New Mansoura University Pharmacology III-Lecture (1) PDF

Summary

This document is a lecture presentation on pharmacology III at New Mansoura University. It covers introduction to chemotherapy and cell wall inhibitors. The lecture also includes an overview of different types of antibiotics, their mechanisms of action, and adverse effects. The presentation presents specific questions to test the understanding of the students.

Full Transcript

New Mansoura University
Faculty of Pharmacy
Pharm D Program
__________________________________________________________
_________________

pharmacology-iii & Biostatistics
Introduction to Chemotherapy
&
Cell Wall Inhibitors
Lecture(1)
 Course Objectives

By the completion of this course, the student should be able to describe
mechanisms of action (pharmacodynamics), pharmacokinetics, prototypic
examples, side effects, contraindications and therapeutic applications of
diverse chemotherapeutic treatments used in infections (antibacterials,
antifungals, antivirals) and cancers (alkylating agents, antimetabolites,
antimitotics, hormonal therapies and tyrosine kinase inhibitors).
Introduction to chemotherapy Antimycobacterials

Cell wall inhibitors Antivirals

Protein synthesis inhibitors Antifungals

Qinolones Anticancer drugs

Folic acid antagonists Immunosuppressants

Urinary tract antiseptics
 Chemotherapy
Chemotherapeutic agents are intended
to eliminate foreign organisms
(antimicrobials) or abnormal (cancer)
cells (anticancer drugs) from healthy
tissues of the patient.
An essential property of all
chemotherapeutic drugs is selective
toxicity; deleterious actions directed
a ga i n s t t h e t a r g e t c e l l s w i t h o u t
comparable effects on the tissue of the
host.
 Identification of the Infecting Organism
&
Determination of Antimicrobial Susceptibility
Bacteriostatic versus Bactericidal Drugs
Minimum Inhibitory Concentration (MIC) & Minimum
Bactericidal Concentration (MBC)
 Chemotherapeutic Spectra
The clinically important bacteria have been organized into eight groups based on gram stain, morphology, and
biochemical or other characteristics.
A. Narrow-spectrum antibiotics
Chemotherapeutic agents acting only on a single or a limited group of microorganisms are said to have a
narrow spectrum. For example, isoniazid is active only against Mycobacterium tuberculosis.
B. Extended-spectrum antibiotics
Extended spectrum is the term applied to antibiotics that are modified to be effective against gram-positive
organisms and also against a significant number of gram-negative bacteria.
For example, ampicillin is considered to have an extended spectrum because it acts against gram-positive and
some gram-negative bacteria.
C. Broad-spectrum antibiotics
Drugs such as tetracycline, fluoroquinolones and carbapenems affect a wide variety of microbial species and
are referred to as broad-spectrum antibiotics.
Administration of broad-spectrum antibiotics can drastically alter the nature of the normal bacterial flora and
precipitate a superinfection.
Chemotherapeutic Spectra
 Drug Resistance
Bacteria are considered resistant to an antibiotic if the maximal level of that
antibiotic that can be tolerated by the host does not halt bacterial growth.
Some organisms are inherently resistant to an antibiotic.
For example, most gram-negative organisms are inherently resistant to
vancomycin.
However, microbial species that are normally responsive to a particular drug
may develop more virulent or resistant strains through spontaneous
mutation or acquired resistance and selection.
Some of these strains may even become resistant to more than one
antibiotic.
Drug Resistance
 Complications of Antibiotic Therapy
A. Hypersensitivity:
Hypersensitivity or immune reactions to
antimicrobial drugs or their metabolic products
frequently occur.
For example, the penicillins, despite their almost
absolute selective microbial toxicity, can cause
serious hypersensitivity problems, ranging from
urticaria (hives) to anaphylactic shock.
Some reactions may be related to the rate of infusion,
such as “Red man syndrome” seen with rapid
infusion of vancomycin.
 Complications of Antibiotic Therapy
B. Direct toxicity:
High serum levels of certain antibiotics may cause toxicity by directly affecting
cellular processes in the host.
For example, aminoglycosides can cause ototoxicity by interfering with
membrane function in the auditory hair cells.
Chloramphenicol can have a direct toxic effect on mitochondria, leading to
bone marrow suppression.
Fluoroquinolones can have effects on cartilage and tendons, and
tetracyclines have direct effects on bones.
A number of antibiotics can cause photosensitivity.
 Complications of Antibiotic Therapy
C. Superinfections:
Drug therapy, particularly with broad-spectrum antimicrobials
or combinations of agents, can lead to alterations of the normal
microbial flora of the upper respiratory, oral, intestinal, and
genitourinary tracts, permitting the overgrowth of opportunistic
organisms, especially fungi or resistant bacteria.
These infections usually require secondary treatments using
specific anti-infective agents.
 Cell Wall Inhibitors
Some antimicrobial drugs selectively interfere with
synthesis of the bacterial cell wall—a structure that
mammalian cells do not possess.
The cell wall is composed of a polymer called
peptidoglycan that consists of glycan units joined to
each other by peptide cross-links.
