Respiratory Physiology

Question 1

What is surfactant?

Answer 1

Used to greatly reduce surface tension, is produced by Type II alveolar epithelial cells (pneumocytes).

Question 2

What is tidal breathing?

Answer 2

Tidal volume → volume inspired or expired with each normal breath

Question 3

What is inspiratory reserve volume?

Answer 3

Inspiratory reserve volume → extra volume of air that can be inspired over and above the normal tidal volume

Question 4

What is expiratory reserve volume?

Answer 4

Expiratory reserve volume → extra amount of air that can be expired by forceful expiration after the end of a normal tidal expiration

Question 5

What is residual volume?

Answer 5

Residual volume → volume of air remaining in the lungs after the most forceful expiration

Question 6

What is inspiratory capacity?

Answer 6

Inspiratory capacity → equals the tidal volume + inspiratory reserve volume
• The amount of air a person can breathe beginning at the normal expiratory level and distending the lungs to the maximum amount.

Question 7

What is functional residual capacity?

Answer 7

Functional residual capacity → expiratory reserve volume + residual volume
• This is the amount of air that remains after normal expiration.

Question 8

What is vital capacity?

Answer 8

Vital capacity → inspiratory reserve volume + tidal volume + expiratory reserve volume
• This is the maximum amount of air a person can expel from the lungs after first filling the lungs to their maximal extent and then expiring to their maximal extent

Question 9

What is total lung capacity?

Answer 9

Total lung capacity →Equals the vital capacity + residual volume
• Maximal volume to which the lungs can be expanded with the greatest possible inspiratory effort

Question 10

How does alveolar ventilation occur?

Answer 10

• Alveolar ventilation: rate at which air reaches the gas-exchange regions
o The gas in the air really only goes down to the terminal bronchioles and not into the alveoli during normal inspiration. It makes it the rest of the way by simple diffusion.

Question 11

What is the difference between anatomic and physiologic dead space?

Answer 11

• Physiological dead space → equal to the number of alveoli not participating in gas exchange
• Anatomic dead space → refers solely to those airways not participating in gas exchange whereas physiologic dead space is equal to the anatomic dead space plus the non-functional alveoli (anatomic and physiologic dead space or nearly equal in healthy patients)

Question 12

What is the rate of alveolar ventilation?

Answer 12

Alveolar ventilation per minute is the total amount of new air entering the alveoli per minute. It is equal to the amount of new air that enters the alveoli X the respiratory rate (Va=RR X (Vt-Vd))
• Vd = dead space
• Vt = tidal volume

Question 13

What is the greatest resistance to passage of air in a normal patient?

Answer 13

The resistance of the large airways

Question 14

Sympathetic stimulation to airways leads to…..

Answer 14

Bronchodilation (B2 adrenergic)

Question 15

Parasympathetic stimulation to airways leads to ….

Answer 15

Bronchoconstriction via acetylcholine release (muscarinic)

Question 16

What is the result of histamine in the airways?

Answer 16

Bronchiole constrictions (works locally)

Question 17

Describe the cough reflex.

Answer 17

Bronchi and trachea are very sensitive to light touch (larynx and carina especially sensitive)
Afferent signals pass from the respiratory passageways to the medulla by way of the vagus nerve. The initiates an influx of air and subsequent closure of the epiglottis and vocal folds to trap the air in the lungs. The abdominal muscles contract and forcefully expel the air.

Question 18

Describe the sneeze reflex.

Answer 18

Irritants in the nose send afferent signals to the medulla by way of CN V

Question 19

What is the function of the nose?

Answer 19

Air is warmed, humidified, and filtered. Turbulent filtration occurs as the air hits the turbinates and must change direction

Question 20

What occurs in automatic control of pulmonary blood flow distribution?

Answer 20

Decreased oxygen concentration in the alveoli (less than 73 mmHg PO2) results in vasoconstriction of the surrounding vessels →shunting blood away from the hypoxic alveoli.
• This is the opposite of what occurs in the other vascular beds

Question 21

What is the normal direction of fluid flow in the pulmonary capillaries?

Answer 21

The normal outward forces of the capillary are just slightly greater than the inward force and so fluid constantly leaks into the interstitium (pumped back into circulation through lymphatics through slight negative interstitial pressure)

Question 22

What are the layers of the respiratory membrane?

