Pulmonary Structure & Function

Question 1

Functions of the lungs and the respiratory system

Answer 1

• Gas exchange
• Filter blood - the lungs are a massive capillary bed
• Metabolize active substances from one form to another
  
  • ​Angiotensin I –> Angiotensin II
  • Bradykinin inactivation
  • Prostaglandins, sertonin, and leukotrienes are removed
• Provide a reservoir for blood for the left ventricle
• Generate positive pressure airflow -> phonate

Question 2

What happens when these things pass through the pulmonary capillary bed?

Blood clots

Bacterial vegetations on the heart valve

Cancers

Answer 2

Blood clots -> pulmonary emboli

Bacterial vegetations -> pulmonary abcesses

Cancers -> metastatic tumors

Question 3

What is the sequence of layers gasses must pass through to get to hemoglobin?

Answer 3

1. Surfactant layer
2. Type 1 pneumocytes (epithelial cell)
3. Basement membrane of epithelial cell
4. Interstitial space between epithelial and ENDOthelial cell
5. Basement membrane of endothelial cell
6. Endothelial cells of alveolar capillaries
7. Plasma of blood
8. RBC membrane
9. Hemoglobin

Question 4

What is the function of FB?

What is pulmonary fibrosis?

Answer 4

Fibroblasts: produce collagen to repair damaged tissue when the lungs are injured.

Pulmonary fibrosis: excessive scar tissue from proliferating fibroblasts forms in a lung injury, impairing gas exchange -> hypoxemia

Question 5

Epithelial vs Endothelial cells

Answer 5

Epithelial cells are in contact with the air outside the body -> vulnerable to inhalational injury & infection

Endothelial cells are in contact with the blood inside the body –> vulnerable to blood-borne substances

Question 6

The thickness of the barrier between the alveolar air and hemoglobin in RBCs is

Answer 6

0.3

Question 7

Air moves from high pressure to low pressure.

How do we lower the pressure within the chest below atmoshperic pressure to cause inspiration?

Answer 7

Move the diaphragm down

Move the ribcage out

Question 8

What has to happen to cause passive exhalation?

Answer 8

Respiratory muscles relax, pushing abdominal contents back up into the thoracic cavity

Elastic recoil of chest wall

Question 9

What is the purpose of branching of the airways so much from the bronchioles and forward?

Answer 9

Total cross-sectional area increases so much that the forward velocity of the gas slows to a standstill at the alveoli –> gas diffusion takes over

Question 10

The area of the lungs where gas moves by diffusion and not by bulk flow is …

Answer 10

Respiratory zone

Respiratory bronchioles, alveolar ducts, alveolar sacs

Question 11

The total volume of the conducting zone (trachea -> terminal bronchioles) is

Answer 11

~150 mL

Question 12

Anatomic dead space - define it & quantify

Answer 12

The fixed volume of tubing it takes for oxygen to get from the nose/mouth to the alveoli / The conducting zone

~1 mL per pound of ideal body weight –> ~150mL

Question 13

The maximum volume of the respiratory zone (volume of lungs that contain alveoli) is

Answer 13

Maximum: ~2.5-3L

However, unlike the anatomic dead space, the respiratory zone is highly variable depending on the size of breath!

Question 14

Volume of an average breath is

Answer 14

0.5L

Question 15

Minute ventilation

Answer 15

Amt of air that enters and leaves the body per minute

Volume of each breath x Respiratory rate per min

Normal: ~6L/min

Question 16

Dalton’s law: The sum of all the partial pressures in a gas mixture equals

Answer 16

the atmospheric pressure

=amt of pressure it would take to push up a column of Hg in a tube

= 1 atm

=760mmHg

=14.7ppi (pounsd-per-square-inch)

Question 17

What’s the proportion of oxygen in the air?

Answer 17

Oxygen = 21%

[FiO2] = .21

(Nitrogen is 78%)

Question 18

As you go higher in the atmosphere, what happens to pressure?

Answer 18

It decreases.

The proportion of oxygen in the air stays the same, but its pressure decreases.

Question 19

What is the partial pressure of oxygen in air in mmHg at sea level?

Answer 19

0.21 x 760 mmHg = 160mmHg

Question 20

Warmer air has more ___ in it than cooler air.

Answer 20

Water vapor

Question 21

What is the partial pressure of water vapor in the inspired air at body temperature at sea level?

Answer 21

47 mmHg

Question 22

What is the effective atmospheric pressure of air once it reaches the alveoli, since it gets warmed and humidified in the body?

Answer 22

760 - 47 = 713

_{(47mmHg is the partial pressure of water vapor in inspired air at body temperature at sea lvl)}

Question 23

What happens to the partial pressure of oxygen as air moves into the trachea? The alveoli?

Answer 23

It decreases because of humidification and addition of CO2.

(760-47) x 0.21 = 150 mmHg after humidification in the trachea

100mmHg after addition of CO2 in the alveoli

Question 24

Bronchial circulation

Answer 24

small branches off the aorta (so it’s systemic) that supply the conducting airways (bronchi) of the lungs, nerves, and lymph nodes of the lungs

Question 25

Pressure in bronchial circulation is the same as the ___.

Pulmonary circulation is much ___

Answer 25

bronchial circulation = systemic circulation (~120mmHg)

Pulmonary circulation (~25mmHg) is lower than systemic circulation

Question 26

What is the purpose of surfactant? What cells produce it? What cells take it up?

Answer 26

Decreases surface tension of the air-liquid interface to prevent alveolar collapse

Produced by type 2 alveolar pneumocytes

Taken up by alveolar macrophages

Question 27

Atelectasis

Answer 27

Collapsed alveoli

May occur if you lack surfactant

Smaller alveoli are easier to collapse than larger ones

Question 28

Compliance

Answer 28

How much volume changes in response to changes in pressure

Question 29

As you decrease surface tension, what happens to compliance?

