Respiratory: Lung Volumes and Capacities in Sickness and in Health L15

Question 1

What is surfactant? What is surface tension? How does surfactant reduce surface tension? How does this affect lung compliance?

Answer 1

Surfactant is a phospholipid produced by the alveolar type 2 cells that lower surface tension in alveoli.
Surface tension stems from the fact that water H2O molecules try to attract each other, thereby contracting the fluid.
The fluid lining the alveoli would tend to cause them to collapse due to these forces if there was no surfactant.
Surfactant lowers surface tension decreases the attractive forces of the water molecules due to hydrogen bonding by interspersing the surfactant through the H2O.
Lowering surface tension will increase lung compliance, the amount of inflation the lung can make, which is required to expand for inspiration. Compliance is a measure of the elasticity of the lung (the change in volume for each unit of pressure change across the lung).

Question 2

What effect does surfactant decreasing alveolar radius by decreasing surface tension, have?

Answer 2

As alveolar radius decreases, surfactant’s ability to lower surface tension increase. This prevents a pressure gradient forming between small and large alveoli causing the smaller alveoli to empty into the larger ones.

Question 3

What are the consequences of a lack of surfactant?

Answer 3

Decreased surfactant = Increased surface tension = Alveoli cannot retain shape, fuse together.
Infant respiratory distress syndrome (IRDS) is caused by a lack of surfactant: prematurely born infants (usually those born before 7 to 8 months of gestation) may not have adequate amounts of surfactant and can experience great difficulty inflating the lungs.

Question 4

What is the value of Total Lung capacity?

What 4 lung volumes makes up total lung capacity?

Answer 4

Total Lung Volume = 6L = Vital capacity + Residual Volume.
'Vital capacity' is made up of 
'Inspiratory Reserve Volume', 
'Tidal Volume' and 
'Expiratory Reserve Volume'.

Question 5

What is Tidal volume?

Answer 5

0.5L. The volume that is breathed in or out during quiet respiration.

Question 6

What is Inspiratory Reserve Volume?

Answer 6

3L, the additional air that can be breathed in after a normal inspiration (i.e the maximum volume that can be inspired above and beyond the tidal volume).

Question 7

What is Expiratory Reserve Volume?

Answer 7

1.5L, the additional air that can be breathed out after the normal expiration.

Question 8

What is Residual Volume?

Answer 8

1L This quantity of air remains trapped in the lungs, keeping them partially inflated, even after a maximal expiration. It cannot be measured directly by spirometry.

Question 9

What is Functional residual capacity?

Answer 9

Functional residual capacity (FRC) = 2.5L, the amount of air remaining in the lungs after you have finished breathing out, during normal quiet respiration: it is therefore equal to the expiratory reserve volume plus the residual volume. FRC = RV + ERV (2.5 = 1 + 1.5)

Question 10

What is Vital Capacity?

Answer 10

Vital Capacity (VC) = 5L: this is the max amount of air that can be forced out of the lungs after a maximal inspiration (i.e if you breathe in as much as you can and then breathe out as much as you can): it is therefore equal to the tidal volume plus the inspiratory reserve volume and the expiratory reserve volume.

Question 11

What is Inspiratory Capacity?

Answer 11

Inspiratory Capacity (IC) = 3.5L: the maximum amount of air you can breathe in after a normal expiration: equal to the tidal volume plus the inspiratory reserve volume.
 IC = VT + IRV (3.5 = 0.5 +3)

Question 12

What is Total lung capacity?

Answer 12

Total lung capacity (TLC) = 6L: the total volume of air that can be contained in the lungs (i.e the amount of air in the lungs if you breathe in as much as you can): equal to all four of the lung volumes added together.
TLC = RV + ERV + TV + IRV
(6=1 + 1.5 + 0.5 + 3)

Question 13

What is spirometry?

Answer 13

The measurement of breath, and is the most common test of respiratory function. It is performed using an instrument called a spirometer.

Question 14

What is a spirometer?

Answer 14

A traditional spirometer consists of a hollow bell inverted over water, and it can measure the volume and speed of air inspired and expired from the lungs.

Question 15

What does 2 important values can be determined by spirometry?

Answer 15

Forced vital capacity (FVC) and forced expiratory volume (FEV):
Forced vital capacity is the volume of air (in litres) that can be forcibly expelled after taking a deep breath.