Answer 22

o Layer of fluid lining alveolus (containing surfactant: surface tension of alveolar fluid)
o Alveolar epithelium composed of thin epithelial cells
o Epithelial basement membrane
o Thin interstitial space btwn alveolar epithelium and capillary membrane
o Capillary basement membrane (fuses with alveolar epithelial basement membrane)
o Capillary endothelial membrane

Question 23

What are factors that affect the diffusion of gas through the respiratory membrane?

Answer 23

Thickness of membrane (edema, fibrosis), surface area of membrane (↓ by lung removal, emphysema), diffusion coefficient of gas in membrane (CO2 20x faster than O2), partial pressure difference of gas btwn 2 sides of membrane (PP> alveoli than in blood (O2), net diffusion from alveoli into blood; PP> blood (CO2), net diffusion from blood to alveoli)

Question 24

What are the two extremes of V/Q mismatches?

Answer 24

Ventilation-perfusion ratio (V/Q): Respiratory exchange when imbalance btwn alveolar ventilation and alveolar blood flow
o No exchange f gases
V/Q = 0 → Ventilation zero, yet there is still perfusion
V/Q = infinity →Ventilation adequate, but zero perfusion

Question 25

What determines tissue PO2?

Answer 25

Tissue PO2 determined by rate of O2 transport to tissue in blood and rate at which O2 is used by tissues

Question 26

What is the role of hemogloblin in oxygen transport?

Answer 26

• 97% O2 carried on hemoglobin in RBCs

* 3% O2 dissolved in water in plasma and blood cells

Question 27

How does oxygen reversible bind to hemoglobin?

Answer 27

O2 combines loosely/reversibly with heme portion of hemoglobin
o PO2 high = O2 binds to hemoglobulin (pulmonary caps)
o PO2 low = O2 is released (tissue caps)

Question 28

What is the oxygen-hemoglobin dissociation curve?

Answer 28

↑ % Hemoglobin bound as PO2 ↑ = percent saturation of hemoglobin
o When PO2 = 95 mmHg → 97% bound to Hgb
o When PO2 = 40 mmHg (tissues) → 75% bound to Hgb

Question 29

Name the factors that can affect the oxygen-hemoglobin dissociation curve?

Answer 29

• pH Changes:
o Acidic (7.4 → 7.2): Shifts curve to right (about 15%)
o Basic (7.4 → 7.6): Shifts curve to left
• ↑ CO2 concentration → Shifts curve to right
• ↑ Blood Temperature → Shifts curve to right
• ↑ 2,3-biphosphoglycerate (BPG) → Shifts curve to right
o Phosphate compound in blood

Question 30

What is the Bohr Effect in regards to the oxygen-hemoglobin dissociation curve?

Answer 30

Shift of curve to right (due to ↑ CO2 or ↑ Hydrogen ions)→ Significant enhancement of release of O2 from blood into tissues, enhancing oxygenation of blood in lungs → Bohr Effect
o Blood passes through tissue: CO2 diffuses from tissue cells to blood → ↑ blood PCO2 → ↑ blood H2CO3 (carbonic acid) and hydrogen ions → Shifts curve to right and downward → forcing O2 away from Hgb and thus delivering ↑ O2 to tissues
o Lungs: CO2 diffuses from blood into alveoli → ¯ blood PCO2 → ¯ hydrogen ions → Shifts curve to left and upward → Greater binding of O2 to Hgb at any given alveolar PO2

Question 31

Explain the dissociation of carbonic acids into bicarbonate and hydrogen ions.

Answer 31

Carbonic acid (in RBC, H2CO3) dissociates into hydrogen and bicarbonate ions (H+ and HCO3-) = Faster with carbonic anhydrase
o About 70% CO2 transported to lungs from tissue
• H+ combine with Hgb (powerful acid-base buffer)

Question 32

What is the chloride shift in RBCs?

Answer 32

• Many ions diffuse from RBCs into plasma (Cl takes their place in RBCs = bicarbonate-chloride carrier protein → 2 ions in opposite directions
o Cl content of RBCs greater in venous than arterial RBCs → Chloride Shift (phenomenon)

Question 33

What are the main forms that CO2 travels in the body?

Answer 33

1. Dissolved in solution
2. Bicarbonate (Major form)
3. Combined with hemogloblin (o CO2 reacts with water, amine radicals of Hgb → carbaminohemoglobin (CO2Hgb)
   o Reversible rxn – slow!!
   o Only small amount of CO2 reacts this way (1/4th quantity of Hgb)
   o Carbamino + Hgb and plasma protein: 30% total amount transported

Question 34

What is the Haldane Effect?

