CPTP 3.10 Pharmacology of Antimicrobials 1

Question 1

What does antimicrobial chemotherapy include?

Answer 1

• Synthetic chemicals to destroy pathogens

* Naturally-occuring antibiotics

Question 2

What is selective toxicity?

Answer 2

When one kind of cell is influenced strongly without any effect on other cells.

Question 3

What two things must be considered when choosing an antimicrobial agent?

Answer 3

• The patient (pharmacokinetics, allergies, pregnancy, other medications)
  
  • The pathogen (antimicrobial sensitivities)

Question 4

What are broad spectrum and narrow spectrum antibiotics? What are the main differences between them and their use?

Answer 4

Broad spectrum:
• Target both gram positive and gram negative antibiotics
• More likely to cause resistance due to lack of specificity
• Prescribed if you don’t know the identity of the pathogen

Narrow spectrum:
• Targets either gram negative or gram positive bacteria
• Less likely to cause resistance due to increased specificity
• Prescribed if the causative agent is known

Question 5

What is the main disadvantage of narrow spectrum antibiotics?

Answer 5

• If the causative agent is misidentified, the treatment may be completely ineffective

Question 6

How are broad and narrow spectrum antibiotics used in practise?

Answer 6

Broad spectrum antibiotic is used until the causative agent is known, then the patient is switched to a narrow spectrum antibiotic

Question 7

In what ways can antibiotics be classified?

Answer 7

Broad and narrow spectrum

Bacteriostatic & bacteriocidal:
• Bacteriostatic - Inhibits bacteria from reproducing but doesn’t kill them
• Bacteriocidal - Actively kills bacteria

Question 8

How are antibiotics placed into bacteriostatic and bacteriocidal categories?

Answer 8

Categorisation is not distinct, it depends not only on the identity of the antibiotic, but also:
• Bacterial species targeted
• The concentration of the drug used

Question 9

What are the ‘classes’ of targets for antimicrobial action in the bacterial cell?

Answer 9

Class I:
• Utilisation of carbon sources (e.g. glucose) to generate ATP
• Synthesis of carbon compounds used in Class II reactions

Class II:
• Utilisation of precursors to create:
> Amino acids
> Phospholipids
> Nucleotides
> Carbohydrates (from Class I precursors)

Class III:
  •  Assembly of small molecules into macromolecules:
         > RNA
         > DNA
         > Proteins
         > Polysaccharides

Question 10

What are the limitations of using Class I targets?

Answer 10

• Bacteria often use similar mechanisms to humans to acquire and internalise sugars
  
  • Bacteria are very good at switching to different substrates

Generally not effective

Question 11

What is the best type of selective toxicity against bacteria?

Answer 11

Class III targeting - there are distinct differences between the pathogen and the host, therefore the toxicity is selective

Question 12

What are the three major targets of antibiotics?

Answer 12

• Cell wall
  
  • Nucleic acid synthesis
  • Protein synthesis

Question 13

What antibiotics does beta-lactam form the core structure of?

Answer 13

• Penicillins

* Cephalosporins

Question 14

Name the penicillins in the formulary and their route of administration

Answer 14

Oral
• Amoxicillin
• Flucloxicillin

Parenteral
• Benzylpenicillin

Question 15

What is the mechanism of action of the penicillins?

Answer 15

• Bacteriocidal
  
  • Binds to penicillin binding proteins on susceptible microorganisms
  • This inhibits peptide cross-linking within the cell wall

Question 16

Describe the pharmacokinetics of penicillins, with regard to distribution and excretion.

Answer 16

Distribution
• Diffuse into all tissues but not CSF
• 60% is plasma protein bound

Excretion
• Excreted in the urine

Question 17

In what case might a penicillin cross the blood brain barrier into the CSF?

Answer 17

If the meninges are inflamed

Question 18

What can penicillins become metabolised into?

Answer 18

Penicilloic acid

Question 19

In what population in clearance of penicillins reduced?

Answer 19

Neonates

Question 20

Penicillin prevents peptide cross-linking between which proteins in the cell wall?

Answer 20

• N-acetyl glucosamine (NAG)

* N-acetyl muramic acid (NAM)

Question 21

What are the penicillin binding proteins? What do they do?

Answer 21

Transpeptidase enzymes

These form the cross links between NAG and NAM using 4 amino acids

Question 22

What are the components of penicillins? What does the active component do do?

Answer 22

(IMG 4)
• A carboxylic acid side chain

• An acylamino side chain
• Thiozidine ring

• Beta-lactam ring
>Forms a covalent bond with transpeptidase enzymes (penicillin binding protein)
>This blocks the active site and prevents the cross linking

Question 23

What is the R (variable) group between the different penicillins?

Answer 23

The acylamino side chain

Question 24

What are the adverse drug reactions of penicillins?

Answer 24

• GI disturbances

* Hypersensitivity and anaphylaxis

Question 25

What causes GI disturbances when penicillins are given?

