70. Penicillins, cefalosporins

β-lactam antibiotics

 
The structure of penicillin, with the beta lactam ring in red. From https://en.wikipedia.org/wiki/%CE%92-lactam_antibiotic

The beta lactam antibiotics is a class of antibiotics that all contain a so-called beta lactam ring.

All beta lactam antibiotics interfere with the synthesis of the bacterial cell wall peptidoglycan. They bind covalently to a protein called penicillin-binding protein (PBP) and inhibits its function. PBP is an enzyme which is essential for the synthesis of peptidoglycans, by crosslinking peptidoglycans. This causes the cell wall to be weakened, eventually causing the cells to lyse.

Many bacteria produce beta-lactamases, a type of enzyme which cleaves the beta lactam ring of beta lactam antibiotics, thereby inactivating the antibiotic.

Four types of antibiotics are beta lactams, the penicillins, cephalosporins, carbapenems and monobactams.

Penicillins

The first penicillins (penicillin G and penicillin V) were isolated from a mould called penicillium (by Alexander Fleming), which produces the aforementioned penicillins. Penicillin G, also called benzylpenicillin, is poorly absorbed by the GI tract and is inactivated by bacterial beta-lactamases. Penicillin V has good oral bioavailability and can be given by mouth. Despite these drawbacks penicillin G and V still has some uses today.

Nowadays we have many other types of penicillin, all of them semisynthetic. These other types lack some of the drawbacks of the basic (natural) penicillins (G and V). The four main types of penicillins are:

  • Beta lactamase sensitive penicillins (basic penicillins)
    • Penicillin G (benzylpenicillin)
    • Penicillin V (fenoxymethylpenicillin)
  • Beta lactamase resistant penicillins (antistaphylococcal)
    • Cloxacillin
    • Dicloxacillin
    • Flucloxacillin
    • (Methicillin)
    • (Nafcillin)
    • (Oxacillin)
  • Aminopenicillins (broad spectrum penicillins)
    • Ampicillin
    • Amoxicillin
  • Antipseudomonal (ultra-broad spectrum) penicillins
    • Carboxypenicillins
      • Carbenicillin
      • Ticarcillin
    • Ureidopenicillins
      • Mezlocillin
      • Piperacillin

Methods of resistance

Some bacteria produce penicillinase, a type of beta-lactamase which is specific for penicillins. This enzyme cleaves the beta lactam ring and inactivates the antibiotic.

Some bacteria have mutated penicillin-binding proteins which have lower affinity for penicillins than normal PBPs. This causes them to be resistant to penicillins.

Some Gram-negative bacteria have outer membrane proteins that prevent penicillins from entering the bacterial cell.

Beta-lactamase sensitive penicillins

Penicillin G and V are still widely used, as they're effective for many organisms while also driving the least resistance and being cheap and safe. How widely they are used depends on local and regional antibiotic resistance rates.

Beta-lactamase resistant penicillins

Like the name suggests these antibiotics are effective even against bacteria that produce beta-lactamase. Like the alternative name suggests (antistaphylococcal), these penicillins are often preferred for methicillin-sensitive staphylococcus aureus (MSSA). Methicillin was the first of this class but is no longer used as it caused interstitial nephritis. Its name is still remembered however as part of the methicillin resistant staphylococcus aureus (MRSA). In Europe cloxacillin, dicloxacillin and flucloxacillin are the most widely used, while nafcillin and oxacillin are rarely used.

These antibiotics have less antimicrobial activity than the basic penicillins and should therefore only be used when there is resistance against the basic ones.

Aminopenicillins (broad spectrum penicillins)

Aminopenicillins themselves are sensitive to penicillinase, but they can be combined with so-called beta-lactamase inhibitors. Ampicillin can be combined with the beta-lactamase inhibitor sulbactam while amoxicillin can be combined with clavulanate (clavulanic acid). The combination amoxicillin+clavulanate is called Augmentin®.

The aminopenicillins have a broader antimicrobial spectrum than the basic and penicillinase-resistant penicillins.

Antipseudomonal penicillins

Like the name suggests these penicillins are effective against pseudomonas aeruginosa. Only piperacillin and ticarcillin are in widespread use.

These drugs are sensitive to penicillinase and are therefore, like aminopenicillins, often combined with beta-lactamase inhibitors. Ticarcillin is combined with clavulanate and piperacillin is combined with tazobactam.

