Antimicrobial Chemotherapy PDF

Summary

This document provides an overview of antimicrobial chemotherapy, including introductions to different categories of antimicrobial agents, principles, and potential problems. It also discusses the selection criteria and classification of antimicrobial agents. The document is presented as a lecture or presentation.

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ANTIMICROBIAL
CHEMOTHERAPY

MATTHEW AIDOO
Department of Phar macolog y and Toxicolog y
School of Phar macy and Phar maceutical Sciences
University for Development Studies, Tamale
 OUTLINE
❑INTRODUCTION
❑ACTIVITY/SPECTRUM OF AMAs
❑CLASSIFICATION OF AMAs
❑PROBLEM OF AMAs
❑SELECTION OF AMAs
❑COMBINATION OF AMAs
❑FAILURE OF AMAs
 INTRODUCTION
❑CHEMOTHERAPY: chemo + therapy
The use of drug (chemical entity or substance derived form
microorganisms) to eradicate pathogenic organisms or
neoplastic cells in the treatment of infectious diseases or cancer
❖ANTIBIOTICS
Antibiotics are natural substances produced by
microorganisms, which selectively suppress the growth of
or kill other microorganisms (at very low concentration)
 INTRODUCTION
❑ANTIMICROBIAL AGENT
(chemotherapeutic agent + Antibiotics)
Any substance of natural, synthetic or semisynthetic
origin which at low concentrations kill or inhibits the growth
of microorganisms but causes little or no host damage
❑Chemotherapy is based on the principle of selective toxicity
This requires utilization of metabolic or structural differences
between normal human cells and disease-producing cells. The
more closely related the disease-producing cells are to normal
human cells, the more difficult to achieve selective toxicity
 ANTIMICROBIAL ACTIVITY
❑Cidal - (bacteriocidal, vermicide, fungicidal, virucidal)
Drug kills sensitive organisms so that the number of viable
organisms falls rapidly after exposure to the drug
❑Static – (bacteriostatic, vermifuge, fungistatic, virustatic)
Drug inhibits the growth of organisms but does not kill them.
Hence, the number of viable organism remains relatively
constant in the presence of a static drug, and immunologic
mechanisms (host) are required to eliminate organisms during
treatment of an infection with this type of drug
 ANTIMICROBIAL SPECTRUM
❑Narrow spectrum
Antimicrobial agents that are active against a single species or
a limited group of pathogens. Preferred if the specific
causative pathogen of an infection is known and non-
serious infections.
❑Broad spectrum
Antimicrobial agents that are active against a wide range of
pathogens. Preferred when the pathogen is not yet known
or multiple pathogens identified and serious infections.
 CLASSIFICATION OF AMAs
❑Chemical structure
Beta-lactams, triazoles, nucleoside/nucleotide reverse transcriptase
inhibitors, nitroimidazoles, benzimidazoles, Aminoquinolines
❑Type of action (Cidal or static)
Bacteriostatic, bactericidal, fungicidal , fungistatic, viricidal,
virostatic, vermicidal, vermifuge.
❑Type of organisms (primary active against)
Antibacterial, Antiviral, Antifungal, Antiprotozoal, Antihelminthic
 CLASSIFICATION OF AMAs
❑Sources
Fungi: penicillins, griseofulvin, Bacteria: polymyxin B,
bacitracin, colistin, Actinomyces: amphotericin B,
aminoglycosides, macrolides, tetracyclines, polyenes.
❑Mechanism/site of action
Protease inhibitors, Integrase Inhibitors, Cell wall inhibitors,
Protein synthesis inhibitors, Nucleic acid synthesis inhibitors etc.
❑Spectrum of activity
Narrow spectrum, Broad spectrum, or Extended spectrum
 PROBLEMS WITH AMAs
❑TOXICITY
❖Local toxicity
Toxicity exerted at site of administration. E.g. gastric
irritation, pain, abscess, thrombophlebitis at the site of injection.
❖Systemic toxicity
Dose related organ damage. E.g. tetracycline –discoloration
of teeth, aminoglycosides – nephrotoxicity and ototoxicity ,
chloramphenicol – grey baby syndrome etc.
 PROBLEMS WITH AMAs
❑HYPERSENTIVITY REACTION
Inappropriate or exaggerated response to an antigen or allergen.
These reactions are unpredictable and unrelated to dose. E.g.
