West Respiratory Phys

Question 1

List other functions of the lung besides gas exchange

Answer 1

Metabolizes some compounds, filters unwanted materials from the circulation, acts as a reservoir for blood

Question 2

Fick’s law of diffusion?

Answer 2

The amount of gas that moves across a sheet of tissue is proportional to the area of the sheet but inversely proportional to its thickness

V = A/T x D x (P1-P2) where A = area, T = thickness, D - diffusion constant, P1, P2 = partial pressure of gas on either side of sheet

Question 3

How thick is the blood-gas barrier?

Answer 3

3 micrometers

Question 4

About how many alveoli in the human lung? How thick are they?

Answer 4

About 500 million; each is 1/3 mm diameter

Question 5

Describe the airways in terms of large structures–>smaller structures using the terms trachea, alveoli, etc

Answer 5

Trachea–>R&L mainstem bronchi–>lobar bronchi–>segmental bronchi–>terminal bronchioles–>respiratory bronchioles–>alveolar ducts–>alveolar sacs

Question 6

What components of the airway are part of the conducting zone? Transitional and respiratory zones?

Answer 6

Conducting- trachea, bronchi, bronchioles, terminal bronchiolesTransitional/respiratory- respiratory bronchioles, alveolar ducts, alveolar sacs

Question 7

Describe the diffusion path from alveolar gas to the interior of the erythrocyte

Answer 7

See pg 3Layer of surfactant–>alveolar epithelium–>interstitium–>capillary endothelium–>plasma

Question 8

What is the function of the conducting airways?

Answer 8

Lead inspired air to the gas-exchanging regions of the lung (example is bronchi)They make up the anatomic dead space b/c they don’t participate in gas exchange

Question 9

What helps increase the volume in the thoracic cavity during inspiration?

Answer 9

Contraction of diaphragm, intercostal muscles raising the ribs

Question 10

Why does inhaled dust frequently settle in the terminal bronchioles?

Answer 10

Because the velocity of gas falls rapidly in the region of the terminal bronchioles

Question 11

A normal breath of 500 ml requires how much distending pressure for the lung?

Answer 11

<3 cm h2o

Question 12

T/F- Initially the pulmonary arteries, veins, and bronchi are far apart but become closer together towards the periphery of the lung?

Answer 12

False- they become further apart towards the periphery

Question 13

What is the diameter of a capillary segment in the lung?

Answer 13

about 7-10 micrometers, just big enough for a RBC

Question 14

What are some reasons why the capillaries in the lung can be easily damaged?

Answer 14

Extremely thin, inflation of the lung can raise the wall stresses of the capillaries and cause structural changes– this can cause leakage of plasma and even RBC into alveolar spaces

Question 15

What is the function of surfactant?

Answer 15

Dramatically lowers the surface tension of the alveolar lining layer- increases stability of alveoli, although collapse of small airways is still possible

Question 16

Mechanism of filtering out particles in the different areas of the airways?

Answer 16

Nose- filters out large particlesConducting airways- filters small particles via mucociliary ladder into epiglottis, where they are swallowedAlveoli- no mucociliary ladder; macrophages engulf the particles and they are removed via lymphatics or blood flow

Question 17

What is functional residual capacity?

Answer 17

Volume of gas in the lung after normal expiration

Question 18

Definition of total ventilation?

Answer 18

Total volume of air leaving the lung each minute (volume of each breath x RR in bpm)

Question 19

What does Boyle’s law state?

Answer 19

Pressure x volume is constant at constant temperature (P1 x V1) = (P2 x V2)

Question 20

Describe the alveolar ventilation equation

Answer 20

Va=[Vco2/Pco2] x K
The partial pressure of CO2 is proportional to the fractional concentration of the gas in the alveoli, or PCO2=FCO2 x K, where K is a constant

Question 21

How do you measure dead space ? (what equation/method?)

Answer 21

Bohr’s method
[VD/VT] = [PACO2-PECO2] / PACO2
*E=mixed expired, A=alveolar

Question 22

T/F: Ventilation per unit volume is greater near the bottom of the lung as opposed to the top of the lung?

Answer 22

True

Question 23

T/F: In the lateral position, the dependent lung is best ventilated?

