Antibiotics

Question 1

What are the 4 mechanisms of drug resistance?

Answer 1

Drug inactivators
Decreased accumulation
Altered binding site
Alternative pathways

Question 2

How does drug inactivation work?

Answer 2

Bacteria expresses B lactamase - can break down B lactam ring of B lactam type antibiotics (penicillin type drugs)

(B lactam —> penicilloic acid)

Question 3

How is resistance passed on?

Answer 3

Selection (chromosomal mutation) occurs when antibiotics overprescribed, kill other colonies but resistant one multiplies

Transference - bacteria carry extra DNA within plasmid, can transfer DNA within or outside of strain - multiple resistance within and between strains

Question 4

Strategies to reduce resistance?

Answer 4

New antibiotics
Correct antibiotic after sensitivity testing
Reduced use as growth promoters
No use in viral infections
Increase compliance
Decrease prescriptions - especially young children (otalgia)

Question 5

What is gram positive and negative?

Answer 5

Positive - cell wall retains the purple stain
(anthracis, listeria, clostridium, staph, strep, (coccuses))

Negative - doesn’t retain purple (pink)
(enterobacter, gonorrhoea, E coli, salmonella, shigella, H. pylori, meningitidis, haemophilus influenzae)

Question 6

What factors should be considered when choosing an appropriate antibiotic?

Answer 6

Spectrum - start with broad if don’t know but narrow down if do because broad cause resistance more quickly

Orally active?
Bactericidal/static (if bacteria full of toxins, static may be better)
Mechanism
Adverse effects (penicillin allergy)
Resistance
Pharmacokinetics

Presumptive treatment (sepsis - if meninges inflammed - some don’t reach there, others only reach there) (simple chest infection - community or hospital?)

Combination therapy
Site of action
Duration of therapy
Chemoprophylaxis
Special situation (pregnancy, renal) - e.g. grey baby syndrome with chloramphenicol (now just used for conjunctivitis usually)

Question 7

Name key antibiotics in each group

1) Nucleic acid
2) Cell wall
3) Protein synthesis

Answer 7

1) Sulfamethoxazole, ciprofloxacin, metronidazole, trimethorpim
2) Flucloxacillin, amoxicillin, (cephalosporins), vancomycin
3) Tetracycline, clarithromycin, chloramphenicol (so toxic used outside body now)

Question 8

What are types of nucleic acid inhibitors?

Answer 8

Sulphonamides
Trimethoprim
Quinolones
Nitroimidazoles

Question 9

How do nucleic acid inhibitors work?

Answer 9

Sulphonamides: block dihydropteroate synthase (eventually prevents synthesis of purines and pyrimidines)

Trimethopim: blocks dihydrofolate reductase (has 100x higher affinity for bacterial version)

Quinolones: inhibits DNA gyrase (topoisomerase II) which packages the DNA (coils it for packaging) - so it remains unwound and is easier to shear and break - ATP needed to fix so causes cell exhaustion

Nitroimidazoles: cause strand breaks within the DNA itself - runs out of energy, also can’t replicate DNA for a while
(metronidazole likes low environments of oxygen, gets metabolised by bacteria (to active ingredient) itself so v specific, metabolised enzyme causes the strand breaks

Question 10

What are sulphonamides?

Answer 10

Sulfadiazine, sulfamethoxazole

Bacteriostatic, orally active

Action prevented by pus (neutrophils provide PABA)
Widespread resistance to hospital acquired infections

Nausea and vomiting
Hypersensitivity reactions (sulphur drug)
Bone marrow suppression (think DMARD - methotrexate inhibits dihydrofolate reductase

Replaced by antimicrobials with less resistance and less toxicity

Question 11

What is co-trimoxazole?

Answer 11

Sulfamethoxazole and trimethoprim

Using two drugs in linear system:

• Partly because of resistance - (think of alternative pathways) but resistance occurs more when using mono therapy (i.e. nucleic acid only or cell wall only)
• Because not all drugs are 100% effective so increase in effectiveness
• Could use less of each one to reduce side effect profile

Stephen-Johnson syndrome - 1 million per year
Bone marrow suppression

Question 12

What are the uses of co-trimoxazole?

Answer 12

Used in TB and prophylaxis of TB

• TB associated with HIV
• used if prone to bacterial infections, especially if poor immune system

Otitis media
Pneumonia
Strepococcus pneumonia and haemophilius influenzae
Toxoplasmosis 
Nocardiasis

Question 13

What are the uses of trimethoprim?

