pulmonary

Question 0

What muscles control expiration?

Answer 0

Expiration is largely passive.
Simply by relaxing, the chest springs back into shape, and expiration can occur without any muscle action.
One can, however, voluntarily exhale forcefully using: external and internal intercostal muscles, the transversus thoracis and innermost intercostal muscles, external oblique, internal oblique and transversus abdominis muscles.

Question 1

What is the main muscle that controls inspiration? And what are the accessory muscles?

Answer 1

The main muscle is the diaphragm. Contraction and downward motion of the diaphragm causes a (-) pressure in the chest, which draws in air.
The accessory muscles of inspiration: pectoralis major and minor, serratus anterior, sternocleidomastoid, scalene muscles, levatores costarum, serratus posterior superior

Question 2

How doe Hgb affect gas exchange?

Answer 2

Oxygen is not very soluble in plasma. Most oxygen (about 97% of it) is transported via hemoglobin, which has special oxygen-binding capabilities. It binds to significant quantities of O2 at the alveolar level, even when O2 conc in the alveoli is relatively low. It also releases O2 easily at the tissue level, but in just the right amounts, since too much can cause oxygen toxicity, and too little will not provide enough for the respiratory needs of the tissue. It also releases large quantities of O2 when the tissues really need it.

Question 3

But how can hemoglobin bind well to oxygen in the alveoli, yet release it easily at the peripheral tissue level?

Answer 3

Oxygen dissociation curve for hemoglobin.
Hgb maintains near saturation (above 90% saturated) even when alveolar O2 decreases from the normal 104mm Hg to 60mm Hg. However, when Hgb encounters the low tissue p02 of the body tissues (normally about 40 mm Hg in interstitial fluid), it readily gives up the oxygen.

Question 4

How does CO2 leaves the body?

Answer 4

CO2 combines with H2O in RBC forming H2CO3.
The H ion from H2CO3 binds with Hgb forming HCO3.
HCO3 leaves the cell, float around the bld until it reaches the lungs.
Hgb releases the H, it combines with HCO3 to form back to H2O and CO2.
CO2 then is expelled by the lungs.

Some CO2 does combine directly to Hgb forming CARBINOHEMOGLOBIN, which releases its CO2 in the lungs

Question 5

There is greater release of oxygen by Hgb when..

In terms of pO2, pCO2, pH, temp

Answer 5

<60mm Hg pO2, high pCO2, low pH, and high temp.

Question 6

What is the rate limiting step in the cell’s oxygen utilization?

Answer 6

Level of ADP.

Question 7

What neural factors control respiration?

Answer 7

Phrenic nerves (C3,4,5) innervates diaphragm and receives voluntary and involuntary message from respiratory centers (medulla and pons)

Question 8

CO2 and Water forms what pH in blood?

Answer 8

Weak acids

Question 9

A slight increase of this pressure potential stimulates the respiration.

Answer 9

PCO2

Question 10

A moderate increase of pCO2 stimulates respiration much more than does a moderate decrease in p02. So why do we need the O2 response mechanism? Wouldn’t it suffice to just have the pCO2 control mechanism?

Answer 10

In severe pulmonary disease, in which there is poor exchange in both O2 and CO2, the CO2 effect is not enough. The large drop in pO2 then comes into play, having a marked effect in increasing the rate of respiration when the pO2 falls to the 30-60 mm Hg range.

Question 11

Then why do we need the CO2 control mechanism? Why does it not suffice to just control respiration according to the O2 level? After all, isn’t it really the O2 that the body needs? Shouldn’t 02 levels alone provide the best feedback control?

Answer 11

CO2 control mechanism is actually needed more for the control of blood pH than for control of respiration. Subtle changes in the pC02 can significantly affect pH, so the body needs the fine CO2 control mechanism to control CO2 levels and thus control pH.

Question 12

Breathing high-pressure oxygen (above atmospheric pressure) can markedly increase the saturation of O2 in the blood, even to toxic levels, not by increased uptake by hemoglobin, but by…

Answer 12

dissolving more of oxygen in plasma.

Question 13

What do you need to do if you want to increase tissue oxygenation?

Answer 13

Increase the O2 conc in the air being breathed, the Hgb conc, or the blood flow ( as by increasing the CO). Hyperventilation is not good enough.

Question 14

In diving, the alveolar pressure rises to meet the increasing atmospheric pressure that results with greater depth. The higher pressure causes more N2 to be dissolved, which may cause N2 toxicity. O2 toxicity may also occur.

