B3 INFECTION AND RESPONSE

Created by

Aayush Patel

Cards (56)

Pathogens 
Microorganisms that cause infectious disease, including viruses, bacteria, protists and fungi
Viruses 
Very small
Move into cells and use the biochemistry to make many copies of itself
This leads to the cell bursting and releasing all of the copies into the bloodstream
The damage and destruction of the cells makes the individual feel ill
Bacteria 
Small
Multiply very quickly through dividing by a process called binary fission
Produce toxins that can damage cells
Protists 
Some are parasitic, meaning they use humans and animals as their hosts (live on and inside, causing damage)
Fungi 
Can be single celled or have a body made of hyphae (thread-like structures)
Can produce spores which can be spread to other organisms
Ways pathogens are spread
Direct contact - touching contaminated surfaces
By water - drinking or coming into contact with dirty water
By air - pathogens can be carried in the air and then breathed in (a common example is the droplet infection, which is when sneezing, coughing or talking expels pathogens in droplets which can be breathed in)
Ways to reduce the damage of disease
Improving hygiene: Hand washing, using disinfectants, isolating raw meat, using tissues and handkerchiefs when sneezing
Reducing contact with infected individuals
Removing vectors: Using pesticides or insecticides and removing their habitat
Vaccination: By injecting a small amount of a harmless pathogen into an individual's body, they can become immune to it so it will not infect them. This means they cannot pass it on.
Measles 
Symptoms: Fever and red skin rash, can lead to other problems such as pneumonia (lung infection), encephalitis (brain infection) and blindness
How it is spread: Droplet infection
How it is being prevented: Vaccinations for young children to reduce transmission
HIV 
Symptoms: Initially flu-like symptoms, then the virus attacks the immune system and leads to AIDS (a state in which the body is susceptible to many different diseases)
How it is spread: By sexual contact or exchange of bodily fluids such as blood
How it is being prevented: The spread - Using condoms, not sharing needles, screening blood when it is used in transfusions, mothers with HIV bottle-feeding their children instead of breastfeeding
The development to AIDS - Use of antiretroviral drugs (stop the virus replicating in the body)
Tobacco mosaic virus 
Symptoms: Discolouration of the leaves, the affected part of the leaf cannot photosynthesise resulting in the reduction of the yield
How it is spread: Contact between diseased plants and healthy plants, insects act as vectors
How it is being prevented: Good field hygiene and pest control, growing TMV-resistant strains
Salmonella food poisoning 
Symptoms: Fever, stomach cramps, vomiting, diarrhoea (all caused by the toxins they secrete)
How it is spread: These bacteria can be found in raw meat and eggs, unhygienic conditions
How it is being prevented: Poultry are vaccinated against Salmonella, keeping raw meat away from cooked food, avoid washing it, wash hands and surfaces when handling it, cook food thoroughly
Gonorrhoea 
Symptoms: Thick yellow or green discharge from the vagina or penis, pain when urinating
How it is spread: It is a sexually transmitted disease spread through unprotected sexual contact
How it is being prevented: By using contraception such as condoms and antibiotics (used to be treated with penicillin but many resistant strains are developing)
Rose black spot 
Symptoms: Purple or black spots on leaves of rose plants, reduces the area of the leaf available for photosynthesis, leaves turn yellow and drop early
How it is spread: The spores of the fungus are spread in water (rain) of by wind
How it is being prevented: By using fungicides or stripping the plant of affected leaves (have to be burnt)
Malaria 
Symptoms: Fevers and shaking (when the protists burst out of blood cells)
How it is spread: The vector is the female Anopheles mosquito, in which the protists reproduce sexually. When the mosquito punctures the skin to feed on blood, the protists enter the human bloodstream via their saliva
How it is being prevented: Using insecticide coated insect nets while sleeping, removing stagnant water to prevent the vectors from breeding, travellers taking antimalarial drugs to kill parasites that enter the blood
Non-specific defence system 
The skin - acts as a physical barrier, produces antimicrobial secretions, has good microorganisms known as skin flora
The nose - has hairs and mucus which prevent particles from entering your lungs
The trachea and bronchi - secrete mucus to trap pathogens, have cilia to waft mucus upwards
The stomach - produces hydrochloric acid that kills any pathogens in your mucus, or food and drink
Specific immune system 
Phagocytosis - white blood cells engulf and consume pathogens
Producing antibodies - each pathogen has an antigen which a specific complementary antibody can bind to
Producing antitoxins - they neutralise the toxins released by the pathogens
Vaccination 
Involves making an individual immune to a certain disease before they have been infected, by injecting a small amount of a harmless pathogen
This stimulates white blood cells to produce antibodies complementary to the antigens on the pathogen
Provides herd immunity by reducing the spread of the pathogen
Antibiotics 
Medicines that kill bacterial pathogens inside the body, without damaging body cells
Different antibiotics are effective against different types of bacteria
Their use has decreased the number of deaths from bacterial diseases
Concern is that bacteria are becoming resistant to antibiotics due to mutations
Painkillers only treat the symptoms of the disease, rather than the cause
To prevent the development of resistant bacterial strains, we can stop overusing antibiotics and finish courses of antibiotics to kill all of the bacteria
Epidemics (lots of cases in an area) can be prevented through herd immunity
Bad reactions (such as fevers) can occur in response to vaccines (although very rare)
The great concern is that bacteria are becoming resistant to antibiotics
Mutations can occur during reproduction resulting in certain bacteria no longer being killed by antibiotics 
1. When these bacteria are exposed to antibiotics, only the non-resistant one die
2. The resistant bacteria survive and reproduce, meaning the population of resistant bacteria increases
3. This means that antibiotics that were previously effective no longer work
To prevent the development of these resistant strains
Stop overusing antibiotics- this unnecessarily exposes bacteria to the antibiotics
Finishing courses of antibiotics to kill all of the bacteria
Toxicity 
How poisonous a drug is
Efficacy 
How well a drug carries out its role
Preclinical testing 
Using cells, tissues and live animals to test drugs
Clinical trials 
Using volunteers and patients to test drugs
Drugs are first tested on healthy volunteers with a low dose to ensure there are no harmful side effects
Drugs are then tested on patients to find the most effective dose
Placebo 
Appears to look like the drug but has no active ingredient so no effect
Single-blind 
Only the doctor knows whether the patient is receiving the drug
Double blind 
Neither the patient or doctor knows whether they are receiving the drug, removing any biases the doctor may have when they are recording the results
The results then need to be peer reviewed by other scientists to check for repeatability
Monoclonal antibodies 
Identical antibodies, that have been produced from the same immune cell
Producing Monoclonal Antibodies 
1. Scientists obtain mice lymphocytes (a type of white blood cell that make antibodies but cannot divide), which have been stimulated to produce a specific antibody
2. They are combined with tumour cells (do not make antibodies but divide rapidly), to form a cell called a hybridoma
3. The hybridoma can divide to produce clones of itself, which all produce the same antibody
4. The antibodies are collected and purified
Uses of Monoclonal Antibodies
Pregnancy tests
In laboratories to measure and monitor
In research to find or identify certain molecules on a cell or tissue
In the treatment of disease, e.g. cancer
Human chorionic gonadotrophin (hCG) 
A hormone present in the urine of women who are pregnant
Mobile antibodies 
Antibodies complementary to the hCG hormone which are also attached to blue beads