lecture 18: oxygen transport in the blood

Question 1

how do we get oxygen from air into your cells

Answer 1

principle of diffusion
air composed of many gases
gas dissolved into liquids

Question 2

gas exchange is the interaction of wht two systems

Answer 2

respiraotry and cardiovascular system

Question 3

explain why the respiratory/cardiovascular systems interact in tnro to gas exchange

Answer 3

RBCs (in blood vessels) carry O2 and CO2

Question 4

gas exchange occurs between what

Answer 4

Occurs between alveolar air and blood

– Across membranes: the blood-air barrier

Question 5

rank the partial pressure of oxygen innn the arteries, alveoli and tissues

Answer 5

PAO2&raquo_space; PaO2&raquo_space; PO2 in tissues

Question 6

since PAO2&raquo_space; PaO2&raquo_space; PO2 in tissues, this allows what

Answer 6

Allows O2 to diffuse from alveoli to blood to tissues

Question 7

rank the partial pressure of carbon dioxide in the arteries, alveoli and tissues

Answer 7

PCO2 in tissues&raquo_space; PaCO2&raquo_space; PACO2

Question 8

since PCO2 in tissues&raquo_space; PaCO2&raquo_space; PACO2, what does that allow in terms of diffusion

Answer 8

Allows CO2 to diffuse from tissues to capillary

blood to alveoli

Question 9

gas exchange depends on what (2)

Answer 9

– Partial pressures of the gases

– Diffusion of molecules between gas and liquid

Question 10

venous blood exits RV by what pathway

Answer 10

pulmonary trunk to

pulmonary arteries to

ramifications to

capillary network

Question 11

oxygenated blood goes back to the heart via what

Answer 11

pulmonanry veins

Question 12

true or false: oxygenated blood goes back to the heard via pulmonary artries

Answer 12

false, pulm veins

Question 13

true or false: venous blood enters pulmonary capillaries at the arterial and exits at the venous end.

Answer 13

true

Question 14

venous blood enters and exits at what end pulmonary capillaries

Answer 14

venous blood enters

pulmonary capillaries at the arterial and exits at the venous end.

Question 15

ADD SLIDE ON LECT 18 SLIDE 5

Answer 15

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Question 16

what happens to o2 requirement during exercise

Answer 16

can icnrease 20 fold

Question 17

what two things happen in terms of uptake of oxygen by pulm cap blood during exercise

Answer 17

– O2 requirement can increase 20-fold

– Also, since heart rate increases. time that blood remains in pulmonary capillaries can dercease by half

Question 18

is it a problem that during exercise
– O2 requirement can increase 20-fold

– Also, since heart rate increases. time that blood remains in pulmonary capillaries can dercease by half

Answer 18

no because we have an extensive backup system

Question 19

what is the safety factor that allows us to combat the increase in 02 requirement during exercise

Answer 19

Safety factor of O2 diffusion through pulmonary membrane

– Oxygen diffusion capacity increases by ~ 3-fold

Question 20

true or false, blood becomes almost saturate with 02 very quickyl?

Answer 20

true , blood becomes almost saturated

with O2 by the time it has passed 1/3 of the capillary

Question 21

why is it not a problem that when heart tate increases, time that blood remains in pulm capilaries can decrease by half

Answer 21

because blood becomes almost saturated
with O2 by the time it has passed 1/3 of the capillary

– So during exercise, even if exposure time is reduced,
blood will still become fully oxygenated

Question 22

in the pulm capillaries, the blood gets oxygenated slowly or quickly

Answer 22

very quickyl

Question 23

what is the reasonn blood can never be 100% saturated with o2

Answer 23

because the blood mixes with pulmonary shunt blood (respiratory muscles deoxygennated blood mixes with oxygenated blood)

Question 24

deoxygenation of the blood can only happen where

Answer 24

at the systemic capilarries

(diffused from blood to tissue(

Question 25

the venous blood PvO2 depends on what

Answer 25

upon tissue metabolic activtiy

Question 26

what ate the two ways that blood carries oxygen

Answer 26

1) in physical solution dissolved in the fluid portion of blood (3%)
2) in loose combo with hemoglobin (97%)

Question 27

what is the function of transporting oxygen dissolved in the fluid portion of blood

