Introduction To Antibiotics PDF - August 2024

Summary

This document is a lecture presentation on introduction to antibiotics, by Kathryn G. Rose. The presentation covers various aspects of antibiotics, including types, targets, and mechanisms of action, and clinical applications, from the University of Texas at Austin.

Full Transcript

AUGUST 2024

INTRODUCTION TO
ANTIBIOTICS

KATHRYN G. ROSE, PHARMD, BCPS, BCPPS, BCIDP
Adjunct Assistant Professor at the University of Texas at Austin College of Pharmacy
Division Director of Clinical Pharmacy, HCA Central West Texas (St. David’s HealthCare and Las Palmas Del Sol Healthcare)
Pre-Work Learning Objectives
1. Recognize the roles that ADME (absorption, distribution, metabolism, and
excretion) and restricted compartments play in mediating the actions of
antimicrobial drugs.
2. Describe the differences between the terms minimum inhibitory
concentration (MIC) and minimum bactericidal concentration (MBC).
3. Explain the concept of MIC breakpoint and interpret MIC breakpoint data
from clinical cases to make informed judgements about antimicrobial dosing.
4. Compare and contrast bactericidal and bacteriostatic antimicrobial agents.
5. Compare and contrast concentration dependent and concentration
independent cell killing activity.
6. Explain post-antibiotic effect.
7. List the major organisms prone to development of antimicrobial drug
resistance and the mechanisms by which they develop/acquire resistance.
In Class Learning Objectives
1. Evaluate a clinical scenario and identify relevant patient-specific factors
guiding antimicrobial drug selection.
2. Use disease-specific factors such as infecting organism and drug resistance
levels to select an appropriate antimicrobial agent.
3. Organize the antibiotics by both mechanism of action and spectrum
(Gram +, Gram -, Anaerobes).
Overview of Today’s Class
Classification of
Antibiotics
Principles of
Treatment
Antibiotic Resistance
 Eukaryotes vs. Prokaryotes
(Prokaryotes)
Unique targets
can be distinguished between
eukaryotes and prokaryotes
Helps minimize toxicity to the host

Example shown here –
Unique target = 50S & 30S ribosomes

Antibiotic mechanism of action =
Inhibit biosynthesis of proteins
 Additional Examples of Antibiotic Targets
Unique target = porin Unique target = peptidoglycan Unique target = mycolic acids

LO: Organize the antibiotics by both mechanism of action and spectrum (Gram +, Gram -, Anaerobes)
LO: Use disease-specific factors such as infecting organism and drug resistance levels to select an appropriate antimicrobial agent.
 Classification of Antibiotics by Mechanism of Action (Target)
Cell Wall B-lactams (penicillins, cephalosporins,
Synthesis carbapenems)
Inhibitors Glycopeptides (vancomycin)
Fluoroquinolones (levofloxacin)
DNA Synthesis Nitrofurantoin
Inhibitors
Metronidazole

Protein Aminoglycosides (gentamicin)
Synthesis Tetracycline (doxycycline)
Inhibitors Macrolide (azithromycin)

RNA Synthesis Rifampin
Inhibitor
Mycolic Acid
Synthesis Isoniazid
Inhibitor
Folic Acid
Synthesis Bactrim (sulfamethoxazole/trimethoprim)
Inhibitor
LO: Organize the antibiotics by both mechanism of action and spectrum (Gram +, Gram -, Anaerobes).
 Antibiotic Spectrum of Activity
Gram Positive Coverage Gram Negative Coverage Anaerobic Coverage
Clindamycin
Penicillin
Augmentin
Oxacillin, nafcillin
Clindamycin Metronidazole
Vancomycin (only anaerobes)
Piperacillin-tazobactam
Aztreonam Moxifloxacin
Aminoglycosides (gentamicin) Unasyn
Amoxicillin, ampicillin Carbapenems
Amoxicillin-clavulanate (Augmentin), ampicillin-sulbactam (Unasyn)
Piperacillin-tazobactam (Zosyn)
1st – 5 generation cephalosporins (i.e. cefazolin, ceftriaxone,
th

