exam 2 lecture 17 and 18

Question 1

blue membranes

Answer 1

cyanosis

Question 2

PaO2

Answer 2

pressure of oxygen gas ***dissolved*** in the arterial blood; in mmHg

Question 3

PaCO2

Answer 3

–pressure of carbon dioxide gas ***dissolved*** in the arterial blood; in mmHg

Question 4

SpO2

Answer 4

percentage ***saturation of hemoglobin (Hb) *** in the arterial blood; in %

Question 5

PiO₂

Answer 5

partial pressure of oxygen in inspired gas; mmHg

Question 6

FiO₂

Answer 6

–fraction of oxygen in inspired gas; in %

Question 7

low PaO2 means

Answer 7

hypoxemia

PaO2 is pressure of oxygen dissolved in arterial blood.

Units: mmHg

Question 8

PaO2 vs PAO2

Answer 8

a= arterial

A = alveolar

pressure of dissolved oxygen

Question 9

dalton’s law

Answer 9

•In a gas mixture, the pressure exerted by each gas is independent of the pressure of the others, so all pressures will sum to the total measured pressure

P_air = PN₂ + PO₂ + P(other gases)

Question 10

P_air = PN₂ + PO₂ + P(other gases)

Answer 10

daltons law

•In a gas mixture, the pressure exerted by each gas is independent of the pressure of the others, so all pressures will sum to the total measured pressure

Question 11

•For dalton’s law. In a gas mixture, the pressure exerted by each gas is independent of the pressure of the others, so ___

Answer 11

all pressures will sum to the total measured pressure

P_air = PN₂ + PO₂ + P(other gases)

Question 12

F_IO₂

Answer 12

fraction of inspired oxygen

=21% or 0.21

Question 13

what happens to atmospheric pressure as you climb a mountain?

Answer 13

decreases

at sea level 760 mmHg

on everest: 235 mmHg

Question 14

how to calculate PiO2

Answer 14

PiO2 pressure of oxygen in airways

P_iO₂= (P_atm - 47 mmHg) x F_iO₂

P_atm depends on elevation 760 mmHg at sea level

47 is water vapor evaporating in the body

FiO2= % inspired oxygen =0.21 at room air, 1.0 on 100% O2

Question 15

PiO2 is the the oxygen pressure in the ___, NOT in the ___

Answer 15

airways

alveolus

Question 16

what is the FiO2 at room air and on oxygen?

Answer 16

room air= 21% or 0.21

oxygen= 100% or 1

Question 17

-Atmospheric pressure at 9000m (Everest summit) is 253 mmHg. What is the partial pressure of oxygen in the air?

Answer 17

253 x FiO2

253x 0.21

53.13

Question 18

what is the PiO2 in Amsterdam (760mmHg)?

Philly (749 mmHg)?

Everest (220 mmHg)?

Answer 18

P_iO₂= (P_ATM - 47 mmHg) x F_iO₂

(760-47) x 0.21 = 149.73 mmHg

(749-47) x 0.21= 147.42 mmHg

(220-47) x 0.21= 36.33 mmHg

Question 19

what is the PiO2(1 atm) on

100% oxygen

Amsterdam (760mmHg)?

Philly (749 mmHg)?

Everest (220 mmHg)?

Answer 19

P_iO₂= (P_ATM - 47 mmHg) x F_iO₂

(760 -47) x 1= 713 mmHg

(749-47)x 1= 702 mmHg

(220-47) x 1= 173 mmHg

Question 20

what is the FiO2 needed to get a PiO2 of 200 mmHg at sea level?

