Respiratory Physiology

Question 1

The conducting zone transports gas to the lungs and is from the nose to the:

Answer 1

Terminal bronchioles

Question 2

The respiratory zone is the site of gas exchange and consists of:

Answer 2

respiratory bronchioles, alveolar ducts, alveolar sacs

Question 3

How many generation of airways do you find int he respiratory system?

Answer 3

23

Question 4

How many alveoli are present in the respiratory system?

Answer 4

500 million

Question 5

What is the sympathetic and parasympathetic effect on the smooth muscles of the airways?

Answer 5

Sympathetic: smooth muscle relaxation via B2 receptors
Parasympathetic: smooth muscle contraction via muscaric receptors

Question 6

Type of pneumocyte which composes 96-98% of surface area, and is for gas exchange

Answer 6

Type I pneumocytes

Question 7

Type of pneumocyte which composes 2-4% of surface area, and is for surfactant production

Answer 7

Type II pneumocytes

Question 8

Alveolar macrophages can convert into what in CHF:

Answer 8

Siderophages/ Hemosiderin-laden macrophages

Question 9

Cells that produce mucus:

Answer 9

Goblet cells, submucosal glands

Question 10

May play a role in epithelial regeneration after injury by secreting protective GAGs

Answer 10

Clara cells/Club cells

Question 11

What is the Reid’s index?

Answer 11

Ratio of submucosal gland layer to the alveolar wall.

In COPD, Reid’s index is >0.4 indicating hyperplasia and hypertrophy of the submucosal gland layer

Question 12

Dual blood supply of the lungs:

Answer 12

1. Pulmonary (deoxygenated blood) circulation
2. Bronchial (oxygenated blood) circulation (1/3 returns to R atrium via bronchial veins, 2/3 returns to L atrium via pulmonary veins)

Question 13

Amount of air inspired/expired during quiet breathing

Answer 13

Tidal volume

Question 14

Maintains oxygenation between breaths

Answer 14

Residual volume

Question 15

Sum of IRV, TV, ERV

Answer 15

Vital capacity

Question 16

Sum of ERV and RV

Answer 16

Functional residual capacity

Question 17

Sum of IRV and TV

Answer 17

Inspiratory capacity

Question 18

Sum of all 4 lung volumes

Answer 18

Total lung capacity (Normal: 6L)

Question 19

Cannot be measured directly by spirometry

Answer 19

Residual volume (and all lung capacities that include residual volume)

Question 20

Equilibrium/resting volume of the lung

Answer 20

Functional residual capacity

Question 21

Marker for lung function

Answer 21

Functional residual capacity

Question 22

Difference in lung volumes/capacities among sexes

Answer 22

Lung volumes and capacities 20-25% lower in females

Question 23

Factors that increase vital capacity

Answer 23

Body size, male sex, conditioning, youth

Question 24

Total volume of the lungs that does not participate in gas exchange; anatomic dead space + alveolar dead space

Answer 24

Physiologic dead space

Question 25

Air in the conducting zone is called the anatomic dead space. What is the normal value in healthy humans?

Answer 25

150mL

Question 26

Air in the alveoli not participating in gas exchange due to V/Q mismatch.

Answer 26

Alveolar dead space (Normal value in healthy humans is 0 mL)

Question 27

Total rate of air movement in/out of the lungs

Answer 27

Minute ventilation

MV = VT x RR

Question 28

Minute ventilation corrected for physiologic dead space

Answer 28

Alveolar ventilation

VA = (VT-VD) x RR

Question 29

25/M, healthy, 70kg with a RR of 20bpm. What is the minute ventilation and alveolar ventilation?

Answer 29

MV = 500mL x 20 = 10, 000mL or 10L
VA = (500mL - 150mL) x 20 = 7,000mL or 7L

Question 30

50/M with TV = 500mL, RR = 20bpm, PCO2 arterial = 40mmHg, PCO2 expired air = 30mmHg. 
What is the minute ventilation?
What is the alveolar ventilation?
What percent of TV reaches the alveoli?
What percent of TV is dead space?

