Vaccines and Antimicrobial Drugs

Question 1

vaccination

Answer 1

• inoculation of a living host with inactive or attenuated (weakened) pathogens, or pathogen products, to stimulate protective active immunity
• active immunity means that your body is making the antibodies
• passive immunity involves obtaining antibodies from a different organism

Question 2

vaccine

Answer 2

• the substance given to a host (usually by injection) that induces artificial active immunity
• acts as an antigen, but does not cause disease
• stimulates the production of antibodies

Question 3

herd immunity

Answer 3

• resistance in a population to a pathogen (disease) as a result of the immunity of a large portion of the population
• breaks the chain of pathogen transmission from one susceptible host to another
• the more highly infectious a pathogen, the greater the proportion of immune individuals needed to prevent disease spread

Question 4

How do vaccines stimulate active immunity?

Answer 4

• the initial exposure to the antigen from the vaccine causes the primary immune response
• the primary immune response causes a rise in antibody concentration that decreases over time
• when exposed to the antigen a second time, the secondary immune response occurs
• the secondary immune response causes a rise in antibody concentration that is higher and faster

Question 5

What are the different types of SARS-CoV-2 vaccines being used or in development?

Answer 5

• mRNA vaccines (Pfizer and Moderna): mRNA that codes for spike protein is purified and injected, body produces spike protein
• adenovirus vector vaccine (Johnson and Johnson): spike protein gene is purified and put inside an adenoviral vector, body produces spike protein
• protein based: spike protein is purified and injected
• all cause the immune system to produce the antibody against the spike protein antigen

Question 6

antimicrobial drugs

Answer 6

• compounds used to treat disease by destroying or inhibiting the growth of pathogenic microbes within a host (in vivo)
• synthetics, antibiotics, semi-synthetics

Question 7

What are synthetics?

Answer 7

chemicals

Question 8

antibiotics

Answer 8

• naturally produced antimicrobial agents (microbial products)
• produced by bacteria and fungi

Question 9

semi-synthetics

Answer 9

chemically modified antibiotics

Question 10

How are antimicrobials classified?

Answer 10

• molecular structure
• mechanism of action
• spectrum of antimicrobial activity

Question 11

selective toxicity

Answer 11

• ability of a drug to kill or inhibit the pathogen while damaging the host as little as possible
• ex: penicillin goes after peptidoglycan

Question 12

therapeutic (effective) dose

Answer 12

drug level required for clinical treatment

Question 13

toxic dose

Answer 13

drug level at which drug becomes too toxic for the patient (produces side effects)

Question 14

therapeutic index

Answer 14

• ratio of toxic dose to therapeutic dose

- the larger the therapeutic index, the better

Question 15

narrow spectrum drugs

Answer 15

attack only a few different pathogens

Question 16

broad spectrum drugs

Answer 16

attack many different pathogens

Question 17

cidal agent

Answer 17

kills microbes

Question 18

static agent

Answer 18

inhibits growth of microbes

Question 19

side effects

Answer 19

undesirable effects of drugs on host cells

Question 20

growth factor analogs

Answer 20

• structurally similar to an essential growth factor
• disrupt cell metabolism
• ex: isoniazid (narrow spectrum, cidal if actively growing, static if dormant)

Question 21

quinolones

Answer 21

• interfere with bacterial DNA gyrase
• prevent DNA packaging
• ex: ciprofloxacin (narrow spectrum, cidal)

Question 22

macrolides

Answer 22

• target the 50S ribosomal subunit
• ex: erythromycin (broad spectrum, static)
• ex: azithromycin (Z-pack) (semisynthetic)

Question 23

tetracyclines

Answer 23

• target the 30S ribosomal subunit

- ex: tetracycline (broad spectrum, static)

Question 24

lipid biosynthesis disruptors

Answer 24

• target fatty acid biosynthesis

- ex: platensimycin (broad spectrum, static, effective againt MRSA and VRE)

Question 25

beta-lactam antibiotics (from fungi)

Answer 25

• include penicillins and cephalosporins
• target cell wall synthesis
• effective primarily against gram-positive bacteria
• cidal against actively growing cells

Question 26

isoniazid

Answer 26

• type: synthetic
• mode of action: lipid synthesis (especially mycolic acid)
• effect: cidal if actively growing, static if dormant
• spectrum of activity: narrow

Question 27

ciproflaxin

Answer 27

• type: synthetic
• mode of action: bacterial DNA gyrase (prevents DNA packing)
• effect: cidal
• spectrum of activity: narrow

Question 28

penicillin

Answer 28

• type: antibiotic
• mode of action: cell wall synthesis
• effect: cidal (if actively growing)
• spectrum of activity: narrow

Question 29

erythromycin

Answer 29

• type: antibiotic
• mode of action: 50S ribosomal subunit
• effect: static
• spectrum of activity: broad

Question 30

tetracycline

Answer 30

• type: antibiotic
• mode of action: 30S ribosomal subunit
• effect: static
• spectrum of activity: broad

Question 31

platensimycin

Answer 31

• type: antibiotic
• mode of action: fatty acid biosynthesis (MRSA and VRE)
• effect: static
• spectrum of activity: broad

Question 32

Why is antimicrobial resistance a threat to public health?

Answer 32

• once resistance originates in a bacterial population, it can be transmitted to other bacteria
• resistance mechanisms are not confined to a single class of drugs
• erroneous practices select for the growth of resistant bacteria

Question 33

What are the mechanisms of bacterial resistance?

Answer 33

• target modification
• preventing entrance
• inactivation
• efflux pumps
• alternate pathway
• impermeability

Question 34

What is the origin of resistance?

Answer 34

• natural immunity genes
• spontaneous mutations
• resistance genes are located in chromosome, plasmids (R factors), or mobile genetic elements such as transposons

Question 35

How is resistance transmitted?

Answer 35

horizontal gene transfer (transformation, conjugation, and transduction)

Question 36

How do drug resistant bacteria emerge?

Answer 36

1. Prescription of antibiotics
2. Antibiotic selective pressure
3. Genetic factors
4. Spread of antimicrobial-resistant bacteria in the community

Question 37

How can drug resistance be prevented?

Answer 37

• give drug in high concentrations to destroy susceptible
• use antimicrobials only when necessary
• take full course of antimicrobial
• use narrow spectrum antimicrobials
• give a combination of unrelated drugs
• possible future solutions: continued development of new antimicrobials and use of bacteriophages to treat bacterial disease

Question 38

How did MRSA become VRSA?

Answer 38

• vancomycin was used to treat MRSA
• increased selective pressure
• VRSA strains have high resistance to vancomycin