Ventilation and Compliance

Question 1

What is the anatomical dead space defined as?

Answer 1

Volume of gas occupied in conducting airways that isn’t exchanged

Question 2

What is the anatomical dead space volume?

Answer 2

Around 150ml

Question 3

What volume of air is usually inhaled and exhaled per breath at rest (tidal volume)?

Answer 3

Around 500ml each way

Question 4

What is the expiratory reserve volume (ERV) defined as?

Answer 4

How much air you can force out after a normal exhalation

Question 5

What is the average expiratory reserve volume?

Answer 5

1100ml

Question 6

What is the inspiratory reserve volume defined as?

Answer 6

The maximum you can breathe in NOT lung capacity

Question 7

What is the volume of the IRV

Answer 7

3000ml

Question 8

What is the inspiratory capacity?

Answer 8

The inspiratory reserve + a normal inhaled breath

Question 9

What is the value of the inspiratory capacity?

Answer 9

3500ml

Question 10

What is the vital capacity?

Answer 10

The max volume of air you can shift in one breath

Question 11

What two other volumes is the vital capacity defined by and what does it equal?

Answer 11

Inspiratory capacity + expiratory reserve volume = 4600ml

Question 12

What is functional residual capacity?

Answer 12

Volume of air left in the lungs after a normal exhalation

Question 13

What other two volumes is the functional residual capacity defined by and what does it equal?

Answer 13

Expiratory reserve volume + residual volume = 2300ml

Question 14

What is the residual volume?

Answer 14

The volume of air that can’t be expelled from the lungs = 1200ml

Question 15

What is the point of the residual volume (2 points)?

Answer 15

• Keeps the alveoli partially inflated so that it is easier to breathe in on the next breath - Maintains a pressure gradient for gas exchange to continue between breaths

Question 16

What is pulmonary ventilation and is it functionally significant?

Answer 16

The total air movement in and out of the lungs, no

Question 17

What is alveolar ventilation?

Answer 17

The volume of fresh air reaching the alveoli and therefore available for gas exchange

Question 18

What will alveolar ventilation indicate?

Answer 18

The amount of gas exchange occurring

Question 19

If lung volume = 2200ml after a normal exhilation, how high will the volume be after a normal inhilation?

Answer 19

2700ml

Question 20

How much of the 500ml breath will reach the alveoli?

Answer 20

350ml as 150ml will be in the dead space

Question 21

Describe what is going on in the diagram

Answer 21

• Respiratory cycle
• Indicating that the not all of the 500ml inhaled air will reach the alveoli for gas exchange
• 150ml MUST always be in the anatomical dead space
• After expiration, the anatomical dead space is filled with stale air

Question 22

When should you consider the implication of stale air in the anatomical dead spaces when dealing with patients?

Answer 22

• Anxious patients will have a low tidal volume and a high RR which means their pulmonary ventilation will be normal but the alveolar ventilation will be low (hypoventilation)

Question 23

What is hyperventilation?

Answer 23

When more air reaches the alveoli and alveolar ventilation is higher than normal, but pulmonary is the same

Question 24

What is the partial pressure?

Answer 24

Pressure of a gas in a mixture of gases = % of gas in the mixture x the pressure of the whole gaseous mixture

Question 25

EXAMPLE OF PARTIAL PRESSURE CALCULATION

Answer 25

Atmospheric Pressure = 760mmHg

Pressure of air we breathe therefore = 760mmHg

21% of air we breath = O2

Partial pressure of O2 in air we breath = 21% x 760mmHg

= 160mmHg

Question 26

What do the pressures of O2 and CO2 do under normal conditions in the alveoli?

Answer 26

Remain constant

Question 27

What is the normal P_O2 in kPa and mmHg?

Answer 27

• 13.3kpA
• 100mmHg

Question 28

How can P_O2 and P_CO2 vary?

Answer 28

With hyper and hypo ventilation

Question 29

What happens to P_O2 and P_CO2 during hypoventilation?

Answer 29

• P_CO2 increases to 100mmHg
• P_O2 decreases to 30mmHg

Question 30

What happens to P_O2 and P_CO2 ​during hyperventilation?

Answer 30

• P_O2 increases to about 120mmHg
• P_CO2 decreases to about 20mmHg

Question 31

What cells produce surfactant?

Answer 31

Type 2 pneumocytes

Question 32

What is the main function of surfactant?

Answer 32

• Reduces surface tension

Question 33

What is surface tension?

Answer 33

The attraction between air and water due to the attraction between water-water molecules, as shown below

Question 34

What does surface tension encourage the alveoli to do?