Answer 30

MV = 500mL x 20 = 10,000 mL or 10L
Physiologic dead space = (0.5L) x (40mmHg - 30mmHg)/40mmHg = 0.125L
VA = (0.5L - 0.125L) x 20 = 7.5L
Percent reaching the alveoli: (0.5 - 0.125)/0.5 = 0.75 = 75%
Dead space: 0.125/0.5 = 0.25 = 25%

Question 31

What happens to FEV1 and FVC in patients with obstructive and restrictive lung diseases?

Answer 31

Decrease

Question 32

What is the FEV1/FVC ratio of a healthy person?

Answer 32

0.8 / 80%

Question 33

What happens to the FEV1/FVC ratio in patients with obstructive and restrictive lung diseases respectively?

Answer 33

Obstructive: Decrease
Restrictive: Normal to increase

Question 34

Normal inspiration is an active process carried out by what muscle?

Answer 34

Diaphragm

Question 35

Predominant muscle in forced expiration

Answer 35

External intercostals

Question 36

Normal expiration is a passive process. However, forced expiration is predominantly done by what muscle:

Answer 36

Internal intercostals

Question 37

In obstructive lung disease, the decrease in FEV1 is ___ than decrease in FVC

Answer 37

greater

Question 38

In restrictive lung disease, the decrease in FEV1 is ___ than decrease in FVC

Answer 38

less

Question 39

In emphysema: 
Pathology is: loss of \_\_\_\_\_ fiber
Compliance: \_\_\_\_\_\_\_\_\_\_\_
Elasticity: \_\_\_\_\_\_\_\_\_\_\_
FRC: \_\_\_\_\_\_\_\_\_\_\_
Effects: \_\_\_\_\_\_-shaped chest

Answer 39

elastic
increased
decreased
increased
barrel

Question 40

In fibrosis:
Pathology is: \_\_\_\_\_\_ of lung tissue
Compliance: \_\_\_\_\_\_\_\_\_\_\_
Elasticity: \_\_\_\_\_\_\_\_\_\_\_
FRC: \_\_\_\_\_\_\_\_\_\_\_

Answer 40

stiffening
decreased
increased
decreased

Question 41

Force cause by water molecules at the air-liquid interface that tends to minimize surface area

Answer 41

Surface tension

Question 42

2 reasons why preterm babies have large collapsing pressure and are prone to atelectasis:

Answer 42

Alveolar radius is 50 micrometers (adult = 100 micrometers)

Lack mature surfactant

Question 43

Cells that produce surfactant

Answer 43

Type II pneumocytes

Question 44

Main component of surfactant

Answer 44

Water

Question 45

Active component of surfactant

Answer 45

Dipalmitoyl-phosphatidylcholine (DPPC)

Question 46

Mechanism for DPPC reducing surface tension

Answer 46

Amphipathic nature

Question 47

Effects of surfactant on lung compliance

Answer 47

Increase

Question 48

Start of surfactant production

Answer 48

24th week AOG

Question 49

Maturation of surfactant

Answer 49

35th week AOG

Question 50

Test for surfactant

Answer 50

Amniotic L:S ratio

Question 51

Treatment for newborn RDS

Answer 51

Steroids, surfactant

Question 52

Ability of the respiratory membrane to exchange gas between the alveoli and the pulmonary blood

Answer 52

Diffusing capacity

Question 53

Diffusing capacity for O2:
At rest: _____
Maximal exercise: _____

Answer 53

At rest: 21 mL/min/mmHg

Maximal exercise: 65 mL/min/mmHg

Question 54

Diffusing capacity for CO2:
At rest: _____
Maximal exercise: _____

Answer 54

At rest: 400 - 450 mL/min/mmHg

Maximal exercise: 1200 - 1300 mL/min/mmHg

Question 55

What are the forms of gases in solutions?

Answer 55

Dissolved gas, bound gas, chemically modified gas

Question 56

What is the only form of gas that contributes to partial pressure?

Answer 56

Dissolved gas

Question 57

What is the only gas in inspired air found exclusively as dissolved gas?

