Year 11 Human Transport (Circulatory system) 1.pptx

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Circulatory systems
A circulatory system consists of a group of organs that
transport substances, such as oxygen, around the body.

heart Some organisms, such as insects, have
an open circulatory system, where the
fluid moves freely between cells.
Other organisms, including humans, have
a closed circulatory system where blood
is contained within vessels, where these
factors can be controlled:
 the speed of blood flow
 the pressure of the blood
 the distribution of blood in the body.

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 One and two circuits

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Closed circulatory systems
A single circulatory system has a two-chambered heart so
that blood can be returned to one chamber, and pumped
back out of the heart from the second chamber.
This ensures blood flow in one direction only.

The double circulatory system has a four-chambered heart
so that blood can be pumped out to the lungs, returned to
the heart, and be pumped out again to the rest of the body.

This maintains a high pressure
in the blood vessels and faster
blood flow to the tissues.
This is essential for organisms
with a large body, such as whales, elephants, and
humans.
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 Circulation
The dissolved food and
oxygen needed for respiration
are carried around the body
by the circulatory system.

The circulatory system
includes the blood, blood
vessels, the heart and
the lungs.

Which part of the
circulatory system actually
carries dissolved food and
oxygen to the body’s cells?

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What does the heart do?
The heart is a muscular
organ located in the thorax.
It pumps blood continuously
around the body.

The blood supplies cells
with oxygen and glucose,
needed for respiration.

The blood also transports the waste products, such as
carbon dioxide, the waste product of respiration, and urea.

Special arteries called coronary arteries carry blood to the
heart to supply the heart muscle cells with oxygen and
glucose for contraction.

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 Your beating heart
The heart is made of very special
muscle called cardiac muscle.
This is because it has to keep beating
for the whole of a person’s life!

If you tried to do the same action
repeatedly (like the heart does),
your muscles would get tired
and, after a while, stop working.
For example, if you keep clenching and unclenching your
hand, it will get tired and may even start to get cramp.

Why is it important for respiration that the heart keeps
beating?

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Contraction and relaxation

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The Heart
Which structure?

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 Pulse
In the closed circulatory system, the blood will flow in:
 arteries  capillaries  veins

Each time the heart muscle contracts, it pushes
blood out of the chambers at high pressure.
This causes the blood vessels to throb.
This is called a pulse.

The pulse can be
detected at various
places around the
body, including the
wrist, at the temple
and in the ear lobe.

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 Arteries
Arteries carry blood under high pressure.
They have a thick muscle wall to withstand the pressure (adaptation)
A small lumen
The elastic walls stretch when the heart beats and then contract
back and force blood forward. (adaptation)
This can be felt as your pulse

Thinking point
Someone has been in an accident and they
are bleeding.
How could you tell – just by looking – if an
artery had been damaged?
Just as important – if it was a damaged
artery what would you do?
 Arteries
Answers

Blood in arteries is under pressure
and in a muscular elastic tube.
So blood squirts out driven by
the heartbeat and pulse.

To seal the wound pressure must
be applied and if possible the wound
site should be lifted up.
Blood flow in arteries
Blood pressure is the main force that drives blood from the
heart around the body.

When the heart contracts The elasticity of the
(systole), blood is fibres in the arteries
pumped through the means they can expand
arteries at high pressure. and allow blood through.

When the heart relaxes The elastic recoil of the
(diastole), the blood in arteries means they can
the arteries is at a much help force the blood
lower pressure. along to the arterioles.

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 Capillaries
Capillaries are very narrow – forcing blood cells to pass in single-
file
Capillaries have very thin walls – about 1 cell thick – which makes
it easy for substances to diffuse through (adaptation)

Capillaries are the point where arteries
become veins!

When you fall and graze your elbow the blood oozes out – you have
damaged a few capillaries. A small skin cut doesn’t bleed much for the
same reason.
 Veins
Veins carry blood towards the heart under low pressure.
They have a thin muscle and elastic wall.
Veins have valves which prevents blood from flowing backwards.

This is what happens when the valves get leaky. Leg muscles help!

leads to
Structure and function of blood
vessels
What is blood?
Blood is a specialized
liquid that circulates
around the body in blood
vessels. An average adult
has 4–6 litres of blood.

Blood has a range of
functions, including to:
 transport substances
 defend against pathogens
 control body temperature
 maintain pH of fluids.

