BIOLOGY

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Aurittri Mannan

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Cards (78)

  • Cholera
    Gram-negative bacterium. Toxins affect the gut lining causing watery diarrhoea leading to dehydration and death.
  • Cholera- mode of transport

    • Water borne
    • Treatment of water
    • Rehydration therapy
  • Tuberculosis
    Bacteria. Lungs, neck and lymph nodes. Causes coughing, chest pain, coughing up blood.
  • Tuberculosis- mode of transport

    • Airborne droplets through coughs and sneezes
  • Smallpox
    The Variola major virus. Mouth, throat, lymph nodes, blood stream. Characterised by fluid filled blisters on the skin.
  • Smallpox- MoT and treatment

    • Contact. Person to person or from contaminated objects
    • Low antigenic variation of the virus led to a highly effective vaccine. This, along with there being no animal reservoir, led to the eradication of smallpox in 1980.
  • Influenza
    Virus- 3 sub-groups with many antigenic types. Lining of the upper respiratory tract leading to sore throat coughing and fever.
  • Influenza- MoT and treatment

    • Airborne droplet infection
    • Quarantine and hygiene
    • Annual vaccination -not always effective
  • Malaria
    Protoctistan parasite. 2 x Plasmodium spp but many antigenic types. Liver and red blood cells. Red blood cells full of virus burst infecting more cells. This corresponds with bouts of fever.
  • Malaria- MoT and treatment

    • Vector, passed to humans by the female mosquito when taking a blood meal
    • Stop the vector- Nets, clothing, insect repellent, fish to eat larvae, drain breeding grounds, spray water surfaces with oil. Use insecticides, bacterial infections of mosquitos, or sterilisation of mosquitos.
    • Kill the parasite- drugs affect the parasite outside of blood cells but resistance is increasing. Vaccine difficult as the parasite mutates, and antibodies only help when the parasite is outside of blood cells.
  • Pathogenic
    An organism that causes damage to its host
  • Infectious
    A disease that may be transmitted from one individual to another
  • Carrier
    Shows no symptoms when infected but can pass the disease on to another
  • Disease reservoir
    Where a pathogen is normally found; this may be in humans or another animal and may be a source of infection
  • Endemic
    A disease, which is always present at low levels in an area
  • Epidemic
    Where there is a significant increase in the usual number of cases of a disease, often associated with a rapid spread
  • Pandemic
    A global epidemic
  • Vaccine
    Uses non-pathogenic forms, products or antigens of micro-organisms to stimulate an immune response, which confers protection against subsequent infection
  • Antibiotic
    Substances produced by microorganisms that affect the growth of other microorganisms
  • Antibiotic resistance

    Where a microorganism, which should be affected by an antibiotic, is no longer susceptible to it
  • Antigen
    A protein on a foreign cell that is recognised by the immune system
  • Antibody
    A protein produced by the immune system to recognise and destroy antigens
  • Vector
    A living organism which transfers a disease from one individual to another
  • Toxin

    A chemical produced by a microorganism, which causes damage to its host
  • Antigenic type

    Organisms with the same or very similar antigens on the surface. Such types are subgroups or strains of a microbial species, which may be used to trace infections. They are usually identified by using antibodies from serum
  • Viral reproduction

    1. Viral DNA/RNA instructs the cell to make virus particles
    2. Cell lysis occurs, and the virus escapes the cells to infect other cells/organisms (shedding)
    3. Production of toxic substances
    4. Viral cell transformation, where they can trigger cells to become cancerous
    5. Viruses infecting white blood cells suppress the immune system (e.g. HIV)
  • Skin
    • A tough barrier. Strong connective tissue maintained by vitamin C that prevents microbes entering the body. Skin flora competes with pathogenic bacteria to avoid infection.
  • Lysozyme
    • An enzyme in tears, saliva and stomach acid that kills bacteria.
  • Ciliated mucous membranes

    • Traps microbes in inhaled air. Passes up the trachea for swallowing and destruction in the stomach.
  • Blood clotting

    • Seals wounds in skin quickly to prevent infection.
  • Inflammation
    • Raised temperature is unfavourable to microbes and increase in blood flow delivers phagocytes to the area.
  • White blood cells called phagocytes
    • Kill invading microbes in a process called phagocytosis.
  • Antibodies
    These are produced by white blood cells called lymphocytes. Antibodies are proteins (globulins). They are Y shaped and formed from four polypeptide chains with two binding sites. They are specific to the antigen and they bind to form an antigen-antibody complex. This renders the antigen inactive by agglutination or marking for phagocytosis.
  • Antibiotic resistance

    • Bacteria divide rapidly and have a high mutation rate. Some mutations confer resistance to antibiotics. Overuse of these antibiotics gives the resistant strain a selective advantage. Numbers of the resistant strain increase, making infections more difficult to treat with the usual antibiotics.
  • Penicillin
    Peptidoglycan bacterial cell walls are strengthened by polysaccharide cross-linked by amino acids. This stops osmotic lysis. Penicillin affects the formation of the cross links by inhibiting the enzyme that makes them. The wall is weakened and osmotic changes can cause cells to burst. Gram negative bacteria have an outer lipopolysaccharide layer that protects the cells from penicillin.
  • Tetracycline
    Tetracycline acts as a competitive inhibitor of the second anticodon-binding site on the 30S subunit of bacterial ribosomes. It prevents the binding of a tRNA molecule to its complementary codon. This prevents protein synthesis common to all bacteria.
  • Humoral immune response

    1. Stem cells in the bone marrow make B lymphocytes that mature in the spleen and lymph nodes and have receptors for the detection of specific antigens on the surface of foreign cells
    2. When the B lymphocytes are activated by a corresponding antigen, they divide rapidly forming antibody secreting plasma cells. This clonal expansion is increased by the cytokines from the cell mediated response
    3. B lymphocytes also make memory cells that remain in the bloodstream and divide rapidly if the antigen is encountered again
  • Primary immune response

    1. On first exposure to the antigen, there is a latent period when antigen presenting cells (including macrophages) carry out phagocytosis and incorporate foreign antigen into their cell membranes
    2. T helper cells detect these antigens and secrete cytokines that stimulate B cells to undergo clonal expansion and stimulate macrophages to carry out phagocytosis
    3. Some B cells then differentiate to become antibody-secreting plasma cells with short lives. Others become long-lived memory cells that retain the ability to undergo mitosis in case of secondary infection
  • Secondary immune response

    1. Following re-exposure to the same antigen, there is a very short latent period due to the presence of memory cells
    2. Only a very small amount of antigen is required to stimulate rapid production of plasma cells
    3. Antibody levels increase to between 10 and 100 times greater than the initial response in a very short time frame
    4. Antibody levels stay high for longer and no symptoms develop
  • Vaccinations
    A vaccination stimulates artificial active immunity in an individual. A vaccine must contain an immunogenic antigen that stimulates a strong immune response. Vaccinations for pathogens that exhibit low levels of antigenic variation can protect an organism after one immunisation, e.g. Rubella. Some pathogens have many antigenic types and mutate frequently. These require seasonally repeated immunisations.