 Penicillins
The basic structure of penicillins consists of a core
four-membered β-lactam ring, which is attached to
a thiazolidine ring and an R side chain.
Members of this family differ from one another in
the R substituent attached to the 6-
aminopenicillanic acid residue.
The nature of this side chain affects the
antimicrobial spectrum, stability to stomach acid,
cross-hypersensitivity, and susceptibility to
bacterial degradative enzymes (β-lactamases).
 Penicillins
v Mechanism of action
Penicillins interfere with the last step of bacterial cell wall synthesis,
which is the cross-linking of adjacent peptidoglycan strands by a process
known as transpeptidation.
Since penicillins structurally resemble the terminal portion of the
peptidoglycan strand, they compete for and bind to enzymes called
penicillin-binding proteins (PBPs), which catalyze transpeptidase and
facilitate cross-linking of the cell wall.
The result is the formation of a weakened cell wall and ultimately cell
death.
For this reason, penicillins are regarded as bactericidal and work in a
time-dependent fashion.
Another mechanism; production and activation of autolysin.
 Penicillins
v Antibacterial spectrum
The antibacterial spectrum of the various penicillins is determined, in part, by their ability
to cross the bacterial peptidoglycan cell wall to reach the PBPs in the periplasmic space.
Factors determining PBP susceptibility to these antibiotics include size, charge, and
hydrophobicity of the particular β-lactam antibiotic.
In general, gram-positive microorganisms have cell walls that are easily traversed by
penicillins, and, therefore, in the absence of resistance, they are susceptible to these
drugs.
Gram-negative microorganisms have an outer lipopolysaccharide membrane
surrounding the cell wall that presents a barrier to the water-soluble penicillins.
However, gram-negative bacteria have proteins inserted in the lipopolysaccharide layer
that act as water-filled channels (called porins) to permit transmembrane entry.
Classification of Penicillins
 Penicillins
v Antibacterial spectrum
1. Natural penicillins
Penicillin G (benzylpenicillin) and penicillin V (phenoxymethylpenicillin)
are obtained from fermentations of the fungus Penicillium chrysogenum.
Penicillin G has activity against a variety of gram-positive organisms,
gram-negative organisms, and spirochetes.
The potency of penicillin G is five to ten times greater than that of
penicillin V against both Neisseria spp. and certain anaerobes.
Most streptococci are very sensitive to penicillin G, but penicillin-
resistant viridans streptococci and Streptococcus pneumoniae isolates
are emerging.
The vast majority of Staphylococcus aureus (greater than 90%) are now
penicillinase producing and therefore resistant to penicillin G.
v Antibacterial spectrum
Penicillins
1. Natural penicillins
D e s p i te w i d e s p re a d u s e a n d i n c re a s i n g
resistance in many types of bacteria, penicillin
remains the drug of choice for the treatment of
gas gangrene (Clostridium perfringens) and
syphilis (Treponema pallidum).
Penicillin V, only available in oral formulation,
has a spectrum similar to that of penicillin G,
but it is not used for treatment of severe
infections because of its limited oral
absorption.
Penicillin V is more acid stable than is penicillin
G and is the oral agent employed in the
treatment of less severe infections.
 Penicillins
v Antibacterial spectrum
2. Semisynthetic penicillins
Ampicillin and amoxicillin (also known as aminopenicillins or
extended-spectrum penicillins) are created by chemically attaching
different R groups to the 6-aminopenicillanic acid nucleus.
Addition of R groups extends the gram-negative antimicrobial
activity of aminopenicillins to include Haemophilus influenzae,
Escherichia coli, and Proteus mirabilis.
Ampicillin (with or without the addition of gentamicin) is the drug
of choice for the gram-positive bacillus Listeria monocytogenes
and susceptible enterococcal species.
These extended-spectrum agents are also widely used in the
treatment of respiratory infections.
Amoxicillin is employed prophylactically by dentists in high-risk
patients for the prevention of bacterial endocarditis.
v Antibacterial spectrum
Penicillins
2. Semisynthetic penicillins
These drugs are coformulated with β-lactamase
inhibitors, such as clavulanic acid or sulbactam, to
combat infections caused by β-lactamase–producing
organisms.
For example, without the β-lactamase inhibitor,
methicillin-sensitive Staphylococcus aureus (MSSA) is
resistant to ampicillin and amoxicillin.
Resistance in the form of plasmid-mediated
penicillinases is a major clinical problem, which limits
use of aminopenicillins with some gram-negative
organisms.
 Penicillins
v Antibacterial spectrum
3. Antistaphylococcal penicillins
Methicillin, nafcillin, oxacillin, and dicloxacillin are β-lactamase
(penicillinase)-resistant penicillins.
Their use is restricted to the treatment of infections caused by
penicillinase-producing staphylococci, including MSSA.
Methicillin-resistant Staphylococcus aureus (MRSA) is currently a
source of serious community and nosocomial (hospital-acquired)
infections and is resistant to most commercially available β-
lactam antibiotics.
The penicillinase-resistant penicillins have minimal to no activity
against gram-negative infections.
 Penicillins
v Antibacterial spectrum
4. Antipseudomonal penicillin