Answer 57

Nitrogen

Question 58

Difference between PAO2 (alveolar PO2) and PaO2 (arterial PO2)

Answer 58

A-a gradient (Normal: not zero; PAO2 > PaO2)

Question 59

Nitrogen, oxygen and CO2 under normal condition exhibit what kind of gas exchange?

Answer 59

Perfusion -limited gas exchange (gas equilibriates with the pulmonary capillary near the start of the pulmonary capillary)

Question 60

CO2 and O2 during strenuous exercise and disease states (emphysema, fibrosis) exhibit what kind of gas exchange?

Answer 60

Diffusion-limited gas exchange (gas doe not equilibriate even until the end of the pulmonary capillary)

Question 61

O2 transport in high altitude is fast or slow?

Answer 61

Slow

Question 62

Equilibration of O2 at sea level is ___ length of the pulmonary capillary

Answer 62

1/3 length

Question 63

Equlibration of O2 at high altitude is ___ length of the pulmonary capillary

Answer 63

2/3 length

Question 64

Percentage of dissolved O2

Answer 64

2%

Question 65

Percentage of O2 bound to Hgb

Answer 65

98%

Question 66

Hgb with attached O2

Answer 66

Oxyhemoglobin

Question 67

Hgb without attached O2

Answer 67

Deoxyhemoglobin

Question 68

Hgb with Fe3+ and doesn’t bind O2

Answer 68

Methemoglobin

Question 69

A2Y2, higher affinity for O2

Answer 69

Fetal hemoglobin

Question 70

A2B2, sickled RBCs, less affinity for O2

Answer 70

Hemoglobin S

Question 71

Max O2 binding with Hgb

Answer 71

O2 binding capacity

Question 72

Percent of blood that gives up it O2 as it passes through the tissues

Answer 72

Utilization coefficient

Question 73

O2-Hgb dissociation curve is sigmoidal in shape. What is the PO2 at the following percent saturation:
50% saturated, 75% saturated, 100% saturated

Answer 73

50% = 25 mmHg (p50)
75% = 40 mmHg
100% = 100 mmHg

Question 74

Binding of first O2 molecule increases affinity for second O2 molecule and so forth

Answer 74

Positive cooperativity

Question 75

Shift to the right or shift to the left?

Increased P50

Answer 75

Right

Question 76

Shift to the right or shift to the left?

Increased unloading of O2 to Hgb

Answer 76

Right

Question 77

Shift to the right or shift to the left?

Increased CO2

Answer 77

Right

Question 78

Shift to the right or shift to the left?

Increased 2,3 BPG

Answer 78

Right

Question 79

Shift to the right or shift to the left?

Increased temperature, exercise

Answer 79

Right

Question 80

Shift to the right or shift to the left?

Acidosis

Answer 80

Right

Question 81

Shift to the right or shift to the left?

Increased binding of O2 to Hgb

Answer 81

Left

Question 82

Shift to the right or shift to the left?

Decreased p50

Answer 82

Left

Question 83

Shift to the right or shift to the left?

Increased Carbon monoxide, HbF

Answer 83

Left

Question 84

90% of chloride in the blood

Answer 84

HCO3-

Question 85

5% of CO2 in the blood

Answer 85

Dissolved CO2

Question 86

3% of CO2 in the blood

Answer 86

Carbamino Hgb

Question 87

Cl-HCO3 exchange in the RBC

Answer 87

Chloride shift (using Band 3 protein)

Question 88

O2 affecting affinity of CO2/H+ to Hgb

Answer 88

Haldane effect

Question 89

CO2/H+ affecting affinity of O2 to Hgb

Answer 89

Bohr effect

Question 90

Haldane effect happens in the:

Answer 90

Lungs

Question 91

Bohr effect happens in the:

Answer 91

Tissues

Question 92

Pressure in the pulmonary circulation is ___ than systemic circulation

Answer 92

less

Question 93

Resistance in the pulmonary circulation is ___ than systemic circulation

Answer 93

less

Question 94

Cardiac output in the pulmonary circulation is ___ than the systemic circulation

Answer 94

equal to

Question 95

Pulmonary blood flow in a supine position is lowest at the apex and highest at the base or same through the entire lung?

