circulation and gas exchange the heart the heart is a muscular organ that is divided into 4...
TRANSCRIPT
Circulation and Gas Exchange
The HeartThe Heart• The heart is a muscular organ that is
divided into 4 chambers:- 2 atria and 2 ventricles. (left and right)
• The left ventricle wall is very thick and muscular since it has to pump blood all round the body.
• The right ventricle wall is less thick since it just pumps blood to the lungs.
• The heart has 4 heart valves.
• 2 of the valves are between the atria and ventricles. On the left hand side is the bicuspid valve. On the right hand side is the tricuspid valve.
• The 2 other heart valves are at the origins of the pulmonary artery and the aorta – these are the semi-lunar valves.
• The valves ensure that blood is only able to flow in one direction. They prevent backflow of blood.
Right atrium
Left atrium
Right ventricleLeft ventricle
Semi lunar valves
Vena cava
Pulmonary artery
aorta
Pulmonary vein
Bicuspid
valve
Tricuspid
valve
• Since the heart wall is made of muscle it must get its own supply of oxygenated blood.
• The heart is supplied by the coronary arteries. (a branch of the aorta).
• If a coronary artery becomes blocked, the heart does not get a supply of oxygen and this may result in death of the tissue.
Path of Blood Flow Through the HeartPath of Blood Flow Through the Heart
• Blood arrives at the heart via the vena cava.• This blood is low in oxygen (deoxygenated.) • From the vena cava it enters the right atrium
then the right ventricle.• It exits the heart by the pulmonary artery where
it is carried to the lungs to pick up oxygen. • The blood becomes oxygenated. • From the lungs it goes back to the heart via the
pulmonary vein. • It enters the left atrium, then the left ventricle. • The blood leaves the heart in the aorta where it
is delivered to the rest of the body.
Head & Body
Vena cava Right atrium
Pulmonary vein
Left atrium
Right ventricle
Pulmonary arteryLungs
Left ventricle
AortaHead & Body
Right atrium
Left atrium
Right ventricleLeft ventricle
Semi lunar valves
Vena cava
Pulmonary artery
aorta
Pulmonary vein
Circulation & Blood VesselsARTERIESARTERIES• Arteries carry blood away from the heart.• Arteries carry oxygenated blood to organs and tissues –
(except the pulmonary artery)• Where an artery lies just under the skin the beating of
the heart can be felt. Each push of blood is called a pulse.
• Artery walls are very thick and muscular since they have to withstand blood travelling at high pressure.
VEINSVEINS
• Veins carry blood to the heart
• Veins carry deoxygenated blood from organs and tissues (except the pulmonary vein)
• Veins have valves present to stop the blood flowing backwards.
CAPILLARIES• Arteries split into a network of tiny thin walled
vessels called capillaries.• Capillaries are 1 cell thick, they are long, narrow
and thin to provide a large surface area.• Capillaries carry food and oxygen to every cell.• Gaseous exchange happens at each cell
(oxygen in, carbon dioxide out) and waste is removed back into the blood.
• Capillaries will reunite to form larger vessels and then into veins.
Blood leaves the heart in arteries, flows through capillaries and returns to the heart in veins
Circulation• Complete the blood vessels cut out sheet.
• You need to know the difference between arteries, veins and capillaries and the structural adaptations related to their function.
• You need to know the next diagram too – and the names and positions of these vessels;
• Pulmonary artery; pulmonary vein; aorta, vena cava; hepatic vein; mesenteric artery; hepatic portal vein; renal artery and renal vein.
• (You will need to add in the mesenteric artery to your diagram. You can colour the oxygenated blood red and deoxygenated blood blue)
gut Mesenteric artery
Deoxygenated blood
Oxygenated blood
The Lungs• The lungs are spongy/hard organs enclosed in
the _______________.• The _______________ (windpipe) branches
into two ___________ each of which enter one lung.
• The _______________ split into smaller and smaller tubes called _______________.
• The function of the cartilage is to _______________.
• The bronchioles end in very thin air sacs called __________.
larynx
Trachea (lined with
rings of cartilage)
Nasal cavity
mouth
Bronchus
Bronchioles
Alveoli (air sacs)
rib
Intercostal muscles
heartdiaphragm
Gas Exchange in the Alveoli
• The alveoli (air sacs) are lined with moisture.
• Oxygen dissolves in this moisture and diffuses into the blood.
• Carbon dioxide diffuses from the blood back into the alveoli.
• Using a red pencil, colour in on the diagrams which blood vessels contain oxygen.
• Using a blue pencil, colour in on the diagram which blood vessels contain carbon dioxide.
• For example…. See next slide
Features of alveoli which allow efficient gas Features of alveoli which allow efficient gas exchange.exchange.
• Large surface area
• Thin walls
• Moist surfaces
• Good blood supply
• These features of the alveoli ensure efficient gas exchange between the alveoli and the blood stream
BEGINNINGS ENDINGSE Oxygen diffuses into the sacs because there is a higher CO2
concentration in the blood.
B The air sacs are thin air sacs, they make a very large surface area.
D The air sacs have many which is moist so that gases can dissolve.
