Lecture #12 - Misc. Antibacterial Agents - Canvas-1.pptx

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Pharmacology & Medicinal Chemistry III
Lecture #12
Miscellaneous Antibacterial Agents
Today’s Outline:

I. Bacitracin
II. Polymixin B and Colistimethate
III. Daptomycin
IV. Rifaximan
V. Mupirocin

Read for this lecture: Goodman and
Gilman – Chapter 59
Learning Objectives for Miscellaneous
Antibacterial Agents Lecture
By the end of this lecture, you should be able
to…

Describe the mechanism of action of drugs in
this lecture.
Describe the antibacterial spectrum for these
medications.
Identify common and severe adverse events
associated with administration of these
medications.
Identify routes of administration and how the
drugs of this lecture are excreted.
Explain why Daptomycin is NOT an effective
treatment for pulmonary infections.
I. Bacitracin
 Bacitracin – Structure and
Mechanism of Action

Chapter 55,
Goodman and
Gilman, 12th ed.

Mechanism of Action
Inhibits synthesis of the _____________________
by interfering with the transport of
peptidoglycan subunits across the cell
membrane.
Bacitracin – Antibacterial Spectrum,
Adverse Effects, and Other
Antibacterial Spectrum
Many _________________ Bacteria

Adverse Effects
Little (with topical administration)
Nephrotoxicity (with systemic administration).
 Renal function must be monitored with IM
administration

Other
Renal excretion
Topical, ophthalmic, and IM (restricted)
administration
- Often combined with other compounds
(Neosporin – Neomycin, Polymixin B, and
II. Polymixin B and
Colistimethate
 Polymixin B and Colistimethate –
Structure
Polymixin B
Comprised of a mixture of
Polymixin B1 and
Polymixin B2

Chapter 55,
Goodman and
Gilman, 12th ed.

Colistimethate (pro-drug)
Converted to _______
(Polymixin E)
Related structure to
Polymixin B
olymixins are amphipathic.
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 Polymixin B and Colistimethate –
Mechanism of Action
Mechanism of Action -
Interact with certain phospholipids
Disrupt the bacterial
__________________________________ (in Gram negative
bacteria), forming abnormally large openings
through which cellular components can leak out.
Has affinity for some bacteria cell membranes
over others (specificity).

Figure 12.4,
Foundations in
Microbiology, 7th
 Polymixin B and Colistimethate –
Antibacterial Spectrum
Most _________________bacteria
- Includes E. coli, Salmonella, Bordetella, Shigella, and
Pseudomonas aeruginosa
- Used especially to treat bacteria resistant to other
antibiotics.

Not effective against Gram positive bacteria.

Resistance is common, so these drugs are usually
used in combination therapies.

Usually reserved for MDR pathogens (for systemic
use) due to adverse effects
 Polymixin B and Colistimethate –
Adverse
Side effects are Effects
few for topical administration,
due to lack of absorption.

Extremely _________________ (if parenteral
administration)- Monitor closely.

Neurotoxicity – (includes dizziness, numbness,
vertigo)
 Neuromuscular blockade leading to
respiratory paralysis
 Polymixin B and Colistimethate –
Other Notes
_________________; poorly absorbed through mucous
membranes

Used to treat infections of the skin, mucous
membranes, eyes, and ears.
- Polymixin B - Opthalmic, otic, and topical are
available.
Often in combination with other compounds
A component of Neosporin
- Colistin – otic administration

Polymixin B is available for IV, IM. Colistin is also
available for oral, IV, IM, and inhalation.
- Oral - Can be used prophylactically before GI
surgery.
- Systemic - for last-line therapy (due to adverse
III. Daptomycin
Daptomycin – Structure

Chapter 55,
Goodman and
Gilman, 12th ed.
 Daptomycin - Mechanism of Action
Binds to bacterial membranes leading to
their depolarization and loss of
__________________________________ This leads to
the inhibition of bacterial metabolism,
including DNA, RNA, and protein synthesis.

Bactericidal

Figure 43.10 Basic and Clinical Pharmacology, 14
Daptomycin – Antibacterial Spectrum
and Resistance
Antibacterial Spectrum
_________________ Bacteria
Effective against MRSA, VRSA, and other drug-
resistant Gram positive bacteria.

Resistance
Little
 Daptomycin – Adverse Effects and
Other
Adverse Effects
Muscle pain / weakness- Damage to the
musculoskeletal system
Diarrhea, vomiting
Anemia

Other
Administered intravenously (poorly absorbed
orally; toxic to muscles when injected
intramuscularly).

Mostly excreted in urine.

Daptomycin is NOT a good choice for
V. Rifaximin
 Rifaximin – Mechanism of Action

RNA synthesis inhibitor
 Targets bacterial DNA-dependent
_________________

 Structurally similar to Rifamycins (which
will be covered with the anti-
mycobacterial drugs)
 Rifaximin – Other

Oral administration is available.
 However, minimal absorption occurs
(under normal conditions), so it is used to
treat infections in the GI tract.

Targets a broad spectrum of bacteria.

Generally well tolerated

Indicated for traveler’s diarrhea and IBS
w/diarrhea
If diarrhea worsens following extended use
of Rifaximin (>2 months), it may be due to
an adverse event (Clostridium difficile
infection).
IV. Mupirocin
 Mupirocin – Structure and
Mechanism of Action

Chapter 55,
Goodman and
Gilman, 12th ed.

Mechanism of Action
Inhibits _________________
- Thereby inhibiting protein synthesis
- Reversible
- Bactericidal
Activity against Gram positive bacteria (e.g.
Staphylococcus aureus, including MRSA) and
several Gram negative bacteria.
 Mupirocin - Resistance
 _________ level of resistance
When resistance is present, it is usually due
to:
- Mutations in the isoleucyl tRNA
synthetase that decrease its affinity for
mupirocin.
- The acquisition of an extra copy of the
isoleucyl tRNA synthetase gene (that
codes for an altered form of the enzyme)
 Mupirocin - Other
 Mupirocin is rapidly metabolized and
inactivated upon entry into the body.

 For topical and intranasal use
‐ E.g. to decolonize MRSA from nasal
passages

 Absorption through intact skin or skin
lesions is minimal.

 Adverse effects
- May cause irritation at site of application.
- Headache
- Systemic issues are very rare due to its
rapid inactivation.
 Which one of the following pairs of drugs
has the most similar mechanism of action?

A. Polymixin B and Streptogramin
B. Mupirocin and Penicillin G
C. Bacitracin and Vancomycin
D. Daptomycin and Oxacillin