Penicillin, Nevirapine, Clindamycin.
❑SUPERINFECTION
A new infection occur in a patient with preexisting infection due to
use of AMAs (mostly in immunocompromised patients).
Bacterial superinfection in viral respiratory disease
Infection of a chronic hepatitis B carrier with hepatitis D virus
Piperacillin-tazobactam may cause superinfection with candida
 PROBLEMS WITH AMAs
❑DRUG RESISTANCE
Unresponsiveness of a microorganism to an AMA, and is
similar to the phenomenon of drug tolerance. Two (2) types
Natural/Intrinsic resistance: Some microbes have resistant to
certain AMAs. E.g. gram negative bacilli not affected by
penicillin G; M. tuberculosis insensitive to tetracyclines.
Acquired resistance: Development of resistance
genes/mechanisms by microorganisms due exposure to AMAs.
 SELECTION OF AMAs
❑PATIENT-PATHOGEN-DRUG RELATIONSHIP
Pharmacokinetics – patient effect on drug
Pharmacodynamics – drug effect on patient
Immunity – patient effect on pathogen
Sepsis – pathogen effect on patient
Selective toxicity – drug effect on pathogen
Resistance – pathogen effect on drug
 SELECTION OF AMAs
❑PATIENT RELATED FACTORS
Patient age – avoid certain AMAs (tetracycline in children)
Renal and hepatic function – aminoglycoside- caution in renal
failure; erythromycin, tetracycline – caution in liver failure
History of drug allergy – Syphilis patient allergic to penicillin,
use tetracycline – Fluoroquinolones cause erythema multiform
Patient immunity – limit use of broad spectrum AMAs
Pregnancy – caution/contraindication of certain AMAs
Genetic factors – G6PD-deficiency and sulfonamides
 SELECTION OF AMAs
❑DRUG RELATED FACTORS
Type of activity – systemic vs non-systemic
Spectrum of activity – Narrow vs broad spectrum
Sensitivity of the organism – MIC, MBC
Pharmacodynamic profile – Side effects/Adverse effects
Pharmacokinetic profile – ADME
Route of administration – enteral, parenteral, topical
Cost – cost effectiveness
 SELECTION OF AMAs
❑PATHOGEN RELATED FACTORS
A clinical diagnosis
Empirical choice of AMAs selected
Specific choice of AMAs to be based on microbial
examination (Antimicrobial Susceptibility Testing)
 COMBINATION OF AMAs
❑AMAs may be combined for the ff reasons:
To prevent resistance – combined antiretroviral agents,
Amoxicillin/Clavulanic acid.
To achieve synergism – Rifampin+ isoniazid for M.
tuberculosis
To broaden the spectrum of antimicrobial action
(Cotrimoxazole: Trimethoprim/sulfamethoxazole)
To reduce toxicity – Amphotericin B + rifampin (rifampin
enhance the antifungal activity of amphotericin B).
 FAIULRE OF AMAs
❑Common causes of AMAs failure include
Improper selection of AMAs, and dosage
Treatment begun too late
Failure to take necessary precaution measures
Poor immunity
Trying to treat untreatable (viral) infections
Presence of dormant or altered organisms which later give risk
to a relapse.
ANTIBACTERIAL AGENTS

MATTHEW AIDOO
Department of Phar macolog y & Toxicolog y
School of Pharmacy and Phar maceutical Sciences
University for Development Studies, Tamale
 OUTLINE
❑STRUCTURE OF BACTERIAL CELL
❑BIOCHEMICAL REACTIONS OF BACTERIA
❑TARGETS OF ACTION OF ANTIBACTERIAL AGENTS
▪FOLATE SYNTHESIS
▪CELL WALL SYNTHESIS
▪PROTEIN STNTHESIS
▪NUCLEIC ACID SYNTHESIS
▪FORMED CELL
 STRUCTURE OF BACTERIAL CELL
❑Bacteria are prokaryotes (cells without nuclei)
❖Cell wall – all contain peptidoglycan (except mycoplasma).
Protects the cell membrane from damage. Supports cell
membrane to resist high internal osmotic pressure.
❖Cell membrane – Functions as selectively permeable
membrane with specific transport mechanisms for various
nutrients.
❖Cytoplasm – contains macromolecules, ribosomes,
chromosome (DNA). Protein synthesis, and energy generation
takes place here.