Answer 27

– Establishes the PO2 of the plasma and tissue fluids

– Helps to regulate breathing

– Determines oxygen loading of hemoglobin in the lungs and subsequent release in tissues

Question 28

is aprtial pressure of o2 in blood mesured by oxygen bound to hemo globinn or oxygen dissolved in fluid portionn of blood

Answer 28

bt oxygen dissolved in fluid portion of blood

Question 29

explain how having oxygen dissolved in the fluid portion of blood can help to regualte breathing

Answer 29

because sensors can pick up o2 in solution to increase/decrese breathing rate

Question 30

what is hemoglobin

Answer 30

the iron protein molecule within the RBC

=globular protein pigment

Question 31

what is the major contnributor to oxygen transport

Answer 31

oxygen in loose combo with hemoglobin

Question 32

oxygen combined with hemoglobin carries more or less oygen than normally dissolved in plasma

Answer 32

Carries 65-70 times more oxygen than normally dissolves

in plasma

Question 33

each of the 4 iron molcules in hemoglobin can bind out many oxygen moleulces

Answer 33

1

1 02 per iron moecule

Question 34

how many ooxygen molecules can each hemoglobinc carry

Answer 34

4 molecules of o2 (because of 4 iron molucles on hemo glib)

Question 35

The partial pressure of

oxygen dissolved in physical solution dictates what

Answer 35

the

oxygenation of hemoglobin to oxyhemoglobin

Question 36

what is cooperative binding

Answer 36

The binding of an O2 molecule to the iron atom in one of the four globin chains progressively facilitates the binding of subsequent
molecules

Question 37

if 1 o2 binds to the hemoglobin, does that make it harder or easier to bind others

Answer 37

easier

Question 38

as you lose 1 o2 molecule, does it imake it harder or easier to lose others

Answer 38

makes it easier

Question 39

as each o2 binds to the hemoglobin, what happens

Answer 39

the hemoglobin “opens up”

=allows more oxygen to be exposed to the surface and easier binding

Question 40

blood of normal person contains how much hemogloib

Answer 40

15 g of HB/ 100 ml of blood

Question 41

each gram of Hb can bind with amax of how many O2

Answer 41

max 1.34 g of O2

Question 42

what is the max ammount of o2 that can be carried by 100 ml of blood

Answer 42

20 ml

Question 43

when is 20 ml o2/100 ml blood obtained

Answer 43

if Hb is
100% saturated with O2, and is known as 20 volume
percent

Question 44

what is the volume percent o2

Answer 44

indicates the amount of O2 carried by 100 ml of blood at different % saturations

Question 45

oxygenated blood leaving the lungs have a higher or lower saturation and what does that mean in terms of tje volume percent

Answer 45

higher saturaration therefore high volume percent

Question 46

what is the PO2 of blood at venous end of tissue capilary

Answer 46

40 mmHG

Question 47

after passing through
tissue capillaries, amount of O2
carried by blood in veins (CvO2) increased or reduced

Answer 47

is reduced to 14.4 ml of O2 for each 100 ml of blood (on average)
(from 20)

Question 48

what is the avo2 difference

Answer 48

describes the difference between the
oxygen content of arterial blood and mixed-venous blood

difference between the the amount of oxygenated blood coming into tissue vs leaving

Question 49

what is the AVO2 difference

Answer 49

Averages 4-5 mL of O2 per deciliter of blood

Question 50

true or false: O2 release from hemoglobin can occur without any increase
in local tissue blood flow

Answer 50

true

Question 51

explain this sentence:
“An active muscle’s uncompromising capacity to use available O2 in its large blood flow supports the position that O2 supply, not muscle O2 use, limits aerobic exercise capacity”

Answer 51

as long as we supply the oxygen with o2=muscle will use it if needed

limit: if not enough oxygen is available (CV system startts not being able to provide O2). avo2 differentce will increae to meet o2 needs

Question 52

what can rapid use of o2 by tissue cells cause

in strenous exercise

Answer 52

can cause PO2 in interstitial fluid to fall from normal of

40 mmHg to as low as 15 mmHg

Question 53

at a low po2 in intersticial fluid of 15 mmHG (after strenous exercse), how much o2 remains bound to HV in each ml of blood and what does this mean

Answer 53

4.4 ml O2

This means that the tissues used up more oxygen (higher oxygen diffusion into the working tissues to supply the increasing metabolic needs)
=larger AVo2 diff

