Lung Elasticity, Surfactant & Work Of Breathing/ Lung Capacities & Volumes

Question 1

Define lung compliance

Answer 1

It is the change in the lung volume per unit change in transpulmonary pressure gradient (i.e. distending pressure)

Question 2

The compliance of lung or chest alone is …. L/cm H2O, while that of lung inside chest cavity is …. L/cm H2O.
Why is this?

Answer 2

0.2
0.1
Because of the limitation effect of the chest.

Question 3

Enumerate conditions which reduce pulmonary compliance

Answer 3

• Pulmonary congestion & edema
• Pulmonary fibrosis
• Respiratory distress syndrome
• Pneumonectomy

Question 4

Enumerate conditions which increase lung compliance

Answer 4

Old age

Emphysema

Question 5

GR: Loss of lung elasticity result is great difficulty in expiration.

Answer 5

• Decreased elastic lateral contraction, leading to alveolar collapse thus increasing airway resistance.
• Decreased elastic recoil makes passive expiration not enough to empty the lungs, thus increasing work of breathing.

Question 6

What are the causes of recoil tendency of the lung?

Answer 6

1. Elastic tissue in the lung & thiracic wall.
2. Alveolar surface tension by the attractive forces between water molecules at the surface of the liquid film that lines the alveoli.

Question 7

Lung expansion requires energy to

Answer 7

A. Stretch the elastic tissue of the lungs

B. Overcome the surface tension force of the fluid layer lining the alveoli

Question 8

Pulmonary surfactant is secreted by ….. .

It is composed of ….,…. & ….. .

Answer 8

Type II alveolar epithelium

Phospholipids, proteins & calcium ions

Question 9

The surfactant has hydrophilic & hydrophobic parts so it remains at the …….; the hydrophilic part is in the ….phase, while the hydrophobic part is in the ….phase.

Answer 9

Gas-liquid interface

Liquid, gas

Question 10

Function of the surfactant

Answer 10

Decreases surface tension, thus has the following functions:

1. Increases pulmonary compliance
2. Reduces tendency of alveoli to recoil & collapse
3. Keeps alveoli dry and prevent pulmonary edema
4. Stabilize the sizes of alveoli and help keep them open

Question 11

Apply LaPlace law on alveolus

Answer 11

The inward-directed (collapsing) pressure (P) of an alveolus is directly proportional to the surface tension (T) and inversely proportional to the radius (r)

Question 12

GR: the density of surfactant is higher in small than large alveoli.

Answer 12

Because the alveolus with smaller radius has pressure higher than alveolus with greater radius, so surfactant decreases surafce tension in smaller alveolus more than larger alveolus. This decrease in surface tension with decrease in radius, prevent the increase in pressure in small alveoli so prevent their collapse and emptying onto larger alveoli.

Question 13

Mention the effects of IRDS

Answer 13

Inadequate synthesis of surfactant, increase surface tension, reduced lung compliance, increased tendency of alveoli to collapse, increased work of breathing, respiratory failure and death. Pulmonary edema is developed due to fluid transudation.

Question 14

GR: hyaline membrane disease is called so.

Answer 14

Beacuse the poteinaceous fluid filling the alveoli looks like hyaline membrane under the microscope.

Question 15

Describe the managemnet of IRDS

Answer 15

For premature infant: surfactant replacement therapy & PEEP

For mother: glucocorticoid therapy, cortisone is used for acceleration of surfactant maturation in the fetus lungs.

Question 16

What is PEEP?

Answer 16

Positive end-expiratory pressure

Ventilate the lungs with positive pressure ventilator and keep the alveolar pressure above the atmospheric pressure.

Question 17

Describe the role of alveolar interdependence in keeping alveoli open.

Answer 17

A) when the alveolus in a group of interconnected alveoli starts to collapse the surrounding alveoli are stretched.
B) the neighbouring alveoli recoil in resistance to being stretched, they pull outward the collapsing alveolus.