Answer 34

Collapse

Question 35

What is the definition of compliance?

Answer 35

Change in volume related to change in pressure, i.e. how much the lungs will inflate with an increase of intrapleural pressure

Question 36

What is the effect of surfactant on compliance and lung recoil?

Answer 36

• Increased compliance
• Reduced lung recoil

Question 37

What effect does surfactant ultimately have on breathing

Answer 37

Makes it easier

Question 38

During embryonic development, at what stage does surfactant production begin?

Answer 38

25 weeks

Question 39

What can an inability to produce surfactant result in in newborns?

Answer 39

Infant Respiratory Distress Syndrome

Question 40

What is the law of laplace?

Answer 40

P = 2T/r

P - pressure

T - surface tension

r - radius

Question 41

If the alveolus was bigger, why would the pressure be lower?

Answer 41

Increase the value of r in P = 2T/r which would mean a lower pressure

Question 42

What is found in the lungs to counteract the small R?

Answer 42

Surfactant reduces the value of T so P is still low

Question 43

Why is surfactant more effective in small alveoli?

Answer 43

Found in higher concentrations due to less space

Question 44

What is high compliance?

Answer 44

Lung volume increases with a small intrapleural pressure increase

Question 45

When does a high compliance occur?

Answer 45

• Healthy lungs
• Emphysema

Question 46

Why is there a high compliance with emphysema?

Answer 46

• Elastase is activated
• Reduces elastin in the lungs
• Lungs can’t expand as far as they should so less air is taken in when intrapleural pressure is reduced

Question 47

What is low compliance?

Answer 47

• Low volume increase from a large pressure change in the lungs

Question 48

Where would you see low compliance?

Answer 48

• Unhealthy lungs
• Bronchitis
• Restrictive disease

Question 49

What does compliance tell you about and what does it not give an indication of?

Answer 49

• Tells you about how effectively the lungs fill up
• Does not give any indication into elastic recoil

Question 50

Why does intrapleural have to become more negative during inspiration than expiration?

Answer 50

• Has to overcome surface tension
• Expiration has the aid of elastic recoil

Question 51

Why does inspiration follow an exponential curve?

Answer 51

• Similar to spontaneous reactions in that in needs some more energy to start
• Imagine blowing up a balloon and that it gets easier after you have it going

Question 52

Why is higher pressure needed to expire as you breathe out?

Answer 52

Need to overcome a higher resistance as airway muscle contracts to push air out

Question 53

Why is normal expiration passive?

Answer 53

Elastic recoil

Question 54

Why do people with emphysema have to expend more energy to breathe out?

Answer 54

Loss of elastic tissue means loss of elastic recoil

Question 55

Why does fibrosis reduce compliance?

Answer 55

More work needed to inflate the alveoli as they don’t stretch

Question 56

Which part of the lung has better compliance and which part has worse compliance?

Answer 56

• Bottom of the lung is better
• Apex is worse

Question 57

Why does the bottom of the lung have better compliance?

Answer 57

Due to gravity more air is forced out of the alveoli at the bottom of the lung, the apex retains a higher reserve volume so doesn’t intake as much air

Question 58

What is an obstructive respiratory disease attributed with?

Answer 58

Air flow obstruction particularly during expiration

Question 59

State 3 obstructive diseases

Answer 59

• Asthma
• Bronchitis
• Emphysema

Question 60

How many people worldwide are affected by COPD?

Answer 60

80 million

Question 61

What type of disease is fibrosis?

Answer 61

Idiopathic

Question 62

Exposure to what can cause restrictive pulmonary disease?

Answer 62

Asbestos

Question 63

Give 2 examples of restrictive diseases

Answer 63

• Fibrosis
• Asbestosis
• IRDS
• Oedema
• Pneumothorax

Question 64

What 5 things can spirometry measure?

Answer 64

• Tidal volume
• Expiratory Reserve
• Inspiratory Reserve
• Inspiratory Capacity
• Vital Capacity

Question 65

What is static spirometry?

Answer 65

Measures volume of air exhaled

Question 66

What is dynamic spirometry?

Answer 66

Time taken to exhale a certain volume

Question 67

What does FEV₁/FVC stand for?

Answer 67

Forced expiratory volume in 1 second/forced vital capacity

Question 68

What is FEV₁/FVC usually equal to?

Answer 68

80%

Question 69

What FEV₁/FVC would an obstructive disease show?

Answer 69

A smaller percentage

Question 70

What FEV₁/FVC would an restrictive disease show?

Answer 70

• Both air flow rate and lung capacity is reduced
• Percentage remains high