 STRUCTURE OF BACTERIAL CELL
❖ Outer membrane
outside the cell wall in
gram-negative bacteria
is the outer membrane.
It prevents penetration
of some antibacterial
agents and easy access of
lysozyme to the cell wall.
Gram-positive bacteria
do not have OM.
 BIOCHEMICAL REACTIONS
A. Class I – utilization of glucose or alternative carbon source
for generation of energy (ATP) and simple carbon
compounds.
B. Class II – utilization of energy (ATP) and simple carbon
compounds to produce small molecules e.g. folate, amino
aids, nucleotides, phospholipids, carbohydrates etc.
C. Class III – assembly of small molecules into
macromolecules e.g. proteins, nuclei acids (RNA, and
DNA, peptidoglycan etc.
TARGETS OF ACTION
 FOLATE SYNTHESIS INHIBITORS
❑Bacteria synthesize folate
(tetrahydrofolate) from
paraaminobenzoic acid
(PABA) and pteridine.
Tetrahydrofolate is used as
precursor for purine and
DNA synthesis
 FOLATE SYNTHESIS INHIBITORS
❑SULFONAMIDES
Contain sulfanilamide; a
structural analogue of PABA,
which compete with PABA
for the enzyme involved in
folate synthesis.
 FOLATE SYNTHESIS INHIBITORS
❑SULFONAMIDES (Bacteriostatic)
E.g. Sulfamethoxazole, Sulphisoxazole
Use during pregnancy only if potential benefit justifies
potential risk to fetus (neural tube defects, oral clefts, club foot)
Avoid breastfeeding during therapy due to potential risk of
bilirubin displacement and kernicterus on breastfed child
Avoid in G6PD deficient patients, sulfonamide group can act
as oxidant and induce oxidative stress causing hemolytic
anemia in patients with G6PD deficiency.
 FOLATE SYNTHESIS INHIBITORS
❑SULFONAMIDES (Bacteriostatic)
Hypersentivity reactions e.g. Stevens-Johnson syndrome, toxic
epidermal necrolysis [due to arylamine group at N4]
Bone marrow suppression; anemia, leukopenia,
thrombocytopenia (caution in aplastic anemia, SCD)
Crystalluria (the acetylated metabolite can precipitate at neutral
or acidic pH in urine causing crystalluria); take enough water to
avoid crystalluria.
 FOLATE SYNTHESIS INHIBITORS
❑TRIMETHOPRIM
For the Bacteria to utilized
folate, dihydrofolate has to
converted to tetrahydrofolate
(active form) by
dihydrofolate reductase
enzymes.
Trimethoprim inhibits
dihydrofolate reductase to
prevent synthesis of
tetrahydrofolate.
 FOLATE SYNTHESIS INHIBITORS
❑TRIMETHOPRIM (bacteriostatic)
It causes folate deficiency with resultant megaloblastic
anemia – can be prevented by giving Folinic acid.
Trimethoprim and Sulfonamide are both bacteriostatic.
Trimethoprim + Sulfamethoxazole (Co-trimoxazole) is
thought to be synergistic and may be bactericidal in
certain cellular conditions.
 CELL WALL SYNTHESIS
❑CELL WALL SYNTHESIS
Peptidoglycan constitutes the cell wall of the bacteria.
Gram-negative organisms have a single thickness whilst gram-
positive organisms have up to 40 layers thick.
Each layer consists of backbones of amino sugars, alternating:
N-acetylglucosamine and N-acetylmuramic acid residue.
N-acetylmuramic acid residue have short peptide side-chains
that are cross-linked to form a polymeric lattice, which is
strong enough to resist the high internal osmotic pressure.
CELL WALL SYNTHESIS INHIBITION
❑Synthesis of
peptidoglycan is a
vulnerable step and
can be blocked at
several points by
antibacterial agents.
Drugs that inhibit
cell wall synthesis
are bactericidal
agents
CELL WALL SYNTHESIS INHIBITION
❑GLYCOPEPTIDES (Vancomycin, Teicoplanin)
Inhibits cell-wall synthesis by blocking glycopeptide
polymerization.
 CELL WALL SYNTHESIS INHIBITORS
❑GLYCOPEPTIDES (Vancomycin, Teicoplanin)
❖VANCOMYCIN
Used for pseudomembranous colitis, clostridium difficile-
associated diarrhea, infective endocarditis, septicemia.