Answer 34

o ↑ CO2 in blood causes O2 to be displaced from Hgb (Bohr effect)
o Important factor for ↑ O2 transport
o Opposite true: Binding of O2 with Hgb tends to displace CO2 from blood (Haldane effect)
More important at promoting CO2 transport than the Borh effect is at promoting O2 transport Combination of O2 with Hgb in lungs causes Hgb to become a stronger acid
• Displaced CO2 from blood into alveoli:
1. More highly acidic Hgb has less tendency to combine with CO2 to form carbaminohemoglobin (displacing more CO2 that is present in carbamino form in blood)
2. ↑ Acidity of Hgb causes release of excess Hydrogen ions and binds with bicarbonate to form carbonic acid (dissociated in water and CO2 and CO2 is releases from blood into alveoli into air)

Question 35

Describe what occurs with control of normal breathing (nervous control).

Answer 35

Normal quiet breathing is controlled by repetitive inspiratory signals from dorsal respiratory group transmitted to diaphragm; expiration is passive elastic recoil of lungs and thorax

Question 36

What is the Hering-Breuer inflation reflex?

Answer 36

o Lung inflation signals limit inspiration (Hering-Breuer inflation reflex)
Stretch receptors in the lungs transmit signals via the vagus nerve to the dorsal respiratory group to limit inspiration when the lungs are full of air
Similar to the pneumotaxic center in that it switches off the inspiratory ramp = inhibits inspiration (but increases the respiratory rate) when the lungs are full

Question 37

What is the role of CO2 in controlling respiration?

Answer 37

Excess carbon dioxide or H+ ions → stimulate the respiratory center directly to increase strength of inspiration and expiration
• Hydrogen ions are the only important stimulus for the chemosensitive area
• However, H+ do not readily cross the BBB or Blood-CHSF barrier; thus CO2 ends up being more important

Question 38

What is the role of O2 in controlling respiration?

Answer 38

Oxygen → no direct effect on respiratory center; acts on peripheral chemoreceptors in carotid and aortic bodies → signals to respiratory center

Question 39

Explain what occurs at the BBB with H+ and CO2 to stimulate respiration.

Answer 39

Effect of blood PCO2 in stimulating the chemosensitive area
• CO2 + H2O → carbonic acid → HCO3- + H+ → H+ after CO2 has diffused across BBB
• Chemosensitive region is stimulated much more rapidly if the CO2 enters via the CSF rather than the brain interstitial water (less protein buffers for the hydrogen in the CSF)
• The excitation of the respiratory center to the increased CO2 is great within the first few days but subsequently declines over the next 1-2 days
o Dt renal compensation for acidosis by retaining bicarb, AND bicarb diffusing across BBB to buffer H+ there

Question 40

Explain the role of peripheral chemoreceptors in respiration. What are they are more responsive to?

Answer 40

o More responsive to changes in the oxygen content of blood but also respond to changes in pH and carbon dioxide.
o Carotid bodies: bilaterally @ bifurcation of common carotids; pass from Hering’s nerves to the glossopharyngeal nerves and onto the dorsal respiratory group
o Aortic bodies: @ aortic arch; pass from the vagus nerve to the dorsal respiratory group
o These bodies are constantly exposed to only arterial blood

Question 41

What happens in the peripheral chemoreceptors when O2 falls below 60 mmHg?

Answer 41

When the pO2 falls below 60 mm Hg, nerve impulses from the carotid body increase rapidly and respiration increases

1. Stimulation by low PO2 may occur via glomus cells in bodies → synapse with nerve endings (or may be direct sensitivity of nerve endings to O2)
2. Increased CO2 and H+ also activate chemoreceptors; this effect is much less in magnitude than their direct effect, but occurs more rapidly

Question 42

What stimulates ventilation during exercise?

Answer 42

Chemical signals ARE NOT the stimulus for increased respiration during exercise (they are normal!)
1, Instead, brain higher functions send collateral messages to the respiratory centers (while they are sending messages to muscles to stimulate contraction)
2. Movements of the limbs stimulates joint and muscles proprioceptive receptors that transmit impulses to the DRG to stimulate ventilation

Question 43

What is Cheyne-Stokes breathing?

