HL Gas transport 10_30 PDF

Summary

This document discusses gas exchange in the lungs, focusing on partial pressures and the movement of oxygen and carbon dioxide. It covers concepts such as atmospheric pressure, partial pressures of gases, humidification, and factors influencing oxygen delivery to the tissues.

Full Transcript

Pulmonary Gas Exchange: Now let’s continue to the heart of the matter – gas exchange
between the blood and the alveoli. Specifically, we need to understand the movement of
oxygen from the alveoli into the blood, and the movement of carbon dioxide from the
blood into the alveoli.

Gas Partial Pressures: When we think about gas molecules moving from one place to
another, we need to apply the same ideas as we have for ions moving across a membrane.
Gas moves from areas of high pressure to low pressure – down its electrochemical
gradient. In this case though, gases are uncharged, so the only force acting on them is
their concentration gradient.
1 Atmosphere Mt. Everest
When comparing the concentration of a = 760 mm Hg 29,000 feet
gas in one compartment to that in another,
= 253 mm Hg
we use the partial pressure for that gas.
What is a partial pressure? Well, we live 
on the surface of the Earth and we are
surrounded by air. The air extends up to
the limits of the atmosphere and each
molecule in the air has a certain mass
and is pulled toward the Earth’s surface
by gravity. Therefore, as we walk around
we have a column of air weighing
Sea Level

down upon us – atmospheric pressure.
 Atmospheric pressure is 760 mm Hg (meaning that the weight of the atmosphere is
enough to support a column of mercury 760 mm high). Air is primarily comprised of
nitrogen and oxygen – where nitrogen is 79% of air and oxygen makes up most of the
remaining 21%. The other gases and water vapor are negligible. Now the neat part: If
nitrogen is 79% of the atmosphere, and total atmospheric pressure is 760 mm Hg, then
the partial pressure of nitrogen in the atmosphere is:

(0.79)(760) = 600 mm Hg

Similarly, the partial pressure of oxygen in the atmosphere is:

(0.21)(760) = 160 mm Hg

There are 4 partial pressures we will be considering: PO2, PCO2, PH2O and PN2

We just saw that PN2 = 600 mm Hg and PO2 = 160 mm Hg, while PCO2 and PH2O were
roughly zero in the atmosphere.
When we inhale, the first thing that happens is humidification of the inhaled air.
Humidification means that we are adding water vapor to the atmospheric air, yet total
atmospheric pressure remains constant at 760 mm Hg. The water vapor (at normal body
temperature) has a partial pressure of 47 mm Hg. So, 47 of the 760 mm Hg total air
pressure heading toward our lungs is now water vapor. This decreases the partial
pressures of oxygen and nitrogen in that air sample:

Inhaled Air PO2 = (760 - 47)(0.21) = 150 mm Hg

Inhaled Air PN2 = (760 - 47)(0.79) = 563 mm Hg
The air which we are inhaling with one breath is called the Tidal Volume, and we saw
that only a portion of the Tidal Volume (about 350 ml of the 500 ml) actually reaches the
alveoli and mixes with the air left in the alveoli at the end of the previous breath.
Therefore, we are constantly mixing some fresh air with some “old” air each time we
inhale. This means that the partial pressures in the alveoli will be different from those of
the Tidal Volume (just as the partial pressures of the Tidal Volume are different from
atmospheric air due to humidification). The list below shows the partial pressures for
nitrogen, oxygen carbon dioxide and water in 4 different locations (in mm Hg):

Nitrogen Oxygen Carbon Dioxide Water

Atmospheric Air 600 160 0.3 3.7
Humidified Air 560 150 0.3 47
Alveolar Air 570 105 40 47
Exhaled Air 565 120 27 47
Notice how alveolar air partial pressures differ from those of atmospheric and humidified
air. This is because only a portion of alveolar air is replaced by atmospheric air with each
breath, and also because there is a constant loss of oxygen and gain of carbon dioxide due
to gas exchange with the blood. For instance, we previously saw that the typical functional
residual capacity of the lungs is around 2.3 liters (the volume of air remaining in the lungs
after we exhale normally). Then when we inhale, only 350 of the 500 ml of the Tidal
Volume actually gets into the alveoli to mix with that residual gas. This means that with
each breath we take we replace only about 15% of the gas in the lungs (350/2300 = 15%).