cefepime)
Carbapenems (meropenem)
Fluoroquinolones (levofloxacin)
Bactrim (sulfamethoxazole/trimethoprim)
Tetracycline (doxycycline)
LO: Organize the antibiotics by both mechanism of action and spectrum (Gram +, Gram -, Anaerobes).
Antibiotic Resistance
Factors contributing to the
development of antibiotic resistance
Treating viral and noninfectious
diseases with antibiotics
Treating positive cultures in
asymptomatic patients with
antibiotics
Using antibiotics when they will not
alter the patient’s clinical course
Not obtaining adequate source
control
Not selecting the shortest effective
duration of therapy
Clatworthy, A., Pierson, E. & Hung, D. Targeting virulence: a new paradigm for antimicrobial
therapy. Nat Chem Biol 3, 541–548 (2007). https://doi.org/10.1038/nchembio.2007.24
 Resistance Prone Organisms
VRE Carbapenem- MRSA
resistant (methicillin-
(vancomycin-
Acinetobacter resistant
resistant
Staphylococcus
enterococcus) spp.
aureus)

CRE MDR ESBL
(carbapenem- (multi-drug (extended-
resistant resistant spectrum
Enterobacterale Pseudomonas cephalosporin
s) aeruginosa) resistance)
CDC. COVID-19: U.S. Impact on Antimicrobial Resistance, Special Report 2022. Atlanta, GA: U.S. Department of Health and Human Services, CDC; 2022.
https://www.cdc.gov/drugresistance/covid19.html

LO: List the major organisms prone to development of antimicrobial drug resistance and the mechanisms by which they develop/acquire resistance.
 Mechanisms of Resistance
Export of drug from bacterial cell
Pumps drugs back out of cell
(promote the active efflux of
multiple classes of antibiotics)
Provides resistance to
– tetracyclines (doxycycline)
– fluoroquinolones (levofloxacin)
Example: gram negative bacteria
and tetracycline AIMS Microbiol. 2018; 4(3): 482–501. doi: 10.3934/microbiol.2018.3.482

LO: List the major organisms prone to development of antimicrobial drug resistance and the mechanisms by which they develop/acquire resistance.
 Mechanisms of Resistance
Decreased access of drug to target site
Mutation of porin proteins in outer
membrane of gram-negative cell
wall → decreased permeability
Provides resistance to
– β-lactams
– aminoglycosides
Example: Pseudomonas
aeruginosa strains resistant to many
β-lactam antibiotics AIMS Microbiol. 2018; 4(3): 482–501. doi: 10.3934/microbiol.2018.3.482

LO: List the major organisms prone to development of antimicrobial drug resistance and the mechanisms by which they develop/acquire resistance.
 Mechanisms of Resistance
Modify drug target in bacterial cell
Resistance
Modification
to
Mutation in penicillin-binding
B-lactams
proteins (PBP)
Aminoglycosid
Mutation in 30S subunit of
es
bacterial ribosome
(gentamicin)
Example: MRSA contains
Replacement of alanine with lactate mecA gene which encodes
Vancomycin
in bacterial peptidoglycan additional PBP2a
Fluoroquinolon
AIMS Microbiol. 2018; 4(3): 482–
Mutation in DNA gyrase es 501. doi: 10.3934/microbiol.2018.3.482
(levofloxacin)
LO: List the major organisms prone to development of antimicrobial drug resistance and the mechanisms by which they develop/acquire resistance.
 Mechanisms of Resistance
Inactivate the drug with a bacterial enzyme
β-lactamases cleaves β-lactam drugs
– Provides resistance to
penicillins
cephalosporins
carbapenems
Aminoglycoside modifying enzymes
Example: KPC-1 carbapenamase in
K. pneumoniae resistant to
carbapenems, broad spectrum
penicillins and cephalosporins AIMS Microbiol. 2018; 4(3): 482–501. doi: 10.3934/microbiol.2018.3.482

LO: List the major organisms prone to development of antimicrobial drug resistance and the mechanisms by which they develop/acquire resistance.
 Classification of Antibiotics by Spectrum of Activity
Narrow Extended Broad
spectrum spectrum spectrum

