Pharmacology: Antibiotics

Question 1

Why are synthetic antibiotics not “true” antibiotics?

Answer 1

By definition, ABX are naturally occurring substances produced by a microorganism to target another microorganism

Question 2

What is the ideal trait of antibiotics to effectively treat a patient? What microbes present an issue for this?

Answer 2

Selective toxicity

Viruses, cause they use our cell’s machinery
Fungi and Parasites: they’re euks and have similar functions

Question 3

What is the minimum inhibitory concentration?

Answer 3

The concentration of an antibiotic where the colony cannot grow its numbers

Question 4

What is the minimum bacteriocidal concentration?

Answer 4

The concentration that kills 99.9% of microorganisms in a colony

Question 5

Why is MIC or MBC unreliable for clinical dosing?

Answer 5

Pharmacokinetic functions, such as first pass metabolism, protein binding, and metabolism, may decrease the effective dose of ABX in a patient

Question 6

What areas are difficult to reach and may require a larger dose of antibiotics?

Answer 6

CNS, bone, adipose tissue

Question 7

What is the reason some people have allergic responses to ABX?

Answer 7

ABX are antigenic, so they can react with the host immune system

Question 8

What are bacteriostatic and bactericidal ABX?

Answer 8

Static: halt growth of bacterium

Cidal: kill and decrease concentration of ABX

Question 9

Knowing the action of bacteriostatic ABX, how does a infection clear? What is a contraindication for this type?

Answer 9

Via host immune system

Compromised immunity

Question 10

What are the chemotherapeutic spectrum types?

Answer 10

Broad, narrow, and extended

Question 11

What are the three general areas that ABX target in a bacterial cell?

Answer 11

Nucleic acid synthesis, ribosomal protein synth, and the cell wall

Question 12

Describe a few ways bacterium can defend and adapt against ABX?

Answer 12

Reduced entry or drug, efflux pumps (MDR protein), alteration of target proteins, alteration of metabolism

Question 13

What kind of antibiotic destabilizes the cell wall of a bacterium?

Answer 13

Bactericidal

Question 14

What enzyme links the layers of sugars in the peptidoglycan walls? What residues are used in this linkage?

Answer 14

Transpepditases

D-alanine

Question 15

What do beta-lactam drugs target in a cell?

Answer 15

Transpeptidase in the cell wall

Question 16

What is another name for transpeptidase?

Answer 16

Penicillin binding protein

Question 17

What does penicillin target? What types of bacterium does this work against? What are its extended-spectrum agents? What do they work against?

Answer 17

1&2)Transpeptidases; & Gram positive bacterii and syphilis

3&4) amoxicillin, ampicillin, amniopenicillin; gram + and -

Question 18

How effective is Penicillin against today’s bacterium?

Answer 18

Not good due to resistance; only acts well with syphilis

Question 19

What class are cephalosporins? How can they be recognized via nomenclature?

Answer 19

Beta-lactams; largest B-lac class; have ceph- or cef- in name

Question 20

What class is carbapenem ABX? What is its spectrum? Potency? What are common clinical uses?

Answer 20

B-lactam; broad spectrum and potent; usually used as a combination therapy drug; NEEDS INHIBITORS WITH ITS MOST UNSTABLE FORM

Question 21

Are monobactams considered true B-lactams? What does it target? What is its spectrum?

Answer 21

No; Gram -; narrow-spectrum

Question 22

What are common allergic responses to B-lactams?

Answer 22

Anaphylaxis/cytolytic anemia

Question 23

How are B-lactams allergenic? What if a patient is allergic to penicillin, what B-lactams can be prescribed?

Answer 23

Bind to human proteins;

NO B-lactams can be prescribed, it is a classwide (monobactams are safe since it does not have extra ring structure)

Question 24

What enzyme gives bacteria resistance to B-lactams?

Answer 24

B-lactamase

Question 25

What are some ways around B-lactamases? How does this work?