Answer 29

Decrease surface tension -> increased compliance

Ex) The saline-filled lung has no surface tension –> more compliant than air-filled lung

Question 30

Hysteresis

Answer 30

The pressure-volume curve changes depending on whether the pressure goes up or down.

Question 31

How are big particles cleaned out?

Small particles?

Particles that make it all the way down to the alveoli?

Answer 31

Big particles/dust gets mixed with mucus -> boogers that are swallowed or cleared out

Small particles are trapped in the mucus layer lining the airways -> respiratory cilia move them up and out the lungs

Particles that make it to the alveoli are taken up by alveolar macrophages & neutrophils -> lymph nodes for antigen presentation to lymphocytes OR push them up to the conducting zone where cilia transport them up an dout

Question 32

Which is emphysema?

Answer 32

The leftmost picture.

It has less fibers; tissue destruction; big spaces of air and you can’t get it out.

Question 33

Chronic bronchitis: productive cough with airway inflammation from long-standing irritation of inhaled substances; can lead to heartfailure, metaplasia, and dysplasia of respiratory epithelium -> cancer

• Increased mucus secretion in large airways due to hypertrophy of submucosal glands + increased goblet cells
• Increased inflammation and fibrosis narrows bronchioles

Which image is chronic bronchitis?

Answer 33

The leftmost picture

It has more mucosal glands & thickened bands of smooth muscle.

Question 34

Where are the axons in teh submucosa of this olfactory epithelium?

Answer 34

Axons in teh submucosa are a defining characteristic of olfactory epithelium

Question 35

Answer 35

Nasal cavity should have tall respiratory epithelium, which is bottom right

Question 36

Answer 36

In the basal lamina!

Question 37

Which respiratory structure is most involved in an asthma attack? What type of stimulation is involved?

Answer 37

Bronchioles - they have a lot fo smooth muscle and no cartilage. So it’s much mroe responsive to parasympathetic stimulation.

Question 38

Answer 38

Increased pulmonary resistance and hemosiderin laden macrophages

Blood is getting backed up into pulmonary circulation

Question 39

Answer 39

Bottom left.

it has no cartilage and the top pic is an alveolar space.

Question 40

What would you NOT see in an intralveolar septum?

• reticular fiber
• elastic fiber
• pneumocyte type II
• colagen fiber
• fibroblast
• sinusoidal capillary
• basal lamina
• macrophage

Answer 40

There are no sinusoidal capillaries in the lungs.

Question 41

Which structure assists in adding humidity to inspired air?

Answer 41

Bowman’s glands in the lamina propria secrete mucus.

Question 42

Is this respiratory or conducting portion?

Answer 42

Conducting

Question 43

The volume of anatomic dead space is about __mL per pound ideal body weight

Answer 43

1mL per pound ideal body weight

(Obese people’s lungs don’t get any bigger)

Question 44

Bronchi are defined by the presence of

Answer 44

cartilage, which keeps the airways open

Question 45

As you go from nose > trachea > alveoli, what happens the partial pressure of O2, H2O, CO2, and N2?

Answer 45

O2 & N₂ decrease

H2O & CO2 increase

Question 46

pO₂ =

Answer 46

P_atm x FO₂

Ex) In Denver, where the barometric pressure is 619mmHg, pO₂ = 619 x .21 = 130mmHg

Question 47

Going from trachea to bronchi, cross sectional area ___

Answer 47

DEcreases

But from bronchi to bronchioles and onwards, it starts increasing

Question 48

If you haev a high heartrate or the lungs are damaged, then blood will spend ___ time in the pulmonary capillaries.

Answer 48

LESS time in the pulmonary capillaries –> not enough time to equilibrate w/the alveolar gas –> hypoxemia

Question 49

What is the A-a gradient? Do we want it to be high or low?

Answer 49

The gradient between the alveolus (A) and the pulmonary arteriole (a). (age/4)+4

The lower, the better.

Question 50

The partial pressure of oxygen

At the nose

At the trachea

At the alveolus

Answer 50

Nose = 160mmHg

Trachea = 150mmHg

Alveolus = 100mmg

Question 51

Smoking

Answer 51

damages cilia

Question 52

The pressure inside a distensible sphere (like an alveolus) is determined by

Answer 52

wall tension (directly proportional)

radius of sphere (indirectly)

Usually, small alveoli are higher pressure bc of their small radius, so they would blow up the larger ones and collapse themselves. With surfactant, T is reduced so that P in the smaller alveoli is decreased and equalized w the larger ones.

Question 53

3 advantages of surfactant

Answer 53

1. Lower surface tension & increase compliance –> less work to breathe
2. Reduces the tendency of smaller alveoli to collapse and blow up the larger ones
3. Reduces hydrostatic pressure in the tissue outside the pulmonary capillaries (keeps the lungs dry)

Question 54

A premature infant in gestational wk 25 has neonatal respiratory distress syndrome. Which is expected in this infant?

• Arterial pO2 of 100mmHg
• collapse of small alveoli
• Increased lung compliance
• Normal breathing rate

Answer 54

25wk old neonates don’t have surfactant.

So compliance would increase and the small alveoli would collapse.

Increased work to breathe –> shallower breaths

Question 55

What is the PO2 (in mm Hg) of moist inspired gas of a climber on the summit of Mt. Everest (assume barometric pressure is 247 mm Hg)?

Answer 55

FiO2 x (Barometric pressure-water vapor)

= 0.21 (247-47)

= 42 mm Hg