Piperacillin is also referred to as an
antipseudomonal penicillin because of its
activity against Pseudomonas aeruginosa.
Formulation of piperacillin with tazobactam
extends the antimicrobial spectrum to include
penicillinase-producing organisms (for
example, most Enterobacteriaceae and
Bacteroides species).
Stability of the penicillins to acid or the action of penicillinase
 Penicillins
v Resistance
Ø Survival of bacteria in the presence of β-lactam antibiotics occurs due to the following:
1. β-Lactamase production
2. Decreased permeability to the drug
– An excellent example of a pathogen lacking high permeability porins is
Pseudomonas aeruginosa.
– The presence of an efflux pump, which actively removes antibiotics from the site of
action, can also reduce the amount of intracellular drug (for example, Klebsiella
pneumoniae).
3. Altered PBPs
– Modified PBPs have a lower affinity for β-lactam antibiotics (This explains MRSA
resistance to most commercially available β-lactams).
 Penicillins
v Pharmacokinetics
1. Administration
The route of administration of a β-lactam antibiotic is determined by the stability
of the drug to gastric acid and by the severity of the infection.
2. Routes of administration
The combination of ampicillin with sulbactam, piperacillin with tazobactam, and
the antistaphylococcal penicillins nafcillin and oxacillin must be administered
intravenously (IV) or intramuscularly (IM).
Penicillin V, amoxicillin, and dicloxacillin are available only as oral preparations.
Others are effective by the oral, IV, or IM routes.
3. Depot forms
Procaine penicillin G and benzathine penicillin G (long acting; 3-4 weeks) are
administered IM and serve as depot forms.
They are slowly absorbed into the circulation and persist at low levels over a long
time period.
 Penicillins
v Pharmacokinetics
4. Absorption
The acidic environment within the intestinal tract is unfavorable for the
absorption of penicillins.
In the case of penicillin V, only one-third of an oral dose is absorbed under the
best of conditions.
Food decreases the absorption of the penicillinase-resistant penicillin dicloxacillin
because as gastric emptying time increases, the drug is destroyed by stomach
acid. Therefore, it should be taken on an empty stomach.
Conversely, amoxicillin is stable in acid and is readily absorbed from the
gastrointestinal (GI) tract.
v Pharmacokinetics
Penicillins
5. Distribution
The β-lactam antibiotics distribute well throughout the body.
All the penicillins cross the placental barrier, but none have been
shown to have teratogenic effects.
However, penetration into bone or cerebrospinal fluid (CSF) is
insufficient for therapy unless these sites are inflamed.
Note: Inflamed meninges are more permeable to the penicillins,
resulting in an increased ratio of the drug in the CSF compared to
the serum.
Penicillin levels in the prostate are insufficient to be effective
against infections.
v Pharmacokinetics
Penicillins
6. Metabolism
Host metabolism of the β-lactam antibiotics is usually insignificant, but
some metabolism of penicillin G may occur in patients with impaired renal
function.
Nafcillin and oxacillin are exceptions to the rule and are primarily
metabolized in the liver.
7. Excretion
The primary route of excretion is through the kidney.
Patients with impaired renal function must have dosage regimens adjusted.
Because nafcillin and oxacillin are primarily metabolized in the liver, they do
not require dose adjustment for renal insufficiency.
Probenecid inhibits the secretion of penicillins by competing for active
tubular secretion and, thus, can increase blood levels.
The penicillins are also excreted in breast milk.
 Penicillins
v Adverse reactions
Ø Penicillins are among the safest drugs. However, adverse reactions may occur.
1. Hypersensitivity
Approximately 10% of patients self-report allergy to penicillin.
Reactions range from rashes to angioedema (marked swelling of the lips, tongue, and periorbital area) and
anaphylaxis.
Cross-allergic reactions occur among the β-lactam antibiotics.
To determine whether treatment with a β-lactam is safe when an allergy is noted, patient history regarding
severity of previous reaction is essential.
2. Diarrhea
Diarrhea is a common problem that is caused by a disruption of the normal balance of intestinal
microorganisms.
It occurs to a greater extent with those agents that are incompletely absorbed and have an extended
antibacterial spectrum.
Pseudomembranous colitis from Clostridium difficile and other organisms may occur with penicillin use.
v Adverse reactions
Penicillins
3. Nephritis
Penicillins, particularly methicillin, have the potential to cause acute interstitial
nephritis.
Note: Methicillin is therefore no longer used clinically.
4. Neurotoxicity
The penicillins are irritating to neuronal tissue, and they can provoke seizures if
injected intrathecally or if very high blood levels are reached.
Epileptic patients are particularly at risk due to the ability of penicillins to cause
GABAergic inhibition.
5. Hematologic toxicities
Decreased coagulation may be observed with high doses of piperacillin and
nafcillin (and, to some extent, with penicillin G).
Cytopenias have been associated with therapy of greater than 2 weeks, and
therefore, blood counts should be monitored weekly for such patients.
Q1: Which of the following is the primary mechanism of action of
penicillin?

