antimicrobial chemotherapy

Question 1

<p>define bactericidal</p>

Answer 1

<p>antimicrobial that kills bacteria

| e.g. penicillin</p>

Question 2

<p>define bacteriostatic</p>

Answer 2

<p>antimicrobial that inhibits the growth of bacteria

| e.g. erythromycin</p>

Question 3

<p>define sensitive</p>

Answer 3

<p>an organism is considered sensitive if it is inhibited or killed by levels of the antimicrobial that are available at the site of infection</p>

Question 4

<p>define resistant</p>

Answer 4

<p>an organism is considered resistant if it isn't killed or inhibited by levels of the antimicrobial that are available at the site of the infection</p>

Question 5

<p>define MIC</p>

Answer 5

<p>minimal inhibitory concentration

| the minimum concentration of antimicrobial needed to inhibit visible growth of a given organism</p>

Question 6

<p>define MBC</p>

Answer 6

<p>Minimum bactericidal concentration

| the minimum concentration of the antimicrobial needed to kill a given organism</p>

Question 7

<p>what are the 3 routes of administration</p>

Answer 7

<p>topical
systemic
parenteral (IV/IM)</p>

Question 8

<p>3 sites of antibiotic action</p>

Answer 8

<p>inhibition of cell wall synthesis
inhibition of protein synthesis
inhibition of nucleic acid synthesis</p>

Question 9

<p>antibiotics that inhibit cell wall synthesis</p>

Answer 9

<p>- penicillins and cephalosporins (beta lactams)

| - glycopeptides</p>

Question 10

<p>penicillins and cephalosporins</p>

Answer 10

<p>- beta lactam antibiotics
- disrupt peptidoglycan synthesis by inhibiting the enzymes (PBPs) responsible for cross-linking the carbohydrate chains</p>

Question 11

<p>benzyl penicillin resistance</p>

Answer 11

<p>many gram -ve are resistant to benzyl penicillin due to the relative impermeability of the gram -ve cell wall</p>

Question 12

<p>beta lactamas are effective against mostly gram</p>

Answer 12

<p>+ve bacteria</p>

Question 13

<p>glycopeptides</p>

Answer 13

<p>work on gram +ve only
vancomycin and teicoplanin
inhibit assembly of a peptidoglycan precursor
can't penetrate the gram -ve cell wall
vancomycin and teicoplanin arent absorbed from the GI tract so are only given parenterally</p>

Question 14

<p>vancomycin toxicity</p>

Answer 14

<p>local tissue damage can occur if it leaks from the veins
side effects: ototoxicity, nephrotoxicity, skin rashes
important to measure levels
teicoplanin appears to be less toxic</p>

Question 15

<p>antibiotics that inhibit protein synthesis</p>

Answer 15

<p>aminoglycosides
macrolides and tetracyclines
oxazolidinones
cyclic lipopeptide</p>

Question 16

<p>Aminoglycosides</p>

Answer 16

<p>e.g. gentamicin
concentration dependent bactericidal
gram -ve resistance is unusual - main use is to treat gram -ve infections
most staphylococci are sensitive, streptococci aren't
gentamicin is toxic and requires careful dosing regime</p>

Question 17

<p>macrolides and tetracyclines</p>

Answer 17

<p>macrolides are useful alternatives to penicillin when treating gram +ve infections in patients who are allergic to penicillin
>10% of Staph aureus, strep pyogenes and strep pneumonia strains are resistant</p>

Question 18

<p>oxazolidinones</p>

Answer 18

<p>bacteriostatic/bactericidal depending on the bacteria

linezolid - good activity against MRSA, orally</p>

Question 19

<p>cyclic lipopeptide</p>

Answer 19

<p>strong bactericidal
daptomycin - activity against gram +ve, particularly MRSA
last resource</p>

Question 20

<p>antibiotics that inhibit nucleic acid synthesis</p>

Answer 20

<p>trimethoprim and sulphamethoxazole

| fluoroquinolones</p>

Question 21

<p>trimethoprim and sulphamethoxazole</p>

Answer 21

<p>both inhibit different steps in purine synthesis
used in a combined form - co-trimoxazole
less likely than other broad spectrum agents to cause C. diff infections</p>

