Intro to antifungal agents

Question 1

Name the 2 (/3) main types of fungi?

Answer 1

1) Filamentous fungi (moulds)
2) Yeats
3) Also have dimorphic fungi which exist in both forms

Question 2

Name the 5 main antifungal targets?

Answer 2

1) DNA synthesis
2) Mitosis
3) Cell wall: beta -1-3-glucan
4) Cell membrane: ergosterol
5) Protein synthesis

Question 3

Why is ergosterol a good target for anti fungal agents?

Answer 3

Humans don’t have ergosterol in cell membranes (we have cholesterol) so reduces toxicity to humans

Question 4

Why is beta-1-3-glucan that makes fungal cell walls a good target for anti fungal agents?

Answer 4

Humans don’t have cell walls so no toxicity to humans

Question 5

What is ergosterol?

Answer 5

Found mainly in fungal cell membranes
Forms clusters within the phospholipid bilayer
Has a role in the regulation of membrane permeability
Required for normal growth and function of the fungal cell membrane, hence fungal viability

Question 6

What are the 2 relevant steps in ergosterol biosynthesis (including enzymes)?

Answer 6

1)Squalene -> Lanosterol
Enzyme = squalene epoxidase
2) Lanosterol -> Ergosterol
Enzyme = lanosterol 14a demethylase

Question 7

What are Beta-1-3 glucans?

Answer 7

Large polymers of UDP glucose
Make up 50-60% of dry weight of fungal cell wall
Forms a fibrous network on the inner surface of the cell wall
Synthesised by Beta-1-,30glucan synthase

Question 8

What are the 4 main classes of antifungal agents?

Answer 8

1) Polyenes
2) Allylamines
3) Azoles
4) Echinocandins

Question 9

What is the mode of action of polyenes?

Answer 9

Association with ergosterol in a physical way, formation of pore-like molecular aggregates
Cause loss of membrane integrity and leakage of K+
Causes cell death

Question 10

Give 2 examples of polyenes?

Answer 10

1) Amphotericin B

2) Nystatin

Question 11

What is the spectrum of activity of Amphotericin B?

Answer 11

Most fungi of medical importance

Question 12

What are the 2 main adverse effects of amphotericin B?

Answer 12

1) allergic reactions

2) nephrotoxicity (pores are formed in ergosterol-free membranes)

Question 13

Why are lipid associated Amphotericin B formulations more commonly used that simply amphotericin?

Answer 13

Minimize delivery of AmB to kidney cells
Delivery is targeted to fungal cell and/or reticulo-endothelial system (liver, spleen, lymph nodes)
This reduces nephrotoxicity

Question 14

When is amphotericin B used clinically and how?

Answer 14

Not absorbed orally so administered parenterally
Used in serious or systemic infections (such as aspergilllosis, candidiasis, cryptococcosis)
Not used, if possible in people with existing nephrotoxicity

Question 15

When is nystatin used clinically and how?

Answer 15

Not absorbed orally and is too toxic for systemic use

Used in superficial infections (such as oral/vaginal candidiasis)

Question 16

What is the mode of actions of Allylamines?

Answer 16

Inhibit ergosterol synthesis (inhibit squalene epoxidase)

Question 17

Give one example of an allylamine?

Answer 17

Terbinafine

Question 18

What is the spectrum of activity of allylamines (terbinafine)?

Answer 18

Broad spectrum of activity in vitro but in practise only used in one type of infection

Question 19

What is the main adverse effect of allylamines?

Answer 19

Liver toxicity - jaundice, hepatitis - rarely fatal

Question 20

What is the clinical use of allylamines?

Answer 20

Dermatophyte infections (superficial fungal infections)

1) Topical use: athletes foot (tinea pedis), tinea corporis, tinea cruris
2) Systemic (oral) use: scalp ringworm (tinea capitis), onychomycosis

Question 21

What are azoles?

Answer 21

Synthetic compounds containing a 5-membered azole ring
Imidazoles have 2 N atoms
Triazoles have 3 N atoms

Question 22

What is the mode of action of azoles?

Answer 22

Inhibit ergosterol synthesis

inhibit lanosterol 14a-demethylase leading to a build up of 14a-sterols in membrane

Question 23

What is the spectrum of activity of azoles?