Answer 20

P_iO₂= (P_ATM - 47 mmHg) x F_iO₂

200= (760-47) x F

FiO2= 0.28

Question 21

What F_iO₂ would you need to supply to get a P_iO₂ of 50 mmHg at seas level

Answer 21

P_iO₂= (P_ATM - 47 mmHg) x F_iO₂

50= (760-47) x F

FiO2= 0.07

Question 22

PaO2 in arterial vs venous blood

Answer 22

150 in airways

100 in alveoli

100 in arterial

40 in venous

Question 23

Gas exchange across blood-gas barrier in the lung is by ___

Answer 23

passive diffusion

Question 24

Passive movement of gas down a partial pressure gradient (difference in PO₂, PCO₂) are influenced by:

Answer 24

Gas diffusivity (D; solubility)

• Surface area (A)
• B-G barrier thickness (T)
• Driving pressure gradient between alveolar-capillary blood (P_A – P_cap)

Question 25

Fick’s law

Answer 25

The amount of gas that moves across a sheet is:

• Proportional to the area of the sheet
• Inversely proportional to its thickness

the bigger the sheet the more things can diffuse, the thicker the sheet the less things can diffuse

Flow of gas= Area/thickness x diffusion constant (P1-P2)

Question 26

why is PaCO2=PACO2

Answer 26

CO2 is 20 times more soluble than O2

will diffuse willingly across membrane and balance itself out

Question 27

what is more soluble CO2 or O2

Answer 27

CO2 is 20x more soluble then O2

Question 28

what happens to pleural pressure when you breathe very hard

Answer 28

more negative!!

Question 29

Oxygen diffuses into ___ and CO₂ diffuses into ___

Answer 29

tissues

blood

Question 30

anatomic dead space

Answer 30

volume of conducting airways- O2 here will never get to the blood

Question 31

alveolar dead space

Answer 31

gas in alveoli not participating in gas exchange

if an blood clot blocks blood flow to some alveoli

Question 32

physiologic dead space

Answer 32

alveolar + anatomic dead space(conducting airway deadspace)

Question 33

•We measure hemoglobin-associated oxygen using __

Answer 33

SaO₂

pulse ox → % of oxygen on hemoglobin

Question 34

how is O2 carried in the blood

Answer 34

98% is carried on hemoglobin

1-2% is dissolved in plasma

Question 35

normal SaO2

Answer 35

95-100%

% saturation of O2 = pulse ox= % of oxygen on hemoglobin

Question 36

how to measure amount of oxygen dissolved in plasma?

Answer 36

arterial blood gas PaO2

Question 37

•A very small quantity of O₂ is carried dissolved in plasm. The amount dissolved is based on the ___of the air in the alveolus. Oxygen molecules are pushed down a gradient

Answer 37

P_iO₂

Question 38

units of PaO2

Answer 38

mmHg

(partial pressure of O2 in arterial blood)

Question 39

normal PaO2

Answer 39

85-95 mmHg

partial pressure of O2 in arterial blood= measured by blood gas machine

Question 40

how to calculate CaO2

• Oxygen carrying capacity of hemoglobin is 1.34 ml/g
• Oxygen carrying capacity of plasma 0.003 ml O₂/dl plasma per mmHg PaO₂

Answer 40

CaO₂ = (SaO₂ x Hb x 1.34) + .003(PaO₂)

= (98% x 19 g/dL x 1.34) + 0.003(92)

=(24.95) + 0.276

=25.226 ml/dL O2

CaO2= total oxygen content in the blood

Question 41

what does CaO2 measure

Answer 41

total Oxygen in the blood

=(amount of O2 on hemoglobin) + (amount of O2 dissolved in plasma)

CaO₂ = (SaO₂ x Hb x 1.34) + .003(PaO₂)

normal = 16-20 ml/dl O2

Question 42

on admission on room air:

–What is the FiO₂?

–PaO₂: 39 mmHg

–SaO₂: 71%

–Hb: 12 g/dL

CaO_{2? ________________________________}

Answer 42

FiO2= 0.21 on room air

CaO₂ = (SaO₂ x Hb x 1.34) + .003(PaO₂)

=(0.71 x 12 x 1.34) + 0.003 (39)

=11.42+0.117

=11.537 ml/dL O2

normal = 16-20 ml/dl O2

Question 43

•On nasal oxygen at 4L/min

–PaO₂: 58 mmHg

–SaO₂: 85%

–Hb: 12 g/dL

CaO_{2? ______________}

CaO₂ = (SaO₂ x Hb x 1.34) + .003(PaO₂)

Answer 43

CaO₂ = (SaO₂ x Hb x 1.34) + .003(PaO₂)

= (0.85 x 12 x 1.34) + 0.003 (58)

=13.842 ml/dl O2

normal = 16-20 ml/dl O2

Question 44

CaO₂ = (SaO₂ x Hb x 1.34) + .003(PaO₂)

•On the ventilator, on pure O₂

–What is the FiO₂?