Question 22

<p>fluoroquinolones</p>

Answer 22

<p>e.g. ciproflaxin
inhibit DNA synth more directly 
given orally and parenterally 
effective against gram -ve 
can't be used in children - interference with cartilage growth 

levofloxacin has more activity against gram +ve</p>

Question 23

<p>what are the 2 types of antibiotic resistance</p>

Answer 23

<p>inherit/intrinsic resistance

| acquired resistance</p>

Question 24

<p>inherit/intrinsic resistance</p>

Answer 24

<p>- all strains of a given species are naturally resistant to an antibiotic

- usually due to the inability of the drug to penetrate the bacterial cell wall to exert its action
e. g. streptococci resistance to amino-glycosides, gram -ve resistance to vancomycin</p>

Question 25

<p>acquired resistance</p>

Answer 25

resistance may be present in some strains of the species but not others
lab sensitivity testing is essential to establish the likely sensitivity of any individual isolate from a patient

Question 26

mechanisms of acquired resistance

Answer 26

• spontaneous mutation during multiplication of the bacterial DNA, can result in change in structure/function
• genes that code for resistance can spread from organism to organism or from species to species (commonest method)

Question 27

widespread use of antibiotics causes …

Answer 27

selective pressure and encourages new resistant organisms to outgrow sensitive strains (natural selection)

Question 28

mechanisms of resistance to beta lactams

Answer 28

• beta lactamase production

- alteration of PBP target site

Question 29

beta lactamase production

Answer 29

• bacterial enzymes that cleave the beta lactam ring of the antibiotic and make it inactive
• common is hospital strains of S aureus and most gram -ve bacteria
• extended spectrum beta lactamases (ESBLs) are produced by some gram -ve organisms can break down 3rd generation cephalosporins as well as penicillin and render the organism resistant to all beta lactam antibiotics

Question 30

combating beta lactamase production

Answer 30

• introduce a 2nd component to the antibiotic (beta lactamase inhibitor) - protects the antibiotic from enzymatic degradation e.g. co-amoxiclav
• modify the antibiotic side chain to produce an antibiotic that is resistant to beta lactamase action e.g. flucoxacillin

Question 31

carbapenemase producing enterobacteriaciae

Answer 31

group of extremely resistant gram -ve organisms
resistant to carbapenems
usually also resistant to multiple other classes of antibiotics - often leaves no antimicrobial options for therapy

Question 32

carbapanems

Answer 32

highly effective antibiotics
used for severe/high risk bacterial infections
member of beta lactam class
reserved for multi-drug resistant infections

Question 33

alteration of PBP target site

Answer 33

• results in a modified target site to which all beta lactams will no longer bind
  these organisms are resistant to all beta lactam agents
  addition of beta lactamase inhibitor makes no difference
  e.g. MRSA - resistant to all penicillins and cephalosporins

Question 34

treatment of MRSA

Answer 34

• flucloxacillin: beta lactamase resistant, treats beta lactamase producing s aureus (NOT MRSA)
• vancomycin and linezolid - MRSA treatment

Question 35

glycopeptide resistance

Answer 35

• vancomycin resistant enterococci - peptidoglycan precursor to which vancomycin normally binds has an altered target site
  these types of bacteria have appeared very recently
  vancomycin resistance is unusual in gram +ve organisms

Question 36

penicillins (examples of drugs)

Answer 36

benzyl penicillin (penicillin G)
amoxicillin, ampicillin
co-amoxiclav
flucloxacillin
piperacillin 
imipenem, meropenem

Question 37

spectrum of benzyl penicillin

Answer 37

largely acts against gram +ve organisms
best choice for IV treatment of serious pneumococcla, meningococcla and S pyogenes infection

phenoxymethylpenicillin has slightly better absorption when taken orally

Question 38

amoxicillin, ampicillin spectrum

Answer 38

better oral absorption that benzylpenicillin
originally better gram -ve activity
20-30% of coliform organisms are now resistant due to beta lactamase production
covers streptococci, enterococci and some coliforms

Question 39

co-amoxiclav spectrum

Answer 39

amoxicillin + beta lactamase inhibitor clavulanic acid

extends the spectrum to cover beta lactamase producing coliforms

Question 40

flucloxacillin spectrum

Answer 40

resistant to staphylococcal beta lactamase
first choice of treatment for staph infections
methicillin is a similar agent, used to represent flucloxacillin in lab testing - resistant organisms are termed MRSA

Question 41

piperacillin spectrum

Answer 41

broad spectrum penicillin
extended gram -ve cover
anti-anaerobic activity

Question 42

imipenem, meropenem spectrum

Answer 42

carbapenems

widest spectrum - used against most bacteria

Question 43

cephalosporin spectrum

Answer 43

often divided into generations
activity against gram -ve organisms increases from 1st to 3rd generation
only ceftazidime has any activity against pseudomonas
gram +ve activity decreases from 1st to 3rd generation

