Disease and the Immune System PowerPoint PDF

Summary

This PowerPoint presentation covers the topic of diseases and the immune system. It explains the differences between infectious and non-infectious diseases, and details the different types of pathogens. The presentation also describes the body's three lines of defense against diseases, including physical and chemical barriers.

Full Transcript

Disease and the Immune System

A high-resolution time-lapse of an immune cell
(red) hunting down and destroying cancerous
Learning intentions: Diseases
Understand the difference between infectious and non-
infectious diseases
Describe how humans become infected with pathogens
(methods of infection)
 What is a Disease?
Discuss with the person next to you and write your
own definition of the word DISEASE.

Can you name 5 diseases?
What is a Disease?
Disease is any condition in which the body
or parts of the body do not function
properly.

Melanoma
(skin cancer)

Tonsillitis
Chickenpo (Sore Rheumatoid arthritis
x throat)
ssifying Diseases
Sometimes referred to as
‘Contagious’ if the disease
spreads from one person to
Diseases can be classified into groups based on how a disease is another person ie. COVID-
obtained.
19
Diseases that are infectious
but not contagious ie. ear
Diseases infectious and Lyme
disease.

Congenital Diseases Acquired Diseases

Non-
Ageing (arthritis,
Cancer
(stomach, Communicable/ communicable/
heart disease)
breast, colon) infectious diseases non-infectious
diseases
Chemical/
metabolic Mental Nutritional
(lactose (depression, Cellular (anaemia, Environm
intolerance, schizophrenia) Non-cellular osteoporosis,
diabetes) pathogen ental
pathogens obesity) (drug-
s
Inherited related,
(haemophilia, Bacteria accident-
colour blindness, (botulism, Viruses
cystic fibrosis) tetanus,
Fungi (thrush, (influenza, Prions (bovine related,
tuberculosis,
tinea, ringworm) measles, AIDs, spongiform asbestos-
cholera) chickenpox, encephalopathy – related)
COVID-19) mad cow disease)

Protozoa Animals (louse,
(malaria, liver fluke,
giardiasis) tapeworm)
 Non-Infectious
Non-infectious diseases not caused by pathogens,
may be caused by such things as lifestyle factors,
environmental toxins, or gene inheritance or mutations.
Examples include:
Diabetes
Cancer
Epilepsy
Asthma and Allergies

Allergy Diabetes
 Infectious diseases
Infectious diseases are caused by pathogens and can
spread from one organism to another.
Pathogens are disease causing organisms. Pathogens can
be:
Cellular (made out of cells) ie. Bacteria and fungi
Non-cellular (not made of cells) ie. Viruses and prions
‘Achooooo
’
The symptoms of
infection with the
pathogen are what
causes the disease.

The worse the
symptoms, the higher
the virulence.

Virulence is the
severity or harmfulness
Allergy Diabetes of a disease or poison.
How do infectious diseases
spread? an organism that helps transmit infection
from one host to another (often does not
show any symptoms of the disease) ie.
mice/rats, fleas, mosquitoes/flies.

Contact with infected person
or animal
How the Bubonic Plague was
transmitted

Example, when a Flea
serves as the vector to
infect humans with
Bubonic Plague (caused
by bacteria).
The flea acquires the
bacteria from rats when
it takes a blood meal.
If the same flea
subsequently feeds on a
human (host), the
plague bacteria can be
Learning intentions: Pathogens
Viruses:
Recount how viruses are non-cellular agents (non-living) and need to
replicate in a host cell.
Bacteria
Bacteria are small single-celled organisms that can
come in good (beneficial) forms and bad
(pathogenic) forms that cause disease.
Bacterial diseases - examples

Diptheria Lyme Disease Meningitis
 Fungi
A KINGDOM of organisms that have a cell
wall made of CHITIN.
Fungi live in air, in soil, on plants and in
water.
Fungi reproduce asexually by
fragmentation, budding, or by producing
spores.
You can inhale the spores or they can land
on you. As a result, fungal
infections often start in the lungs or on
the skin.
Parasitic fungi use enzymes to break down
living tissue, which causes illness in the
host.
 Fungal diseases - examples

Thrush Ringworm Tinea/Athlete’s Foot
Viruses
A virus is a tiny, infectious particle that can
reproduce only inside a host cell.
Viruses "commandeer" the host cell and use its
resources to make more viruses, basically
reprogramming it to become a virus factory.
Because they can't reproduce by themselves
(without a host), viruses are not considered
living.

COVID-19 is a serious infectious disease caused
by a pathogenic and new strain of coronavirus.