C Because there are so many to let gases through easily
A The air sac is lined with mucus blood capillaries in close contact with them
F Carbon dioxide diffuses into the air
blood because there is a higher O2 concentration in the air sacs.
The letters give the running order ….check your answers
BEGINNINGS ENDINGSE Oxygen diffuses into the 1
sacs because there is a higher CO2 concentration in the blood. 6
B The air sacs are thin 2 air sacs, they make a very large surface area.
4
D The air sacs have many 3
which is moist so that gases can dissolve.
5
C Because there are so many 4
to let gases through easily
2
A The air sac is lined with mucus 5
blood capillaries in close contact with them
3
F Carbon dioxide diffuses into 6 the air
blood because there is a higher O2 concentration in the air sacs.
1
Features of a capillary network which Features of a capillary network which allow efficient gas exchange in tissuesallow efficient gas exchange in tissues
• They have a large surface area.
• They are in close contact with the body cells.
• They have thin walls.
• These properties of the capillary network allow efficient gas exchange to occur between the blood stream and the body cells.
THE BLOODTHE BLOOD
Composition of the BloodComposition of the Blood
Blood contains:-
• Red blood cells
• White blood cells
• Plasma
• Platelets
• Oxygen is carried in the red blood cells.
• Carbon dioxide is carried in the plasma.
• The concentration of carbon dioxide carried in the plasma is limited since it combines with water to form an acid.
• Too much acid in the blood would lead to problems since blood functions best between pH 7.36 and 7.44.
• Most carbon dioxide is transported in blood plasma as bicarbonate ions. (Some CO2 is carried in the red blood cells attached to other molecules)
• Soluble food such as glucose and amino acids are also transported dissolved in the plasma.
Function of HaemoglobinFunction of Haemoglobin Haemoglobin is found in red blood cells.
In high oxygen concentrations haemoglobin combines readily with oxygen to form oxyhaemoglobin
This happens in the lungs
In low oxygen concentrations, oxyhaemoglobin releases its oxygen to the body cells.
Blood with oxygen is bright red.
Haemoglobin carries oxygen to the tissues of the body.
Colour in the blood high in high in
oxygenoxygen red and the blood low low
in oxygenin oxygen blue.
• So:-
Haemoglobin + oxygen oxyhaemoglobin
Association (in lungs)
Dissociation (in tissues)
Associate = to combine with oxygen
Dissociate = to release oxygen
White Blood CellsWhite Blood Cells
• Are less numerous than RBC’s
• They contain nuclei, can change shape and squeeze through tiny pores in capillary walls.
• They are suited to their function of defending the body since they can reach the site of infection outwith the circulation.
• Two types of white blood cell are monocytes and lymphocytes.
lymphocytesmonocytes
PhagocytosisPhagocytosis• Is the process by which bacteria are engulfed and
destroyed by phagocytic cells such as monocytes and macrophages (Macrophages are cells that come from monocytes)
• The macrophage will engulf a bacterial cell and then digest it.
• During infection, 100’s of monocytes and macrophages migrate to the infected area and engulf many bacteria by phagocytosis. Dead bacteria and these cells often accumulate at a site of injury forming pus!
Bacterium giving out chemical
macrophage
Vacuole forming
Trapped bacterium
Lysosome (structure containing digestive enzymes)
Lysosomes move towards and fuse with vacuole
Bacteria being digested by enzymes from lysosomes
Immunity and AntibodiesImmunity and Antibodies• Immunity is an organism’s ability to resist
infectious disease.
• Phagocytosis is an example of non-specific immune response since it provides general protection against a wide range of micro-organisms.
• Antibody production is an example of specific immune response as they are specific to a particular antigen.
ANTIGENA molecule that is recognised as alien to the
body by the body’s lymphocytes.
ANTIBODYThe presence of an antigen in the body stimulates the
lymphocytes to produce antibodies.
An antibody is a Y-shaped molecule. Each arm has a
receptor site whose shape is specific to a particular antigen.
When an antibody meets its complementary antigen, they combine at
their specific sites like a lock and key and the antigen is rendered
harmless. It will then be engulfed by phagocytosis.
AntibodyReceptor
sites
Antigens meet antibodies
virus antigen
Virus gains access to body & multiplies
inside the cell
Some viral particles become attached to
their antigens to lymphocytes
lymphocyte
Lymphocytes respond to this antigen by multiplying and producing cells that mass produce a specific type of antibody
Antigens combine with antibodies at receptor sites and become a harmless complex later engulfed by a phagocyte.
Primary and Secondary ResponsesPrimary and Secondary Responses• When a person is infected by a disease-
causing organism, the body responds by producing antibodies.
• This is the primary response.
• Because it takes a while before the antibodies appear, the primary response is often unable to prevent the person from suffering the disease.
• If the person survives and are exposed to the same disease-causing antigen in the future, a secondary response happens.
• This happens because the body has memory cells which remember the antigen.
• This time the disease is usually prevented.
• During the secondary response– Antibody production is more rapid– The concentration of antibodies produced reaches a
higher level– The higher concentration of antibodies is maintained
for a longer time
0 10 20 30 40 0 10 20 30
Increasing concentration of
antibodies
First exposure to antigen
Second exposure to antigen
Time (days) Some later time in a person’s life
(days)
Primary Response
Secondary Response