A) Inhibition of protein synthesis
B) Disruption of cell membrane function
C) Inhibition of bacterial cell wall synthesis
D) Inhibition of DNA gyrase
Q2: Which of the following bacteria is most likely to be resistant to
penicillin due to the production of beta-lactamase?

A) Staphylococcus aureus
B) Streptococcus pyogenes
C) Clostridium tetani
D) Bacillus anthracis
Q3: Penicillin G is administered primarily via which route due to its
instability in the acidic environment of the stomach?

A) Oral
B) Intramuscular
C) Subcutaneous
D) Inhalational
Q4: Which of the following adverse effects is most commonly
associated with penicillin use?

A) Hepatotoxicity
B) Nephrotoxicity
C) Hypersensitivity reactions
D) Hemolytic anemia
Q5: Which of the following types of penicillin is effective against
Pseudomonas aeruginosa?

A) Penicillin V
B) Ampicillin
C) Amoxicillin
D) Piperacillin
Q6: Which of the following penicillins is classified as a narrow-
spectrum, penicillinase-resistant antibiotic?

A) Amoxicillin
B) Methicillin
C) Ticarcillin
D) Penicillin G
Q7: Which of the following is the primary reason for combining
penicillin with a beta-lactamase inhibitor (e.g., clavulanic acid)?

A) To reduce the cost of treatment
B) To enhance absorption
C) To increase the spectrum of activity against beta-lactamase-
producing bacteria
D) To prevent gastrointestinal side effects
Q8: Which of the following is a common indication for penicillin
use?

A) Viral infections like the common cold
B) Fungal infections like candidiasis
C) Bacterial infections such as syphilis
D) Parasitic infections like malaria
Q9: What is the main reason penicillin is less effective against
gram-negative bacteria compared to gram-positive bacteria?

A) Gram-negative bacteria lack a cell wall
B) Gram-negative bacteria have an outer membrane that limits
drug entry
C) Gram-positive bacteria produce more beta-lactamase
D) Penicillin is rapidly metabolized in gram-negative bacteria
Q10: Which of the following drugs should be avoided in patients
with a known penicillin allergy due to potential cross-reactivity?

A) Cephalexin
B) Erythromycin
C) Ciprofloxacin
D) Vancomycin
thank
you