1.3.1 Mechanism of Ventilation 2 Flashcards Preview

Pulmonary > 1.3.1 Mechanism of Ventilation 2 > Flashcards

Flashcards in 1.3.1 Mechanism of Ventilation 2 Deck (29)
Loading flashcards...
1
Q

What is the formula for total airway resistance?

A
2
Q

What is important about the FEV1/FVC? What can it indirectly determine?

A

The FEV1 is the volume that can be exhaled during the first second of an FVC maneuver. The normal value for an FEV1/FVC is roughly 0.7 to 0.8. Deviations from this value can provide an indirect estimate of airway resisitance.

3
Q

For a patient with increased airway resistance, how will this effect their value for FEV1?

A

They will have a lower value for FEV1 due to the increased airway resistance.

4
Q
A
5
Q
A
6
Q

What is the site of highest airway resistance?

A

Nose

7
Q

What is the formula for resistance?

A

R = Pressure difference/flow

8
Q
A

Increased airway resistance would not be produced. The stiff lung would help keep the airways open.

9
Q

Add the answer e. If surfactant is added, surface tension will decrease proportionately more in A than in B.

A

Both answer C and E are correct

C - This is correct, surface tension is a characteristic of the liquid; when there is no surfactant the surface tension would be the same everywhere. This is what creates the problem, since, according to Laplace’s law: PALV= 2ST/r. If ST is the same, the value of PALV to maintain the alveoli inflated is higher in the smaller alveolus; since both alveoli are connected the small alveolus collapses and inflates the larger one. If surfactant were present, ST would be lower in the small alveolus and both could remain inflated at the same PALV.

10
Q

What are each of the shaded areas?

A
11
Q

The graphs below represent the airflow-pressure curves of the right and left lungs of a patient. How would this difference influence ventilation in each lung?

A

Airway resistance is higher in the right lung. When the person inspires and reduces PALV, the associated flow will be lower than that in the left lung; i.e. the volume of air entering the lungs per unit time will decrease; this will tend to reduce ventilation.

12
Q

The curve in the attached image is representative of a person giving a low effort expiration and a max effort expiration. How does a low effort vs max effort expiration affect airway resistance?

A

First, the red arch in the first image is due to higher flow because of a greater pressure in the Palv due to contraction of muscles. At first this will generate more flow. The greater ‘squeeze’ on the lungs will also narrow the airways thus increasing the resistance. The pressure inside the airway is lower than the pressure outside the airway, compressing the airway.

The same factors that tend to increase flow (higher PB-PALV), also tend to decrease flow (increased resistance).

13
Q

What is the reason for airflow decreasing with lung volume?

A

The reason that the airflow decreases with lung volume is that the airway resistance increases throughout expiration. This is due to narrowing of the airways as the lungs become smaller. This means that, if airway resistance is increased by disease, it is always more difficult to get air out of the lungs than get air into the lungs.

14
Q

Chronic interstitial pneumonia is a restrictive pulmonary disease characterized by the presence of collagen fibers in the lung parenchyma. The major pathophysiological feature is reduced lung compliance. Which of the following would you NOT expect to see in a patient with this condition?

A. Total lung capacity lower normal

B. Pleural pressure at FRC more negative than normal

C. Residual volume lower than normal

D. FEV1/FVC lower than normal

E. Tidal volume lower than normal

A

D. FEV1/FVC

FEV1/FVC, on the other hand, is not lower than normal. FEV1/FVC is determined by the airway resistance and in these cases airway resistance is normal or even a bit lower than normal. The high tendency of the lung to recoil generates a greater pressure difference between the pleura and the airway, which tends to keep the airways open at all lung volumes. Think of the airways as if tethered by elastic fibers as shown in slide 20 of the Mechanics of Ventilation lecture. The stronger the tendency of the fibers to recoil (i.e., the stiffer the fibers), the smaller the lungs, the wider the airways will be. These patients have difficulty stretching the lungs, but have no trouble getting the air out of the lungs.