ANTIBIOTICS DO NOT WORK AGAINST VIRUSES
Virus structure However, they have the
Viruses are structurally diverse. following features in common:
A protective protein shell,
or capsid
DNA tucked inside of the
capsid

Capsid enables
the virus to
attach to the host
cell
Virus reproduction

1. Virus injects DNA into the
host cell.
2. Viral DNA is replicated by
the host cell’s organelles.
3. 1000s of new viruses
burst the cell to go on
and infect 1000s of new
host cells.
Viral Diseases
Polio

Rabies

Hepatitis
Rubella COVID-19
 How do we stop the spread of
disease?
What strategies are used depends on the
pathogen and its mode of transmission. These
include:
Vaccination programs
Strategies to help authorities assess risk, eg
contract tracing, testing, wastewater
testing
Strategies that restrict movement, eg
lockdowns, quarantining, isolating
Strategies that reduce spread, eg masks,
social distancing, washing hands.
Treatment with antibiotics (only bacteria)
and antivirals
Social strategies are implemented to support
scientific strategies, and include: public
awareness campaigns, funding for vaccine
research and roll out, public
compliance/enforcement, international
cooperation.
Learning intentions: The Immune System
Define and give examples of the First line of defence (passive immune
system).
Define and give examples of the Second line of defence, and the immune cells
involved.
Define and give examples of immune cells involved in the Third line of
 The onset of disease
Pathogens can enter the body in a number of ways:
Through Food and Water
Breathing In
Cuts and Wounds
Once infected, depending on the disease, it may only take a few days before any symptoms
appear. This time is called the incubation period. An incubation period occurs because the
pathogen needs to multiply and toxins often need to build up.
Your body has THREE Lines Of Defence against Disease

Ctrl + click on the
image to watch
the videos.
The First Line of Defence
Pathogens can enter the body in many
ways. The body’s first line of defence is
designed to stop them from entering
the body.
These defences can be:
Physical barriers – such as intact
skin, cilia and nasal hairs.
Chemical barriers — body fluids such
as saliva, tears, and stomach acid.
Biological – good bacteria in on our
skin and the lining of our intestine that
prevents bad bacteria from flourishing.
They do this by out competing the
harmful bacteria for food and space.
 The First
Line of
Defence
Barriers are chemical or
physical:
Barrier Chemic Physic
al al
Skin (+ acid x x
on skin)
Tears x
Stomach acid x
Mucus x
Saliva x
Cilia (hair-like X
structures) in
the throat
Nose hairs x
The Second Line of Defence
Once pathogens enter the body, the second line of defence gets started.
This includes:
Clip
1. Inflammation
White blood immune cells called ‘Mast Cells’ release
HISTAMINE, a chemical that causes an INCREASE of blood flow to
the area where pathogens have been detected.
White blood cells then come in and consume pathogens
(Phagocytosis) – next slide
This leads to the site becoming RED, SWOLLEN, HOT and PAINFUL.

2. Fever: having a high fever may be uncomfortable, but it is an
important part of the immune response, as a rise in temperature
will make it harder for the pathogens to survive.

3. Blood clots (and then scabs), prevent pathogens from
entering the blood.

4…. Next slide *drum roll*
 4. Phagocytes
Phagocytes are a type of immune cells
involved in the second line of defence. E.g.
Macrophages, Neutrophils and Monocytes.
Macrophages ingest and absorb the pathogens
that invade the body through a process of
Phagocytosis. In theory…
Having digested a pathogen, the macrophage
then is able to present the pathogenic antigen
(part of the pathogen) to a Lymphocyte (T
helper cell – third line immune cell) in order to
initiate the third line of defence.

What happens in
Non-specific immune response

The first and second lines of
defence are innate – this means
that they are present at birth.

They are not specific – this
means that they defend against
infection in a way that is the
same for any invading
pathogen. Non-specific
immunity provides an instant
response to an invading
pathogen.
Third Line of Defence – specific
immunity.
The 3rd line of defence is carried out by specialised
white blood cells called Lymphocytes. There are
two types: T cells and B cells.
What’s so special about third line of defence?
Is Specific – it differentiates between specific
pathogens.
Is Acquired – it depends on the types of pathogens
that the body is exposed to from the time of birth to
death.
There is an immunological memory (Memory B
cells). This means that a particular pathogen will be
recognised by the body’s immune system upon
secondary exposure to this pathogen and that
the immune response will be greater and more
rapid the second time round, such that the
pathogen is completely eliminated before it has the
ability to cause disease. This is the basis from which
vaccines have been developed by scientists, for
particular diseases.
A major component of specific immunity is the
production of specific antibodies against specific
pathogens by B cells.
B cell producing antibodies..
Antigens
Pathogens contain chemicals that are foreign to the body called
antigens.
They are the unique “shape” present on the surface of a
pathogen. Our immune system uses these to determine what is
“Self” and what is “non-self” (foreign).
T Cell Lymphocytes
Some T-cells find and destroy infected cells.
Like B-cells, they attack only one kind of pathogen, by recognising
its unique antigen on the surface of the infected cell.
They attach to the outside of the cell and secrete chemicals into
the cell that destroys it.

