Carriage of Blood Gases PDF - UM1010

Summary

This document presents a lecture on the carriage of blood gases, covering the transport of oxygen and carbon dioxide in the blood. It includes diagrams and discussions of factors influencing their carriage, such as pH, temperature, and the role of 2,3-BPG.

Full Transcript

Carriage of Blood gases

Kath Taylor slides adapted from Darrell Brooks
UM1010
ISCM 1 CVS-R physiology
 Lecture Outline

How oxygen is carried in the blood

Factors that affect the carriage of oxygen,
and how this changes in different areas of
the body

How carbon dioxide is carried in the blood

Importance of the bicarbonate buffer
system
Schematic diagram showing the basic structure of a single haemoglobin A molecule, including two α-
globin chains (green), two β-globin chains (yellow), each containing a haem–iron complex (blue).
 Deoxygenated and Oxygenated Haemoglobin

The transition from ‘tense’ to ‘relaxed’ haemoglobin. In its
deoxygenated ‘tense’ form, the crevice containing the haem
molecule is narrow, restricting the access of oxygen to its
binding site. As each oxygen molecule binds, the position of the
haem molecule changes which affects the interaction between
adjacent globin chains, relaxing the molecule and so allowing
easier access of subsequent oxygen molecules to their binding
site.
Contin Educ Anaesth Crit Care Pain, Volume 12, Issue 5, October
2012, Pages 251–256,
Hb saturation with 02 and partial pressure
 The relationship between percentage saturation of Hb with
oxygen, and partial pressure of oxygen is a sigmoid curve. In
the alveoli, the partial pressure of oxygen is about 104mmHg,
which means that Hb is almost 100% saturated; it has a high
AFFINITY for oxygen Deoxygenated blood
(contracting skeletal
 In systemic veins, the muscle) Oxygenated
blood
partial pressure of oxygen in systemic
is about 40mmHg, and Hb arteries

is around 77% saturated
 This means that some of
the oxygen has been
released for use in aerobic Deoxygenate
respiration d blood
in systemic
 In systemic veins Hb has a veins
(average at
LOWER affinity for oxygen. rest)
Effect of pH on affinity of haemoglobin for
oxygen
 When pH is reduced High blood pH
(high concentration (7.6)
of hydrogen ion),
the affinity of Hb for
oxygen reduces Normal blood pH
 This means that at (7.4)

any PO the SaO2 is Low blood pH
2
lower – more (7.2)
oxygen has been
released
 The curve shifts to
the right (Note curve
down)

Why is this an advantage?
When is this a disadvantage?
Effect of P CO
2
on affinity of haemoglobin for
oxygen
 Blood also carries Low blood PCO
2

carbon dioxide

 When blood PCO2 is
Normal blood PCO
high, the affinity of 2

Hb for oxygen falls
High blood PCO
 The curve shifts to 2

the right, and more
oxygen is released

(Note curve down)
Effect of Temperature on haemoglobin O2
affinity
 Increasing Low
temperature
temperature reduces (20°C, 68°F)
affinity and shifts the
curve to the right
 Decreasing Normal
temperature shifts blood
the curve to the left temperatur
e
High (37°C,
98.6°F)
temperature
(43°C, 110°F)
Effect of 2,3 DPG on affinity of haemoglobin
 2,3-Bisphosphoglyceric
acid (2,3-BPG), is a Decreased 2,3 BPG
three-carbon isomer of
a glycolytic
intermediate
 Present in human red
blood cells at @ 5
mmol/L
 binds with greater Increased 2,3 BPG
affinity to
deoxygenated
haemoglobin
 promotes the release of
the remaining oxygen
 2,3-BPG increases x5
within 1-2 hrs in
patients with chronic
anaemia
 Decreases with dialysis
Foetal Hb affinity for oxygen
 Foetal Hb (α2γ2) predominates during most of gestation
HbF. Foetal Hb has a higher affinity for oxygen than
maternal HbA.
 This is essential because it means that under conditions
where maternal Hb is releasing some oxygen, foetal Hb
can take it up.
 This allows effective transfer of oxygen from maternal to
Foetal
foetal blood
Matern
al
Transfer of oxygen to tissues
 Myoglobin also has greater affinity for O2 than
haemoglobin (curve shifted left)
 Accepts O2 from haemoglobin when PO2 in blood is low
and release O2 in muscle (e.g. during exercise).
 The myoglobin binding
curve lacks the
sigmoidal shape of the
haemoglobin binding
curve because of the
single O2 binding site
in each molecule.
CO2 transport in blood
 CO2 produced as a waste product of metabolism.
 Transported to lungs for excretion.
 Different ‘pools’ of CO2 in blood.
 Bicarbonate contributes the overwhelming majority of CO2.

 carbonic anhydrase
catalyses the reaction to
produce carbonic acid which
then readily dissociates to
form hydrogen ions and
bicarbonate
CO2 transport in blood
 A small amount of CO2 dissolves
in plasma
 Most carbon dioxide diffuses into
red blood cells
 Some carbon dioxide attaches to
Hb, displacing oxygen (note O2
affinity)

 Most carbon dioxide reacts with
water catalysed by carbonic
anhydrase to produce
bicarbonate and hydrogen ion
 Bicarbonate diffuses out of the
red blood cell and is replaced by
chloride ions (chloride shift)
 In the lungs the process is
The importance of the bicarbonate ion
 One of the most important buffer systems in the body
 A reversible chemical reaction that can absorb or release hydrogen
ions (H+).
 Hydrogen ion concentration must be kept constant. Changes in pH
affect:
 The affinity of Hb for oxygen
 The rate of enzyme reactions (optimal within a very
narrow range)
 The ionisation states of many substances, disrupting their
structure e.g. DNA
The importance of bicarbonate ion
 Mechanisms involved in the bicarbonate balance
 Carbon dioxide production from metabolism (Krebs
cycle )
 Exhalation of carbon dioxide by the lungs
 Hydrogen ion excretion by the kidney
 Bicarbonate reabsorption
The importance of bicarbonate ion
 Other tissues
 Stomach – parietal cells: acid
secretion
 Pancreas – duct cell: pancreatic juice
Metabolic and respiratory disorders

 Metabolic processes affect bicarbonate concentration, and
respiratory processes affect PCO.
2

 Changes in ventilation compensate for metabolic disorders,
and renal excretion of acid compensates for respiratory
disorders.
 In primary acid–base disorders, the underlying disorder will be
evident from examination of the pH, PCO , and serum
2
bicarbonate.
Metabolic and respiratory disorders

Metabolic disorders
 Respiratory compensation for primary metabolic disorders
begins within minutes as chemoreceptors sense the change in
extracellular pH and signal the respiratory centre to change
minute ventilation.
 In a primary metabolic acidosis, the acidaemia stimulates an
increase in minute ventilation and subsequent decrease in
PCO ; conversely, a metabolic alkalosis results in
2
hypoventilation and increased PCO.
2

Respiratory disorders
 Renal compensation for primary respiratory disorders is a
much slower process, taking 6–12 hours to respond to
sustained changes in pH.
 In a primary respiratory acidosis, the kidneys increase
bicarbonate synthesis, excrete more organic acids, and
 Learning outcomes

Demonstrate the physiological process
of respir
ation and its nervous control
Demonstrate the significance of
maintaining normal acid-base balance
within the body and the role of the
respiratory system in it.