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Features of red blood cells
What are the specialized features of a red blood cell?

flattened, biconcave disc shape:
ensures large surface area to volume
ratio for efficient gas exchange large amount of
haemoglobin: for
transporting oxygen

no nucleus or
organelles:
maximizes space for
haemoglobin, so more
diameter (6–8 µm) larger than oxygen can be
capillary diameter: slows blood transported
flow to enable diffusion of oxygen
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Haemoglobin
Red blood cells are packed with haemoglobin, which is a
red protein that gives blood its colour. Haemoglobin makes
up 95% of the dry mass of a red blood cell.

Haemoglobin is made up of four protein chains,
each bound to one haem group.

In the lungs, the haem group
combines with oxygen to form
oxyhaemoglobin.

When blood reaches the organs,
oxyhaemoglobin splits to reform
haemoglobin and oxygen, where the
oxygen is free to diffuse into cells.

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 What is blood?
Plasma straw coloured liquid
mainly water
carries dissolved substances

White cells two sorts
both kill
Red cells carry oxygen pathogens
contain haemaoglobin

Blood also contains platelets, hormones, digested food
products, dissolved carbon dioxide
Blood clotting
At the site of a cut or wound the blood will clot. This prevents
further blood loss, reduces the risk of pathogens entering
and forms a framework for repairing the damaged tissue.

Platelets rapidly stick to
a damaged area,
releasing chemicals that
start a series of reactions.

This results in a network
of fibrin fibres which form
a mesh. This mesh traps
blood cells and debris,
forming a solid clot.

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Why can blood clots be dangerous?
Blood clots normally occur at the site of a cut. However,
they can arise within blood vessels. This can be dangerous
as a clot could obstruct the flow of blood to a major organ.
A blood clot can cause organ damage and even death.

Anti-coagulant drugs, such as
warfarin, heparin and aspirin can
be taken when a person’s blood is
clotting too quickly.

These drugs can control clotting by reducing
the ability of the blood to clot. Substances
such as vitamin K, alcohol, green vegetables
and cranberries can also affect clotting.

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What is haemophilia?
Haemophilia is an inherited disease that prevents the
body from controlling bleeding properly.

Haemophilia is a recessive
sex-linked disease that mainly
affects males.

People with haemophilia
(haemophiliacs) are
partly or completely
missing a clotting factor
that is needed to make
their blood clot properly.

There are about 6,000 people with haemophilia in the UK.

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Reduced blood flow
Arteries can become blocked when fatty deposits build up.
This reduces blood flow and increases the pressure.

A reduced blood flow is
especially dangerous in
the coronary arteries,
which supply the heart
with oxygen and glucose.

fatty deposits

To restore normal blood flow, a small mesh tube called a
stent is inserted into the narrow artery. The metal or fabric
mesh of the stent is used to support the inner wall of the
artery to keep it open artificially.

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Heart rate and exercise
During exercise several
changes occur:
 the heart rate increases
 the rate and depth of
breathing increases
 the arteries supplying
the muscles dilate.
These changes help to provide oxygen and glucose to
muscles and remove carbon dioxide more quickly.
Heart rate can also be altered by hormones such as
adrenaline. The presence of adrenaline causes the heart rate
to increase, allowing a quick response to danger.

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 How does regular exercise affect the heart?
Regular exercise can strengthen the heart, causing:
 the heart to become bigger
 the amount of blood pumped by the heart to increase
 the walls of the heart to become thicker and stronger.

The result is that the heart becomes a more efficient pump.

The resting pulse rate gets
slower as a person becomes
fitter, because the heart
needs fewer beats to pump
blood round the body.

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ECG in diagnosis of irregular heartbeats
ECGs are used to diagnose problems with the heart, as
variations in different components of the trace can
indicate a disease or other abnormality.

An ECG may be taken
while the patient is relaxed
or it may be taken before,
during and after exercise.

This is called a ‘stress test’
and usually involves the
patient exercising on a
treadmill while attached to
an ECG machine.

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What is an electrocardiogram?
The electrical activity of the heart can be monitored by
using an electrocardiograph.
Several electrodes are attached to
specific places on a person’s chest.
These detect electrical changes in
the heart by measuring current at
the skin’s surface.
The leads are connected to a machine
that draws an electrocardiogram
(ECG). A normal ECG is shown below.

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