Renally excreted (IV; 80–90% as unchanged drug) and oral
primarily excreted in faeces.
Dose reduction and monitoring of serum levels in renal
impairment especially with IV.
It is excreted in human milk, use with caution in lactation.
CELL WALL SYNTHESIS INHIBITION
❑BETA-LACTAMs
Inhibit the final transpeptidation that establishes the cross-
links of peptidoglycan by forming covalent bonds with
penicillin-binding proteins (PBP) via binding to the
transpeptidase active site of PBP.
This prevents cross-linking (i.e. binding between
pentaglycine peptides and tetra-peptide side chains on
NAM).
E.g. Penicillins, Cephalosporins, Monobactams,
Carbapenems
CELL WALL SYNTHESIS INHIBITORS
CELL WALL SYNTHESIS INHIBITORS
CELL WALL SYNTHESIS INHIBITORS
❑PENICILLINS
Diffuse well into body tissues and fluids but penetration into
CNS is poor except when the meninges are inflamed
Dose reduction may be essential in renal impairment – most
penicillins primarily excreted renally.
The most important side effect is hypersentivity reaction
which causes rashes (non-severe) and anaphylaxis (severe life
threatening). Penicillin skin test may be necessary.
Treatment of hypersentivity reaction include antihistamines, or
adrenaline, or corticosteroids.
CELL WALL SYNTHESIS INHIBITORS
❑PENICILLINS
Penicillins should not be given by intrathecal injection
because they can cause encephalopathy.
Penicillins can cause accumulation of electrolytes
Some injectable penicillins contains sodium salts (caution in
hypertensive patients)
Some injectable penicillins contains potassium salts (caution in
patients with hyperkalemia).
 CLASSIFICATION OF PENICILLINS
❑NATURAL PENICILLINS
These penicillins are most active against non-beta lactamase
gram-positive bacteria and Enterococcus species.
Examples
❖Benzylpenicilin [penicillin G] (benzathine and procaine
penicillin) – inactivated by gastric acid and absorption from the
gut is low, therefore it is given by injection.
❖Phenoxymethylpenicillin [penicillin V]– it is gastric acid
stable, thus given orally. Has same activity as benzylpenicilin.
 CLASSIFICATION OF PENICILLINS
❑PENICILLINASE SUSCEPTIBLE PENICILLINS
Staphylococcus sp, Bacteroides sp, Neisseria gonorrhea, Moraxella
catarrhalis and Heamophilus sp, produce penicillinase enzymes
that hydrolyze beta-lactam rings.
These penicillins are inactivated by the bacterial beta-
lactamases (penicillinase)
E.g. Benzylpenicilin , Phenoxymethylpenicillin,
Amoxicillin, Ticarcillin, and Piperacillin.
 CLASSIFICATION OF PENICILLINS
❑PENICILLINASE RESISTANT PENICILLINS
These penicillins are not inactivated by beta-lactamases
bacteria
E.g. ampicillin, flucloxacillin, cloxacillin, dicloxacillin,
[methicillin, and nafcillin, oxacillin – resistant to
enterococci).
Clavulanic acid, Tazobactam and Sulbactam (active
against beta-lactamases)
Avibactam, Vaborbactam, and Relebactam (active
against carbapenemase)
 CLASSIFICATION OF PENICILLINS
❑AMINOPENICILLINS
These penicillins have broad spectrum activity (gram positive
and negative) and some enterobcteriaceaes.
❖Ampicillin – absorption is decreased by the presence of
food in the stomach.
❖Amoxicillin – a derivative of ampicillin and better absorbed
orally, absorption not affected by presence of food in the
stomach
 CLASSIFICATION OF PENICILLINS
❑ANTIPSEUDOMONAL PENICILLINS
These penicillins are active against pseudomonas aeruginosa.
They are administered only parenterally.
❖Carboxypenicillins (e.g. Ticarcillin) – only available as
Ticarcillin + Clavulanic acid (active against beta-lactamases)
❖Ureidopenicillins (Piperacillin, Mezlocillin, Azlocillin) –
Piperacillin + Tazobactam. Piperacillin is more active than
ticarcillin against pseudomonas aeruginosa.