Answer 14

On rising from a dive, it is important that the diver gradually let out air. otherwise, the lungs will continue to expand against the decreasing outside envi. pressure, thereby causing lung injury.

Question 15

Normal air outside the body consists about how many percent of 02, N2, CO2 and water?

Answer 15

20% O2
79% N2
0.04% CO2
<1% water

Question 16

At high altitude, as in low altitudes, the alveolar pressure in normal breathing cannot be more than the atmospheric pressure.

Answer 16

The body’s long range compensation to high altitude may occur initially through hyperventilation, and over weeks to months, through increased tissue vascularity and increased numbers of RBC.

Question 17

Between CO2 and O2, which of these is more soluble in air and blood?

Answer 17

CO2

Question 18

What is the normal arterial pO2 level?

Answer 18

95mm Hg

Question 19

What is the normal arterial pCO2?

Answer 19

40mm Hg

Question 20

Normal pO2 in peripheral intracellular level

Answer 20

23mm Hg. But not to worry, the cell needs a pO2 of only about 2mm Hg for adequate functioning

Question 21

It is the amt of air normally inhaled or exhaled with each average breath like the steady tides going in and out.

Answer 21

Tidal volume

Question 22

What is normal amt of TV?

Answer 22

500 ml

Question 23

It is the extra amt you could have inhaled after breathing in normally.

Answer 23

Inspiratory reserve volume.

Question 24

It is the extra amt you could have exhaled after exhaling normally.

Answer 24

Expiratory reserve volume

Question 25

It is the residual left in the lungs after the strongest expiration.

Answer 25

Residual volume.
If you didn’t have a RV, there would be marked fluctuations in CO2 and O2 content of blood passing thru the lungs during respirations.

Question 26

It is the amt of air exchanged from the maximal intake to the most forceful expiration.

Answer 26

Vital capacity

VC = ERV + TV + IRV

Question 27

It is the increase in chest volume with each degree of increase of alveolar pressure.

Answer 27

Compliance.

The greater the increase in lung volume with a given increase in alveolar pressure, the greater the compliance

Question 28

It refers to the tendency of the respiratory system to spring back to its original shape after expansion. It it simple the reciprocal of compliance.

Answer 28

Elastance.
The greater the elastance, the greater tendency to rebound, the greater the rise in pressure that results from an increase in lung volume.

Question 29

Functional residual capacity (FRC) = RV + ERV

Answer 29

Inspiratory capacity (IC) = TV + IRV

Question 30

For the lung, elastance is partly due to elastic tissues in the lungs, but mainly due to…

Answer 30

Surface tension produced by the fluid coating the alveoli (surfactant) which tends to release the resist expansion. Surface tension is normally kept at a reduced level by surfactant

Question 31

It is the total amount if air in the lung after a forceful inspiration.

Answer 31

Total lung capacity.

TLC = VC + RV

Question 32

VC and rate of expulsion is (high, low) in restrictive lung disease and airway obstructive disease.
What is an important distinction between these two?

Answer 32

RV is low in restrictive lung disease while it is high in airway obstructive disease.
Another difference is the FRC, wherein it is low in restrictive lung disease, and high in airway obstructive disease.

Question 33

Which is more difficult (inspiration or expiration) in airway obstructive disease (eg. Asthma, bronchitis, emphysema)?

Answer 33

Expiration. The positive pressure of expiration collapses the respiratory passages.

Question 34

Which is more difficult (inspiration or expiration) in fixed airway obstruction?

Answer 34

Both

Question 35

Which is more difficult (inspiration or expiration) in upper airway ( extrapulmo) obstruction?

Answer 35

Inspiration. The negative pressure of inspiration is transmitted thru bronchi and trachea to cause constriction of areas higher up

Question 36

Oxygen therapy (e.g. using an oxygen tent, face mask or nasal cannula) may be useful in hypoxia secondary to poor atmosphere oxygenation or to poor pulmonary gas exchange from lung disease.

Answer 36

Oxygen administration may help, though, in carbon monoxide poisoning. Carbon monoxide (CO) binds more strongly than does O2 to the same site on the hemoglobin molecule, in effect reducing the number of available RBCs.

Question 37

When the patient cannot breathe or the effort of breathing becomes too much for the patient, it may be necessary to use a mechanical ventilator. Te ventilator is a positive pressure device.

Answer 37

Normally, inspiration occurs because the chest expansion creates a negative pressure in the alveoli, which results in the influx of air from the atmosphere outside the patient, where the pressure is greater.