Answer 25

Combination therapy: strong B-lact with weak B-lact- weak B-Lac binds to enzyme, strong kills the bacteria

Chemical modifications to drugs (ie Methicillin from penicillin)

Question 26

How do glycopeptides work to be an ABX?

Answer 26

Bind to D-alanine and prevent crosslinking from transpeptidase

Question 27

What antibiotic is historically effective against MRSA? What class is this ABX? What is this drug not effective against? How has MRSA adapted to this drug?

Answer 27

• Vancomycin
• Glycopeptide
• gram - bacteria
• changed transpeptidases to not use D-alanine links in cell wall

Question 28

What type of antibacterial inserts into the plasmalemma and disrupts the cell wall? What are these effective against?

Answer 28

Lipopeptides (like Daptomycin)

-vancomycin resistant strains

Question 29

How do lipopeptides kill bacteria?

Answer 29

Create pores in the cell mem to disrupt osmolarity

Question 30

What does bacitracin do?

Answer 30

Prevents peptidoglycan subunits from reaching cell surface

Question 31

Are bacitracin and lipopeptides bacteriostatic or bactericidal? What are their draw backs? How are they typically administered?

Answer 31

• cidal
• very toxic to humans (nephrotoxic due to lipid mems in the kidney)
• topical administration

Question 32

What are polymixins? What are they effective against? What are its drawbacks?

Answer 32

Positively charged peptides that disrupt cell membrane structure

• gram -
• cannot be taken orally due to charge

Question 33

Are direct nucleotide synthesis inhibitors cidal or static? Broad or narrow spectrum?

Answer 33

Cidal and broad

Question 34

How can bacteria become resistant to nucleotide synthesis disrupting ABX?

Answer 34

Changing the antibiotic, altered protein targets, expression of protective proteins

Question 35

What do quinolones do?

Answer 35

Inhibit topoisomerases on bacterial DNA during replication

Question 36

What does rifampin target?

Answer 36

RNA polymerase to prevent mRNA synth

Question 37

What does metronidazole do?

Answer 37

Cleaves daughter strand of DNA to prevent replication

Question 38

Are indirect DNA/RNA synth inhibs bacteriostatc or cidal? Broad or narrow?

Answer 38

Static; broad spectrum (even protozoa)

Question 39

How do sulfonamides function on bacteria?

Answer 39

Targets dihydropteroate synthase (in folic acid synthesis)

Question 40

How does trimethoprim target bacteria?

Answer 40

Inhibits dihydofolate reductase (in folic acid synthesis)

Question 41

How are indirect RNA/DNA synth inhibs resisted?

Answer 41

Increased substrates for their target proteins to overpower them

Question 42

Are protein synth inhibs bacteriocidal or static? Where do they function? Broad or narrow? Gram + or -?

Answer 42

Mostly static, but can be cidal

Mostly on the ribosome

Can be broad or narrow

Can be Gram - or +

Question 43

Why shouldnt protein synth inhibs be used as first line against infections?

Answer 43

Toxicity is abundant in this class

Question 44

Where does tetracycline bind? What does it do?

Answer 44

Binds to 30s subunit/ disrupts tRNA interaction

Question 45

Where does erythromycin bind? What does it do?

Answer 45

Binds to ribosome/ prevents translocation of peptide chain

Question 46

Where does chloramphenicol bind? What does it do?

Answer 46

Mimics/binds to amino group attached to tRNA; prevents formation of peptide chain

Question 47

What are some reasons to do combination therapy?

Answer 47

Multiple microbes, very ill patients, prevent spread of drug resistant pathogens, reduce chances of toxicity

Cons: drug-drug interactions

Question 48

What are addative and synergistic combinations?

Answer 48

Addative is the addition of each drug’s potency

Synergy is 1+1=4 (more than sum of parts)

Question 49

What is a good example of antagonistic combinations?

Answer 49

Tetracyclines and penicillins- tet reduce efficacy of penicillin

(Penicillin better on growing bacterial colonies)