The FVC is measured by having the subject take the deepest breath that they can and then exhaling as hard as they can for as long as they can (known as performing the FVC manoeuvre).

The forced expiratory volume (FEV) is the volume of air (in litres) that can be forcibly expelled in a particular interval of time during the FVC manoeuvre.

Question 16

How long is FEV measured over in the FVC manoeuvre?

Answer 16

FEV is usually measured over the first second of FVC manoeuvre: FEV1.0

Question 17

What does the value of FEV1.0 reflect?

Answer 17

Pulmonary Expiratory power (or driving pressure) and the overall resistance to air movement upstream in the lungs.

Question 18

Why do we not solely use FVC value as an indicator of lung health?

Answer 18

FVC is not a useful measurement by itself, values that can be considered normal can still be measured to have normal values despite having lung disease present. This is the case because the disease can mean the person is still capable of expiring the same volume of air, but it does not take into account how long this takes.

Question 19

How do we use FVC, if it is not viable to use as a value by itself?

Answer 19

We can implement FVC with FEV1.0 into an equation: FEV1.0 divided by the FVC, indicating pulmonary airflow capacity with a value of 0.8 as normal.

Question 20

Why do we measure for FEV1.0 and FVC? If values aren’t normal what does this suggest?

Answer 20

These values together bring a good indicator of how healthy a person’s lungs may be function. The values are compared to predicted values based on age, sex, ethnicity, height, if the lung function is not normal, then these values may indicate the presence of either obstructive lung disease or restrictive lung disease.

Question 21

What is obstructive lung disease?

Answer 21

Lung disease characterised by an increase in resistance to airflow. This includes asthma, emphysema and chronic bronchitis.
FEV1.0 is decreased (because of resistance to airflow).
FVC may also be decreased (if expiration is incomplete due to the airways closing prematurely) but is often normal. Less than 0.7 value of FEV1.0/FVC is indicative of obstruction.

Question 22

What is restrictive lung disease?

Answer 22

Lung disease characterise by a decreased in lung volume.
Includes diseases that affect the compliance of the lungs, such as those that cause pulmonary fibrosis or pulmonary oedema, diseases that affect compliance of the chest wall, and diseases affecting the respiratory muscles.

FVC is decreased (because lung volume has decreased)

FEV1.0 often decreased, but proportionally to the decrease in FVC.

Because of this, REV1.0/FVC is either normal or increased.

Question 23

Explain peak expiratory flow rate (PEFR).

Answer 23

Another measure of spirometry:
Peak expiratory flow rate is the greatest amount of airflow someone can make during forced expiration, that begins with lungs fully inflated (L/min).
The PEFR is a measure of amount of obstruction in airways.
Portable hand-held PEFR meters can be used on a regular basis, and if there are changes to one’s normal values, can see if symptoms are improving or not.

Question 24

What is anatomical dead space?

Answer 24

Not all air that is breathed in takes part in gas exchange. Some air doesn’t reach the alveoli, instead it remains in conducting parts of the respiratory tract (i.e the nose, the pharynx, the larynx, the bronchi, trachea, bronchioles). This space is referred as ‘anatomical dead space’.
There is also ‘alveolar dead space’ from alveoli ceasing to act in gas exchange due to collapse or obstruction.
Total dead space is the sum of both anatomical dead space and alveolar dead space.

Question 25

What is alveolar ventilation?

Answer 25

The volume of gas that reaches the alveoli in a particular time, accounts for dead space:
Alveolar ventilation (VA) = f x (VT - D)
where:
f= frequency (breaths/min)
VT = tidal volume
D = dead space (150ml approx)

Question 26

How does dead space cause particular efficiencies in breathing? E.g What is better, fast small breaths or long deep breaths?

Answer 26

Due to dead space remaining constant, slow deep breaths result in greater alveolar ventilation than does taking rapid shallow breaths. This is evidenced by using the alveolar ventilation equation. For example, compare a given frequency (20) and tidal volume (0.2), then half frequency (10) but double tidal volume (0.4) to reenact deep slow breaths:
VA = 20 x (0.2 - 0.15) = 1 L/min
VA = 10 x (0.4 - 0.15) = 2.5L / min
This explains why if you take rapid shallow breaths you will end up feeling dizzy: there is actually less gas exchange taking place as this pattern of breathing decreases ventilation to the alveoli.

Question 27

What is pulmonary ventilation?

Answer 27

Similar to alveolar ventilation without taking dead space into account.
V=fxVT