Tidal Volume
(150 ml)

Dead Space
(150 ml of
previously Dead Space
alveolar air) (150 ml of fresh air)

Residual
capacity Only 350 ml of
(2,300 ml) the tidal volume
actually reaches
the alveoli
At first this may seem like an inefficient way to try and maintain or maximize oxygen
transport to the blood, but it has a distinct benefit: The relatively slow replacement (or
turnover) of alveolar gas means that the alveolar gas concentrations remain fairly stable
throughout time. This in turn will help assure that the resulting blood gases leaving the lungs
will remain constant, independent of whether we had just inhaled or exhaled. This makes the
respiratory monitoring and control mechanisms (to be discussed later) much more stable.

85% of gas is 104 mm Hg,
100% of gas is 104 mm Hg
15% is 149 mm Hg

PO2 = PO2 =
104 mm Hg 110 mm Hg

Just before inhaling Just after inhaling
Something else to take note of here: Normal alveolar ventilation at rest is 4.2 liters/min
([350 ml per tidal volume][12 breathes per minute]). At rest, 250 ml of oxygen will be
removed from the alveoli to the blood each minute, and 200 ml of carbon dioxide will
leave the blood and enter the alveoli during that same minute. During moderate exercise
the alveolar ventilation will rise to around 17 liters/min, oxygen loss rises to 1000 ml/min
and carbon dioxide gained from the blood rises to 800 ml/min. Yet, alveolar partial
pressure of oxygen remains at 104 mm Hg and CO 2 at 40 mm Hg. In other words, the
increase in ventilation rate matches the increased demand for oxygen and CO 2
replacement, maintaining the gas partial pressures in the alveoli at a stable value over a
wide range of ventilation.
4,200 ml gas 17,000 ml gas
exchange/min exchange/min
At Rest: During
Moderate
Exercise:

200 ml 250 ml 800 ml 1,000 ml
CO2/min O2/min CO2/min O2/min
Gas Transport in Blood:

Gas Composition in Blood Entering Pulmonary Capillaries: Let’s start by looking at
the situation for gases in venous blood traveling back to the right atrium. That blood has
just passed through systemic capillaries, offloading oxygen to the tissues and taking up
carbon dioxide from metabolizing cells. The carbon dioxide that entered the blood is
transported back to the heart in three forms:

1.About 7% of the carbon dioxide remains in the plasma, in the form of carbon dioxide in
free solution. This produces a venous partial pressure for CO2 of 45 mm Hg (in contrast to
the systemic arterial P CO2 of 40 mm Hg).
CO2
CO2
CO2

CO2 (7%) PCO2 = 45 mm Hg
CO2 (100%)
93% CO2 in another form
2.The remaining 93% of the carbon dioxide enters erythrocytes, where one of two
things happen:

A. 23% of the carbon dioxide becomes bound to hemoglobin, producing the
compound called carbaminohemoglobin (CO2HHb). NOTE: Some carbon
dioxide can also bind to plasma proteins, thereby taking it out of solution,
but the amount of binding to plasma proteins is fairly trivial.
CO2

CO2 CO2

CO2 (7%) PCO2 = 45 mm Hg
CO2 (100%)
93% CO2

CO2 (23%) HHb
23%
RBC
O2

CO2HHb
B. The remaining 70% of carbon dioxide which is found in venous blood is converted in red
blood cells to carbonic acid, using the enzyme carbonic anhydrase (CO 2 + H2O → H2CO3).

Carbonic acid is a weak acid and the majority of the molecules dissociate to form H + and
HCO3-. The bicarbonate is then transported out of the red blood cell and back into the
plasma by a chloride-bicarbonate antiport protein. Therefore, in venous blood we see
elevated levels of bicarbonate and lowered levels of chloride in plasma – a phenomenon
referred to as the chloride shift.
CO2

CO2 CO2

CO2 (7%) PCO2 = 45 mm Hg
CO2 (100%)
93% CO2
CO2 (70%) H2O

70% Carbonic
RBC Anhydrase
Cl-
H2CO3
HCO3-

H+
 The distribution pattern described above makes it clear that the majority of carbon
dioxide transported in the blood to the lungs is in the form of bicarbonate (HCO3-). If the
carbonic anhydrase of red blood cells is inhibited (such as by acetazolamide) we see that
venous PCO2 levels rise dramatically – up to 80 mm Hg instead of 45 mm Hg.