Question 18

GR: inspiration is an active process. Mention the percentage of each work.

Answer 18

1. Elastic work: to overcome elastic tissue & alveolar surface tension. 65%
2. Resistive work (airway, 80%) & (tissue, 20%)

Question 19

The percentage of breathing from TEE

Answer 19

At rest, 3%
In streneous exercise, 5%
Poorly compliant lungs/obstructive lung disease, 30%

Question 20

The work of breathing is increased in which situations?

Answer 20

1. Decreased pulmonary compliance (lung fibrosis & respiratory distress syndrome)
2. Increased airway resistance (COPD)
3. Increased ventilation (exercise)
4. Decreased elastic recoil (emphysema)

Question 21

Mention factors increasing ealstic/resistive work of breathing.

Answer 21

E: pulmonary fibrosis & deficiency of oulmonary surfactant
R: tissue: sarcoidosis, airway: asthma, bronchitis & emphysema

Question 22

The volume of air inspired/expired can be measured by ….. .

Answer 22

Spirometer

Question 23

Define tidal volume and its normal volume

Answer 23

Volume of air entering/leaving the lungs in a single breath in resting condition
500 ml

Question 24

Define inspiratory reverve volume and its normal value

Answer 24

Extra volume of air that can be maximally inspired over the noraml tidal volume.
3000 ml

Question 25

Define Expiratory reserve volume and its normal value

Answer 25

It is the extra volume of air that can be expired beyond that normally passively expired.
1000 ml

Question 26

Define residual volume and its normal value.

Answer 26

The volume of air remaining in the lungs after the most forceful expiration. Expelled when chest is opened and lungs collapse.
1200 ml

Question 27

Amount of air that remains after opening the chest

Answer 27

Minimal air, 150 ml

Question 28

Significance of residual volume

Answer 28

1. Maintains aeration between breaths
2. Prevents marked changes in arterial concentration of O2 & CO2 which may disturb respiratory function.
3. Prevents lung collapse & helps easy inflation
4. Normally is 20% of lung capacity, and increases in bronchial asthma & emphysema.
5. Medicolegal importance: in determining if an infant is stillborn or killed.

Question 29

Define inspiratory capacity and its normal value.

Answer 29

The maximum volume of air that can be inspired by maximal forced inspiration following a normal quiet expiration.
3500 ml

Question 30

Define functional residual and its normal value

Answer 30

Volume of air remaining in lungs after a normal passive expiration
2200 ml

Question 31

Define total lung capacity and its normal value

Answer 31

Volume of air present in lungs after maximal forced inspiration
5700 ml

Question 32

Define vital capacity and its normal value

Answer 32

The volume of air expelled from the lungs by maximal forced expiration following maximum deep inspiration.
4500 ml

Question 33

All pulmonary capacities & volume are …… in men than in women, they are ….. in atheletic than asthenic people thus a measure of physical fitness.

Answer 33

20-25% more

Larger

Question 34

Mention the factors affecting vital capacity

Answer 34

1. Strength of respiratory muscles
2. The range of diaphragm mobility
3. Lung compliance

Question 35

Conditions affecting diaphragm mobility

Answer 35

Chest deformities
Painful chest conditions (fractured rib , pleurisy)
Increased abdominal contents (pregnancy & ascites)

Question 36

Conditions affecting lung compliance

Answer 36

Pulmonary fibrosis
RDS
Pulmonary congestion

Question 37

Define forced vital capacity and its normal value.

Answer 37

Timed vital capacity
Largest amount of air that can be expired as deep and as fast as possible after a maximal inspiratory effort.
Normal people can expire FVC in 4 to 6 sec

Question 38

Define FEV1 , normal FEV1/FVC % and its value in obstructive lung disease

Answer 38

Amount of FVC expired during the first second of forced expiration
80%
Decreased

Question 39

Describe the clinical importance of measuring FVC & FEV1

Answer 39

Indicates the maximal air flow that is possible from the lungs.
Differentiated obstructive (difficulty emptying the lungs) from restrictive (difficulty in filling the lungs).