Answer 23

True

Question 24

[Mult Choice]
Concerning the blood-gas barrier of the human lung:
A. The thinnest part of the blood-gas barrier is about 3 micrometers thick
B. The total area of the blood-gas barrier is about 1 square meter
C. About 10% of the area of the alveolar wall is occupied by capillaries
D. If the pressure in the capillaries rises to unphysiologically high levels, the blood-gas barrier can be damaged
E. O2 crosses the blood-gas barrier by active transport

Answer 24

D

Question 25

How much more rapidly does CO2 diffuse through lung tissue (as compared to O2) and why?

Answer 25

It diffuses about 20 times more rapidly than O2 because it has a higher solubility but not a very different molecular weight. The rate of transfer of a gas is proportional to a diffusion constant, which depends on the properties of the tissue and the particular gas. The constant is proportional to the solubility of the gas and inversely proportional to the square root of the molecular weight.

Question 26

What type of gas is diffusion limited and what does this mean?

Answer 26

Carbon monoxide- the amount of carbon monoxide that gets into the blood is limited by the diffusion properties of the blood-gas barrier and not by the amount of blood available; a large amount of this gas can be taken up by the cell without a resultant increase in partial pressure in the blood (because of the tight bond that forms between it and hemoglobin)

Question 27

What type of gas is perfusion limited and what does this mean?

Answer 27

Nitrous oxide- partial pressure of nitrous oxide rises rapidly when it moves into the blood because it does not combine with hemoglobin; the amount of nitrous oxide in the blood has reached that of alveolar gas by the time the rbc is only 1/10 of the way through the capillary, then no more nitrous oxide is transferred

Question 28

Is oxygen diffusion or perfusion limited in normal health?

Answer 28

Normally, it is perfusion limited like nitric oxide; the pO2 virtually reaches that of alveolar gas when the RBC is about 1/3 the way along the capillary

Question 29

In what situation would O2 be diffusion limited?

Answer 29

When the diffusion properties of the lungs are impaired (thickening of blood-gas barrier). Blood PO2 does not reach the alveolar value by the end of the capillary

Question 30

What are the two stages of uptake of O2 (or CO) to the RBC?

Answer 30

1. Diffusion through the blood-gas barrier (including the plasma and RBC interior)
2. Reaction with hemoglobin

Question 31

What are the normal main pulmonary artery pressures?

Answer 31

Systolic- 25 mm Hg
Mean- 15 mm Hg
Diastolic- 8 mm Hg

Question 32

What are the normal pressures in the LA/LV/RA/RV/aorta?

Answer 32

LA- 5 mm Hg
LV- 120
RA- 2
RV- 25
Aorta- 100

Question 33

T/F: The walls of the pulmonary artery and its branches are thick with a large amount of smooth muscle?

Answer 33

False-Thin walls because the pressures in these vessels is very low; no smooth muscle needed because the blood is staying in the lungs and does not need to be pumped to organs that are far above the level of the heart

Question 34

Define transmural pressure

Answer 34

The pressure difference between the inside and outside of the capillaries

Question 35

What happens to the large vessels (MPA, for example) as the lung expands?

Answer 35

They are pulled open by the radial traction of the elastic lung parenchyma that surrounds them. This leads to low pressure around them (even lower than intrapleural pressure)

Question 36

T/F: The behavior of the capillaries and the larger blood vessels in the thorax are similar?

Answer 36

False- they are so different they are often referred to as alveolar & extra-alveolar vessels

Question 37

What is the difference between alveolar and extra-alveolar vessels in terms of pressure and give an example of each?

Answer 37

Alveolar: capillaries and slightly larger vessels in the corners of the alveolar walls

• Their caliber is determined by relationship between alveolar pressure and pressure within them
• Can be compressed with increased alveolar pressure

Extra-alveolar: arteries and veins that run through the lung parenchyma

• Their caliber is determined by lung volume b/c this determines the expanding pull on their walls
• Not affected by increased alveolar pressure

Question 38

Write the equation for vascular resistance

Answer 38

Vascular resistance= (input pressure-output pressure) / blood flow

Question 39

What is a normal pulmonary vascular resistance?

Answer 39

1.7 mm Hg/liter/min

Question 40

What two mechanisms are responsible for the decreased pulmonary vascular resistance when increased arterial or venous pressure?

Answer 40

1. Recruitment

2. Distension

Question 41

Describe recruitment & distension of pulmonary vessels

Answer 41

1. Recruitment: As pulmonary pressure rises, capillaries that are normally closed open; this is the chief mechanism for lowering pulm vascular resistance
2. Distension: Widening of individual capillary segments; occurs at higher vascular pressures

Question 42

What is the critical opening pressure?