 CEPHALOSPORINS
❑Broad spectrum with similar activity to penicillins
Principally excreted renally, thus dose modification is required
in renal impairment.
Cephalosporins penetrate the CNS poorly unless inflamed
(exception; Cefotaxime)
Cephalosporins most active against pseudomonas aeruginosa;
Ceftazidime, Cefoperazone, Ceftriaxone, Cefepime.
Principal SE is hypersentivity reactions, and about 3% of
penicillin-sensitive patients will also be allergic to CPS.
 CEPHALOSPORINS CLASSFICATION
CLASS 1ST GEN 2ND GEN 3RD GEN 4TH GEN 5TH GEN
Gram+ +++ ++ + +++ ++++
bacteria
Gram- + +++ ++++ ++++ ++++
bacteria
E.g. Cefazolin Cefuroxime Ceftriaxone Cefepime Ceftaroline
Cephalothin Cefprozil Ceftazidime (Not active
Cephapirin Cefaclor Cefotaxime against
Cephradine Cefpodoxime P. aeruginosa)
Cephalexin Cefmetazole Cefixime Active against
Cefadroxil Cefoxitin Ceftibuten MRSA
Cefotetan Cefoperazone
 CEPHALOSPORINS
❑CEFTRIAXONE
Avoid in premature neonates and in neonatal jaundice –
ceftriaxone can displace bilirubin from albumin-binding sites,
causing hyperbilirunemia in premature neonates.
Use with caution in breastfeeding women – ceftriaxone
can displace bilirubin from albumin-binding sites, increasing
risk of kernicterus in the baby.
Do not give ceftriaxone concurrently with calcium
containing products (e.g. ringers lactate) – risk of calcium-
ceftriaxone precipitant formation in the lungs, and kidneys of
term and preterm neonates.
 CARBAPENEMS
❑Broad spectrum agents with activity against anaerobes
They are NOT active against MRSA
Some may NOT be effective against gram-negative
bacteria like enterococcus faecium, klebsiella
pneumoniae, pseudomonas aeruginosa because these
produce different class of beta-lactamases called
carbapenemases.
Imipenem-Cilastatin-Relebactam
Meropenem-Vaborbactam
 CARBAPENEMS
❑IMIPENEM
It is partially inactivated in the kidney by enzymatic
activity (dihydropeptidase)
It is therefore administered with Cilastatin (a specific
inhibitor of dihydropeptidase) and thus blocks renal
inactivation of Imipenem.
Neurotoxicity has been observed at very high dosage, in renal
failure or in patients with CNS disease
 CARBAPENEMS
❑MEROPENEM
It is similar to Imipenem in activity
It is stable to renal enzyme which inactivates imipenem
and can thus be given without Cilastatin.
It has less seizure-inducing potential and can be used for
CNS infections
 CARBAPENEMS
❑DORIPENEM
Similar in activity to Imipenem and Meropenem
It also stable to renal enzymatic inactivation.
Active against pseudomonas aeruginosa.
❑ERTAPENEM
It also stable to renal enzymatic inactivation.
It is not active against P. aeruginosa unlike meropenem
and imipenem.
 MONOBACTAM
❑AZTREONAM
Monocyclic beta-lactam (monobactam) with activity
against gram-negative aerobic bacteria e.g.
P. aeruginosa, N. meningitides and H. influenza.
It is a narrow-spectrum antibacterial agent
It should not be used alone for blind treatment because it
is not active against gram-positive and anerobic bacteria.
Aztreonam binds poorly to PBP sites of gram-positive
and anerobic bacteria and thus has relatively poor
inhibitory effects against them.
 PROTEIN SYNTHESIS
❑Protein synthesis is an essential requirement of any cell.
In eukaryotes, protein synthesis occurs with the 40S (Svedberg)
and 60S subunits.
In prokaryotes, such as bacteria, protein synthesis occurs in 30S
and 50S ribosomal subunits.
The differences in the ribosomes in prokaryotes (70S) and
eukaryotes (80S), provides the basis for selective toxicity.
The ribosome [50S subunit] has three binding site for tRNA;
the A (aminoacyl), P (peptidyl) and E (exit), and [30S subunit]
has a binding site for mRNA.
PROTEIN SYNTHESIS
 PROTEIN SYNTHESIS INHIBITION
❑TETRACYCLINES
(bacteriostatic)
Binds to the 30S RSU, and
possibly 50S RSU.