Act primarily G+ Intermediate Act on both G+
OR G- bacteria coverage of G+ and G- bacteria
Example: G+  and G- bacteria including multi-
penicillin, Example: drug resistant
oxacillin ceftriaxone, pathogens like
ampicillin- Pseudomonas
sulbactam aeruginosa
(Unasyn) Example:
piperacillin-
tazobactam
LO: Organize the antibiotics by both mechanism of action and spectrum (Gram +, Gram -, Anaerobes).
Introduction to Antibiotics

Pathog The right drug against the
en right pathogen must be
administered at the right dose
to be safe and effective.
Antibio
tic
Selecti
on Spectrum of activity
Antibio Pharmacokinetics
Patient
tic
Pharmacodynamics

Pai, MP, Cottrell ML, & Bertino JS. (2020). Pharmacokinetics and Pharmacodynamics of Anti-infective
Agents. In Bennett JE, Dolin R, & Blaser MJ (Eds.), Mandell, Douglas, and Bennett's Principles and
In the following patient case…
What are patient, pathogen, and
antibiotic specific factors that
should be considered to guide
antibiotic selection?
 61 year old female presents to the Emergency Department with shortness of
breath and fever that has worsened over the past 5 days.
PMH: metastatic breast cancer, hypertension, craniotomy ~2 weeks ago for
tumor removal.
HPI: per the patient, she began coughing five days ago and started to feel
worse so she took her temperature today and upon discovering she had a
fever she contacted her provider who told her to seek care immediately.
Vital Signs:
– Heart rate 112 Neuro Examination: normal
Chest X-ray: abnormal (diffuse bilateral patchy
– Blood pressure 90/54 mm Hg infiltrates)
(MAP 66) WBC 10 x 109/L
– Temperature 39.2°C SCr 0.87 mg/dL
Bilirubin: 1.8 mg/dL
– Respiratory rate 18 on room air
Lactate: 2.8 mmol/L
– Weight: 70 kg
 Patient-Specific Factors to Guide Antibiotic Selection
Severity of Illness Age

Past Medical History Weight
Presence of chronic co-
morbidities Renal and hepatic
Immunosuppression function
Previous/recent antibiotic use
Community vs. hospital onset Allergies
Site of Infection
Pregnancy &
breastfeeding
LO: Evaluate a clinical scenario and identify relevant patient-specific factors guiding antimicrobial drug selection.
 Using Pathogens to Guide Antibiotic Selection
Diagnosis of a suspected or
confirmed
Pathog microbial infection
en
Obtain tests to identify and
determine pathogen
susceptibility
Antibio
tic What pathogens are associated with
Selecti the suspected or confirmed site/source
of the microbial infection?
on
Antibio
Patient
tic Make antibiotic selection
(empiric vs. targeted) considering
patient and antibiotic factors
LO: Use disease-specific factors such as infecting organism and drug resistance levels to select an appropriate antimicrobial agent.
In the following patient case…
What are patient, pathogen, and
antibiotic specific factors that
should be considered to guide
antibiotic selection?
 61 year old female presents to the Emergency Department with shortness of
breath and fever that has worsened over the past 5 days.
PMH: metastatic breast cancer, hypertension, craniotomy ~2 weeks ago for
tumor removal.
HPI: per the patient, she began coughing five days ago and started to feel
worse so she took her temperature today and upon discovering she had a
fever she contacted her provider who told her to seek care immediately.
Vital Signs:
– Heart rate 112 Neuro Examination: normal
Chest X-ray: abnormal (diffuse bilateral patchy
– Blood pressure 90/54 mm Hg infiltrates)
(MAP 66) WBC 10 x 109/L
– Temperature 39.2°C SCr 0.87 mg/dL
Bilirubin: 1.8 mg/dL
– Respiratory rate 18 on room air
Lactate: 2.8 mmol/L
– Weight: 70 kg
 Susceptibility Testing
Laboratory methods to determine the sensitivity of the isolated
pathogen to antimicrobial drugs
Minimum inhibitory concentration (MIC)
– the lowest concentration of an antibacterial agent that inhibits
visible growth
– Whether an MIC is interpreted as susceptible depends on the
drug-bug combination and the set breakpoints
Minimum Bactericidal Concentration (MBC)
– the lowest concentration of an antibacterial agents that either
totally prevents growth or results in a >99.9% decrease in the
initial inoculum (could be at or above the MIC)
LO: Describe the differences between the terms minimum inhibitory concentration (MIC) and minimum bactericidal concentration (MBC).
LO: Use disease-specific factors such as infecting organism and drug resistance levels to select an appropriate antimicrobial agent.
LO: Describe the differences between the terms minimum inhibitory concentration (MIC) and minimum bactericidal concentration (MBC).
LO: Use disease-specific factors such as infecting organism and drug resistance levels to select an appropriate antimicrobial agent.
 MIC Breakpoints
The highest inhibitory concentration that is reached by an
antibiotic with FDA dosing
Standardized value by organism and antibiotic
Determines:
− Whether an organism will be susceptible, intermediate, or
resistant
− Likelihood of clinical success and/or microbiologic
eradication
Applies only to the immunocompetent patient whose host
defenses are able to resolve the infection
LO: Explain the concept of MIC breakpoint and interpret MIC breakpoint data from clinical cases to make informed judgements about antimicrobial dosing.
LO: Use disease-specific factors such as infecting organism and drug resistance levels to select an appropriate antimicrobial agent.
 MIC Breakpoints Example
Example: Pseudomonas aeruginosa
MIC
Interpretative Criteria Comments
S I R
Breakpoints for susceptible are based on
Piperacillin/tazobactam ≤ 16/4 32/4 ≥ 64/4 a dosage regimen of 4.5 g administered
every 6 h over 30 minutes or over 3 h.
Breakpoints are based on a dosage
Cefepime ≤8 16 ≥ 32 regimen of 1 g administered every 8 h or
2 g administered every 12 h.
Breakpoints are based on a dosage
Levofloxacin ≤1 2 ≥4 regimen of 750 mg administered every
24 h