Answer 42

Describes the pressure at which pulmonary artery pressure must be raised above downstream pressure before any flow occurs through the extra-alveolar vessels; this is because the extra alveolar vessels have smooth muscle and elastic tissue that resist distension and reduce the caliber of the vessels when lung volume is low
P 42

Question 43

Name some drugs that increase pulmonary vascular resistance

Answer 43

Histamine, serotonin, norepi

Question 44

Name drugs that can relax smothuc pulmonary ciculation

Answer 44

Acetylcholine, isoproteronol

Question 45

T/F: The lung has equal amounts of blood flow to all the parts of the pulmonary circulation

Answer 45

False- Blood flow decreases almost linearly from bottom to top in upright human lung; reaches very low values at the apex- it is affected by posture and exercise

Question 46

What type of pressure influences the uneven distribution of blood flow in the lung?

Answer 46

Hydrostatic pressure- the difference in pressure between top and bottom of lung is ~23 mm Hg, which is a large pressure difference for such a low pressure system

Question 47

Describe “zone 1” of the lung aka anatomic dead space

Answer 47

Does not occur under normal conditions because pulmonary arterial pressure is just sufficient to raise blood to the top of the lung. If arterial pressure is reduced or alveolar pressure is raised, zone 1 may occur. In this zone, pulmonary artery pressure falls below alveolar pressure and squishes the capillaries, occluding blood flow

Question 48

Describe “zone 2” of the lung

Answer 48

In this zone pulmonary arterial pressure increases b/c the hydrostatic effect and now exceeds alveolar pressure. Venous pressure is still less than alveolar pressure which leads to pressure-flow characteristics.

Question 49

Describe “zone 3” of the lung

Answer 49

Venous pressure>alveolar pressure; flow is determined by arterial-venous pressure difference. There is increased blood flow down this region of the lung caused by distension of the capillaries

Question 50

True or False: Expiration is a passive process during rest

Answer 50

True. The lung and chest wall are elastic and tend to return to their equilibrium positions after being expanded during inspiration

Question 51

What is hysteresis?

Answer 51

This is the phenomenon of a difference in the pressure-volume curve on inspiration v. expiration. The lung volume at any given pressure during deflation is larger than during inflation.

Question 52

The slope of the pressure-volume curve is also known as….

Answer 52

Compliance = Change in Volume / Change in Pressure

Question 53

A reduced lung compliance can be seen in what conditions?

Answer 53

Increase of fibrous tissue in the lungs, pulmonary edema, atelectasis, and with high pulmonary venous pressure

Question 54

An increased lung compliance can be seen in what conditions?

Answer 54

Pulmonary emphysema, and in the normal aging lung due to changes in the elastic tissue of the lung

Question 55

What cells make surfactant and what is DPPC?

Answer 55

Surfactant is made by type II pneumocytes. Surfactant is a phospholipid of which dipalmitoyl phosphatidylcholine (DPPC) is an important constituent. DPPC is synthesized in the lung from fatty acids.

Question 56

How does surfactant reduce surface tension?

Answer 56

The molecules of DPPC are hydrophobic at one end and hydrophilic at the other. When they align themselves, the intermolecular repulsive forces oppose the normal attractive forces between the liquid molecules normally responsible for surface tension.

Question 57

Name 3 physiological advantages of surfactant

Answer 57

1. A low surface tension in the alveoli increase the compliance of the lung and reduces the work of expanding it with each breath.
2. They promote stability of the alveoli by reducing the tendency of small alveoli to empty into large alveoli.
3. They help to keep the alveoli dry by reducing the hydrostatic pressure in the tissue outside the capillaries.

Question 58

What is Poiseuille’s law for laminar flow?

Answer 58

Volume flow rate = (Driving pressure * Pi * radius^4)/ (8 *viscosity * length)

Question 59

What is Reynold’s number and what is the equation for it?

Answer 59

Reynold’s number determines whether flow will be laminar or turbulent. A value greater than 2000 is most consistent with turbulent flow.

Re = 2rvd / n
where r is radius, v is average velocity, d is density, and n is viscosity.

Question 60

What is the major site of resistance in the bronchial tree?

Answer 60

The medium-size bronchi contribute the most to airway resistance.

Question 61

What % of oxygen consumption is done during quiet breathing?