They compete with tRNA for
the A site of the ribosome.
E.g. Tetracycline,
Oxytetracycline, Demecycline,
Doxycycline, Minocycline,
Methacycline, Demeclocycline,
Tigecycline, Eravacycline.
 PROTEIN SYNTHESIS INHIBITORS
❑TETRACYCLINES (bacteriostatic)
Absorption of tetracyclines are impaired by food in the gut.
Except minocycline and doxycycline.
Antacids, aluminum, calcium, iron, magnesium, zinc salts and
milk decrease absorption of tetracyclines.
Deposition in growing bones (reversible inhibition of
bone growth) and teeth (permanent discoloration and
dental hypoplasia) by binding to calcium.
Thus, tetracyclines should not be given to children below
12 years, pregnant woman and breastfeeding women.
 PROTEIN SYNTHESIS INHIBITION
❑TETRACYCLINES (bacteriostatic)
These tetracyclines should be used with caution in
patients with hepatic impairment: (Minocycline,
Doxycycline, Tigecycline, and Eravacycline). Primarily
eliminated hepatically (in bile; feces).
These tetracyclines should be used with caution in
patients with renal impairment: (Minocycline,
Tetracycline, Oxytetracycline, Methacycline,
Demeclocycline). Primarily eliminated renally
 PROTEIN SYNTHESIS INHIBITION
❑AMINOGLYCOSIDES (Bactericidal)
Binding to the 30S ribosomal subunit, distorting its
structure and causing misreading of mRNA.
Their penetration into bacteria cell membrane, depends
partly on an oxygen-dependent active transport by a
carrier system and thus have minimal action against
anaerobic organisms.
Their transport into cell membrane is blocked by
Chloramphenicol and enhanced by agents that
interfere with cell wall synthesis (Beta-lactams).
 PROTEIN SYNTHESIS INHIBITION
❑E.g.
Gentamicin,
Amikacin,
Neomycin,
Streptomycin,
Tobramycin,
Netilmicin.
 PROTEIN SYNTHESIS INHIBITION
❑AMINOGLYCOSIDES
They are highly polar cations and therefore poorly
absorbed from the GIT, thus given parenterally for
systemic therapy.
They should preferably not be given concurrently with
ototoxic diuretic (e.g. furosemide) if not possible separate
dosing by a practicable long period.
Aminoglycosides have require serum monitoring to avoid
supra or sub therapeutic levels especially in renal disease.
 PROTEIN SYNTHESIS INHIBITORS
❑AMINOGLYCOSIDES
Excretion is principally by the kidney and accumulation
occurs in renal impairment, hence dose reduction in renal
impairment and elderly patients
The important side effects are ototoxicity and
nephrotoxicity; they occur commonly in the elderly and in
patients with renal failure.
Nephrotoxicity and ototoxicity are dose and duration
dependent.
Paralysis may occur when given concurrently with NMBA
PROTEIN SYNTHESIS INHIBITION
❑MACROLIDES (bacteriostatic/bactericidal)
Bind to the 50S ribosomal subunit
This blocks the transfer of peptidyl tRNA from the A-site
to the P-site of the ribosome, thus preventing the
elongation of the polypeptide chain.
The binding site of macrolides is the same as
Chloramphenicol and Clindamycin and thus these agents
could compete if given concurrently.
PROTEIN SYNTHESIS INHIBITION
❑MACROLIDES
Erythromycin,
Azithromycin,
Clarithromycin,
Roxithromycin
Spectinomycin
PROTEIN SYNTHESIS INHIBITION
❑MACROLIDES
Macrolides should not be given concurrently with
Chloramphenicol and Clindamycin – these agents bind to
the same site (50S ribosomal subunit of bacteria).
Caution in hepatic disease – hepatic dysfunction or
cholestatic jaundice associated with use of macrolides.
Avoid in patients with cardiac arrhythmias – prolongs
cardiac repolarization and QT interval.
Clostridium difficile associated diarrhea (CDAD) has been
reported with macrolides.
 PROTEIN SYNTHESIS INHIBITORS
❑MACROLIDES
Azithromycin and clarithromycin more acid stable, and
erythromycin is acid labile.