LO: Explain the concept of MIC breakpoint and interpret MIC breakpoint data from clinical cases to make informed judgements about antimicrobial dosing.
LO: Use disease-specific factors such as infecting organism and drug resistance levels to select an appropriate antimicrobial agent.
 Application of MIC Breakpoints
AN is a 60 year old male growing Pseudomonas aeruginosa from 2
sets of blood cultures. He is currently on empiric cefepime. Based on
this susceptibility panel, do you believe you should change therapy?
ANTIBIOTIC MIC INTERPRETATION BREAKPOI DILUTIONS FROM
NT BP
PIP-TAZO 16 S 16 0
CEFEPIME 2 S 8 2
LEVOFLOXAC 1 S 1 0
IN
MEROPENEM Continue
2 S current therapy 4 1
Activity is defined by MIC relative to antibiotic-organism breakpoint
LO: Explain the concept of MIC breakpoint and interpret MIC breakpoint data from clinical cases to make informed judgements about antimicrobial dosing.
LO: Use disease-specific factors such as infecting organism and drug resistance levels to select an appropriate antimicrobial agent.
Antibiotic-Specific Factors to Guide Antibiotic Selection

Pathog The right drug against the
en
right pathogen must be
administered at the right dose
Antibio
to be safe and effective.
tic
Selecti
on Spectrum of activity
Antibio
Patient
tic Pharmacokinetics
Pharmacodynamics
Pai, MP, Cottrell ML, & Bertino JS. (2020). Pharmacokinetics and Pharmacodynamics of Anti-infective
Agents. In Bennett JE, Dolin R, & Blaser MJ (Eds.), Mandell, Douglas, and Bennett's Principles and
 Pharmacokinetics
Describes the process by which a drug enters and leaves the body
General goal is to ensure that the antibiotic can reach the site of
action and persist until the infection is resolved

Absorptio Distributi Metabolis Eliminatio
n on m n
Bioavailability Transfer of drug Enzymes in liver Renal clearance
% of a drug’s dose from systemic
that reaches circulation into
systemic circulation tissue or site of
action (infection)
LO: Recognize the roles that ADME (absorption, distribution, metabolism, and excretion) and restricted compartments play in mediating the actions of
antimicrobial drugs.
 Pharmacodynamics

Concentrati Concentrati
Dosage Biological
on in on at
Regimen Effect
Serum Infection

Pharmacodynamic
s
Pharmacokine The drug’s impact
tics on the body
LO: Recognize the roles that ADME (absorption, distribution, metabolism, and excretion) and restricted compartments play in mediating the actions of
antimicrobial drugs. (efficacy & toxicity)
 Bactericidal vs. Bacteriostatic Antibiotics
Mechanism of action: general goal is to eradicate or slow the growth
of bacteria without harming the host