Answer 61

Less than 5%

Question 62

What is Laplace’s law?

Answer 62

Pressure = (2 x surface tension) / radius

Pressure is inversely proportional to the radius for the same surface tension

Is 4 x surface tension / radius if the sphere is a bubble

Question 63

What is Cheyne-Stokes respiration?

Answer 63

Periods of apnea of 10-20 seconds, followed by equal periods of hyperventilation when the tidal volume gradually waxes and then wanes. This is seen in patients at high altitude (especially during sleep), it is also seen in patients with severe heart disease or brain disease.

Question 64

Describe hypoxic pulmonary vasoconstriction

Answer 64

When the PO2 of alveolar gas is reduced, there is contraction of smooth muscle in the walls of small arterioles in the hypoxic region.

Question 65

What is the mechanism of hypoxic pulmonary vasoconstriction?

Answer 65

Unknown; possibly inhibition of voltage gated K channels and membrane depolarization, leading to increased Ca ion concentration in the cytoplasm. Increased cytoplasmic Ca ion concentration is the major trigger for smooth muscle contraction
Nitric oxide may also be inhibited

Question 66

At what alveolar PO2 does hypoxic pulmonary vasoconstriction occur?

Answer 66

<70 mm Hg; at lower values the local blood flow may even be almost abolished

Question 67

How does NO play a role in hypoxic pulmonary vasoconstriction (HPVC)?

Answer 67

It’s an endothelium-derived relaxing factor for blood vessels. Formed from L-arginine via catalysis by endothelial NO synthase. Activates guanylate cyclase and increases synthesis of cyclic GMP, which leads to smooth muscle relaxation. Inhibitors of NO synthase augment hypoxic pulmonary vasoconstriction

Question 68

What role do pulmonary vascular endothelial cells play in pulmonary vasculature?

Answer 68

They release potent vasoconstrictors such as endothelin-1 and thromboxane A2.

Question 69

Why is HPVC important ?

Answer 69

Helps direct blood flow away from hypoxic areas of lung, making deleterious effects on gas exchange less severe. Also occurs during fetal life

Question 70

Concerning the ventilatory response to carbon dioxide:
A. It is increased if the alveolar PO2 is raised.
B. It depends only on the central chemoreceptors.
C. It is increased during sleep.
D. It is increased if the work of breathing is raised.
E. It is a major factor controlling the normal level of ventilation.

Answer 70

E is correct. The normal level of ventilation is controlled by the ventilatory response to CO2.

The ventilatory response to CO2 is increased if the alveolar PO2 is reduced, the ventilatory response depends on the peripheral chemoreceptors in addition to the central chemoreceptors, and the ventilatory response is reduces during sleep and if the work of breathing is increased.

Question 71

Concerning the ventilatory response to hypoxia:
A. It is the major stimulus to ventilation at high altitude.
B. It is primarily brought about by the central chemoreceptors.
C. It is reduced if the PCO2 is raised
D. It rarely stimulates ventilation in patients with chronic lung disease.
E. It is important in mild carbon monoxide poisoning.

Answer 71

A is correct. Ventilation increases greatly at high altitude in response to hypoxic stimulation of chemoreceptors.

It’s the peripheral chemoreceptors, not the central, that are responsible for the response. The response is increased if the PCO2 is also raised. Hypoxic stimulation is often important in patients with longstanding severe lung disease who have nearly normal values for the pH of the CSF and blood. Mild carbon monoxide poisoning is associated with a normal arterial PO2, and therefore, there is no stimulation of the peripheral chemoreceptors.

Question 72

The most important stimulus controlling the level of resting ventilation is:
A. PO2 on peripheral chemoreceptors.
B. PCO2 on peripheral chemoreceptors.
C. pH on peripheral chemoreceptors.
D. pH of CSF on central chemoreceptors.
E. PO2 on central chemoreceptors

Answer 72

D. is correct. The most important stimulus comes from the pH of the CSF on the central receptors.

The effect of PO2 on the peripheral chemoreceptors under normoxic conditions is very small. Changes in PCO2 do affect the peripheral chemoreceptors but the magnitude is less than that for the central chemoreceptors. The effect of changes in pH on peripheral chemoreceptors under normal conditions is small, and changes in PO2 don’t affect the central chemoreceptors.