Answer 25

Altered gut flora

D&V, nausea

Question 26

What are the components of cephalosporins?

Answer 26

(IMG 5)
• Dihydrothiazine ring
• Beta-lactam ring (works in the same way as penicillins)

Question 27

What is the benefit of the dihydrothiazine ring on cephalosporins?

Answer 27

Makes the beta-lactam more resistant to beta-lactamases

Question 28

What happens when antibiotics successfully prevent cross links to form in the cell wall?

Answer 28

The bacteria cell explodes out through the weakened cell wall, killing it

Question 29

What type of antibiotics are cephalosporins?

Answer 29

• Broad spectrum

* Bacteriocidal

Question 30

Name the formulary cephalosporins and their route of administration.

Answer 30

Cefalexin - oral

Cefotaxime - parenteral

Question 31

How are the cephalosporins used?

Answer 31

As a second choice agent for many infections

Question 32

Describe the pharmacokinetics of cephalosporins, with regard to distribution and excretion.

Answer 32

Distribution

• Diffuse into all tissues but not CSF (unless inflamed like with penicillins)

Question 33

What can be used to treat bacterial meningitis?

Answer 33

Cefotaxime

Question 34

What must be considered for patients with renal disease?

Answer 34

Penicillin clearance is reduced in people with renal disease, so it may be better to use cephalosporins for these patients (still mostly excreted through kidney tho)

Question 35

What are the adverse effects of cephalosporins?

Answer 35

• Shares sensitivity with penicillin
  
  • Antibiotic associated colitis
  • Hepatitis and jaundice
  • Blood disorders (aplastic ones like with chemotherapy)

Question 36

How is folate acquired by humans and bacteria?

Answer 36

Humans
• Absorbed
• No pathways for synthesis

Bacteria
• Synthesised
• No pathways for absorption

Question 37

How do bacteria synthesise DNA? (Pathway)

Answer 37

(IMG 6) By biosynthesising folate:

PABA
  •  Dihydropteroate synthase
FOLATE
  •  Dihydrofolate reductase
TETRAHYDROFOLATE
THYMIDYLATE
THYMIDINE (pyramidine)
DNA

Question 38

What class of antibiotics inhibits the metabolic pathways involving folate? What enzyme does this class act on? It it bacteriostatic or bacteriocidal?

Answer 38

Sulphonamides (act on Dihydropteroate synthase)

Bacteriostatic, as it prevents DNA replication

Question 39

What is PABA? What is it used for by bacteria?

Answer 39

p-aminobenzoic acid

Essential in bacterial folate synthesis and subsequent production of pyrimidines and purines for DNA synthesis

Question 40

Name an analogue of folate. What enzyme is it used to antagonise

Answer 40

Trimethoprim (note, this does act on the folate pathway but is not a sulphonamide because it does not act on Dihydropteroate synthase)

BACTERIAL Dihydrofolate reductase (but not human)

Question 41

What gives trimethoprim its selective toxicity? (i.e. acts on bacteria but not humans) What other drug works on the same enzyme and what is it used for?

Answer 41

Bacterial dihydrofolate reductase has a higher affinity for trimethoprim than for folate

Human dihydrofolate reductase has a higher affinity for folate than for trimethoprim

Methotrexate is also DHFR inhibitor, used in chemotherapy. In this case, HUMAN pyrimidine and purine synthesis is inhibited, to prevent mitosis of cancer cells (form of chemo)

Question 42

What are the routes of administration of the antibiotics affecting folate pathways? What type of antibiotic are each of these?

Answer 42

Trimethoprim - oral

Co-trimoxazole - Parenteral

Both bacteriostatic:

Question 43

What is co-trimoxazole a combination of?

Answer 43

Trimethoprim (not a sulfonamide, DHPR)

Sulfamethoxazole (sulphonamide, DHFR)

Question 44

What is the distribution and excretion of the drugs affecting folate pathways?

Answer 44

Distribution
• Good diffusion and passes the blood-brain barrier

Excretion
• Renal

Question 45

How could sulphonamides be used for burns victims?

Answer 45

Topical application

Question 46

What are the contraindications of sulphonamides (and similar folate-affecting compounds i.e. trimethoprim)?

Answer 46

Pregnancy, because these drugs can cross the placenta (NTDs from no folate)

Neonates (as it causes bilirubin displacement causing brain damage)

Question 47

So whats the deal with trimethoprim, it’s kind of confusing?

Answer 47

It can be considered a sulphonamide because it affects the same pathway, but it technically isn’t one because it affects a different enzyme.

Question 48

What are sulphonamides (and trimethoprim) typically used to treat?

Answer 48

•  Simple UTIs 
  •  Respiratory tract infections
  •  Immunocompromised patients:
        > T. gondii
        > P. jirovecil

Question 49

What are the unique side effects of sulphonamide?

Answer 49

• Bone marrow
  
  • Crystalluria (causing renal failure)
  • Hepatitis