Answer 95

same through the entire lung

Question 96

Pulmonary blood flow in a standing position is lowest at the apex and highest at the base or same through the entire lung?

Answer 96

Lowest at the apex and highest at the base

Question 97

Effect of hypoxia (low PAO2) on pulmonary arterioles

Answer 97

vasoconstriction

Question 98

Causes of pulmonary global hypoxic vasoconstriction

Answer 98

high altitude, fetal circulation

Question 99

Called the slow reactive substances of anaphylaxis and causes bronchoconstriction in asthma

Answer 99

Leukotriene C4, D4 and E4

Question 100

Lung zone:

Local alveolar capillary pressure

Answer 100

Zone 1

Question 101

Lung zone:
Local alveolar capillary systolic pressure > alveolar air pressure during systole but less than that during diastole;
Intermittent blood flow

Answer 101

Zone 2

Question 102

Lung zone:
Local alveolar capillary pressure > alveolar air pressure throughout the cycle;
Continuous blood flow

Answer 102

Zone 3

Question 103

What lung zones do we see in the apex of the lungs at rest?

Answer 103

Zone 2 and 3

Question 104

What lung zones do we see in the base of the lungs at rest?

Answer 104

Zone 3

Question 105

What lung zones do we see in a supine position, or during exercise throughout the lungs?

Answer 105

Zone 3

Question 106

What lung zones do we see in cases of pulmonary hemorrhage or positive pressure ventilation?

Answer 106

Zone 1

Question 107

Site of highest ventilation

Answer 107

Base of the lungs

Question 108

Site of highest perfusion

Answer 108

Base of the lungs

Question 109

Site of highest V/Q ratio

Answer 109

Apex of lungs

Question 110

Ventilated area of the lungs with no perfusion (V/Q = infinity)

Answer 110

Dead space (eg. pulmonary embolism)

Question 111

Perfusion of lungs with no ventilation (V/Q = zero)

Answer 111

Shunt

Question 112

Alveolar gas has same composition as humidified inspired air (PAO2 = 150 mmHg and PACO2 = 0)

Answer 112

Dead space

Question 113

Pulmonary capillary blood has same composition as mixed venous blood: PaO2 = 40mmHg and PaCO2 = 46mmHg

Answer 113

Shunt

Question 114

Creates the basic respiratory rhythm; contains the dorsal respiratory group, ventral respiratory group, central chemoreceptors

Answer 114

Medulla

Question 115

Modifies the basic respiratory rhythm; contains the apneustic and pneumotaxic centers

Answer 115

Pons

Question 116

Inspiratory center; control basic rhythm; for normal respiration

Answer 116

Dorsal respiratory group

Question 117

Overdrive mechanism during exercise; for forced inspiration and expiration

Answer 117

Ventral respiratory group

Question 118

Found in the lower pons; for prolonged duration of inspiration –> decreases RR

Answer 118

Apneustic center

Question 119

Found in the upper pons; shorten duration of inspiration –> increases RR

Answer 119

Pneumotaxic center

Question 120

Found in the ventral medulla, respond directly to CSF H+ (increases RR)

Answer 120

Central chemoreceptors

Question 121

Responds mainly to PaO2

Answer 121

Peripheral chemoreceptors

Question 122

Stimulated by lung distention

Answer 122

Lung stretch receptors

Question 123

Decreases RR by prolonging expiratory time; prevent overinflation of the lungs

Answer 123

Hering-Breuer reflex

Question 124

Stimulated by limb movement; causes anticipatory increase in RR during exercise

Answer 124

Joint and muscle receptors

Question 125

Stimulated by noxious chemicals; causes bronchoconstriction and increases RR

Answer 125

Irritant receptors

Question 126

Found in juxtacapillary areas; stimulated by pulmonary capillary engorgement; causes rapid shallow breathing and responsible for the feeling of dyspnea

Answer 126

J receptors