Question 38

Normal quiet breathing is accomplished almost entirely by movement of the diaphragm.

Answer 38

During heavy breathing, extra force is needed achieved mainly by contraction of abdominal muscles, which pushes the abdominal contents upward against the diaphragm, thereby compressing the lungs.

Question 39

Muscles for inspiration

Answer 39

Diaphragm
Scalene muscles
Sternocleidomastoid
External intercostalis
Serrated anterior

Question 40

Muscles of expiration

Answer 40

Internal intercostalis

Rectus a dominos

Question 41

It is the pressure of the fluid in the thin space between the lung pleura and the chest wall pleura.

Answer 41

Pleural pressure.

Question 42

Pleural pressure at the beginning of inspiration

Answer 42

-5 cm H2O

Question 43

Pleural pressure during inspiration

Answer 43

-7.5cm H2O

Question 44

It is the pressure of the air inside the lung alveoli.

Answer 44

Alveolar pressure.

Question 45

If there is no pulmo respiration, the alveolar pressure is zero references pressure in the airways, that is, 0 cm H2O. How about during inspiration?

Answer 45

-1 cm H2O

Question 46

Alveolar pressure during expiration

Answer 46

+2 cm H2O

Question 47

It is the pressure difference between the alveolar pressure and the pleural pressure and it is the measure of recoil pressure.

Answer 47

Transpulmonary pressure

Question 48

It is the elastic forces in the lungs that tends to collapse the lungs at each instant of respiration, or it is the pressure generated at a given lung volume.

Answer 48

Elastic recoil pressure

Question 49

It is the extent to which he lungs will expand for each unit increase in transpulmonary pressure.

Answer 49

Lung compliance

Question 50

The normal lung compliance

Answer 50

200ml / cm H2O

Question 51

True or false: the tissue elastic forces tending to cause collapse of the air-filled lung represent two-thirds of the total lung elasticity, whereas the fluid-air surface tension forces in the alveoli represent about one-third.

Answer 51

False. the tissue elastic forces tending to cause collapse of the air-filled lung represent only about ONE-THIRD of the total lung elasticity, whereas the fluid-air surface tension forces in the alveoli represent about TWO-THIRDS.

Question 52

A phenomenon where in water surface is attempting to contract. This results in an attempt to force air out of the alveoli thru the bronchi and, in doing so, causes the alveoli to try to collapse.

Answer 52

Surface tension

Question 53

What is the effect of surfactant on surface tension?

Answer 53

Surfactant is a surface active agent in water, which means that it greatly reduces surface tension. It is secreted by type2 alveolar epith cells which are granular.

Question 54

What component of surfactant is responsible for reducing the surface tension

Answer 54

Dipalmitoylphosphatidylcholine

Question 55

True or false: A positive pressure in the alveoli attempts to push the air out.

Answer 55

True.

Question 56

Surfactants are normally begin to be secreted into the alveoli between what months of gestation?

Answer 56

6-7 mos

Question 57

What is the compliance of the combine lung-thorax system?

Answer 57

110 ml / cm H2O.

Question 58

Spirometers is a simple method for studying pulmonary ventilation by recording the volume movement of air into and out of the lungs. What lung vol and capacity can the spirometer measure? And cannot?

Answer 58

Spirometry measures TV, IRV, ERV, IC and VC.

It can’t measure RV, FRC and TLC (because pt can’t expire all the air in his/her lungs)

Question 59

It is the volume of air inspired or expired with each normal breath

Answer 59

Tidal volume

Question 60

What is the normal amt of TV?

Answer 60

500ml

Question 61

It is the extra volume of air that can be inspired over and above the normal tidal volume when the person inspires with full force.

Answer 61

Inspiratory reserve volume

Question 62

What is the usual Amt of IRV?

Answer 62

3000ml

Question 63

It is the maximum extra volume of air that can be expired by forceful expiration after the end of a normal tidal expiration.

Answer 63

Expiratory reserve volume

Question 64

What is the usual amt of ERV?

Answer 64

1100ml

Question 65

It is the volume of air remaining in the lungs after the most forceful expiration.

Answer 65

Residual volume

Question 66

What it the usual amt of RV?

Answer 66

1200ml

Question 67

This is the amount of air (about 3500 milliliters) a person can breathe in, beginning at the normal expiratory level and distending the lungs to the maximum amount.