Bactericidal Bacteriostatic
 Kill more than  Prevent growth of
99.9% of bacteria bacteria, keeping
them in the stationary
 Examples: B-lactams phase of growth
(i.e. penicillin, cefazolin,
meropenem)  Examples: clindamycin,
azithromycin
Overall, there is no evidence that cidal antibiotics are
intrinsically more clinically effective than static antibiotics
LO: Compare and contrast bactericidal and bacteriostatic antimicrobial agents.
 Pharmacodynamic Indices
Pharmacodynamics
combines pharmacokinetics
parameters and
microbiology parameters to
describe drug effect in
relation to some measure of
exposure
– Cmax / MIC
– AUC / MIC
– TIME / MIC

Pai, MP, Cottrell ML, & Bertino JS. (2020). Pharmacokinetics and Pharmacodynamics of Anti-infective
Agents. In Bennett JE, Dolin R, & Blaser MJ (Eds.), Mandell, Douglas, and Bennett's Principles and
Practice of Infectious Diseases. Elsevier Inc.
LO: Compare and contrast concentration dependent and concentration independent cell killing activity.
 Concentration Dependent Activity (Cmax / MIC)
Described in relation to MIC
(i.e., 4 X MIC, 10 X MIC)
↑ the concentrations result in improved
bacterial activity (increased killing)
Post antibiotic effect (PAE)
–Growth inhibition continues for a
variable period after the concentration
at the site of the bacteria has
decreased below the MIC for the Example antibiotics: fluoroquinolones
(levofloxacin), aminoglycosides
antimicrobial agent. (gentamicin), metronidazole, daptomycin
LO: Compare and contrast concentration dependent and concentration independent cell killing activity.
 Post-antibiotic Effect Proposed Mechanisms
1. Slow recovery of bacteria after
non-lethal damage to cell
structures
2. Persistence of the antibiotic at
its binding site (e.g.
aminoglycosides bind
irreversibly to ribosomes).
3. A need for bacteria to
synthesize new proteins before
growth can continue

LO: Explain post-antibiotic effect.
 Time Dependent (concentration independent) Activity
(TIME / MIC)
Maintaining steady serum levels above MIC over
time results in maximum killing
time that free (unbound) drug above MIC of
infecting pathogen results in bacterial activity
Effect often saturates 4-5 X MIC
More ≠ better
Desired percentage of time above the MIC for
bacterio-STATIC and –CIDAL killing
-STATIC -CIDAL
Penicillins 30% 50%
Example antibiotics: penicillins,
Cephalosporins 35-40% 60-70%
cephalosporins (cefepime),
Carbapenems 20% 40%
carbapenems (meropenem)
LO: Compare and contrast concentration dependent and concentration independent cell killing activity.
Patient Case
What are patient, pathogen, and
antibiotic specific factors that
should be considered to guide
antibiotic selection?
 61 year old female presents to the Emergency Department with shortness of
breath and fever that has worsened over the past 5 days.
PMH: metastatic breast cancer, hypertension, craniotomy ~2 weeks ago for
tumor removal.
HPI: per the patient, she began coughing five days ago and started to feel
worse so she took her temperature today and upon discovering she had a
fever she contacted her provider who told her to seek care immediately.
Vital Signs:
– Heart rate 112 Neuro Examination: normal
Chest X-ray: abnormal (diffuse bilateral patchy
– Blood pressure 90/54 mm Hg infiltrates)
(MAP 66) WBC 10 x 109/L
– Temperature 39.2°C SCr 0.87 mg/dL
Bilirubin: 1.8 mg/dL
– Respiratory rate 18 on room air
Lactate: 2.8 mmol/L
– Weight: 70 kg
AUGUST 2024

INTRODUCTION TO
ANTIBIOTICS

KATHRYN G. ROSE, PHARMD, BCPS, BCPPS, BCIDP
Adjunct Assistant Professor at the University of Texas at Austin College of Pharmacy
Division Director of Clinical Pharmacy, HCA Central West Texas (St. David’s HealthCare and Las Palmas Del Sol Healthcare)