Answer 13

Invasive salmonella
Respiratory tract
Prostaitis (UTI)
Shigellosis

Question 14

What are quinolones?

Answer 14

Ciprofloxacin, norfloxacin

-ve > +ve - widely used in some gram -ve organisms

V.broad spectrum - useful in hospital e.g. simple chest infection - don’t get side effects seen with some drugs

Effective against organisms resistant to penicillins and some cephalosporins

Orally active, poorly absorbed by BBB (not used meningitis, avoid in sepsis - good for presumptive treatments but be careful what you try)

Inhibition of P450 enzymes (interaction with theophylline and warfarin - they build up) - ciprofloxacin interactions

Question 15

What are first line uses of quinolones?

Answer 15

Pyelonephritis (UTI)
Bacillary dysentry
Severe gastroenteritis - normally even bactericidal gastroenteritis is self limiting - travellers diarrhoea
Pseudomonas (opportunistic often in CF or HIV)

Question 16

What are nitroimidazoles?

Answer 16

Metronidazole, tinidazole

Bactericidal - causes strand breaks in DNA following metabolism by the bacteria
Broad spectrum
Orally active

Important in serious anaerobic infections e.g. sepsis
Anaerobes metabolise the imidazole to its active form
Effective against H. pylori

Interacts with ethanol, warfarin metabolism
Bitter taste (goes into breast milk)

Question 17

What are first line uses of nitroimidazoles?

Answer 17

Pelvic infections
Anaerobic sepsis
Infected wounds
C. difficile colitis
Post surgery

Question 18

How do cell wall synthesis inhibitors work?

Answer 18

Block elongation and division, makes cell wall less rigid

Peptidoglycan on outside of wall - can provide antigenicity (Cag-A, pic-B) and provide sticky surface for getting into blood vessels/sticking in gut

Has to build using variety of enzymes - one is blocked by penicillin-like antibiotics

Peptidoglycan made of polymer chains cross linked by pentapeptide bridges - B lactam antibiotics inhibit enzymes that cross link PG and render wall weak - lose structural integrity of cell, can’t control what enters/leaves - tries to fix but runs out of energy and dies / ‘pops’

Question 19

How does methicillin work?

Answer 19

Inhibits transpeptidase (penicillin binding protein, PBP)
Stops cross-linking of peptidoglycan

Normally transpeptidase incorporates the building blocks into the cell wall - with methicillin (penicillin-like, B lactam type drug) - worked on by transpeptidase and gets incorporated –> causes bacterial lysis

Lots of resistance due to altered binding site - may be changes to transpeptidases that stops it binding, but still binds to its own correct precursors

Question 20

What is clavulanic acid?

Answer 20

Not an antibiotic alone but used in combination with amoxicillin / lactamase sensitive antibiotics

Inhibits beta lactamase - amoxicillin not resistant to B lactamase and gets broken down

(alternatives = flucloxacillin, quinolone, some cephalosporins)

If still want to use amoxicillin - use claculanic acid to inhibit the enzyme and amoxicillin is still incorporated into wall causing loss of cell wall –> Co-amoxyclav

Side effects: cholestatic jaundice / acute hepatitis, rarely fatal

Question 21

How does B lactamase (penicillinase) resistance occur?

Answer 21

B lactamase hydrolyses the lactam ring reducing activity (penicilloic acid)

• Secreted by gram positive (Staph aureus) - secreted easier to test
• Gram negative - often located between outer and inner cell membranes (harder to test for)

Often encoded on plasmid and resistance is by transference (so be careful when start to see B lactamase resistance in a bacteria)

Some lactam antibiotics can induce lactamase enzyme expression so don’t see it when you first test but later on induced by previous exposure to the antibiotics

Question 22

What are penicillins?

Answer 22

Benzylpenicillin +»>- Flucloxacillin (methacillin) +»>-
Amoxicillin +»- Azlocicillin +>- Piperacillin +>-

Bactericidal, orally available, range of bioactivity

Low adverse effects
Hypersensitivity (1-10% of exposed, 0.05% anaphylaxis) - more likely anaphylaxis/rash if atopic allergy so shouldn’t be given B lactams (e.g. try quinolones, ciprofloxacin)
Encephalopathy

Excreted in kidney (make sure no renal insufficiency, Na penicillin, K penicillin, often given IV)

Resistance

Question 23

What are first line uses of penicillins?