Answer 67

Inspiratory capacity. The inspiratory capacity equals the tidal volume plus the inspiratory reserve volume.

Question 68

This is the amount of air that remains in the lungs at the end of normal expiration (about 2300 milliliters).

Answer 68

Functional residual capacity. It is equals the expiratory reserve volume plus the residual volume.

Question 69

This is the maximum amount of air a person can expel from the lungs after first filling the lungs to their maximum extent and then expiring to the maximum extent (about 4600 milliliters).

Answer 69

The vital capacity equals the inspiratory reserve volume plus the tidal volume plus the expiratory reserve volume.

Question 70

It is the maximum volume to which the lungs can be expanded with the greatest possible effort (about 5800 milliliters); it is equal to the vital capacity plus the residual volume.

Answer 70

Total lung capacity

Question 71

It is the total amount of new air moved into the respiratory passages each minute; this is equal to the tidal volume times the respiratory rate per minute.

Answer 71

Minute respiratory volume.

Question 72

What is the normal MRV?

Answer 72

MRV = RR x TV; 12beats x 500ml = 6L/min

Question 73

A person can live for a short period with a minute respiratory volume as low as ____ L/min and a respiratory rate of only ____ breaths per minute.

Answer 73

as low as 1.5 L/min and a respiratory rate of only 2 to 4 breaths per minute.

Question 74

The ultimate importance of pulmonary ventilation is …

Answer 74

to continually renew the air in the gas exchange areas of the lungs, where air is in proximity to the pulmonary blood.

Question 75

True or false: On expiration, the air in the dead space is expired first, before any of the air from the alveoli reaches the atmosphere.

Answer 75

True. Therefore, the dead space is very disadvantageous for removing the expiratory gases from the lungs.

Question 76

Normal dead space volume.

Answer 76

150ml. This increases slightly with Age.

Question 77

Rate of alveolar ventilation

Answer 77

12 beats/min x 500ml TV x 150ml dead space = 4200ml/min

Question 78

True or false: cartilage rings are already gone in later generations of bronchi.

Answer 78

False. They are gone in the bronchioles.

Question 79

What is the effect of sympathetic release of norepinephrine and epinephrine on the lungs?

Answer 79

Dilation of bronchial tree

Question 80

What is the effect of parasympathetic release of acetylcholine on the lungs?

Answer 80

Constriction of bronchioles

Question 81

Local secretory factories that often cause bronchiolar constriction.

Answer 81

Histamine and slow reactive substance of anaphylaxis. Both of these are released in lung tissue by mast cells during allergic reactions.

Question 82

The direction of the power stroke of cilia in respiratory passageways is always…

Answer 82

Towards the pharynx. That is, the cilia in the lungs beat upward, whereas those in the nose beat downward.

Question 83

The difference between cough reflex and sneeze reflex.

Answer 83

The initiating stimulus of sneeze reflex is irritation in nasal passageways while cough reflex is in bronchi and trachea.
The afferent impulses of sneeze reflex pass in 5th cranial nerve to medulla, while cough reflex impulse pass in vagus nerve.

Question 84

The automatic sequence events of sneeze and cough reflex is triggered by the neuronal circuits of the medulla, causing the following effect:

Answer 84

1. Up to 2.5 L of air is rapidly inspired
2. Epiglottis closes and vocal cords shut tightly to entrap air within the lungs
3. Expiratory muscles contract forcefully, thus pressure in lungs rises rapidly to as much as 100mm Hg
4. Vocal cords and epiglottis suddenly open widely, causing air in lungs to explode outward.

Question 85

The air conditioning functions of the nose

Answer 85

Air is warmed, humidified and filtered

Question 86

What are the obstructing vanes that the air hits causing removal of particles by turbulent precipitation?

Answer 86

Conchae (Turbinates), septum and pharyngeal wall

Question 87

Size of particles entrapped in nose.

Answer 87

6 micrometer

Question 88

Size of particles entrapped in smaller bronchioles

Answer 88

1-5 micrometers

Question 89

Size of particles suspended in alveolar air and are expelled by expiration.

Answer 89

0.5 micrometer. For instance, the particles of cigarette smoke is 0.3 micrometer.

Question 90

3 major organs of articulation

Answer 90

Lips, tongue and soft palate

Question 91

3 Organs that are resonators

Answer 91

Mouth, nose and asso nasal sinuses, and pharynx

Question 92

The pulmonary artery extends only about how many cm beyond the apex of R ventricle and then divides into L and R main branches that supply blood to 2 respective lungs.