Oxygen is also present in venous blood. The partial pressure of oxygen in free solution is
40 mm Hg (in contrast to the 95 mm Hg partial pressure for oxygen in systemic arterial
blood). However, the majority of the oxygen present in venous blood is in a form bound to
hemoglobin in red blood cells. When ambient oxygen partial pressure is 40 mm Hg,
hemoglobin is still about 75% saturated with oxygen – meaning that only a fraction of the
oxygen available from hemoglobin has been lost in the systemic capillary.

Venous Blood:

CO2 7% in solution O2 Oxygen in solution
(PCO2 = 45 mm Hg) (PO2 = 40 mm Hg)

23% bound to Hb Oxygen bound to Hb
(Hb is 75% saturated)
70% as HCO3-
Gas Exchange in Pulmonary Capillaries: At the arterial end of a pulmonary capillary
plasma PO2 is 40 mm Hg and alveolar PO2 is 104 mm Hg. Therefore, there is an initial P
of 64 mm Hg forcing oxygen into plasma. Oxygen diffuses into the plasma, and within
1/3rd the length of the capillary there is equilibration of plasma and alveolar P O2 (both are
104 mm Hg). Note the large “safety” factor here: It doesn’t take the entire length of the
capillary to equilibrate, just 1/3rd the length.
Similarly, carbon dioxide equilibrates about as rapidly, with plasma PCO2 equilibrating with
alveolar PCO2 (40 mm Hg) during the first third of the capillary transit. Notice that the P
for CO2 is only 5 mm Hg (45 mm Hg in blood and 40 mm Hg in alveoli) compared to the
initial 64 mm Hg gradient driving oxygen diffusion across the alveolar capillary. At rest,
about 5 ml oxygen per 100 ml of blood needs to enter the capillary while 4 ml of carbon
dioxide needs to exit into the alveoli. Therefore, similar amounts of carbon dioxide and
oxygen need to diffuse across the alveolar capillary at the same rate, but carbon dioxide
has a much lower driving force. It is possible for this to occur because of the 20-fold
greater diffusion coefficient for carbon dioxide (e.g. Carbon dioxide needs its greater
diffusion coefficient because it has a much smaller diffusion gradient across the alveolus).
O2 PO2

5 ml/100 ml

O2 PO2 O2 diffusion coefficient

CO2 CO2 diffusion coefficient
PCO2
4 ml/100 ml

CO2 PCO2
This safety margin becomes more important during exercise: During strenuous exercise
there is a 20-fold increase in oxygen demand by the body. One way that demand is met is
by a large increase in cardiac output. As the amount of blood per minute increases, it
means that each milliliter of blood spends less time in transiting the alveolar capillary. If it
took 100% of total transit time at rest to allow oxygen equilibration, then during exercise
we would expect to see blood being less than 100% saturated with oxygen. The safety
margin means that we still have ample time to equilibrate with alveolar oxygen, even
during periods of increased cardiac output.
 Cardiac Output
NOTE: The safety margin is not the only thing
allowing us to maintain oxygen saturation.
Two other changes which help assure saturation
 Transit time
during exercise are:

1) the three-fold increase in oxygen diffusing
capacity (due to opening of previously closed
capillaries), and

2) improved ventilation-perfusion matching
(increased flow to well-ventilated alveoli). During Exercise
Gas Transport in Arterial Blood: So, the blood reaching the venous end of the alveolar
capillary has a PO2 of 104 mm Hg and PCO2 of 40 mm Hg, even during periods of moderate
to heavy exercise (increased oxygen demand). Yet when we measure oxygen pressure in
systemic arteries (or even in the pulmonary vein) we see P O2 is only 95 mm Hg. What
happened to the missing oxygen? The PO2 drops because about 2% of total pulmonary blood
flow has bypassed alveolar capillaries and has instead been shunted to oxygenate pulmonary
tissue which is not next to alveoli – just like systemic blood flow is used to provide oxygen
to peripheral tissues. The blood that has been shunted has a P O2 of 40 mm Hg, and it is the
mixing of this 2% of “deoxygenated” pulmonary blood with the 98% of pulmonary blood
with a PO2 of 104 mm Hg which yields a systemic arterial PO2 of 95 mm Hg.

