Haemoglobin and oxygen levels
The city of La Paz in Bolivia is a city with one of the highest altitudes in the world. Some poeple who visit La Paz find it very difficult to breathe especially if they exercise. Newcomers to La Paz are recommended to move slowly at first to acclimatise themselves to the altitude. Yet people who are born, grow up and live in this Andean city do not experience these problems.
This relates to the process of obtaining oxygen from the air at high altitudes and to the molecule that binds the oxygen - haemoglobin.
Haemoglobin is a miltipurpose molecule. It plays a role in transporting some carbon dioxide and it buffers the hydrogen ions produced from carbonic acid.
STRUCTURE OF HAEMOGLOBIN
The red pigment haemoglobin is the main component of our red blood cells. It is composed of four units of a protein called globin. Towards the centre of each globin is a haem unit. Haem is a ring structure with iron in the centre. it is the iron that binds the oxygen, in a weak interaction that can be easily broken. A red blood cell is packed with haemoglobin molecules. The cell has no nucleus so more haemoglobin molecules can be included. They symbol for haemoglobin is Hb.
THE FUNCTION OF HAEMOGLOBIN IN TRANSPORTING OXYGEN
The functions of haemoglobin include:
- transport of oxygen to body cells from the lungs
- transport of some carbon dioxide from body cells to the lungs.
- buffering of the hydrogen ions that are produced from the ionisation of carbonic acid (carbonic acid is made when some carbon dioxide reacts with water). They hydrogen ions are attached to amino acid groups on the large haemoglobin molecule.
The major role of haemoglobin is the transport of oxygen. Oxygen is not very soluble in water and most of it is carried by haemoglobin in the red blood cells. The interaction of iron ions with oxygen bind oxygen to haemoglobin, forming oxyhaemoglobin. This occurs when the pressure (concentration) of oxygen is very high, for example in the lungs. Each haemoglobin molecule can bind four oxygen molecules (one molecule per haem). The opposite occurs at the body cells, where oxygen pressure (concentration) is low. This is a reversible reaction that can be summarised as follows:
Hb + O2 = HbO2
Haemoglobin + oxygen = oxyhaemoglobin
There are approximately 280 million haemoglobin molecules in each red blood cell. If each haemoglobin can bind four oxygen molecules than each red blood cell can thoretically carry 4(280 000 000) or 1,120,000,000 molecules of oxygen.
SATURATION OF HAEMOGLOBIN WITH OXYGEN
Haemoglobin saturation is the percentage of haem units containing bound oxygen. For example, if all the haemoglobin molecules are fully loaded with oxygen, there is 100% saturation. If all the haemoglobin molecules have, on average, two molecules of oxygen then there is 50% saturation.
The saturation of haemoglobin with oxygen is dependant on the PO2 (pressure of oxygen, whcih is directly related to the concentration of oxygen) in the evironment of the haemoglobin. At the lungs PO2 is high so oxygen diffuses into the blood and binds to the haemoglobin. At the body cells the opposite occurs. The PO2 is low so O2 is released from the haemoglobin and diffuses into the body cells.
The relationshop between PO2 and haemoglobin saturation provides a mechanism for regulating the amount of oxygen delivered to tissues. When tissues are relatively inactive the local PO2 is approximately 40mm Hg. Not much oxygen is released. When the tissues become more active they use more oxygen, so the PO2 in the tissue decreases to 15-20 mm Hg. More oxygen is releaased from haemoglobin. So the release of oxygen depends on how much oxygen is being used, Under normal resiting conditions haemoglobin returning to the lungs in the veins will still be 75% saturated with oxygen (although it may be called deoxyhaemoglobin). Haemoglobin fully saturated with oxygen is called oxyhaemoglobin.