Answer 92

5cm

Question 93

True or false: pulmonary artery has low compliance.

Answer 93

False. It has large compliance which allows the pulmonary arteries to accommodate the stroke volume output of the R ventricle

Question 94

True or false: the bronchial arterial tree is oxygenated blood.

Answer 94

True. It supplies the supporting tissues of the lungs, including the ct, septa and large and small bronchi. It empties to pulmonary veins and enters the L atrium rather than passing back to R atrium.

Question 95

Blood volume of the lungs

Answer 95

450 ml, about 9% of the total bld vol of the entire circulatory system.

Question 96

Lungs is considered as a blood reservoir. Under various physiological and pathological conditions, the quantity of blood in the lungs can vary from as little as one half normal up to twice normal.

Answer 96

For instance, when a person blows out air so hard that high pressure is built up in the lungs— such as when blowing a trumpet—as much as 250 ml of blood can be expelled from the pulmonary circulatory system into the systemic circulation. Also, loss of blood from the systemic circulation by hemorrhage can be partly compensated for by the automatic shift of blood from the lungs into the systemic vessels.

Question 97

What is the effect if diminished alveolar oxygen on local alveolar blood flow?

Answer 97

When the conc of O2 in the air of alveoli decreases below normal, the adjacent bld vessels constrict (opposite to the effect observed in systemic vessels, which dilates in response to low O2)

Question 98

The effect of low oxygen on pulmonary vascular resistance (bv constriction) has an important function…

Answer 98

To distribute blood flow where it is most effective.
That is, if some alveoli are poorly ventilated so that their O2 conc becomes low, the local vessels constrict. This causes the blood to flow through other areas of the lungs that are better aerated, thus providing an automatic control system for distributing blood flow to the pulmonary areas in proportion to their alveolar oxygen pressures.

Question 99

True or false: any time the lung alveolar air pressure becomes greater than the capillary blood pressure, the capillaries close and there is no blood flow.

Answer 99

True

Question 100

Under different normal and pathological lung conditions, one may find any one of three possible zones of pulmonary blood flow.
It is the zone where in the local alveolar capillary pressure in that area of the lung never rises higher than the alveolar air pressure during any part of the cardiac cycle

Answer 100

Zone 1: no blood flow during all portions of the cardiac cycle

Question 101

It is the zone where the pulmonary arterial pressure peaks because the systolic pressure is then greater than the alveolar air pressure, but the diastolic pressure is less than the alveolar air pressure

Answer 101

Zone 2: intermittent blood flow

Question 102

It is the zone where in the alveolar capillary pressure remains greater than alveolar air pressure during the entire cardiac cycle

Answer 102

Zone 3: continuous blood flow

Question 103

Normally, the lungs have only zones 2 and 3 blood flow. Zone 2 in the apices and zone 3 in all lower areas.

Answer 103

Zone 1 blood flow occurs only under abnormal conditions.

Question 104

The mean left atrial pressure

Answer 104

2mm Hg

Question 105

Mean pulmonary arterial pressure

Answer 105

15mm Hg

Question 106

Mean pulmonary capillary pressure

Answer 106

7mm Hg. In contrast to the peripheral capillary pressure of about 17mm Hg.

Question 107

the interstitial fluid pressure in the lung is slightly more negative that that in the peripheral subcutaneous tissue.

Answer 107

The pulmonary capillaries are relatively leaky to protein molecules, so that the colloid osmotic pressure of pulmonary interstitial fluid is 14mm Hg

Question 108

Forces tending to cause the movement of fluid outward form the capillaries and into the pulmonary interstitium:

Answer 108

Capillary pressure: 7
Interstitial fluid colloid osmotic pressure: 14
Negative interstitial fluid pressure: 8

TOTAL OUTWARD FORCE: 29mm Hg

Question 109

Forces tending to cause absorption of fluid into the capillaries

Answer 109

Plasma colloid osmotic pressure: 28

TOTAL INWARD FORCE: 28mm Hg

Question 110

Why alveoli do not normally fill with fluid?

Answer 110

The pulmonary capillaries and the pulmonary lymphatic system normally maintain a slight negative pressure in the interstitial spaces, it is clear that whenever extra fluid appears in the alveoli, it will simply be sucked mechanically into the lung interstitium through the small openings between the alveolar epithelial cells. Then the excess fluid is either carried away through the pulmonary lymphatics or absorbed into the pulmonary capillaries.