–PaO₂: 124 mmHg

–SaO₂: 99%

–Hb: 12 g/dL

CaO_{2? ___________________________}

Answer 44

CaO₂ = (SaO₂ x Hb x 1.34) + .003(PaO₂)

FiO2 on pure O2= 100%

(0.99 x 12 x 1.34) + 0.003 (124)

=16.29 ml/dl O2

normal = 16-20 ml/dl O2

Question 45

•On admission, on room air

–What is the FiO₂?

–PaO₂: 96 mmHg

–SaO₂: 98%

–Hb: 3.5 g/dL

CaO_{2? ____________________}

CaO₂ = (SaO₂ x Hb x 1.34) + .003(PaO₂)

Answer 45

FiO2= 0.21

(.98 x 3.5 x 1.34) + (0.003 x 96)

=4.88 ml/dl O2

normal = 16-20 ml/dl O2

Question 46

•In surgery to ligate the artery, on pure O₂

–What is the FiO₂?

–PaO₂: 496 mmHg–SaO₂: 99%–Hb: 3.5 g/dL

CaO_{2? __________}

CaO₂ = (SaO₂ x Hb x 1.34) + .003(PaO₂)

Answer 46

FiO2 on oxygen = 1

CaO₂ = (SaO₂ x Hb x 1.34) + .003(PaO₂)

= (.99 x 3.5 x 1.34) + (0.003 x 496)

=6.13 ml/dl O2

normal 16-20 - need hemoglobin to fix the horse

Question 47

Gas exchange influenced by

Answer 47

1. ventilation (delivery of atmospheric O2 to alveoli);
2. perfusion (transport of O2 from lungs in the blood);
3. gas exchange at level of alveoli (influenced by amount of gas, properties of gas, tissue properties). Amount of gas available for transport (partial pressure) changes as move from atmosphere to alveolus

Question 48

Driving pressure (ΔP) = P_AO₂ – P_VO₂

Answer 48

100-40

60 mmHg

arterial blood - venous blood

this will pull O2 into the blood from the alveolus until PAO2 and PaO2 are equal

Question 49

how long does it take for a RBC to get fully loaded with O2?

Answer 49

0.25 seconds

Question 50

at rest how fast does RBC go across alveoli?

Answer 50

0.75 seconds

Question 51

what does this graph show?

Answer 51

how long is takes for RBC to get fully loaded with O2

in normal takes 0.25 seconds to reach full load. partial pressure of O2 in the arterial blood (PaO2) goes from 40→100 mmHg

in abnormal= takes 0.75 seconds, if exercising this is not enough cause blood is moving faster then it can pick up O2

in grossly abnormal= RBC never reaches normal even at rest and it barely gets any O2 with exercise

Question 52

•Normal transit time for an RBC across the capillary:___

Answer 52

0.75 seconds

Question 53

Answer 53

PAO2 a high altitude or hypoventilation

amount of O2 in your lungs can not be greater then the amount of O2 in the air, therefore max O2 is 50 at high altitude

that means any pulmonary disease or exercise would lead to even smaller amount of O2 in the blood

Question 54

what is a pulmonary disease that can increase barrier thickness?

Answer 54

edema and fibrosis

Question 55

what kind of pulmonary disease can lead to decrease in surface area?

Answer 55

capillary destruction and tumor

Question 56

explain hemoglobin cooperativity

Answer 56

deoxygenated O2= tense

oxygenated = relaxed

(shy person drinking at a party)

Hb has different affinities for oxygen based on how much oxygen it’s already carrying. The first oxygen molecule is hard to bind, but when one oxygen attaches, the second binds more easily, and the third and fourth easier yet.