Question 54

during strenous exercise, is AV o2 difference greather or lower than normal

Answer 54

3x normal level, i.e. 3x more O2 is extracted in
from each volume of blood that passes
through tissues

Question 55

a large utilaxationn coefficent = large BLANK

Answer 55

large avo2 difference

Question 56

at rest, what is the utilzation coeeffient

Answer 56

25% (5 ml of o2/100 ml blood over possible max of 20)

75% of the o2 is still bound and does not get used up by tissues

Question 57

during strenous exercuse, what is the utilazation coefficint

Answer 57

greater than 75% (15/20)

means that alot of the oxygen is getting diffused to working tissues

Question 58

what are 4 Factors That Shift the Oxygen
Dissociation Curve to the right
(less hemoglobin saturation)

Answer 58

1) incnrease hydrogen atoms
2) increase co2
3) increase temp
4) increase BPG

Question 59

what are the 2 metabolic factors that shift the oxygen dissocaition curve

Answer 59

effect of ph

effect of co2 in blood

Question 60

what is the effect of PH on oxygen dissocaiteion cruve

Answer 60

After metabolism, there is a
Decrease in pH or increase in H+ (acidosis) which shifts the O2
dissociation curve to the right

• Decrease of pH from 7.4 (normal level) to 7.2 leads to ~15% decrease of hemoglobin saturation with O2
=more oxygen being dropped off to tissue, less o2 in the blood

Question 61

explain the effect of carbon dioxide on the oxygen disscoation curve

Answer 61

Increase of CO2 in blood or increase of PCO2 (hypercapnia) leads to shift of O2 dissociation curve to the right

(moves equilibrum curve to make more H)

Question 62

what is the bohr effect

Answer 62

result of changes in blood acidity and PCO2
and affects Hb’s O2 binding affinity

=hemoglobin has a lower affinity for 02 secondary to incrases in PCO2 or decreases in pH (incrase H)
=this increase the 02 being unloaded in order to meet o2 demand

Question 63

what is the bohrs effect in the tissues

Answer 63

rightward shift of O2 dissociation curve
caused by increase of CO2 (and PCO2) and a
decrease in pH of blood

• Enhances release of O2 from blood in tissues

Question 64

what is the bohrs effect in the lungs

Answer 64

curve is shifted to the left as
blood PCO2 drops and pH increases

• Enhances oxygenation of blood in lungs

Question 65

explain the effect of body/tissue temp of the oxygen dissociateing cruve

Answer 65

increase in core temp leads to rightward shirt in the curve
=lower hemoglobin saturation
=unloading more o2 for the tissues beacuse heat is a sign of metabolism

Question 66

explain why during exrecise, even if exposure time of blood to the alveoli is reduced, we can still get fully oxygenated blood ?

Answer 66

because during exercise, oxygen diffusion will increase by 3 fold
(o2 can more easily pass though the pulmonary membrane)

Question 67

what does the partial pressure of oxygen in venous blood in tissues depend on

Answer 67

depends on tissue metabolic activtiy,

if greater metabolic need=great avo2 difference

Question 68

explain the oxyhemoglobin dissocaitionn curve!!!

Answer 68

s,mfnajsf

Question 69

what does it mean if you are at 20 volume percent

Answer 69

if you carry 20 ml of 02/100 ml of blood that means the hemoglobin is 100% saturated with o2 and is known as the 20 vol percent

=never happens because shunt

Question 70

o2 gets reased when

Answer 70

02 gets released from Hb as systemic arterial blood flows through tissues

Question 71

the blood leaving the lung has a higher or lower volume percent than the blood returning from the tissues

Answer 71

it has a higher hemoglobin saturation (ie. higher volume percent(

Question 72

after oxygen unloading at the tissue level, do we unload all of it?