Deoxygenated blood from
O2 bronchial vessels

Lung cells

To systemic
Deoxygenated circulation
blood enters lungs PO2 = PO2 =
O2 104 mm Hg 95 mm Hg

Alveoli
(PO2 = 104 mm Hg)
The partial pressure of oxygen (and carbon dioxide) is unchanged from the time the blood
enters the pulmonary vein until it reaches the arterial end of systemic capillaries (the gas
content of the blood remains constant except in capillary beds). The interstitial fluid P O2 is
about 40 mm Hg, because oxygen is constantly being consumed by the mitochondria of
metabolizing cells (Therefore, interstitial oxygen diffuses to the lower P O2 found
intracellularly – around 5 mm Hg). From there it diffuses into the mitochondrial matrix,
where PO2 is approximately zero because oxygen is promptly consumed in the final step of
electron transport. So, capillary PO2 rapidly equilibrates with interstitial PO2, replacing the
oxygen that is being consumed by cells. This means that the plasma P O2 of blood entering
the systemic veins is 40 mm Hg, and remains at that value until reaching the arterial end of
the pulmonary capillaries.

Arterial end
PO2 = 104 mm Hg

PO2 = 40 PO2 = 5 PO2 =
mm Hg mm Hg 0 mm
Hg

Venous end PO2 = 40 mm Hg
The movement of carbon dioxide from cells into the blood obeys the same principles as
does oxygen moving from the blood into the cell, just with a lower pressure gradient: The
highest partial pressure of carbon dioxide in the body is in the mitochondrial matrix (where
the majority of CO2 is produced during metabolism). Overall, intracellular PCO2 is about 46
mm Hg and interstitial PCO2 is 45 mm Hg. This is a small concentration gradient (1 mm
Hg), but remember that carbon dioxide’s diffusion coefficient is 20-times greater than that
for oxygen. Therefore, carbon dioxide produced in cells readily diffuses into the
interstitium. From the interstitium to the plasma we have a 5 mm Hg gradient for diffusion,
and carbon dioxide rapidly enters the blood. This results in systemic venous P CO2 being 45
mm Hg, the value we see for blood entering the alveolar capillary.

Arterial end
PCO2 = 40 mm Hg

PCO2 = 45 PCO2 = 46 PCO2 =
mm Hg mm Hg 46 mm
Hg

Venous end PCO2 = 45 mm Hg
 Up until now we have been talking about the movement and transport of oxygen and
carbon dioxide in terms of their partial pressures. Let’s shift now to considering the total
AMOUNT of oxygen required by the peripheral tissues (and therefore the amount that
must be transported in the blood).

At rest, the tissues of the body require about
250 ml of oxygen per minute (5 ml extracted
per deciliter [0.1 liter] of blood). 0.29 ml of
oxygen is dissolved in every deciliter of blood
when PO2 = 95 mm Hg, and that falls to 0.12 ml
at PO2 = 40 mm Hg. Therefore, if ONLY
dissolved oxygen was transported in blood we
could deliver (0.29 – 0.12)(Cardiac Output
= 5 L/min) = 8.5 ml/min oxygen.

Clearly, that will not meet the resting body
requirement of 250 ml/min. Even at maximal
cardiac output during exercise
(about 13 liters/min) oxygen in free solution
can deliver only 22.1 ml/min.
Fortunately, we have hemoglobin to loosely bind and transport oxygen – taking it out of
free solution. NOTE: Oxygen bound to hemoglobin does not contribute to partial pressure.
Partial pressure is only exerted by gas molecules in free solution. Normally, roughly 97%
of all oxygen delivered to the tissues is transported bound to hemoglobin:

[250 ml/min total delivery – 8.5 ml/min in solution]/250 ml/min total delivery = 96.6%

and only 3% of total oxygen transport to tissues occurs in the form of free solution of
oxygen. Now, normal blood contains about 15 grams of hemoglobin per deciliter of blood
and each gram of hemoglobin can bind 1.34 ml of oxygen. Therefore, each deciliter of
blood can hold 20 ml of oxygen bound to hemoglobin.