Answer 43

o Characterized by slowly waxing and waning respiration, occurring over and over again about every 40-60 secs
o The basic cause is due to transient overbreathing:
1. Blow off too much CO2 → delay before changed pulmonary blood can be transported to brain and inhibit excess ventilation
2. When overventilated blood eventually reaches the brain, the center becomes depressed an excessive amount → CO2 increases in alveoli → again takes brain delay before it catches up

Question 44

Name 5 major categories of hypoxemia?

Answer 44

Extrinsic problems
• 1. Low FIO2 (high altitude)
• 2. Hypoventilation (neuromuscular disease)
 Pulmonary disease 
• 2. Hypoventilation (increased airway resistance, decreased lung compliance)
• 3. Diffusion impairment
• 4. V/Q mismatch 
o High V/Q: physiologic dead space
o Low V/Q: physiologic R-L shunt
Anatomic shunts
• 5. Right-to-left cardiac shunts 
 Inadequate O2 transport to tissues
• 6. Anemia or abnormal Hgb
• 7. Hypovolemic shock
Inadequate capability of the cells to use oxygen (uncoupling of oxidative phosphorylation)
• 8. Metabolic abnormalities, cyanide toxicity

Question 45

Describe when oxygen therapy will be effective in hypoxemia.

Answer 45

1. 100% effective with decreased atmospheric oxygen
2. Pretty effective (5x O2 delivery) with hypoventilation hypoxia
3. Pretty effective with a decreased alveolar membrane diffusion because the increased PaO2 facilitates diffusion at a higher partial pressure
4. Minimally effective in hypoxia caused by anemia, abnormal hemoglobin transport of oxygen, circulatory deficiency, or physiologic shunt
   • Normal amounts of oxygen are already available to the alveoli
   • Small amount of increased O2 transport in the dissolved state may make a difference
   5, Not effective in hypoxia caused by inadequate tissue use of oxygen

Question 46

What graph is used to assess the compliance of the lungs?

Answer 46

Pressure-volume loops - The slope of each line is the compliance of the lung itself

Question 47

What are the effects of emphysema and pulmonary fibrosis on lung compliance?

Answer 47

Emphysema = Increased lung compliance (loss of elastic fibers)
Pulmonary Fibrosis = Decreased lung compliance (increased stiffness of the lungs)

Question 48

What is the most important component of surfactant?

Answer 48

DPPC (dipalmitoyl phosphatidylcholine) - based on amphipathic nature of phospholipid (hydrophobic on one end and hydrophilic on the other end) - Reduces surface tension depsite small radius on alveoli

Question 49

What is the intrapleural pressure?

Answer 49

It is negative pressure (opposing forces of the lung trying to collapse and the chest wall trying to expand

Question 50

Based on the oxygen-hemoglobin dissoication curve, what is the PO2 when 50% of Hb is saturated?

Answer 50

PO2 at 25 mmHg when Hb 50% saturated

Question 51

Name the 4 major factors that will shift the oxygen-hemogloblin dissociation curve to the right.

Answer 51

Situations when there is a decreased affinity of Hb to oxygen → Unloading of O2 (great in tissue)

1. Increased PCO2
2. Decreased pH (more acidic)
3. Increased temp
4. Increased 2,3-DPG (byporduct of glycolysis)

Question 52

What happens when there is left shift in the oxygen-hemogloblin dissociation curve?

Answer 52

There is an increased affinity of Hb to oxygen → Harder to unload O2 (great in lungs)

Question 53

Where is carbonic anyhdrase found in high concentrations?

Answer 53

In RBCs

Aids in transport of CO2 in blood

Question 54

What is the equation for forming bicarbonate from CO2?

Answer 54

CO2 + H2O → (carbonic anhydrase) H2CO3 → H+ + HCO3-

Question 55

What controls the mechanism of hypoxic vasconstriction?

Answer 55

Direct action of alveolar PO2 on the vascular smooth muscle of pulmonary arterioles

Question 56

Where is the inspiratory center in brain?

Answer 56

Dorsal respiratory center

Question 57

Where is the expiratory center in brain?

Answer 57

Ventral respiratory center

Question 58

What Law governs the diffsuion of O2 and CO2 across membranes?

Answer 58

Fick’s Law of Diffusion (driven by partial pressures difference of the gas)

Question 59

How many molecules of oxygen can be bound by 1 Hemoglobin?

Answer 59

4 molecules of Oxygen per 1 Hb

Question 60

What does the sigmoidal shape of the oxygen-hemoglobin curve reflect?

Answer 60

Increased affinity for each successive molecule of O2 that is bound