Blood Composition.docx

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**[Blood Composition]**

[Plasma\
]Plasma makes up 55% of blood. Plasma is a straw-coloured
liquid matrix composing of 90% water and 10% dissolved proteins, salts,
foodstuffs and waste materials.\
*Functions of Plasma Proteins\
*- A series of proteins prevent blood loss and the entry of pathogens by
clotting\
- Antibodies mark pathogens and infected or damaged cells for attack by
phagocytic white blood cells\
- Albumen maintains the osmotic balance within the organism\
*Functions of Dissolved Salts\
*- Maintain osmotic balance\
- Essential for the proper functioning of cells

[Red Blood Cells\
]-Red blood cells are the most abundant cells and are
produced in the red bone marrow of long bones.\
- Red blood cells do not contain a nucleus or mitochondria when they are
mature, which allows them to carry out their role of transporting oxygen
around the body with maximum efficiency\
- Biconcave discs\
- Filled with the red respiratory pigment haemoglobin\
- Survive for approximately 120 days before being broken down and
recycled by the spleen and liver to make bile pigments

[White Blood Cells\
]White blood cells are made in the bone marrow. Their
numbers can increase when an infection is present. White blood cells
defend the body from attack. There are many different types of white
blood cells including:\
- Monocytes: The largest white blood cell and account for about 7% of
all white blood cells. They form part of the innate immune system,
attacking and engulfing anything they consider not to be part of the
body itself. Monocytes have a large bean shaped nucleus; they move by
amoeboid motion and engulf cells by phagocytosis. After engulfing the
cells, they present antigens from the destroyed cell to T-Cells.\
- Lymphocytes: Have a large spherical nucleus and they make up 20-40% of
all white blood cells. They are stored in the lymphatic system. Most are
short lived, surviving for only a few weeks. There are many types of
lymphocytes including T Cells (attack invaders), and B-Cells (make
antibodies).

[Platelets\
]- Cellular fragments that play a major role in blood
clotting\
- They gather at the site of a wound and start a series of chemical
reactions that result in the production of fibrin\
- Fibrin forms a network of strands across the wound, trapping blood
cells and forming a scab. This prevents blood loss and the entry of
pathogens

[Blood Groups\
]- Blood groupings are based on antigens that occur on the
outer surface of blood cells. An antigen is a substance that produces an
immune response, which is essentially the production of a protein called
an antibody.\
- Blood groups determine which blood groups can be safely received in
blood transfusions.\
- If someone is given the wrong blood group in a transfusion there may
be a sever allergic reaction, which can kill.

Blood Group O A B AB
------------- --------- ----- ----- ---------
Antigens Neither A B A and B
Antibodies A and B B A Neither
Population 55% 31% 11% 3%

[Rhesus Factor\
]- The Rhesus protein was first discovered in Rhesus
Monkeys\
- Blood with the rhesus antigen on the surface is said to be Rhesus
positive (RhD+), and blood without it is said to be Rhesus negative
(RhD-)\
*Importance in pregnancy*\
- If the mother is Rhesus negative, and the unborn child is Rhesus
positive, then some of the baby's Red blood cells with Rhesus antigens
may cross into the mother's bloodstream at the end of pregnancy.\
- The mother will recognise these rhesus antigens as 'foreign' and
produce antibodies against them. Usually there is no danger to the baby
during the first pregnancy, though the mother is now sensitised to the
rhesus antigen.\
- The antibodies produced by the mother will destroy the baby's red
blood cells in subsequent Rhesus positive babies because antibodies pass
into baby.\
- This may cause the baby to be anaemic, brain damaged or stillborn\
- To prevent this happening, the mother may be injected with Rhesus
antibodies immediately after the birth of her first child. These will
destroy the baby's red blood cells before they cause a natural build-up
of anti-Rhesus antibodies in her blood

[Mandatory Practical -- Dissect, Display and identify a sheep's or ox's
heart]

\- Place the heart on a dissecting board with the front facing upwards\
- Identify the blood vessels: aorta, pulmonary artery, vena cava and
pulmonary vein.\
- Make a shallow cut in the left ventricle and the left atrium.\
- Push open the chambers and examine the internal structure.\
- Locate the bicuspid valve and note the chordae tendinae -- anchoring
the cusps of the valve\
- Repeat the previous steps for the right side of the heart.\
- Locate the tricuspid valve and note the chordae tendinae anchoring the
cusps\
- **Note the difference between the walls of the left ventricle and the
right ventricle\
- Locate the septum separating the left from the right side of the
heart.\
- Insert a forceps under the moderator band in the right ventricle\
- Identify the opening at the base of the aorta, above the semi-lunar
valves, leading to the coronary arteries\
- To highlight the coronary arteries: Using a dropper, pump air into the
opening at the base of the aorta**

**[Mandatory Practical -- Investigate the effect of exercise on the
pulse rate of a human\
]- Measure your resting pulse rate at the wrist, using your
second finger. Count the number of beats in 15 seconds and multiply this
figure by 4. Repeat twice more and take an average\
- Take some gentle exercise, like walking, for three minutes and then
sit down\
-Record your new pulse rate three times and take an average\
Note the time taken for the pulse to return to its resting rate\
- Take some strenuous exercise, like running, for three minutes and sit
down\
- Record the new pulse rate three times and take an average\
- Once again, note the time it takes for your pulse to return to its
resting rate\
- Document the results as follows\
**

**Activity** **Pulse Rate 1** **Pulse Rate 2** **Pulse Rate 3** **Average Pulse Rate** **Time taken to return to resting rate**
-------------- ------------------ ------------------ ------------------ ------------------------ ------------------------------------------
**Resting**
**Running**
**Walking**

**- Heart rate increases with level of exercise\
- The faster the heart rate is after exercise, the longer it takes to
return to normal\
- A fit person's heartbeat is slower at rest, and returns to resting
rate faster than that of an unfit person**