Pharmacokinetics and dosing

Penicillin G and piperacillin are acid labile and therefore only available as parenteral preparations, mostly IV. Penicillin G is also available as a slow-release intramuscular injection, given once per day. The dosing for penicillin G should be 5 – 20 million international units (IU) per day.

Penicillin V, oxacillin, cloxacillin, dicloxacillin, flucloxacillin, ampicillin and amoxicillin are all acid stable and therefore available as oral preparations.

Penicillins are well distributed in the extracellular space but penetrate poorly into the intracellular space, prostate and eyes. It penetrates very poorly into the CNS, except during meningitis, which is the only case where we can reach therapeutic concentrations in the CSF.

Most penicillins are eliminated unchanged by tubular secretion. Broad spectrum penicillins are partially excreted in the bile, too.

Penicillins have a short half-life, around 0,5 – 1 hour so for maximum effect they should be administered at 6-hour intervals, four times a day.

Side effects

The most important side effect of penicillins is hypersensitivity; penicillin allergy is common. Penicillins can act as haptens and induce anaphylaxis, bronchospasm, interstitial nephritis etc. High doses can cause convulsions.

As is common for most antibiotics are gastrointestinal symptoms like diarrhoea and nausea common. Skin rashes and fever are also common.

Antibiotic spectrum

The following list is not exhaustive and merely shows which bacteria the antibiotics are first choices.

  • Penicillin G/V
    • Neisseria meningitidis
    • Clostridia
    • Treponema pallidum
    • Streptococcus pyogenes
  • Penicillinase-resistant penicillins
    • Methicillin-sensitive staphylococcus aureus
  • Aminopenicillins
    • Streptococcus pneumoniae
    • Salmonella
    • Shigella
    • Enterococci
  • Antipseudomonal penicillins
    • Gram negatives
    • Pseudomonas aeruginosa
    • Klebsiella

Cephalosporins

Cephalosporins are beta lactam antibiotics originally derived from the fungus cephalosporium. They have a wider antibacterial spectrum than the penicillins, but have the same mechanism of action as them. Most cephalosporins are semisynthetic compounds. They’re divided into generations from 1 – 5 based on which bacteria they're active against, and whether they’re used parenterally or orally. The following are the most important ones.

1. generation 2. generation 3. generation 4. generation 5. generation Siderophore cephalosporin
Parenteral Cefalotin

Cefazoline

Cefuroxime Cefotaxime

Ceftazidime

Ceftriaxone

Cefepime Ceftaroline Cefiderocol
Oral Cefalexin Cefaclor Cefixime
Effective against Gram positives and some gram negatives Gram positive and gram negatives Gram negatives Gram negatives MRSA Multidrug-restistant bacteria

Methods of resistance

Almost all Gram-negative bacteria produce a beta-lactamase which inactivates many cephalosporins (but not penicillins). Resistance can also develop due to outer membrane proteins that prevent cephalosporins from entering the bacterial cell.

Pharmacokinetics

The first and second generation don’t penetrate the CNS well, but the other generations do.

Most cephalosporins are eliminated unchanged via tubular secretion in the kidneys. Their half-life is 1 – 2 hours.

Ceftriaxone stands out among the cephalosporins for these reasons:

  • it is excreted into bile (not eliminated by kidney)
  • it binds strongly to albumin and can therefore displace other drugs which do the same.
  • it has a half-life of 6 – 8 hours.

Side effects

As with penicillins hypersensitivity reactions can develop. In 5 – 7% of cases there is cross-sensitivity between them, meaning that 5 – 7% of people with penicillin allergy will be allergic to cephalosporins as well.

Gastrointestinal symptoms are common. If given together with aminoglycosides they can cause nephrotoxicity. Some cephalosporins (none of the most widely used, though) have a disulfiram-like effect and can cause symptoms when taken with alcohol. Some have a coumarin-like effect.

Clinical uses

1. generation: Cefazoline is used as perioperative prophylaxis.

2. generation: Upper and lower respiratory tract infections.

3. generation: Urinary tract and respiratory tract infections (including nosocomial), meningitis, gonorrhoea, pseudomonas

4. generation: Same as for 3. generation, used in case of severe infections or resistance to 3. generation.

5. generation: MRSA.