Question 44

aminoglycosides spectrum

Answer 44

parenteral use only
noted for use against gram -ve organisms
most staphylococci are sensitive (not streptococci)
gentamicin is the cheapest and most commonly used - BUT IS TOXIC

Question 45

Glycopeptide spectrum

Answer 45

parenteral use only
vancomycin and teicoplanin
activity against gram +ve only - anaerobic and aerobic
vancomycin - toxicity

Question 46

macrolide spectrum

Answer 46

clarithomycin or erythromycin
activity against mostly gram +ve
alternative to penicillin (for allergic patients)
azithromycin -newer, useful for single dose treatment of chlamydia

Question 47

quinolone spectrum

Answer 47

newer generations have wider specturm and are active against nearly all gram -ve (including pseudomonas)
only possibility for oral treatment of pseudomonas
streptococci activity is generally poor but levofloxacin is active against pneumococci

Question 48

metronidazole spectrum

Answer 48

effective against gram +ve and -ve anaerobes

no useful activity against aerobes

Question 49

fusidic acid spectrum

Answer 49

anti-staphylococcal drug
should always be used in combination with other anti-staphylococcal drugs to prevent resistance developing
diffuses well into bone and tissues

Question 50

trimethoprim spectrum

Answer 50

urinary infection treatment
co-trimoxazole = trimethoprim + sulfamethoxazole
- used for a few specialised conditions and sometimes the treatment of chest infections (as long as it doesnt predispose to C diff infection)

Question 51

tetracyclines spectrum

Answer 51

broad spectrum
inhibit protein synthesis
few limited applications
some genital tract and respiratory tract infections
shouldn’t be given to pregnant women or young children - deposited in teeth and bones (toxic)

Question 52

clindamycin spectrum

Answer 52

only lincosamide antibiotic in common use
good gram +ve activity e.g. staphylococci and streptococci
good activity against anaerobes
very good tissue penetration
can be taken orally

Question 53

linezolid spectrum

Answer 53

good MRSA activity
can be given orally
can cause bone marrow suppression

Question 54

daptomycin spectrum

Answer 54

gram +ve only

serious MRSA infections

Question 55

fidaxomicin

Answer 55

new macrocyclic antibiotic

bactericidal against C diff

Question 56

urinary tract agents

Answer 56

used only in the treatment of lower UTI (cystitis)
nalidixic acid - urinary antiseptic, gram -ve aerobes only
nitrofurantoin - urinary antiseptic, most gram -ve (not proteus and pseudomonas spp), also effective against some gram +ve

Question 57

allergic reactions

Answer 57

most commonly associated with beta lactams
true penicillin hypersensitivity is rare
10% of truly penicillin allergic patients will also be allergic to cephalosporins

Question 58

types of allergic reactions

Answer 58

immediate hypersensitivity
delayed hypersensitivity
GI side effects

Question 59

immediate hypersensitivity

Answer 59

anaphylactic shock - usually follows parenteral administration
IgE mediated
occurs within minutes of administration
itching, urticaria, nausea, vomiting, wheezing, shock, laryngeal oedema

Question 60

delayed hypersensitivity

Answer 60

hours or days to develop
immune complex or cell mediated mechanism
drug rashes (most common), drug fever, serum sickness, erythema nodosum
rashes are usually maculopapular, restricted to the skin
Steven’s johnson syndrome: severe and sometimes fatal, associated with sulphonamides, skin and mucous membranes are involved

Question 61

GI side effects

Answer 61

commonly encountered with anti-microbial usage
nausea and vomiting are common
diarrhoea associated with toxin production by C diff is a major problem with HAI
C diff appears to overgrow normal flora during antibiotic therapy and produces toxins - can develop to pseudomonas colitis
treated with oral metronidazole or oral vancomycin - other antibiotic use is discontinued if clinically appropriate
relapses are common and further courses of treatment may be required

Question 62

thrush

Answer 62

suppression of normal flora, overgrowth of resistant orhanisms
therapy with broad spectrum penicillins or cephalosporins may be complicated by the overgrowth of C albicans (yeast)
results in oral and/or vaginal candidiasis

Question 63

liver toxicity

Answer 63

more common in patients with pre-existing liver disease and in pregnancy
tetracyclines, flucloxacillin and anti TB drugs (isoniazid and rifampicin) have been associated with hepatotoxicity

Question 64

renal toxicity

Answer 64

dose related and more common in patients with pre-existing renal disease
most commonly seen with aminoglycosides or vancomycin
usually reversible but can be permenant