Question 73

What is the Henderson-Hasselbach equation

Answer 73

pH = 6.1 + log [ (HCO3) / (0.03 x PCO2) ]

Question 74

How does NO play a role in hypoxic pulmonary vasoconstriction?

Answer 74

It’s an endothelium-derived relaxing factor for blood vessels. Formed from L-arginine via catalysis by endothelial NO synthase. Activates guanylate cyclase and increases synthesis of guanosine

Question 75

hello

Answer 75

test

Question 76

What is Starling’s Law?

Answer 76

Net flow out = K (Pc - Pi) - δ (πc - πi)

K = filtration coefficient, δ = reflection coefficient, P = hydrostatic pressure, π = colloid osmotic pressure

Question 77

Why is HPVC important ?

Answer 77

Helps direct blood flow away from hypoxic areas of lung, making deleterious effects on gas exchange less severe. Also occurs during fetal life

Question 78

Net fluid equation for the lungs?

Answer 78

K[(Pc-Pi)-(omega)(IIc-IIi)]
K-constant (filtration coefficient)
P-hydrostatic pressure
omega-reflection coefficient
II- pi, osmotic pressure

Question 79

What is the approximate COP within a capillary?

Answer 79

25-28 mm Hg

Question 80

What is the approximate COP of interstitial fluid in lung?

Answer 80

20 mm Hg

Question 81

Where does fluid go when it leaves the pulmonary capillaries (when it leaks out into interstitium)

Answer 81

Is removed via lymphatics in perivascular space and is drained by hilar LN

Question 82

Where does pulmonary edema accumulate in the lung in early vs late stages?

Answer 82

Early- interstitial edema, peribronchial and perivascular spaces
Late- Fluid crosses alveolar epithelium into alveolar spaces

Question 83

How is fluid pumped out of epithelial cells in alveolar space?

Answer 83

Na/K ATPase

Question 84

T/F: The lung filters blood and removes small blood thrombi before reaching the brain or other vital organs. It also traps WBC to later release them

Answer 84

True

Question 85

What is the only known example of biological activation by passage thru the pulmonary circulation?

Answer 85

Angiotensin I–>angiotensin II via ACE in surface of capillary endothelial cells

Question 86

Name some vasoactive substances that are completely or partially inactivated during passage thru the lung?

Answer 86

serotonin, norepinephrine, prostaglandins E2 & F2alpha, leukotrienes

Question 87

Name some vasoactive materials that pass through the lung w/out significant gain or loss of activity

Answer 87

Epinephrine, prostaglandin A1 & A2, angiotensin II, vasopressin

Question 88

How is the lung involved in clotting mechanisms?

Answer 88

There are a large # of mast cells containing heparin in the interstitium

Question 89

What are the 4 causes of hypoxemia?

Answer 89

1. Shunt
2. Diffusion impairment
3. V/Q mismatch
4. Hypoventilation

Question 90

Name some causes of hypoventilation

Answer 90

Drugs- morphine, barbituates
Damage to chest wall
Paralysis of respiratory muscles
High resistance to breathing

Question 91

Which equation describes the relationship between the fall in PO2 and the rise in PCO2 that occurs in hypoventilation

Answer 91

Alveolar gas equation

P 59

Question 92

T/F: Hypoventilation always reduces the alveolar and arterial PO2 except when the subject breathes an enriched O2 mixture?

Answer 92

True

Question 93

Examples of diffusion impairment?

Answer 93

Exercise, blood-gas barrier thickened, low O2 mixture inhaled

Question 94

Describe shunting of blood and how it causes hypoxemia

Answer 94

Refers to blood that enters the arterial system without going thru ventilated areas of the lung

Question 95

At sea level and body temperature, what is the PO2 in the inspired air? in the lungs? in the mitochondria?

Answer 95

150 mmHg
100 mmHg
30 mmHg

Question 96

What is the fluctuation in alveolar Po2 with each breath?

Answer 96

The fluctuation in alveolar Po2 with each breath is only about 3 mm Hg, because the tidal volume is small compared with the volume of gas in the lung

Question 97

What is a normal alveolar PCO2?

Answer 97

40 mmHg

Question 98

T/F: PO2 in the tissue/mitochondria is about 30 mmHg and identical throughout the body

Answer 98

The “tissue” PO2 probably

differs considerably throughout the body, and in some cells at least, the PO2 is as low as 1 mm Hg. However,

Question 99

What are possible causes for hypoventilation?