Concurrent use with ergotamine or dihydroergotamine can
cause vasospasm and ischemia of extremities and CNS
symptoms (i.e. Ergotism)
Erythromycin, and Clarithromycin are enzyme inhibitors
and increases serum levels of drugs that are metabolized
by CYP3A4 (e.g. simvastatin, colchicine, benzodiazepines)
INHIBITION OF PROTEIN SYNTHESIS
❑CHLORAMPHENICOL (Bacteriostatic)
It is primarily bacteriostatic but can be bactericidal in
high concentrations against some bacteria.
Binding to the 50S subunit of the bacterial ribosome
It inhibits the action of peptidyl transferase, thus
preventing transpeptidation (i.e. transfer of peptide chain
from peptidyl tRNA to aminoacyl tRNA)
 PROTEIN SYNTHESIS INHIBITORS
❑CHLORAMPHENICOL (Bacteriostatic)
Serious and fetal blood dyscrasias, (including aplastic anemia,
thrombocytopenia, and granulocytopenia).
Grey baby syndrome in premature neonates – due to under-
developed UDP-glucuronyl transferase enzyme to metabolize
excessive drug levels for excretion (serum levels > 50 mcg/mL
after repeated dose).
Furthermore, there is insufficient renal excretion of the
unconjugated chloramphenicol.
Avoid chloramphenicol in lactation or do not nurse
Use with caution in pregnancy, and premature neonates.
 PROTEIN SYNTHESIS INHIBITION
❑LINCOSAMIDES (Clindamycin)
Binding to the 50S subunit (23S RNA) of the bacterial
ribosome.
It prevents peptide formation (translation of amino acids
to longer chain) thereby inhibits protein synthesis.
Bacteriostatic or bactericidal depending on the drug
concentration, organism and infection site.
Active against gram positive organisms, anerobic organism and
minimal effect on gram-negative organisms.
 PROTEIN SYNTHESIS INHIBITION
❑LINCOSAMIDES (Clindamycin)
 PROTEIN SYNTHESIS INHIBITORS
❑LINCOSAMIDES (Clindamycin)
Poor penetration into cerebrospinal fluid and thus should not
be used for CNS infections (meningitis)
Clindamycin has good penetration into joints and bones,
and it is thus use for infections at these sites.
Use with caution in hepatic impairment, monitor for
hepatic abnormalities.
Severe skin reaction including toxic epidermal necrolysis, and
Stevens-Johnson syndrome can occur. Discontinue drug
permanently if reactions occurs.
 PROTEIN SYNTHESIS INHIBITION
❑STREPTOGRAMINS (Quinupristin/Dalfopristin )
They are two types of chemically different compounds,
group A (Dalfopristin) and group B (Quinupristin).
Individually they exhibit only very modest bacteriostatic
activity but their combination offer bactericidal effect.
Dalfopristin changes the structure of the ribosome so as
to promote the binding of Quinupristin.
The combination is effective against MRSA and
vancomycin-resistant enterococcus faecium.
 PROTEIN SYNTHESIS INHIBITION
❑STREPTOGRAMINS (Quinupristin/Dalfopristin )
Binds sequentially to the 50S ribosomal subunit.
They block the translation of mRNA into protein.
Both group A and group B bind to peptidyl-transferase
domain of the bacterial ribosome.
Group A streptogramin inhibits the elongation of the
polypeptide chain.
Group B streptogramin stimulates the dissociation of
peptidyl-tRNA from the ribosome.
 PROTEIN SYNTHESIS INHIBITION
❑LINEZOLID (OXALIZIDONONES)
Binds to 50S ribosomal subunit.
They block the translation of mRNA into protein.
Useful for methicillin-resistant satph. aureus, penicillin-
resistant streptococcus pneumonia, and vancomycin
resistant enterococci.
 PROTEIN SYNTHESIS INHIBITION
❑FUSIDIC ACID (Bactericidal)
It bind to the 50s RSU similar to the macrolides
It inhibits translocation
It is narrow spectrum mostly against gram-positive
bacteria (e.g. staphylococcus)
It is well absorbed from the gut and distributed widely in
the tissues
 NUCLEIC ACID SYNTHESIS
❑It is possible to interfere with nucleic acid synthesis in the
following ways;
▪Inhibiting the synthesis of the nucleotides (e.g. fluorouracil,
mercaptopurine)
▪Altering the base-pairing properties of the template (e.g.
acriflavin)
▪Inhibiting DNA or RNA polymerase (e.g. dactinomycin,
rifampicin)
▪Inhibiting topoisomerases (e.g. fluoroquinolones)
▪Direct effects on DNA itself (e.g. mitomycin)
 NA SYNTHESIS INHIBITION
❑QUINOLONES (Bactericidal)
It blocks bacterial DNA synthesis by inhibiting bacterial
topoisomerase II (DNA gyrase) and topoisomerase IV.