Question 65

neurological toxicity

Answer 65

ototoxicty - aminoglycoside or vancomycin use
optic neuropathy - ethambutol associated with dose related optic nerve damage
encephalopathy and convulsions - high dose penicillin and cephalosporin use or with aciclovar, especially if the dose isnt reduced in the presence of renal impairment
peripheral neuropathy - metronidazole and nitrofurantoin, may produce reversible peripheral neuropathy of uncertain mechanisms; anti TB drug isoniazid may also induce peripheral neuropathy

Question 66

haematological toxcity

Answer 66

• toxic effect on bone marrow resulting in selective depression of one cell line or unselective depression of all bone marrow elements
  co-trimoxazole may result in folate deficiency which can cause megaloblastic anaemia after prolonged therapy

toxicity of some antivirals requires close monitoring of blood count
linezolid also causes bone marrow suppression and may lower platelet counts

Question 67

prevention of adverse reactions

Answer 67

antimicrobials should be used only when indicated and in the minimum dose and duration necessary to achieve efficacy
exercise care when administering to susceptible groups
carefully monitor antimicrobials with a low therapeutic margin to ensure maximal efficacy and minimal toxicity
report all adverse reactions

Question 68

preventing resistance

Answer 68

antibiotics should only be prescribed when absolutely necessary
use narrow spectrum antibiotics targeted at the likely infecting organism

Question 69

patient characteristics

Answer 69

age: certain drugs are contraindicated in children
renal function: antimicrobials tend to accumulate in the body in the case of renal failure due to the reduced ability of the kidneys to excrete the drug, in this case dose will need to be reduced
liver function: dose should be decreased in hepatic insufficiency or chose an alternative drug
pregnancy: some drugs are contraindicated in pregnancy (mutagenic, teratogenic or both), many other drugs are contraindicated because their effects on the unborn foetus are unknown

Question 70

prophylaxis

Answer 70

administration of antimicrobias to prevent the future occurrence of infection
dosage should cover the period of risk only and shouldnt be extended beyond this to avoid selecting out resistant organisms

Question 71

therapy

Answer 71

when the organisms causing infection aren’t known, empirical antimicrobial therapy may have to be commenced if urgent treatment is required
this takes into account the site and type of infection and the likely causative agent
the treatment prescribed should always be reviewed once the results of culture and antibiotic sensitivity tests become available

Question 72

drug related considerations

Answer 72

spectrum of antimicrobial agent
monotherapy vs combination
penetration to the site of infection
additive/synergistic/antagonistic effects 
monitoring 
dose and duration of therapy

Question 73

spectrum of the antimicrobial agent

Answer 73

antibiotic chosen should normally be effective against the known or likely causative agents

Question 74

monotherapy vs combination

Answer 74

simplest approach (monotherapy) is generally best but sometimes it is necessary to use a combination

• to cover mixed infection by more than one organism
• 2 antimicrobials that have an enhanced effect (synergy)
• minimise the development of resistant strains to any one agent

Question 75

what are the 3 possible outcomes when using antibiotics in combination

Answer 75

• their effects are additive
• they are antagonistic and their combined effect is less than the sum of their individual contributions
• they are synergistic and their combined effect is more than the sum of their individual contributions e.g. penicillin and gentamicin in the treatment of streptococcal endocarditis

Question 76

combined effects of antibiotics (general rules)

Answer 76

two cidal/two static = additive/synergistic

one static + one cidal = may result in antagonism

Question 77

penetration to the site of infection

Answer 77

antibiotics must be able to penetrate to the site of infection in order to have effective use in clinical practice

Question 78

monitoring

Answer 78

certain antimicrobials have a low therapeutic index and the serum levels of these should be monitored careully to prevent toxicity

Question 79

dose and duration of therapy

Answer 79

• consult BNF for appropriate dosage schedules
• patients with serious infections often require much higher doses than normal
• combination of drugs may further influence dosage
• children and patients with renal failure may require reduced dosage
• standard course for many infections is 7 days (some are longer and some are shorter)

Question 80

what are the 2 main reasons for monitoring serum levels of an antimicrobial

Answer 80

1. to ensure that therapeutic levels have been reached
2. to ensure that levels aren’t high enough to be toxic
   - most commonly measured are gentamicin and vancomycin

Question 81

suceptibility testing

Answer 81

automated methods: growth of individual isolates is measured in the presence of different concentrations of each antibiotic and the likely MIC of the antibiotic for that organism is calculated. In vitro lab testing only gives a prediction of whether the infection is likely to be cured by the antibiotic
E test: simplest way to measure the MIC of one antibiotic, gradient of antibiotic concentrations on the strip, MIC of the organism can be read directly from the point where organism growth intersects the strip