Answer 99

Drugs as morphine and barbiturates that depress the central drive to the respiratory muscles, damage to the chest wall or paralysis of the respiratory muscles, and a high resistance to breathing (for example, very dense gas at great depth underwa- ter)

Question 100

What is the relationship between alveolar ventilation and PCO2, derived from the alveolar ventilation equation?

Answer 100

PCO2 =

[(CO2 production) / (alveolar ventilation)] x K (constant)

Question 101

What is the respiratory exchange ratio?

Answer 101

The respiratory exchange ratio is given by the CO2

production/O2 consumption and has a normal value of 0.8

Question 102

Give the simplified form of the alveolar gas equation

Answer 102

Alveolar PO2 (PAO2) is the PO2 from the inspired gas (PIO2) minus the PO2 consumed (using respiratory exchange ratio):

PAO2 = PIO2 - [PACO2/R] + F

Where: R is the respiratory exchange ratio and F is a small correction factor

Question 103

If alveolar ventilation is suddenly increased after an episode of hypoventilation, which one comes to equilibrium first: alveolar PO2 or alveolar PCO2

Answer 103

The alveolar PCO2
takes longer to come to equilibrium due to the
large amount of CO2
in the form of bicarbonate in the blood and interstitial fluid

Question 104

Give 2 reasons for the fact that PO2 of arterial blood does not reach PO2 of alveolar gas

Answer 104

• Incomplete O2 diffusion
• Shunt (blood enters the arterial system without going through ventilated areas of the lung, ex. arteries perfusing bronchi or coronary venous blood that drains directly into the left ventricle)

Question 105

How many mLs of O2 is dissolved in 100 mLs of blood for each mmhg of PO2?

Answer 105

0.3 ml O2/100 mL of blood for each mmhg of PO2

Question 106

Which form of hemoglobin binds oxygen? Ferrous or ferric

Answer 106

Ferrous hemoglobin.

Ferric hemoglobin (methemoglobin) cannot bind oxygen.
Ferrous ion is oxidized to the ferric form by various drugs and chemicals, including nitrites, sulfonamides, and acetanilid.

Question 107

Above what PO2 does the Hb-O2 dissociation curve becomes flatter?

Answer 107

PO2 50 mmhg

Question 108

Give the definition of O2 capacity

Answer 108

O2 capacity is the maximum amount of O2 that can be combined with Hb.

Question 109

How many mls of O2 is combined in 1 gram of pure Hb?

Answer 109

1.39 mLs of O2.

Some measurements give 1.34 or 1.36 ml. The reason is that under the normal conditions of the body, some of the hemoglobin is in forms such as methemoglobin that cannot combine with O2.

Question 110

What is the definition of O2 saturation?

Answer 110

The O2 saturation of Hb is the percentage of the available binding sites of hemoglobin that have O2 attached and is given by:
[(O2 combined with Hb) / (O2 ×capacity)] x 100

Question 111

What is the O2 saturation of arterial blood with a PO2

of 100 mmHg? 40 mmHg?

Answer 111

The O2 saturation of arterial blood with PO2 of 100 mm Hg is about 97.5%, whereas that of mixed venous blood with a PO2 of 40 mm Hg is about 75%

Question 112

What form of hemoglobin is the R (relaxed) state/ the T (tense) state?

Answer 112

The oxygenated form is the R (relaxed) state, whereas the deoxy form is the T (tense) state.

Question 113

What is the formula for the total O2 concentration in blood?

Answer 113

[O2] = [1.39 x Hb x %Sat] + 0.003 x PO2

Question 114

What is the effect of anemia on the concentration of oxygen in blood? Effect of polycythemia? effect of carbon monoxide?

Answer 114

For an equal %HbO2 saturation:

• Anemia and carbon monoxide –> lowers the concentration
• Polycythemia –> increases the concentration

Question 115

What is the effect of carbon monoxide on the O2 dissociation curve?

Answer 115

Shift to the left (more tight to Hb)

Question 116

What color is Hb?

Answer 116

Purple

Question 117

Which patient is more likely to appear clinically cyanotic? the anemic or polycythemic patient?

Answer 117

Polycythemic patient

Question 118

What is the consequence of a shift of the O2 dissociation curve to the right?

Answer 118

The O2 affinity of Hb is reduced –> more unloading of O2 at a given PO2 in a tissue capillary

Question 119

What are the factors leading to a shift of the O2 dissociation curve to the right?

