#3.4.1.1
The haemoglobins are a group of chemically similar molecules found in many different organisms. Haemoglobin is a protein with a quaternary structure.
#3.4.1.2
The role of haemoglobin and red blood cells in the transport of oxygen. The loading, transport and unloading of oxygen in relation to the oxyhaemoglobin dissociation curve. The cooperative nature of oxygen binding to show that the change in shape of haemoglobin caused by binding of the first oxygens makes the binding of further oxygens easier. The effects of carbon dioxide concentration on the dissociation of oxyhaemoglobin (the Bohr effect).
#3.4.1.3
Many animals are adapted to their environment by possessing different types of haemoglobin with different oxygen transport properties.
#3.4.1.4
The general pattern of blood circulation in a mammal. Names are required only of the coronary arteries and of the blood vessels entering and leaving the heart, lungs and kidneys.
#3.4.1.5
The gross structure of the human heart. Pressure and volume changes and associated valve movements during the cardiac cycle that maintain a unidirectional flow of blood.
#3.4.1.6
The structure of arteries, arterioles and veins in relation to their function.
#3.4.1.7
The structure of capillaries and the importance of capillary beds as exchange surfaces. The formation of tissue fluid and its return to the circulatory system.
#3.4.1.8
Students should be able to:
- analyse and interpret data relating to pressure and volume changes during the cardiac cycle
- analyse and interpret data associated with specific risk factors and the incidence of cardiovascular disease
- evaluate conflicting evidence associated with risk factors affecting cardiovascular disease
- recognise correlations and causal relationships.
#3.4.1P5
Required practical 5
Dissection of animal or plant gas exchange system or mass transport system or of organ within such a system.