The same process works in reverse: once fully loaded hemoglobin lets go of one oxygen, it lets go of the next more easily, and so forth.

This is known as cooperativity

Question 57

Answer 57

oxygen hemoglobin dissociation curve

x axis= Pa O2=partial pressure of O2 dissolved in the plasma= measured by total blood gas

y axis= SpO2= pulse ox

illustrates the % of hemoglobin that is chemically bound to O2 at each oxygen pressure

steep part of curve loose or gain O2 quickly

end of curve- max out at 100% no matter how much extra O2 you add

start of curve- hard to get started

Question 58

why a sigmoid curve?

Answer 58

hemoglobin cooperativity

hard to get started, then very fast, then maxed out

steep slope between 10 and 60 mmHg

flat portion between 70 and 100 mmHg.

Question 59

There are different oxygen levels in venous blood versus arterial. Why?

Answer 59

In venous blood, the PvO₂ is about 40mmHg, which corresponds to an SaO₂ of about 75%

tissues have used up O2 and it has dropped to 75%

Question 60

The amount of oxygen in the arterial blood can be lower in patients with lung disease, or on the top of Everest. Why?

Answer 60

there is less O2 to begin with at the top of Everest= PiO2 is low

or lung disease: can’t get O2 into lungs or into blood so they drop even lower

Question 61

arterial vs venous

SaO2

PAO2

PACO2

Answer 61

99%→75%

100 → 40

40→ 46

Question 62

What happens if the oxygen-hemoglobin dissociation curve shifts to the RIGHT?

Answer 62

more O2 will be unloaded if shifted to the right instead of tissues using 25% they will use 50%

Question 63

how to move oxygen hemoglobin dissociation curve to the right and left?

Answer 63

right- exercise= decrease pH (lactic acid- more acid), increase temp and DPG

left= increase pH, decrease temp and DPG

Question 64

how does pH effect oxygen hemoglobin dissociation curve?

Answer 64

•↓pH–When you exercise, or in some forms of shock, blood pH goes down (acidemia)–This moves the curve to the RIGHT, so at a given PaO₂, the SaO₂ is LOWER so more O₂ was delivered to the tissues–This is called the Bohr effect

Question 65

Bohr effect

Answer 65

during exercise

pH decreases (more acid)

this shifts the curve to the right, this means more O2 is delivered to tissues so they can exercise more

Question 66

What increases 2,3 DPG?

Answer 66

–High altitude, anemia, chronic hypoxia, hyperthyroidism, chronic alkalosis (high pH)

Question 67

Answer 67

Question 68

•Myoglobin is an oxygen-carrying protein in the muscles. Why is its curve so far to the left of Hb?

Answer 68

At any given PaO₂, it more saturated than Hb – this means it can “grab” the O₂ off the Hb as the arterial blood passes by in capillaries to feed the tissues

myoglobin grabs really fast and really well to O2, only need very small amount of O2 to reach full capacity of myoglobin

Question 69

P₅₀

Answer 69

a way to measure how far the curve moves

at normal 27

left= 10

right =40

Question 70

•When the O2/saturation curve shifts RIGHT, the oxygen affinity of hemoglobin ___ causing the hemoglobin to be ___saturated at a given PaO₂

Answer 70

DECREASES,

LESS

right = 40 where normal = 27

Question 71

•When the curve shifts LEFT the oxygen affinity of hemoglobin ___, causing the hemoglobin to be ___ saturated at a given PaO₂

Answer 71

INCREASES,

MORE

left = 10 where normal =27

Question 72

• On room air (FiO₂ 0.21), Hb is almost 100% saturated, and PaO₂ is usually in the high 90s
• What happens to the amount oxygen carried in the blood when a patient receives 100% oxygen (FiO₂ 1.0) and their PaO₂ goes up to ~500 mmHg?

Answer 72

will increase the amount of oxygen dissolved in the plasma which is 1-2% of all oxygen

will not make a big difference

Question 73

how is CO2 transported in the blood?