Answer 72

no , at the venous level, the %Hb saturation is still 75% which means we only lost about 5 ml of o2 in the blood and the rest returns to the

Question 73

is our AV o2 difference always the same (around 5ml)

Answer 73

no , it can increase (greater diff) during exrecise which means we are unloading/diffusing more oxygen to the tissues

Question 74

explain how 02 release from hemoglobin can increase withouht any increase in local tissue blood flow

Answer 74

just by changing the oxygen diffusion into the tissues

The amount of o2 rleased to the muscles is amost 3 times above the normal supply at rest

Question 75

if there is a high body temp, do we unload more 02 or do we keep more o2 bound

Answer 75

we geet rid of o2 easier

Question 76

what happens to hemoglobin saturation with a decrease in tissue temp

Answer 76

a decrease in tissue temp leads to an increased hemoglobbin saturation with 02 (keep more oxygen bound to the blood)

Question 77

how does a red blood cell derive its energy what was does that mean in terms of waste products

Answer 77

A red blood cell derives its energy solely from the anaerobic
reactions of glycolysis because they contain no mitochondria,
causing them to produce the compound 2,3-diphosphoglycerate
(2,3-DPG)

Question 78

explain the effect of 2,3 diphosglycerate in the blood and that affect on hemoglobin saturation with o2

Answer 78

as a reselt of RBC anerobic glycolis, 2.3 is formed and binds with hemoglobin
=reduced the affinity of oxygen allowing for greater oxygen release to the tissues because of a decrease in PO2

Question 79

during exrecise is the compound 2,3 DPG helpful or harmful

Answer 79

it is helpful

it is a waste product of glycolysis of RBC
=it will bind with hemoglobin
=it will decrease affinity for 02
=o2 will more easilty be released which aids in oxygen transfer to the muscles

Question 80

what accelerates 2,3 DPG in the blood

Answer 80

during exercise, heat acceleates glycolysis (formation of ATP from glucose) threfore increases the levels of DPG in blood which aids in oxygen transfer to muscles

Question 81

if the oxygen dissocaiteion curve shifts to the right, what does that mean in term of hemoglobin saturation

Answer 81

it decreases (Drop off oxygen easier)

Question 82

what is the affect of hypoxia on oxygen dissocaiton curve (hemo globin saturation with o2)

Answer 82

In hypoxia condition (lasting longer than a few hours), lack of O2
in tissues promotes production of DPG in blood à O2
dissociation curve shifts to the right à decreased hemoglobin
saturation with O2
• Causes O2 to be released to tissues at much higher PO2 levels
(as much as 10 x higher); can become an important adaptive
mechanism to hypoxia, e.g. if poor tissue blood flow

Question 83

during exercise, what are some reasons the oxygen dissociation curve would shift to thee right (release o2 from blood HB to tissues)

Answer 83

1) exercising muscles release large quantities of CO2
2) increase in H+ (decrease pH) in muscle caps
3) incrase in muscle temp
4) release of 2.3 GPD

Question 84

true or false: fetal hemoglobin has a strog affinity for o2

Answer 84

true

Question 85

does fetal globin movee the curve to the right or left (o2 diss curve)

Answer 85

Fetal hemoglobin has strong affinity for O2 and therefore, shifts
O2 dissociation curve to the left

Question 86

explain the effecet of sickle cell on oxygen dissociateion curve

Answer 86

Sickle cell (abnormal type of hemoglobin (HbS)) binds O2 like
normal hemoglobin, but sickle cells have greater 2,3
diphosphoglycerate (DPG), therefore it shifts O2 dissociation
curve to the right

Question 87

what is myoglobin

Answer 87

An iron-containing globular protein in skeletal and cardiac

muscle fibers

Question 88

what is the function of myoglbin

Answer 88

provides intramuscular oxygen storarage (binds and stores o2 in thee muscles for later use)

Question 89

what types of musclese have more myoglobin

Answer 89

slow twitch

Question 90

if a msucle is dark red, does it have more of less myoglobin

Answer 90

more

Question 91

true or false: hemoglobin and myogolbin are the esame

Answer 91

Resembles hemoglobin because it also combines reversibly
with oxygen but each molecule contains one iron atom while
hemoglobin contains four

Question 92

what is the main diff between hemoglobin and myoglobin

Answer 92

each molecule of myoglobin contains one iron atom while

hemoglobin contains four

Question 93

true or false: myoglobin removes oxygen from the myscle

Answer 93

false, it adds additional oxygen to the muscle

Question 94

true or false: myoglobin will only release o2 at very low o2 pressures

Answer 94

true

Question 95

when does myoglobin facilitate oxygen transfer

Answer 95

Myoglobin facilitates oxygen transfer to the mitochondria when
exercise begins and during intense exercise when cellular PO2
declines rapidly

