Lung function

Question 1

What are the normal conditions for air moving into the lung at rest?

Answer 1

PO2= 100±2 mm Hg, PCO2 = 40±2 mm Hg 
Ventilation:      ~6 L/min 
(~12 breaths/min, 500 ml/breath) 
Gas exchange:  ~ 250 ml/min O2 consumed 
~200 ml/min CO2 expired.

Question 2

When does ventilation increase?

Answer 2

During exercise to maintain blood gas homeostasis

Question 3

What is the function of the nasal cavities and paranasal sinuses in moving air into lungs?

Answer 3

Filter, humidify air and detect smells

Question 4

What is the function of the pharynx in moving air into the lungs?

Answer 4

Conducts air to larynx; a chamber shared with the digestive tract

Question 5

What is the function of the larynx in moving air into the lungs?

Answer 5

Protects opening to trachea and contains vocal cords

Question 6

What is the function of the trachea in moving air into the lungs?

Answer 6

Filters air, traps particles in mucus

Question 7

What is the function of the bronchi in moving air into lungs?

Answer 7

Same functions as trachea

Question 8

What is the lungs function in moving air into the lungs?

Answer 8

Responsible for air movement through volume changes during movements of ribs and diaphragm; include airways and alveoli

Question 9

What is the function of the alveoli in moving air into lungs?

Answer 9

Act as sites of gas exchange between air and blood

Question 10

Briefly describe diaphragm

Answer 10

Major inspiratory, dome-shaped skeletal muscle active during more strenuous breathing

Question 11

Briefly describe Quiet Breathing

Answer 11

Inspiration- active , diaphragm contracts downwards pushing abdominal contents outwards
Expiration- Passive, elastic recoil

Question 12

Briefly describe Strenuous breathing

Answer 12

Inspiration- Active, greater contraction of diaphragm and external intercostals
Expiration- Active, abdominal muscles, internal intercostals muscles oppose external intercostals by pushing ribs down and inwards

Question 13

Describe the pressure and volume changes from inspiration to expiration

Answer 13

• Beginning of inspiration PA=0 (pressure in lung) because no flow.
• Inspiratory muscles contract (diaphragm contracts)
• Thorax expands (upper chest wall extracts, lungs pulled outwards, pressure becomes more negative)
• Pleural pressure becomes more negative.
• Increase in transpulmonary pressure (difference between lung and pleural pressure, lung negative, air outside positive so air flows into lung)
• Lungs expand.
• PA becomes negative.
• Air flows into alveoli.
• Beginning of expiration (stop expanding thorax)
• Muscles stop contracting.
• Chest wall moves inwards.
• Ppl & PL return to pre-inspiration values.
• Lungs recoil (elastic recoil pressure).
• Air in alveoli compressed.
• PA becomes greater than atmospheric pressure.
• Air flows out of lungs.

Question 14

What are the major functions of the upper airways?

Answer 14

Humidify (saturate with water)
Warm (to body temp)
Filter- upper airways to bronchioles lined by pseudostratified (one layer) , ciliated columnar epithelium

Question 15

What happens to inhaled particles

Answer 15

Stick to mucus, mucus moved towards mouth by beating cilia

Question 16

What is the respiratory tree?

Answer 16

Airways that branch to bronchioles until terminating in a group of alveoli

Question 17

What occurs with each division of the respiratory tree?

Answer 17

Increase in number, a decrease in diameter and an increase in surface area
With each division lumen becomes smaller, but more tubes are added on

Question 18

What do conducting airways do?

Answer 18

Do not participate in gas exchange

Form anatomic dead space

Question 19

What do Respiratory airways do?

Answer 19

Bronchioles with alveoli, where gas exchange occurs ( from terminal bronchioles to alveoli)

Question 20

What is a respiratory unit?

Answer 20

Gas exchange unit, basic physiological uni of the lung consisting of respiratory bronchioles, alveolar ducts and alveoli

Question 21

How many alveolar sacs are in an adult?

Answer 21

300-400 million

Question 22

What shape and diameter are alveoli?

Answer 22

Polygonal in shape, roughly 250 micrometers in diameter

Question 23

What cells make up alveoli?

Answer 23

Type 1 and type 2 epithelial cells

Question 24

What innervate alveoli?

Answer 24

Blood vessels, this is important for gas exchange

Question 25

How many type 1 epithelial cells are there in the alveoli?

Answer 25

Occupy 97% of surface area of alveoli. Primary site of gas exchange, most important

Question 26

How many type 2 (septal cells) epithelial cells are there in the alveoli?

Answer 26

Occupy 3% surface area. Produce pulmonary surfactant (reduces surface tension, important for elasticity of lung)

Question 27

How are alveoli perfectly designed for gas exchange?

Answer 27

• Large surface area: roughly 100m2
• Very thin walls (mean 0.5 micrometers- important for gas exchange)
• Good diffusion characteristics

Question 28

What are the two different blood supply for the lungs?

Answer 28

Pulmonary circulation

Bronchial circulation

Question 29

What is pulmonary circulation?

Answer 29

Brings deoxygenated blood from heart to lung and oxygenated blood from lung to heart and then rest of body

Question 30

What is bronchial circulation?

Answer 30

Part of systemic circulation, brings oxygenated blood to lung parenchyma
Lymphatic system- defense and removal of lymph fluid

Question 31

Describe the structure of an artery

Answer 31

Thin walled (much lower pressure and larger diameters that can deal with higher flow), highly compliant, larger diameter, low resistance (compared to systemic circulation).

Question 32

What is the alveolar capillary network?

Answer 32

Gas exchange occurs through dense mesh-like network of capillaries and alveoli.

Question 33

How far is diffusion between alveolar sacs and capillary lumen?

Answer 33

Small distance- ideal for gas exchange

Question 34

How long does it take for redblood cells to pass through capillaries?

Answer 34

Less than 1 second

Question 35

What are the average gas concentration gradients for the pulmonary and systemic capillary?

Answer 35

Gas Concentration gradients:
Pulmonary Capillary 
Alveolar Air Venous Blood 
PO2 100          40 mmHg 
PCO2 40          46 mmHg 
Systemic capillary 
Tissues    Arterial Blood 
PO2 <46    40 mmHg 
PCO2 >46   40mmHg