answer 65

• Smaller number of larger air sacs with much thicker walls
• Huge air space (pulmonary bullae)
• total surface area for gas exchange is considerably reduced
• Distance over which diffusion of gases occurs is increased

= gas exchange is much less effective
= lung is less elastic, so ventilation is more difficult

Question 66

What happens when a lung is less elastic?

Answer 66

Ventilation is more difficult

Question 67

What do phagocytes ustually do inside aleveoli?

Answer 67

normally prevent lung infections by:
* engulfing bacteria
* producing elastase, a protein-digesting enzyme, to kill them inside the vesicles formed by endocytosis

Question 68

What prevents elastase and other proteases form digesting lung tissue?

Answer 68

An enzyme inhibitor called alpha 1-antitrypsin (A1AT)
* Elastase activity can be blocked by an enzyme inhibitor (α-1-antitrypsin), but not when elastase concentrations are increased

Question 69

What would you expect of the phagocytes in smokers?

Answer 69

The number of phagocytes in the lungd increases and they try to produce more elastase

Question 70

How does smoking cause damage to alveolar walls

Answer 70

The damage to lung tissue leads to the recruitment of phagocytes to the region, which produce an enzyme called elastase
This elastase, released as part of an inflammatory response, also breaks down the elastic fibres in the alveolar wall

Question 71

How does smoking cause damage to alveolar walls

Answer 71

The damage to lung tissue leads to the recruitment of phagocytes to the region, which produce an enzyme called elastase
This elastase, released as part of an inflammatory response, also breaks down the elastic fibres in the alveolar wall

Question 72

How does genetic factors play a role in emphysema?

Answer 72

• affect the quantity and effectiveness of A1AT produced in the lungs

Question 73

Why is emphysema a chronic disease?

Answer 73

The damage to alveoli is usually irreversible
* It causes low oxygen saturation in the blood and higher than normal carbon dioxide concentrations.

Question 74

What explains an emphysema patients lack o energy?

Answer 74

Low oxygen saturation in the blood and higher than normal CO2 conc.
* Ventiation is laboured and tends to be more rapid than normal