Question 96

what is the oxygen saturation of myoglobin at rest and mod exercise

Answer 96

maintains high saturation

Question 97

explain the difference between the oxygen saturation curve for hemoglobin vs myoglobin

Answer 97

Compared with the oxygen saturation curve for hemoglobin,
the curve for myoglobin shows that it much more readily binds
and retains oxygen at low PO2

Question 98

true or false: the greatest oxygen releases frm myoglobin happen at high levels of partial oxygen

Answer 98

false, the greatest quantity of oxygen release from myo occurs when tissue PO2 declines below 5 mmHG (VERY LOW)

Question 99

what is the affect of acidity, co2 and body temp on myoglobin

Answer 99

Acidity, carbon dioxide, and temperature do not affect

myoglobin’s oxygen-binding affinity

Question 100

explain the po2 difference in the arterial blood vs in the tisues

Answer 100

When arterial blood reaches peripheral tissues, PO2 is still
~95 mmHg, while PO2 in interstitial fluid surrounding tissue
cells is only 40 mmHg

• I.e. tremendous initial O2 pressure difference (95 – 40 = 55)

• This causes O2 to diffuse rapidly from capillary blood into
tissues

• PO2 in capillaries will then fall (fast since O2 diffusion into
tissue occurs rapidly)

• So blood leaving tissue capillaries and entering systemic
veins will have PO2 of ~ 40 mmHg

Question 101

why does the partial presure of oxygen drop drastically when going from air and then to the alveoli

Answer 101

1) we add water vapour to the air which must decrease the PO2
2) the residual vol of o2 in lungs is continuously being used in exhale and inhale (partial pressure of o2 must decrase in air because theres already oxygen in lungs)

Question 102

why is there a slighy decrease in partial pressure of 02 when going from alveoli to the arterial

Answer 102

because of the shunt
=respiratory muscles consuemee some o2 and mix with fully saturated 02 which will decerase ethe partial pressure of o2 slightlt

Question 103

what is the affect of blood flow on oxygen pressure in the intersituatl fluid pressure

Answer 103

Increased blood flow=

=Increased O2 transported into tissue fluid

=Increased PO2 in interstitial fluid

Question 104

what is the affect of o2 consumption of oxygen pressur ein the intersital fluid

Answer 104

Increased tissue metabolic rate

=Increased O2 consumption

=Decreased interstitial fluid PO2

Question 105

why is intraceellcular po2 usually low

Answer 105

because 02 is continuously being used up from tissue cells

Question 106

true or false: we need a high intracellular o2 pressure to maintain metabolic oxygen demand for tissues

Answer 106

false, In normal resting conditions, only 1 to 3 mmHg of intracellular O2 pressure is
required for tissue cells to fully support the metabolic oxygen demand. Average
intracellular PO2 = 23 mmHg thus provides a large safety factor.

Question 107

cells need how much po2 to maintain normal demand

Answer 107

Cells only need a PO2 of 1 mmHg for normal intracellular
chemical reactions to occur (i.e. O2 is not a limiting factor to
rates of chemical reactions at cellular PO2 > 1 mmHg)

Question 108

what is the main limited factor to ratse of chemical reactions at cellular po2 and explain

Answer 108

Main limiting factor is cellular concentration of adenosine
diphosphate (ADP)

• When adenosine triphosphate (ATP) is used in cells to
provide energy, it gets converted to ADP

• Rate at which ADP is formed from ATP (i.e. rate of energy
expenditure within cell) is what controls rate of O2 usage by
cells under normal operating conditions

Question 109

if atp/adp is greater than 1 what doese that mean in terms of o2

Answer 109

Plenty of ATP is available

– Tissue will not consume additional quantities of O2 for
producing ATP

Question 110

if atp/adp is less than 1 what does that mean in terms of 02

Answer 110

– Relatively more ADP than ATP is present

– More O2 will be consumed to raise the ATP level

Question 111

if ADP levels increase, does rate of o2 consumption increase or decrease

Answer 111

inncrease

Question 112

what are the transport factors that affect oxygen comsumption at the tissue leevel

Answer 112

• Blood flow
• Perfusion pressure
• Capillary resistance
• Hemoglobin

Question 113

what are the metabolic factorst that affect oxygen connsumption at the tissue level

Answer 113

Tissue activity
• State of conditioning
• Number and size of mitochondria