Answer 119

Increase in H+ concentration, PCO2, temperature, and the concentration of 2,3-diphosphoglycerate in the red cells (binds to Hb at high concentrations)

(=what would happen in an exercising muscle)

Question 120

What are conditions that affect 2,3-DPG within the red blood cell?

Answer 120

Remember 2,3-diphosphoglycerate (2,3-DPG) is a special intermediate of glycolysis in erythrocytes which is rapidly consumed under conditions of normal oxygen tension. However, when hypoxia is encountered in peripheral tissues, the concentration of 2,3-DPG can accumulate to significant levels within hours

Increase: chronic hypoxia (for example at high altitude or in the presence of chronic lung disease), Erythropoietin treatment

Decrease: hypophosphatemia, stored red blood cells (blood bank), high pyruvate kinase activity

Question 121

What is the affinity of CO for Hb compared to O2?

Answer 121

CO has about 240 times the affinity of O2 for Hb.

For example, at a PCO of 0.16 mm Hg, about 75% of the Hb is combined with CO as COHb

Question 122

What is the solubility of CO2 compared to O2?

Answer 122

CO2 is about 20 times more soluble than O2

Question 123

What are the 3 forms of CO2 carried in the blood in?

Answer 123

CO2 is carried in the blood in three forms: dissolved, as bicarbonate, and in combination with proteins as carbamino compounds.

Question 124

What is the percentage of CO2 that evolves from the blood into the lung, in the dissolved form?

Answer 124

About 10% of the CO2 that is evolved into the lung from the blood is in the dissolved form

Question 125

Differentials for respiratory alkalosis

Answer 125

decreased CO2, hypoventilation, high altitude, anxiety attack, pain, fear, hypotension, pulmonary disease, neurological disorders

Question 126

Differentials for respiratory acidosis

Answer 126

hypoventilation (head trauma, neuromuscular disease, airway obstruction, pleural disease), rebreathing or excess dead space, malignant hyperthermia

Question 127

What receptors are responsible for raising ventilation in response to metabolic acidosis.

Answer 127

peripheral chemoreceptors in response to H+ ions

Question 128

T/F: respiratory compensation in response to metabolic alkalosis occurs most of the time.

Answer 128

False: respiratory compensation sometimes occurs by a reduction in alveolar minute ventilation that raises the pCO2. However, compensation is often small and may be absent.

Question 129

What is the mechanism of respiratory compensation in response to metabolic alkalosis?

Answer 129

Reduction in alveolar minute ventilation that raises pCO2.

Question 130

T/F: CO2 diffuses about 20 times faster than O2 through tissue

Answer 130

True

Question 131

Define hypoxia versus hypoxemia

Answer 131

Hypoxia
Hypoxia[1] is a condition in which the body or a region of the body is deprived of adequate oxygen supply at the tissue level.

Hypoxemia
Hypoxemia is an abnormally low level of oxygen in the blood.[1][2] More specifically, it is an oxygen deficiency in arterial blood.[3] Hypoxemia has many causes, often respiratory disorders, and can cause tissue hypoxia as the blood is not supplying enough oxygen to the body.

Question 132

Discuss the causes of tissue hypoxia

Answer 132

1. hypoxic hypoxia (low PO2 in arterial blood), by pulmonary disease
2. reduced ability of blood to carry oxygen, as in anemia or carbon monoxide
3. reduction in tissue blood flow (shock, local obstruction)
4. toxic substance that interferes with the ability of the tissues to utilize available O2 (histotoxic hypoxia): cyanide

Question 133

What nerves supply the diaphragm and which cervical segments do they come from?

Answer 133

The diaphragm is supplied by the phrenic nerves from cervical segments 3, 4, and 5

Question 134

When the diaphragm is paralyzed, does the diaphragm move up or down during inspiration?

Answer 134

When the diaphragm is paralyzed, it moves up rather than down with inspiration because the intrathoracic pressure falls.

Question 135

T/F: During quiet breathing, expiration is active

Answer 135

F

Question 136

What are the most important muscles for active expiration?

Answer 136

The most important muscles of expiration are those of the abdominal wall, including the rectus abdominis, internal and external oblique muscles, and transversus abdominis.

Question 137

Which muscles assist active expiration? internal intercostal muscles OR external intercostal muscles?