Answer 23

Complex, varies between drugs
Essentially broad spectrum - treat both yeasts and filamentous fungi
With the exceptions of fluconazole and aspergillus spp.

Question 24

What is the toxicity and systemic use of imidazole and triazoles?

Answer 24

Imidazoles:
Toxic and rarely used systemically (ketoconazole)
Triazoles:
Less toxic, systemic use more common

Question 25

Name the main imidazole in use?

Answer 25

Clotrimazole

Question 26

Name the 3 main triazoles in use?

Answer 26

1) Fluconazole
2) Itraconazole
3) Voriconazole

Question 27

What are the adverse effects of azoles? 2

Answer 27

1) Hepatotoxicity
- Mild liver enzyme abnormalities
- Life-threatening hepatitis
2) Drug interactions
- Inhibition of cytochrome P450 enzymes (increases concentration of all drugs metabolised by CP450 enzymes)

Question 28

What is the spectrum of fluconazole (yeasts/aspergillus spp./mucoraceous moulds)?

Answer 28

Effective against yeasts

Not effective against Aspergillus spp. or mucoraceous moulds

Question 29

What is the spectrum of Itraconazole/ voriconazole (yeasts/aspergillus spp./mucoraceous moulds)?

Answer 29

Effective against yeasts and aspergillus spp.

Not effective against mucoraceous moulds

Question 30

What is the spectrum of posaconazole/ isavuconazole (yeasts/aspergilus spp./mucoraceous moulds)?

Answer 30

Effective against yeasts, aspergillus spp. and mucoraceous moulds

Question 31

What is the clinical use of imidazoles (a type of azole)?

Answer 31

Superficial infections (topical administration)
Cadidiasis (canestan)
Dermatophyte infections

Question 32

What is the clinical use of triazoles?

Answer 32

Systemic infections (oral/parenteral administration)
Aspergillosis (used in treatment and occasionally prophylaxis)
Candidiasis (fluconazole)

Question 33

What is the mode of action of Echinocandins?

Answer 33

Inhibition of beta-1,3-glucan (used to make fungal cell walls)
Leads to construction of severely abnormal cell wall

Question 34

Give 3 examples of Echinocandins?

Answer 34

1) Anidulafungin
2) Caspofungin
3) Micafungin

Question 35

What is the spectrum of activity of echinocandins?

Answer 35

Apergillus spp and candida spp

Misses certain moulds and cryptococcus spp.

Question 36

What are the adverse effects of echinocandins?

Answer 36

Minimal: eg. skin rash, nausea, vomiting, headache, diarrhoea in common with any other drug

Question 37

What is the clinical use of echinocandins?

Answer 37

Systemic infections

Parenteral formulations only

Question 38

What is 5-fluorocytosine (5-FC)?

Answer 38

Synthetic analogue of cytosine (a pyrimidine nucleoside)
Developed as an anti-cancer drug, has no anti-cancer properties but incidentally was found to have anti-fungal properties

Question 39

What is the mode of action of 5-fluorocytosine, how does it show selective toxicity?

Answer 39

Entry into cell requires fungal cytosine permease (not found in humans so cant get into our cells - selective toxicity)
Converted to 5-fluorouracil and 5-fluorodeoxyuridine monophosphate, inhibit RNA/protein synthesis and DNA synthesis

Question 40

What is the spectrum of activity of 5-fluorocytosine?

Answer 40

Yeasts only - candida and cryptococcus spp.

Question 41

What are the adverse effects of 5-fluorocytosine?

Answer 41

Bone marrow suppression - selective toxicity is incomplete

Question 42

When is 5-fluorocytosine used clinically?

Answer 42

To treat cryptococcal meningitis (in combination with AmB)

Question 43

What are the 2 reasons for therapeutic drug monitoring?

Answer 43

1) To minimize toxicity - level should remain below a threshold value
2) To maximize efficacy - level should exceed threshold value

Question 44

Why does itraconazole require therapeutic drug monitoring?

Answer 44

To maximize efficacy - has few side effects but their is a minimum level below which it doesnt work

Question 45

Why does 5-fluorocytosine require therapeutic drug monitoring?

Answer 45

To minimize toxicity

Question 46

Why does voriconazole require therapeutic drug monitoring?

Answer 46

To minimize toxicity AND to maximize efficacy