If cardiac output at rest is 5 L/min (50 deciliters/min), then the total potential oxygen
output to the circulation each minute is:
(20)(50) = 1000 ml oxygen/min

– more than sufficient to meet the 250 ml/min used by the tissues at rest. Now that’s an
upper limit, because hemoglobin isn’t saturated with oxygen when the P O2 is 95 mm Hg
(as it is in blood leaving the lungs). At P O2 = 95 mm Hg hemoglobin is 97% saturated,
meaning that the normal resting oxygen available from the circulation is:

(1000)(0.97) = 970 ml oxygen/min (or, 19.4 ml/deciliter of blood).
Hemoglobin binding to oxygen is an
allosteric relationship – the hemoglobin
dissociation curve is often used to
illustrate allosteric binding relationships.
While the hemoglobin is 97% saturated
at PO2 = 95 mm Hg (as occurs in the
lungs), when it is placed in an
environment where ambient PO2 = 40 mm
Hg (such as is the case in the systemic
capillaries) there is significant unbinding
of oxygen from hemoglobin. Not all of
the oxygen becomes unbound. In fact, we
see that hemoglobin is 75% saturated with
oxygen when oxygen partial pressure falls
to 40 mm Hg. Therefore, only a fraction of the oxygen being transported in the bound state
is off-loaded at tissue capillaries: (0.97-0.75)(970 ml/min) = 213 ml/min oxygen delivered
to the tissues (or, 19.4 – 14.4 ml oxygen/deciliter of blood flow = 5 ml oxygen/deciliter –
the amount of oxygen being consumed per minute by the tissues). Looking at it slightly
differently, at rest there is 4 times the amount of oxygen being transported each minute
than the total oxygen consumption by the tissues (The tissues use only 25% of the total
oxygen supply present). Small local increases in oxygen consumption can easily be
supplied by greater oxygen extraction, while during exercise we can further increase
oxygen delivery by the 6-7 fold increase in cardiac output.
The allosteric nature of hemoglobin binding to oxygen acts to naturally regulate the level
of oxygen that is present in the interstitium within a few mm Hg of the normal 40 mm Hg,
through a range from 60-500 mm Hg PO2 for inhaled air. In addition, the hemoglobin
dissociation curve can be shifted to
the left or right by different regulatory
compounds and situations.

A shift to the right means that it is
more difficult to get oxygen to bind
to hemoglobin, meaning that the
hemoglobin will off-load more
oxygen in the tissues.

A shift to the left makes it easier to
saturate hemoglobin, but the
hemoglobin will release less oxygen
to the tissues.
Factors that shift the dissociation curve to the right:

1) Increased blood acidity: A drop in blood pH from 7.4 to 7.2 shifts the dissociation
curve to the right by about 15%. This could occur if oxygen supply was not meeting
oxygen demand by the tissue, increasing lactate production locally. The right shift will
cause more oxygen to dissociate from hemoglobin, thereby supplying more oxygen to
the metabolizing tissue.

2) Increased blood PCO2: An increase in carbon dioxide (hypercapnia) causes a right shift
in the hemoglobin dissociation curve (basically for the same reasons as listed for
acidification). When a tissue becomes metabolically more active it produces more
carbon dioxide, and its need for oxygen will also increase.

3) Increased blood 2,3-diphosphoglycerate (2,3-DPG – a compound which now called 2,3
bisphosphoglycerate): 2,3-DPG is synthesized in greater amounts when we are in
hypoxic conditions for periods of several hours or more (such as when you visit a high
altitude).