In In
B Cell Lymphocytes
B-cells (Plasma cells) produce
antibodies - proteins that have a
chemical 'fit' to a specific antigen in a
complementary manner.
This means that antibodies are
designed to attack only one kind of
antigen. For example, an antibody The enormous diversity of
designed to destroy smallpox is unable antibodies allows the immune
to attack the common cold. system to recognize an equally wide
variety of antigens (pathogens)
When a B-cell with the matching
antibody meets the antigen, it makes
many copies of the antibody, which
neutralise the pathogen.
How is the third line of defence
involved?
Cell-mediated immunity
It all starts when a Macrophage (2nd line of defence
cell) digests a pathogen, it presents the
pathogenetic antigen to a T-helper cell.
T-helper cell then creates copies of itself (clonal
expansion)
Some of these copies differentiate (specialise)
into Cytotoxic T-cells, and others into Memory T-
cells.
Cytotoxic t-cells not only attack foreign invading
cells, but may also attack your own cells that have
been infected or are cancerous.
How is the third line of defence
involved?
Humoral immunity
T-helper cells also secrete Cytokines to
activate B-Cells.
Activated B-Cells then create many
copies of themselves (clonal expansion),
then differentiate into Memory B-Cells
and Plasma Cells.
These plasma cells produce proteins
called antibodies that are specific to
the invader’s antigens. These antibodies
assist in the destruction of the invading
pathogen.

B memory cells and T memory cells
formed during the adaptive immune
response remain in the blood for an
extended period of time, allowing the
body to respond to pathogens it has
How do Antibodies neutralise pathogens?

…in a number of ways:
1. They can bind to pathogens and
damage or destroy them.
2. They can coat pathogens, clumping
them together so that they are
easily ingested by phagocytes (2nd
line).
3. They can bind to the pathogens and
release chemical signals to attract
more phagocytes (2nd line).
Long lasting Immunity
Most T cells and B cells die after the
infection has been brought under
control.
Some remain for many years. These
are called MEMORY T and B CELLS.
If you become infected again with the
same pathogen, the memory cells
respond much FASTER and
STRONGER compared to the first
encounter with the pathogen. The
pathogen is destroyed much more
quickly.

This is what is meant when we say
“we are immune” and why we can’t
get the same disease twice.
Learning intentions: Vaccines and Antibiotics
List and explain the types of vaccines including dead pathogens,
weakened strains and parts of broken-down pathogens.
Explain the concept of herd immunity and the importance of
vaccinations.
Understand that antibiotics are only used for bacterial infections
Vaccines
People can be immunised against a pathogen
through vaccination. Different vaccines are needed
26 doses of 9
for different pathogens. vaccines by the
Vaccinations in early childhood protect against first birthday
many serious diseases. Sometimes more than one 48 doses of 14
vaccine is given at a time, like the MMR triple vaccines by age 6
vaccine against mumps, measles and rubella. and a total of 70
doses of 16
The vaccine contains a weakened or harmless vaccines by age
version of a pathogen, which means that the 18
vaccinated person is in no danger of developing the
disease.
The challenge in 2020, was for a COVID-19 vaccine
to be developed, trialled and distributed.
How do
Vaccines work?
Looking at the graph…
1st injection: produces
immune response
(antibodies).
2nd injection: memory B
and T cells ensure quicker
response if the pathogen is
encountered later.
Protective antibody level is
reached and only and
annual booster is needed
after that.

The vaccine conditions the immune
system to respond however it poses no real
threat to the body. Upon exposure to an
actual pathogen, a secondary fast and
strong response is elicited.
History of Vaccination
Edward Jenner and the Cowpox vaccination Clip
Herd Immunity
If enough people in a community are
immunised against an infectious disease,
it is harder for the disease to spread.
Protection of “the herd” is achieved when
immunity reaches a certain value, which
is different for each disease.
Watch this video:

Herd immunity is important because there
are members within every community
who are not immune/cannot be Australians are not at herd immunity
vaccinated, such as the elderly, newborn levels for any of the vaccinations in the
babies and people being treated for National immunisation program!
Antibiotics
Antibiotics are drugs that are used to treat bacterial infections only.
They are not effective against viruses, such as the common cold or
flu. Nor are they effective for treating COVID-19, which is also
caused by a virus.
In 1928, Alexander Fleming noted that mould belonging to the
genus Penicillium produced a chemical that stopped the growth of
bacteria. Fleming called this unknown antibacterial
substance penicillin.
Penicillin has saved more than 200 million lives.
Antibiotic resistance
Overusing antibiotics is a major cause of antibiotic resistance.
Overuse has created superbugs – strains of bacteria that have
adapted after coming into contact with an antibiotic.
Once this happens, these bacteria become "resistant" to the
antibiotic to which they have been exposed, which means the
antibiotic cannot kill the bacteria or stop them from multiplying.
The World Health Organisation has identified antibiotic resistance
as one of the greatest threats to human health.
https://www.sbs.com.au/news/doctors-warn-about-superbugs-antib
iotic-resistance-in-australia
Measures to reduce antibiotic
resistance
Do not take antibiotics for non-bacterial infections
Take the full prescription even if you are feeling
better.
Never share antibiotics with others or use leftover
prescriptions.