Answer 23

First line in rare diseases as orally available/active - works in range of areas (internally/surface/absorbed), good bioavailability

Pseudomonas
Meningitis
UTI  gonorrhoea
Bronchitis
Pneumonia
(anthrax, diphtheria, gas gangrene, leptospirosis, Lyme disease)

Question 24

What are cephalosporins?

Answer 24

Cefalexin po, +ve»>-
Cefuroxime po, -ve&raquo_space; +ve, crosses BBB
Cefotaxime ive, -ve&raquo_space; +ve crosses BBB

Broad-spectrum, but individually slight more specific
Bactericidal
Both oral and parenteral types

Used in surgical prophylaxis (also metronidazole)
‘Blind’ meningitis therapy - meningitis only when inflammed

Renal excretion, reduced dose in impairment

Question 25

What are uses of cephalosporins?

Answer 25

UTI
Peritonitis
Biliary tract
Meningitis
Pneumonia
Septicaemia

Question 26

What can cefotaxime cause and why?

Answer 26

Potent broad spectrum antibiotic so can cause opportunistic infections e.g. Candida and C. Difficile

Candida albicans and candida parapsilosis = fungal infections (antibiotics leave a niche)
Live on skin commencally = not infected because commencal
Back of throat thrush infection
Amphotericin - statin - easily treated

C diff - causes diarrhoea, caused by cephalosporins and amoxicillin
Very difficult to treat
METRONIDAZOLE

Question 27

What are carbapenems?

Answer 27

Imipenem iv, +ve = -ve
(Add cilastatin - inhibits kidney metabolism)

Meropenem +ve = -ve
Not metabolised in kidney

Beta lactamase resistant
Broadest spectrum - Active against many aerobic and anaerobic gram pos/neg organisms

Side effects similar to penicillins
Neurotoxicity at high doses in renal failure as excreted by kidney

Question 28

What are used of carbapenems?

Answer 28

Pseudomonas
Gynaecological
Foot infections soft tissue (diabetes)

Community acquired pneumonia (might need something stronger eg quinolone for hospital acquired infection because of increased risk of resistance )

Abdominal infections

Question 29

What are monobactams?

Answer 29

Aztreonam iv
-ve

Beta lactamase resistant
Only active on aerobic gram negative organisms

Side effects similar to penicillins - all the same warning signs
No cross hypersensitivity, can be used in penicillin sensitive patients

Kidney excretion and short half life
Liver and marrow toxicity

Question 30

What are uses of monobactams?

Answer 30

H influenzae
Pseudomonas
Gonorrhoea
Meningitis

Question 31

How do protein synthesis inhibitors work?

Answer 31

Tetracyclines block tRNA binding (stops process of amino acids being brought in)

Chloramphenicol blocks TRANSPEPTIDATION (when growing protein is moved in ribosome) by inhibiting peptidyl transferse

Aminoglycosides cause incorrect reading of mRNA (incorrect amino acid brought in so protein cannot function)

Macrolides & streptogramins block TRANSLOCATION (bring protein back to start position)

Question 32

How does resistance occur in tetracyclines?

Answer 32

• tetracycline eflux
• ribosome protection
• tetracycline modification
• via transference

Question 33

How does resistance occur in aminoglycosides/chloramphenicol?

Answer 33

Reduced membrane permeability
Increased acetylation
Ribosomal mutation

Transference and selection

Question 34

What are tetracyclines?

Answer 34

• Tetracycline
• Doxycycline
• Gram +ve & -ve

Bacteriostatic

Broad spectrum
Widespread resistance therefore use limited (because they are so broad spectrum)

Question 35

Side effects of tetracyclines?

Answer 35

Tend to live in skin - being treated for acne - have to cover/use sunblock

• 3,4,5,6 months of treatment
• because lives in skin - reacts with sun, photosensitive response, burn much more quickly

Erythema and photosensitisation
Tooth discolouration - causes more calcium to be stored in the teeth

Question 36

First line uses of tetracyclines?

Answer 36

Chlamydia

Plague - squirrels in US

Brucellosis - zoonotic disease (undulant fevers, sweating wet hay like smell, migratory arthralagia and myalgia)

Community acquired pneumonia

Cholera

Question 37

What are aminoglycosides?