4) Increased body temperature: As body temperature rises there is a right shift in the
dissociation curve. This would help meet the oxygen demand for tissues that are
producing and using ATP rapidly (exercising muscle, cells fighting infections, etc.).
Factors 1 and 2 above (low pH and high PCO2) produce what is called the Bohr Effect –
Blood passing through the lungs is in an environment where PCO2 is decreased and pH is
increased relative to systemic capillaries. Therefore, the hemoglobin dissociation curve is
shifted to the left in the lungs. This maximizes the amount of oxygen that binds to
hemoglobin at the ambient PO2 in the lungs. Then, when this oxygenated blood reaches a
systemic capillary it is in an environment where PCO2 is elevated and pH is relatively low
(compared to that found in the alveolar capillaries). This causes a right shift in the
dissociation curve, and more oxygen being off-loaded from the hemoglobin than if no shift
had occurred.

The Bohr Effect optimizes hemoglobin’s ability to load up with oxygen in the lungs and to
then off-load oxygen in the tissues.
Factors that shift the dissociation curve to the left:

1) Decreased blood acidity: Alkaline blood (pH = 7.6 or higher) causes hemoglobin to
bind oxygen more tightly.

2) Decreased blood PCO2: Hypocapnia shifts the dissociation curve to the left. Hypocapnia
can result from hyperventilation or low total metabolic rate.

3) Fetal hemoglobin: The form of hemoglobin found in fetal blood is different than that
found in adult blood (adult hemoglobin). One major difference in their characteristics
is that the dissociation curve for fetal hemoglobin is shifted to the left compared to
adult hemoglobin. Why? The fetal hemoglobin must extract oxygen from the maternal
circulation. This is made possible by the greater binding affinity of fetal hemoglobin
for oxygen. In essence, the fetal blood plucks oxygen out of the maternal circulation.
Sure, that fetal hemoglobin doesn’t give up its bound oxygen as readily, but it will still
easily meet all of the metabolic oxygen demands of the developing fetus.
Now on to carbon dioxide transport in the blood.

We began this section by discussing how 70% of the carbon dioxide in blood is in the
form of bicarbonate (HCO3-), 23% is bound to hemoglobin in red blood cells
(Carbaminohemoglobin) and 7% is in free solution in plasma and intracellular fluid of
blood cells. In terms of amounts of carbon dioxide present in blood, we must transport 4
ml carbon dioxide/100 ml of blood (the product of metabolism in the tissues which must
be excreted from the body).
NOTE: We do not get rid of all of the carbon dioxide that is present in the blood when the
blood passes through the lungs. Rather, we get rid of 4 ml CO 2 per 100 ml of blood that
passes through the lungs. The average total amount of carbon dioxide in the blood is 50
ml/100 ml of blood. In venous blood there is 52 ml CO2 per 100 ml blood, and in arterial
blood there is 48 ml/100 ml of blood – so the 4 ml of carbon dioxide that we get rid of in
the lungs is only a fraction (8%) of the total carbon dioxide present. This means that the
carbon dioxide content of the blood stays quite stable, even when comparing arterial to
venous content.

Alveoli

Pulmonary Pulmonary
Artery 4 ml CO2/100 ml blood Vein
End End

Total CO2 = 52 ml/100 ml Total CO2 = 48 ml/100 ml

PCO2 = 45 mm Hg PCO2 = 45 mm Hg
NOTE: We saw earlier that the binding of protons and carbon dioxide decreased the
affinity of hemoglobin for binding to oxygen (the Bohr Effect). It turns out that the binding
of oxygen alters hemoglobin’s binding to carbon dioxide, and this is called the Haldane
Effect. The Haldane Effect is simply that increased binding to oxygen decreases
hemoglobin’s affinity for carbon dioxide. In practical physiological terms this means that
in the alveolar capillaries (where PO2 is high and more oxygen will begin binding to
hemoglobin) the hemoglobin will off-load carbon dioxide (which then diffuses into
alveoli). Conversely, in the systemic capillaries, PO2 is relatively low and oxygen becomes
unbound from hemoglobin. This causes the hemoglobin to increase binding to carbon
dioxide. The bottom line: Although the Haldane Effect may not seem real critical, it
actually doubles the amount of carbon dioxide that can be transported in the blood at any
given time.

CO2 (23%) HHb O2 CO2HHb

O2 CO2

CO2HHb O2-Hb

Bohr Effect - in tissues Haldane Effect - in lungs