15
Q

What does curve C represent in the two graphs?

A

Severe increase in resistance

Such as with severe asthma or COPD, expiration is even slower than in the preceding example, and FEV1/FVC is much less than 75%.

The intense expiratory effort, coupled with the elevated resistance, leads to airway closing at a very high lung volume; air is trapped behind the airway occlusion and residual volume increases and vital capacity decreases.

Increase in RV accounts for the barrel chest associated with COPD

16
Q

What are two mechanisms of increased airway resistance?

A
17
Q

What are the two factors that control the cross-sectional area of the airways?

A

Neurohumoral factors affeting the tone of bronchial smooth muscle

Factors influencing the pressure difference across the airway wall

18
Q

Airway resistance is determined by?

A

Airway diameter - inverse proportion

19
Q

What are the affectors of bronchial smooth muscle tone?

A
20
Q

The graph above represents a forced vital capacity of a healthy 25 year-old man. After a dinner of clams in a fine New Orleans eatery, he developed an anaphylactic reaction with intense bronchoconstriction. What changes would you expect to see in the volumes and capacities listed below?

a. Increase; b. Decrease; c. No change

Select a, b, or c to answer each of the following:

A. Volume 1-2

B. Volume 2-3

C. Volume 3-4

D. Volume 1-4

E. Volume 4-8

F. Slope of line 5-7

A

A-D : Answer is B

E : A

F : B

7A: Volume 1-2 (the inspiratory reserve volume will decrease (Answer: B)

7B: Volume 2-3 is the tidal volume, and this will also tend to decrease (Answer: B)

7C: Volume 3-4 is the expiratory reserve volume, and this will also decrease (Answer: B)

7D: Volume 1-4 is the vital capacity, which will decrease since all its components have decreased (Answer B)

7E. Volume 4-8 is the volume and it will increase: as expiration is limited, the amount of air remaining at the end of the forced expiation is greater than normal. (Answer: A)

7F: Slope of line 5-7 will decrease, (more shallow, lower FEV1/FVC) because the increase resistance does not allow air to flow out as rapidly as normal (Answer: B)

21
Q

Is both of these graphs of differing effort levels, which point has the highest flow?

Explain what is also going on between the effort dependent and effort independent section.

A

At high lung volumes, expiratory flow depends on the expiratory effort, i.e. flow is highest in a, lower in b and lowest of all in c.

As expiration proceeds, and the lungs get smaller, expiratory flow becomes independent of effort. In the effort-independent part of expiration, at any given lung volume, the flow is the same no matter what the effort is.

The mechanism responsible for this is known as dynamic airway compression, and is due to the fact that the high PPL needed to generate a high expiratory airflow tends to narrow the airways and limit the flow.

22
Q

Pulmonary capillaries make up how much of the total resistance?

A

less than 10% due to high cross sectional area

23
Q

The graphs below represent the static pressure volume curves of the right and left lungs of a patient. How would this difference influence ventilation in each lung?

A

Compliance is lower in the left lung. This means that for a given increase in PTP, the increase in volume will be lower in the left lung, consequently ventilation will be lower in the left than in the right lung.

24
Q

What is the VC normally measured as?

A

The vital capacity is usually measured as the Forced Vital Capacity (FVC). In the FVC the patient is not only asked to empty the lungs as completely as possible, but also to do it as rapidly as possible.

25
Q
A
26
Q

What is the vital capacity?

A

the volume of air that can be exhaled in a maximal expiration after having inhaled maximally

27
Q
A
28
Q

What is the formula for flow?

A
29
Q

What does curve B represent in the two graphs? What accounts for these changes?

A

Curve B represents moderately increased airway resistance.

As airway resistance increases, the slope of the FVC tends to flatten. Vital capacity itself does not change, but the individual is not able to exhale as rapidly, and FEV1/FVC decreases

In the flow volume curve, increased resistance is manifested by a lower expiratory flow for any given lung volume.