Answer 73

10% dissolved in blood

22% carbamino compounds in hemoglobin

68% bicarbonate ion formation

Question 74

explain how CO2 is transported on hemoglobin

Answer 74

22% of CO2 carried by Carbamino compounds in Hb

–CO₂ joins reversibly with non-ionized terminal amino groups (-NH₂) of Hb in RBC–Hb.NH₂ + CO₂ ↔ Hb.NH.COOH

Question 75

explain bicarbonate ion formation for carrying CO2

Answer 75

68% of CO2

–most CO₂ in the blood is transported in the bicarbonate ion form

–bicarbonate ion is from reversible reaction accelerated by enzyme, carbonic anhydrase, in RBC:

CO₂ + H₂O ↔ H₂CO₃ ↔ H⁺ + HCO₃^-

–the first reaction is slow in plasma but fast in red cells due to carbonic anhydrase

–the second reaction (carbonic acid ionic dissociation) is fast even without an enzyme

Question 76

how is most of CO2 transported in the blood?

Answer 76

as bicarbonate ion

carbonic anhydrase helps

CO₂ + H₂O ↔ H₂CO₃ ↔ H⁺ + HCO₃^-

Question 77

CO2 transport at the tissues

Answer 77

most into RBC: bicarbonate quickly with help of carbonic anhydrase

some into hemoglobin

Plasma: some dissolved

small amount into bicarbonate slowly cause no carbonic anhydrase in plasma

Question 78

CO2 transport at the lung

Answer 78

reverse process

most out of RBC: bicarbonate quickly with help of carbonic anhydrase back into CO2

some from hemoglobin into CO2

Plasma: some dissolved

small amount from bicarbonate back into CO2 slowly cause no carbonic anhydrase in plasma

Question 79

haldane effect

Answer 79

• Deoxygenation of blood increases its ability to carry carbon dioxide. Conversely, oxygenated blood has a reduced capacity for carbon dioxide
• This means it is easier for Hb to pick up CO2 at the tissues (where Hb is least O₂ saturated), and release it in the lungs, where O₂ is the most saturated. That’s really convenient, right?

Question 80

1.What is the FiO2 of room air at sea level? What is the FiO2 in Denver, CO? What is the FiO2 of pure oxygen at sea level? In Denver?

Answer 80

0. 21
1. 0

????

Question 81

1.If you were in a small room of 1000 L capacity and someone accidentally opened a helium canister that released 100L of helium into the room, what would be the FiO2 in that room? What principle of physics did you use to make this answer?

Answer 81

FiO2 would still be 21%, always 21%???

Question 82

1.What is PiO2? What is the difference between FiO2 and PiO2, conceptually? Numerically? Give an example.

Answer 82

PiO2= partial pressure of inhaled O2= affected by elevation

P_iO₂= (P_ATM - 47 mmHg) x F_iO₂

FiO2= fraction of inhaled air that is O2= at room air always 0.21

Question 83

1.What is normal PaO2 on room air at sea level? What is normal SaO2 on room air at sea level? Include the units.

Answer 83

PaO2 on room air at seas level: measure of dissolved O2 in arterial blood= measured by a blood gas machine

P_iO₂= (P_atm - 47 mmHg) x F_iO₂

PO2 of inspired air = 150, PAO2= 100 PaO2= 100 mmHg ???

SaO2=95-100%

Question 84

If you treating an animal with pneumonia, if the PaO2 is less than 60mmHg, that animal probably needs to be on oxygen. What will be the SaO2 at a PaO2 of 60mmHg?

Answer 84

use o2- saturation curve

90%

Question 85

When the PaO2 is <40mmHg, the animal develops cyanosis (what’s that?). What SaO2 does that correspond to?

Answer 85

cyanosis- blue gums

SaO2 less then 75

Question 86

If normal PaO2 and SpO2 are both the same approximate numerical value in the normal animal on room air, how come they are so different from each other in Q4 and 5? Draw a picture to illustrate.

Answer 86

ox sat curve is sigmoid

Question 87

What is expected SaO2 on 100% oxygen at sea level? Include the units.

Answer 87

100%