Answer 37

• Gentamicin
• Streptomycin
• Neomycin

Gram -ve > gram +ve
Spectrum and bacterial resistance varies with individual drug

• Poor penetration of BBB (so not for meningitis)
• Not orally active

Resistance a problem: bacteria makes drug degrading enzymes

Serious side effects: ototoxicity, (deafness), nephrotoxicity (netilmicin less toxic)

Renal assessment and drug monitoring required

Question 38

What are first line uses of aminoglycosides?

Answer 38

MRSA

• if MRSA and other multi-drug resistant infections
• have to go to things that are very old - not used a drug for 40 years, the bacteria that were resistant have moved on
• tend to be out-competed by other bacteria because of their resistances etc.
• some of the drugs that haven’t been used for years become useful again

Gram -ve septicaemia

Endocarditis: Streptococci or Staph

• Drug injectors right heart others more commonly on the left
• Heart valve involvement
• No blood flow, no humoral immune response
• Therefore antibiotics to clear infection

Question 39

What are macrolides?

Answer 39

• Erythromycin +ve&raquo_space;> -ve
  
  • po
• Clarithromycin +ve > -ve
  
  • po
  • iv
• Azithromycin +ve > -ve
  
  • po
  • iv

Bacteriostatic

Similar range of action and efficacy to penicillins
(alternative to penicillin sensitive individuals- monobactam aztreonam can be used for penicillin allergy - Clarithromycin can be used instead_

Can cause diarrhoea (bad bacteria take over) and jaundice (affects liver)
- Because of that may have CYP450 interactions

Warfarin and some antihistamines - blocker - antihistamines that cause drowsiness - may get more drowsiness as not metabolised - so be careful with clarithromycin

Proton pump inhibitors - omeprazole and clarithromycin interaction can be problem - both of which - drug concentrations increase because they both inhibit the same CYP450 enzyme

Question 40

First line uses of macrolides?

Answer 40

• Respiratory infection
• Otitis media
• Pertussis
• Legionnaire’s disease
• Bronchitis
• H. pylori

Question 41

What is cloramphenicol?

Answer 41

• Bacteriostatic
• Orally active
• Gram +ve > Gram -ve
• Very toxic: bone marrow suppression, effects on newborns ‘grey baby syndrome’
• builds up in fetus
• tends to only be used externally e.g. eye drops
• can be used internally as well but less often as so toxic
• Acts in the same way as erythromycin but wider spectrum

Question 42

First line uses chloramphenicol?

Answer 42

• conjunctivitis
• meningitis
• haemophilus influenza
• reserved for serious infections because of all of side effects

Question 43

What are glycopeptides?

Answer 43

• Vancomycin
• Teicoplanin
• Gram +ve&raquo_space;> Gram -ve (restricted spectrum)
• Bactericidal except against Streptococci

Resistance is developing

Teicoplanin similar to vancomycin only longer acting

- so strong - usually used for 3 days
- relatively short time but higher dosage
- contrast to amoxicillin - 7-14 days

Synergises with amino glycosides (works better than individually/alone)

Question 44

Adverse effects of glycopeptides?

Answer 44

• Ototoxicity

- Allergic ‘red man syndrome’

Question 45

Uses of glycopeptides?

Answer 45

• Reserved for serious Gram +ve infections by IV administration
• Give po in resistant C. difficult (treat C. diff with metronidazole but if can’t get rid of it need things like vancomycin, teicoplanin)

Question 46

Which antibiotics are high risk for developing C. diff?

Answer 46

CEPHALOSPORINS (quite often have C diff inside of us but kept in control by other bacteria)
- also clindamycin, co-amoxiclav, ciprofloxacin and other quinolones

• More people take AMOXICILIN so more likely to get it in association with amoxicillin - even though the risk is lower (MEDIUM) - more people to take it so more likely to see it
• Classic side effect seen with amoxicillin but not the only one!
• Metronidazole (LOW) used for C. diff treatment anyway
  
  • and vancomycin/teicoplanin (vanomycin also LOW)
• Soton uses tetracycline in house, instead of amoxicillin for a simple chest infection because of C. diff risk - but only 15% of hospitals do this, 85% would first treat chest infection with amoxicillin and run risk of C. diff
• Soton lots of problems with C. diff rampant strains - difficult to treat with metronidazole and vancomycin

Question 47

1) B lactam antibiotics inhibit which enzyme?
2) Name mechanisms of resistance?
3) Which drugs make up co-amoxyclav?

Answer 47

1) transpeptidase (penicillin binding protein)

2) - alternative pathway
- decreased accumulation
- altered binding site

3) amoxicillin, clauvanic acid