Inhibition of DNA gyrase prevents relaxation of
supercoiled DNA that is required for normal
transcription and replication.
Inhibition of topoisomerase IV probably interferes with
the separation of replicated chromosomal DNA into
respective daughter cells during cell division.
 NA SYNTHESIS INHIBITORS
❑CIPROFLOXACIN
Use with caution in patients with history of epilepsy –
decrease seizure threshold and may induce convulsions.
Caution in pediatrics – risk of tendonitis or tendon rapture.
Caution in pregnancy but contraindicated in lactation
Do not use concurrently with antacids (magnesium,
aluminum), milk, dairy products interfere with absorption of
quinolones.
Avoid in G6PD deficiency (full defect) – Ciprofloxacin and
Nalidixic acid
 NA SYNTHESIS INHIBITION
❑CIPROFLOXACIN
Phototoxicity reactions occur, Avoid excessive sunlight or UV
radiation exposure during treatment and for 48 hours after
stopping treatment.
Caution in renal impairment, dose reduction required
Prolongation of QT interval avoid concomitant use with
macrolides especially Azithromycin.
Ciprofloxacin increases the level of theophylline via inhibition
of CYP3A45 enzymes, Avoid or use alternative drug.
 QUINOLONES CLASSIFICATION
Class 1ST GEN 2ND GEN 3RD GEN 4TH GEN

Gram - + ++ +++
positive
Gram ++ , but not +++ +++ +++
negative Pseudomonas

Examples Nalidixic acid Ciprofloxacin Levofloxacin Trovofloxacin
Oxolinic acid Norfloxacin Spafloxacin
Cinoxacin Ofloxacin Moxifloxacin
Rosoxacin Enoxacin Gatifloxacin
Lomefloxacin
Pefloxacin
 NA SYNTHESIS INHIBITION
❑NITROIMIDAZOLE
The MOA involves reduction of the nitro group on these
drugs by nitroreductases produced by susceptible
organisms.
This results in the formation of a highly reactive
intermediates that disrupts the organism’s DNA.
These antimicrobial agents are only active in anaerobic
conditions because oxygen will compete with antibiotic
for electrons necessary in the nitroreductases reaction
 NA SYNTHESIS INHIBITION
❑NITROIMIDAZOLE
Effective against gram-positive or gram-negative anaerobic
bacteria, and also against Entamoeba histolytica, Giardia lamblia.
Examples
Metronidazole
Tinidazole
Secnidazole
Nimorazole
Ornidazole
 NA SYNTHESIS INHIBITION
❑METRONIDAZOLE
Contraindicated in pregnancy (causes cleft lip/palate), Except, 1st
trimester in trichomoniasis and bacterial vaginosis infection.
Caution in lactation – potential tumorigenicity in animal studies,
discontinue lactating or discontinue drug.
Contradicted – Use of alcohol during therapy or 3 days of
discontinuing therapy; use of disulfiram within past 2 weeks.
Caution in hepatic impairment, dose reduction required.
Blood dyscrasia; agranulocytosis, leukopenia, and neutropenia have
been associated with use.
 PROTEIN & NUCLEIC ACID
SYNTHESIS INHIBITION
❑NITROFURANTOIN (Bactericidal)
It inactivates bacterial proteins synthesis and other
macromolecules that may interfere with metabolism and cell
wall synthesis.
It is converted by bacterial nitroreductases to electrophilic
intermediates which inhibit the citric acid cycle as well synthesis
of protein, DNA, and RNA
It is broad spectrum. It’s use is confined to the treatment of
urinary tract infections.
Avoid in G6PD deficient patents.
FORMED STRUCTURE OF THE CELL
❑CELL MEMBRANE (bactericidal)
❖POLYMIXINS
Cationic detergents that have selective effect on bacterial cell
membranes.
They interact with the phospholipids of bacteria cell
membrane and disrupts its structure
They mostly used for antibacterial topical infection.
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