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RESPIRATORY PHYSIOLOGY

4. Gas transport in the blood

Andre Azevedo, DVM, MSc
Assistant Professor of Veterinary Physiology
[email protected]
Gas transport

Pearson Education
 Oxygen transport

Oxygen is poorly soluble in water/plasma – carried in 2 forms in blood

Dissolved – 2% Normal tissue need: 5 ml/dL
O2 dissolved: 0.3 ml/dL
Produces partial pressure (drives O2 bound: 20.1 ml/dL
diffusion). O2 bound to hemoglobin
does not contribute to PaO2

Insufficient do meet tissue demands

Bound to hemoglobin – 98%
https://drrajivdesaimd.com/2015/08/24/pulse-oximetry/
 Oxygen transport

Hemoglobin - Globular protein with 4 subunits –
each contains:
Heme molecule – iron-binding protoporphyrin,
produced by mitochondria https://www.britannica.com/science/hemoglobin

Globin chain – polypeptide designated either
alpha (α) or beta (β), produced by ribosomes

A single red blood cell contains 270
million molecules of hemoglobin

https://www.rcsb.org/3d-view/1GZX/1
https://en.wikipedia.org/wiki/Hemoglobin#/media/File:1GZX_Haemoglobin.png
 Oxygen transport

The type and sequence of amino acids that compose globin are critical
to oxygen binding
Heme is a protoporphyrin consisting of four pyrroles with a ferrous iron (Fe2+) at the center
Each ferrous iron can combine reversibly with a single molecule of O2
Without the presence of globin, oxygen would irreversibly oxidize the ferrous iron (Fe2+) to
ferric iron (Fe3+)
The amino acids in globin cradle the heme and limit the access of O2 to the ferrous iron,
preventing oxidation, allowing uptake and release of oxygen in response to local PO2
An enzyme called METHEMOGLOBIN REDUCTASE is located inside red blood cells and also
helps keeping iron in its reduced state
 Oxygen transport

The type and sequence of amino acids that compose globin define the
different types of mammalian hemoglobin
Adult hemoglobin (HgA) – contains 2 alpha and 2 beta chains
Fetal hemoglobin (HgF) – contains 2 alpha and 2 gamma chains
HgF has higher affinity for O2, facilitating O2
movement from the mother to the fetus

2,3-BPG (2,3-bisphosphoglycerate) binds to HgA
and reduces its oxygen affinity, but it doesn’t
bind strongly to HgF.

Usually replaced by HgA in the first year of life
https://pdb101.rcsb.org/motm/257
 Oxygen transport

A molecule of hemoglobin can reversibly combine with 4 molecules of oxygen
When hemoglobin is deoxygenated is called DEOXYHEMOGLOBIN – 0% saturation
When oxygenated is called OXYHEMOGLOBIN
individually can vary saturation levels - 25% - 50% - 75% - 100% (fully saturated)
heme-heme interactions increase/decrease affinity for O2 as hemoglobin saturates/desaturates

POSITIVE
COOPERATIVITY
https://ib.bioninja.com.au/options/option-d-human-physiology/d6-transport-of-respiratory/oxygen-dissociation-curve.html
 Oxygen transport

Cyanosis results from increased desaturated hemoglobin

https://www.ncbi.nlm.nih.gov/pmc/articles/PMC6463781/

https://medizzy.com/feed/32715046 https://heartsmart.vet.tufts.edu/difficulty-breathing-dyspnea/
Oxyhemoglobin dissociation curve

amountofoxygen
Cunningham's Textbook of Veterinary Physiology, 6th Edition Cunningham's Textbook of Veterinary Physiology, 6th Edition
 Oxyhemoglobin dissociation curve

https://ib.bioninja.com.au/options/option-d-human-physiology/d6-transport-of-respiratory/oxygen-dissociation-curve.html
 Oxygen transport

Oxyhemoglobin dissociation curve
Saturation does not increase linearly as PO2 increases
Heme-heme interactions affecting affinity (positive
cooperativity) are responsible for the sigmoidal shape
Increase steeply as PO2 increases from 0 to 40 mmHg, levels
off between 50 and 100 mmHg, where most of the
hemoglobin is saturated
Change in affinity – binding of first molecule to a heme
increases affinity for the second one, and so forth
Under normal conditions, on average, only a single O2 molecule
is removed from each hemoglobin to satisfy the tissues’ need
for O2.
 Oxygen transport

4 O2 bound to Hb -> oxyhemoglobin fully saturated -> highest affinity
How is O2 released to the tissues?
 Oxygen transport

Factors affecting O2 affinity:
Temperature
pH
PCO2
2,3-BPG Concentration 50%

P50 = 30 mmHg

Produces changes in P50,
shifting the curve to the 30 42

left or to the right
Cunningham's Textbook of Veterinary Physiology, 6th Edition

pso cosaturation sot rewatch
 Oxygen transport

Factors affecting O2 affinity:
Temperature temp
pH pH
PCO2 PLOz RIGHT SHIFT
(decreased affinity)

2,3-BPG Concentration 2,3 BPG 50% higher temp
lower pH
higher PCO2
Right shift – easier O2 release P50 = 30 mmHg
higher [2,3-BPG]
in high metabolic areas (the tissues)
30 42

Cunningham's Textbook of Veterinary Physiology, 6th Edition
 LEFT SHIFT
(increased affinity)
Oxygen transport
lower temp
higher pH
lower PCO2
Factors affecting O2 affinity: lower [2,3-BPG]

Temperature temp
pH pH
PCO2 PLO2 RIGHT SHIFT
(decreased affinity)

2,3-BPG Concentration 2,3BPG 50% higher temp
lower pH
higher PCO2
Right shift – easier O2 release P50 = 30 mmHg
higher [2,3-BPG]
in high metabolic areas (the tissues)
21 30 42
Left shift – more difficult O2 release
in areas with low metabolic demand
Cunningham's Textbook of Veterinary Physiology, 6th Edition
 Oxygen transport

Right shift – occur when there is
decreased affinity of Hb to oxygen
P50 increase – need higher PO2 to reach 50% of saturation
Cunningham's Textbook of Veterinary Physiology, 6th Edition
Decreased affinity = O2 release facilitated
High metabolic rate areas (need oxygen):
high PCO2
high temperature
low pH
high 2,3-BPG – byproduct of glycolysis in RBCs, increases during hypoxic conditions
 Oxygen transport

Left shift – occur when there is
increased affinity of Hb to oxygen
P50 decrease – need lower PO2 to reach 50% of saturation
Cunningham's Textbook of Veterinary Physiology, 6th Edition
Increased affinity = O2 release more difficult
Low oxygen demand areas:
low PCO2
low temperature
high pH
low 2,3-BPG
 Carbon dioxide transport

CO2 is carried in the blood in three forms:

23% carried in RBCs bound to
hemoglobin (carbaminohemoglobin)
70% dissolved in plasma as bicarbonate
7% free, dissolved in plasma

https://teachmephysiology.com/respiratory-system/gas-exchange/transport-carbon-dioxide-blood/
 Carbon dioxide transport

CO2 carried bound to hemoglobin
Carbon dioxide reacts directly with amino radicals (-NH) of the
hemoglobin molecule to form carbaminohemoglobin
CO2 does not bind to the same position where O2 binds
Reversible reaction, driven by PCO2
CO2 is easily released in the lungs where PCO2 is lower
There are other carbamino proteins in the plasma, transporting
CO2 the same way (