Answer 137

The internal intercostal muscles assist active expiration by pulling the ribs downward and inward (opposite to the action of the external intercostal muscles assisting inspiration)

Question 138

Define hysteresis

Answer 138

The lung pressure-volume curves during inflation and
deflation are different. This behavior is known as hysteresis.
The lung volume at any given pressure during deflation is larger than during inflation.

Question 139

What does the slope of the pressure-volume curve represent?

Answer 139

Compliance

Question 140

What are the reasons for increased or decreased compliance?

Answer 140

• Increased compliance: pulmonary emphysema, normal aging lung
• Decreased compliance: increase of fibrous tissue in the lungs, alveolar edema, atelectasis, increased pulmonary venous pressure

Question 141

What is Laplace’s law?

Answer 141

Laplace’s law: pressure = (4 × surface tension)/radius.

Question 142

Define surface tension

Answer 142

Surface tension is the force (in dynes, for example) acting across an imaginary line 1 cm long in the surface of the liquid

Question 143

What are the physiological advantages of surfactant?

Answer 143

First, a low surface tension in the alveoli increases the compliance of the lung and reduces the work of expanding it with each breath. Next, stability of the alveoli is promoted. A third role of surfactant is to help to keep the alveoli dry.

Question 144

Where is the peripheral chemoreceptor located?

Answer 144

1. carotid bodies at the bifurcation of the common carotid arteries
2. in the aortic bodies above and below the aortic arch

Question 145

True/false: peripheral chemoreceptor’s response is to the concentration of oxygen in arterial rather than to venous.

Answer 145

False: response to the pO2 of artery rather than venous pO2

Question 146

True/false: peripheral chemoreceptors are responsible for all the increase of ventilation that occurs in human in response to arterial hypoxemia

Answer 146

True

Question 147

Where is pulmonary stretch receptors located?

Answer 147

Airway smooth muscle

Question 148

What’s the main reflex of pulmonary stretch receptors? And what’s the name of the reflex?

Answer 148

Hering-Breuer inflation reflex: Slowing or RR due to an increase in expiratory time

Question 149

Location of irritant receptors? What’s the reflex effect of the irritant receptor?

Answer 149

lie between airway epithelial cells, reflex effects include bronchoconstriction and hyperpnea

Question 150

J receptors: where are they located, what’s the reflex effect of J receptors?

Answer 150

in the alveolar walls, close to the capillaries (Juxtacapillary)
result in rapid, shallow breathing, although intense stimulation causes apnea

Question 151

What are the activators of J receptors?

Answer 151

1. engorgement of pulmonary capillaries

2. increase in the interstitial fluid volume of the alveolar wall

Question 152

In what condition (disease) J receptors play a role in the rapid, shallow breathing and dyspnea?

Answer 152

Left heart failure, interstitial lung disease

Question 153

T/F: arterial baroreceptors

1. increase in arterial blood pressure can cause reflex hypoventilation or apnea through stimulation of aortic and carotid sinus baroreceptors
2. Decrease in blood pressure may result in hyperventilation

Answer 153

True

Question 154

True/False: lowering the PO2 may result in higher ventilation for a given PCO2

Answer 154

True

Question 155

What causes the rightward shift of the O2 dissociation curve at moderate altitude?

Answer 155

Increase in concentration of 2-3-DPG, which develops primarily because of respiratory alkalosis

Question 156

At higher altitude, which direction does the O2 dissociation curve shift?

Answer 156

Leftward shift due to respiratory alkalosis

Question 157

What’s the mechanism of the development of pulmonary edema from pulmonary hypertension?

Answer 157

arteriolar vasoconstriction is not even, and leakage occurs in unprotected, damaged capillaries. The edema fluid has high protein concentration, indicating that the permeability of the capillaries is increased.

Question 158

Where do the first pathological changes associated with oxygen toxicity occur?

Answer 158

endothelial cells of the pulmonary capillary impair gas exchange

Question 159

T/F: Collapse is particularly likely to occur at the bottom of the lung, where the parenchyma is least well expanded or the small airways are actually closed

Answer 159

True

Question 160

What causes decompression sickness?

Answer 160

Formation of nitrogen bubbles during ascent from a deep dive due to high solubility.

Question 161

What are the premonitory symptoms of convulsion from oxygen toxicity?

Answer 161

nausea, ringing in the ears, twitching of the face

Question 162

True/False: the likelihood of convulsions depends on the inspired PO2 and the duration of exposure.

Answer 162

True