Question 40

FRC & RV are ….. in obstructive lung diseased , and FEV1/FVC % is …..

Answer 40

Increased

Less than 80%

Question 41

Enumerate examples of restrictive lung diseases.

Answer 41

Abnormalities in lung tissue, pleura, chest wall & neuromuscular machinery.
e.g. pulmonary fibrosis, RDS & thoracic cage deformity

Question 42

Mention 3 values that are reduced in restrictive lung disease

Answer 42

TLC, inspiratory capacity & FVC

Question 43

In restrictive lung disease, FEV1/FVC is ….

Answer 43

Normal or even higher

Question 44

Define pulmonary ventilation & its normal value.

Answer 44

The volume of air breathed in or out in one minute at rest

6 L/min

Question 45

Define maximum voluntary ventilation and its normal value.

Answer 45

It is the maximal volume of air that can be inspired or expired per minute by the deepest and fastest breathing.
80-170 L/min in men
60-120 L/min in women

Question 46

The MVV is done for how much time and why?

Answer 46

15 seconds

To avoid effects of washout of CO2 on ventilation

Question 47

GR: The increase in TV is more important than increase in RR.

Answer 47

Because of the presence of anatomical dead space

Question 48

What is the importance of MVV?

Answer 48

It is affected by all factors which affect vital capacityy but its measurement is preferred because it can never be normal in lung diseases (it indicates lung dysfunction) while vital capacity can be normal in early stages of some lung diseases.

Question 49

Determination of breathing reserve is good test for …

Answer 49

The functional reserve of the respiratory system

Question 50

Normal BM/MBC, and its value in case of dyspnea

Answer 50

90%

70%

Question 51

Define anatomical dead space and its percentage of TV

Answer 51

It is the volume of air in the conducting airways (nasal cavity, pharynx, trachea, bronchi & terminal bronchioles), where no gas exchange takes place.
30% of TV

Question 52

Dead space normal value

Answer 52

150 ml

Question 53

Mention factors increasing and decreasing anatomical dead space.

Answer 53

Inc - inspiration/bronchodilatation

Dec - supine position, bronchoconstriction & endotracheal intubation.

Question 54

Define alveolar dead space.

Answer 54

It is the volume of gas within unperfused alveoli, thus not participating in gas exchange.

Question 55

GR: the match between air & blood is not always perfect

Answer 55

Because not all alveoli are equally ventilated with air & perfused with blood.

Question 56

GR: Normally physiological almost = anatomical dead space

Answer 56

Beacuse all alveoli are functioning in normal lung

Question 57

Mention the factor increasing anatomical dead space

Answer 57

Increased breathing rate

Question 58

GR: Expired air contains higher PO2 and less PCO2 than alveolar air

Answer 58

Because expired air is a mixture of dead space air (fresh atm air) and alveolar air (old air).

Question 59

Alveolar ventilation is …. than pulmonary ventilation.

Answer 59

Less

Question 60

GR: Rapid shallow breathing produces less alveolar ventilation than slow deep breathing at the same pulmonary ventilation.

Answer 60

In rapid shallow breathing, the dead space volume increases which decreases alveolar ventilation , causing hypoxia.

Question 61

Mention two modifications to air caused by presence of dead space.

Answer 61

• Humidification and warming of inspired air.
• It protects alveoli from damage by bacteria and foreign particles by:
  1. Filtration action of nose that removes dust and large foreign particles from inspired air.
  2. Foreign particles stich to mucus the expelled by sneezing & coughing.

Question 62

…… produced by larynx & ….. by nose ;due to presence of dead space

Answer 62

Phonation

Smell sensation

Question 63

During exercise we should breathe ….. to….

Answer 63

Slowly & deeply to increase alveolar ventilation

Question 64

Define pulmonary ventilation

Answer 64

It is the volume of air breathed in/out the lungs in one minute.