Question 82

antifungal drugs

Answer 82

polyenes
azoles
allylamines
echinocandins

Question 83

polyenes

Answer 83

bind to ergosterol in the fungal cell wall - increases permeability of the cell wall
active against yeasts and filamentous fungi
toxic as they bind to other sterols in our cell walls
Amphotericin B - only drug available for IV use, for the treatment of serious systemic fungal infection
lipid complexed formulations of the drug reduce incidence of side effects
Nystatin - only available for topical use and in oral suspension

Question 84

azoles

Answer 84

inhibit ergosterol synthesis

older: miconazole, ketoconazole
newer: fluconazole, itraconazole, voriconazole
fluconazole: oral and parenteral treatment of yeast infections, no activity against filamentous fungi, no apparent toxicity problems, resistance among some candida species
itraconazole: active against yeasts and filamentous fungi
voriconazole: treatment of aspergillosis

Question 85

allyamines

Answer 85

suppress ergosterol synthesis
terbinafine: active primarily against dermatophytes (clinical use is restricted to infections of the skin and nails), mild infections are treated topically and serious infections are treated orally

Question 86

echinocandins

Answer 86

inhibit glucan polysaccharide synthesis
caspofungin, mycafungin, anidulafungin
fungicidal against candida spp, inhibit growth of several aspergillus spp (used for serious infections)

Question 87

antiviral drugs

Answer 87

antibiotics have no action against viruses
there are no virucidal agents (only virustatic)
many anti-viral drugs are nucleoside analogues which interfere w/ nucleic acid synthesis

Question 88

anti herpes virus drugs

Answer 88

HSV, VZV, EBV CMV - not all are equally sensitive to anti-viral treatment
treatment is most effective if started early but doesnt eradicate the virus
Aciclovir - nucleoside analogue, specific for virus infected cells, low toxicity for uninfected host cells, extremely active against HSV and VZV, IV form is given to treat severe infections , cold sores can be treated orally or with the topical preparation
in the case of renal impairment, dose may need to be reduced to avoid neurological toxicity
famiclovir, valaciclovir: oral, better oral bioavailability than aciclovir, HSV and shingles treatment
ganciclovir: CMV treatment, toxic and given by IV injection, treatment of life-threatening infections or immunocompromised patients
Valganciclovir: pro-drug of ganciclovir, oral alternative for some CMV infections
foscarnet: some HSV, VZV and CMV infections resistant to the above drugs, highly nephrotoxic, IV only
cidofovir: CMV retinitis

Question 89

anti HIV drugs

Answer 89

first treatment: zidovudine (AZT, ZDV), nucleoside analogue, slows viral replication, high incidence of side effects
combination therapy with 3 drugs is now common practice: drugs are selected that are active on at least 2 different stages of HIV replication
e.g. two nucleoside analogue reverse transcriptase inhibitors + non-nucleoside reverse transcriptase inhibitor (nevirapine, efavirenz) or a protease inhibitor (saquinavir, darunavir)
these drugs are used for prophylaxis also following occupational/sexual exposure to HIV +ve blood or body fluids

Question 90

drugs for chronic hep B/C

Answer 90

interferon - alpha: treats selected chronic hep B and C infections , low response rates and serious side effects
combination therapy with ribavarin is now common

Question 91

drugs for viral respiratory infections

Answer 91

zanamavir, osteltamivir: influenza A/B treatment within 48 hrs of symptom onset and also for post-exposure prophylaxis
influenza immunisation remains the first line of protection

ribavarin: nucleoside analogue, treatment of severe respiratory syncytial virus infections, must be inhaled as a fine spray to reach the site of infection - difficult administration

Question 92

anti-viral resistance

Answer 92

genotypic analysis may help in choosing rational treatment in selected patients

Question 93

anti-viral drug levels

Answer 93

available only for a few drugs

ensures therapeutic, but not toxic, serum levels are achieved

Question 94

how long is antimicrobial treatment of osteomyelitis or endocarditis

Answer 94

several weeks

Question 95

how long is treatment for S aureus bacteraemia

Answer 95

at least 14 days of IV therapy

Question 96

how long is treatment of a simple UTI infection

Answer 96

3 days of trimethoprim

Question 97

standard length of an antimicrobial course

Answer 97

7 days

Question 98

what length of course is recommended for Staph aureus bacteraemia

Answer 98

14 days IV