Aminoglycosides Dosing & Monitoring PDF

Summary

This document provides comprehensive information on aminoglycosides, focusing on their pharmacokinetics and dosing strategies. It explores the LADME scheme, concentration-dependent killing, and various parameters for effective treatment. The discussion includes specific details for different patient populations and situations.

Full Transcript

Objectives

• To understand the Pharmacokinetics of
aminoglycosides.
• To learn about the behaviour of various
aminoglycosides.

DOSING AND MONITORING
OF DRUG
1
LEVELS OF AMINOGLYCOSIDES

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2

LADME scheme
LADME :
Pharmacokinetic processes which follow a given
dosage regimen.
L = Liberation,
Release of the drug from its dosage form.
A = Absorption,
Movement of drug from the site of administration
to the blood circulation.
D = Distribution,
Process by which drug diffuses or is transferred
from intravascular space to extravascular space
(body tissues).

• M = Metabolism,
• Chemical conversion or transformation of
drugs into compounds which are easier to
eliminate.
• E = Excretion,
• Elimination of unchanged drug or
metabolite from the body via renal, biliary,
or pulmonary processes.
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LADME processes :
Two classes,
Drug input and
Drug output.
Input processes :
L = Liberation,
A = Absorption,

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Aminoglycosides
Output processes, or disposition of drug are:
Introduction
●Bactericidal antibiotics used in treatment of serious
gram-negative systemic infections.

D = Distribution,
M = Metabolism,
E = Excretion,

Our main focus is on IV administered drugs,
shown to be efficacious without causing
toxicity in the majority of patients.
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● Active against most strains of Staphylococcus
aureus and S. epidermidis.
● Most strains of enterococcus resistant to
aminoglycosides.
8

•In most instances, amino glycosides must be
administered by intravenous infusions.
Anaerobic bacteria are universally resistant
Aminoglycoside transport into cells is oxygen-dependent

• Gentamycin,

•Amino glycosides must be administered parenterally.

• Tobramycin

Reason:

• Amikacin.

•Absorption from gastrointestinal tract poor.
.

•Three most commonly monitored amino
glycoside antibiotics :

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●
Pharmacodynamic properties of aminoglycosides

• Exhibit significant post-antibiotic effect (PAE).

● Concentration-dependent killing
● Significant post-antibiotic effect
● Aminoglycosides eliminate bacteria quickest when
their concentration is appreciably above 10 times of MIC
for an organism;

• PAE :
• Persistent suppression of bacterial growth
following antibiotic exposure.
• Trough levels can drop below the MIC of
targeted bacteria for a sustained period
without decreasing efficacy.

● Referred to as concentration dependent activity.
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Key parameters;
1.Therapeutic serum concentration; Conventional dosing: Once daily
dosing
Gentamicin,Tobramycin
Peak:5-8mg/L
20mg/L
Trough <2mg/L
Undetectable
--------------------------------------------------------------------------------------------------Amikacin
Peak:20-30mg/L
60mg/L
Trough <10mg/L
Undetectable
--------------------------------------------------------------------------------------------------2.Volume of distribution (V)
0.25L/Kg
--------------------------------------------------------------------------------------------------3.Clearance(Cl)
Equal to Clcr
Functionally Anephric patients
0.0043L/Kg/hr
Surgically Anephric patients
0.0021L/Kg/hr
Hemodialysis
1.8L/hr
---------------------------------------------------------------------------------------------------

4.AUC24

70-100 mg. hr/L

5.T

1/2

Normal renal function
Functionally Anephric patient

2-3 hrs.
30-60 hr.

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Concentration-toxicity relationships

BIOAVAILABILITY(F):
● Very water soluble
● Poorly lipid soluble.
● Poorly absorbed when administered orally.
● Must be administered parenterally for
treatment of systemic infections.
-------------------------------------------------------------------------------15

● For gentamicin, tobramycin and netilmicin
risk of ototoxicity and nephrotoxicity
increased if trough levels consistently
exceed 2 mg/ml.
● For amikacin, trough levels consistently
greater than 10 mg/ml have been associated
with a higher risk of ototoxicity and
nephrotoxicity
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● For AG's the ideal dosing regimen would maximize
concentration,

-grickest

● The higher the concentration, the more extensive
and the faster is the degree of bactericide.

● Peak/MIC ratio : important predictor of efficacy.
● aminoglycosides eradicate bacteria best when they
achieve a Peak/MIC ratio of at least 8-10.
● Important to give a large enough dose to produce a
peak level 8 to 10 times greater than the MIC.
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Pharmacokinetics
● When given by IV infusion over 30 minutes

Follows a 3-compartment pharmacokinetic model;
Alpha (distribution),

ß (elimination), and

S

• Amount released from tissue is very small,
• Accumulates over time, contributing to AG
toxicity.

Gamma (tissue release).

● When infused over one hour :
Distribution phase usually not observed.

● Gamma phase begins approximately sixteen hours
post infusion,
● Drug that was tissue bound to various organs is
released.

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Extended-interval (or "once-daily") aminoglycoside
Dosing gained popularity in recent years.
● Pharmacodyamic properties of AG's form the basis
of EI dosing.

Although this model accurately represents the time course of AG serum
levels, it cannot be used clinically because of its complexity. Therefore,
the simpler one compartment model is widely used, and does, in fact,
accurately predict serum AG levels .

● Concentration dependent activity of AG's
demonstrates that a large dose (5mg/kg) is needed to
maximize killing.

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Volume of distribution(v):
• Persistent (post-antibiotic) effect of AG's
allows a dosing interval of 24-36 hours.

->

● 0.25L/kg ( 0.1-0.5 L/kg )

Range

↳ Average

• ● Extended interval provides a beneficial
wash out period during the gamma (tissuerelease) phase, thus decreasing the
incidence of toxicity.

● Distributes very poorly into adipose tissue.
van

● Amino glycoside V (L)= 0.25L/kg×Nona
write
↳
normal
obese, Non-excess fluid weight (kg)
+0.1(excess adipose weight (kg)+ excess third
space fluid weight (kg)

Gies

Patient kam

23

Liter

zu

obesity

elemen

es

.

24

• Pediatric patients younger than 5 years of
Childs
age
cuz
&

• Non-obese, non-excess fluid weight
Estimated as the ideal body weight and
the patient's total weight without excess
third space fluid.
• Excess third space fluid weight estimated
clinically.

• Volume of distribution of 0.5 L/kg.
• In children 1to 5 years

more
werfen

um

↳ Huss

why

• V of 0.25L/kg generally used.
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CLEARANCE (cl)
Eliminated almost entirely by the renal route.

Non-renal clearance, : 0.0021L/kg/hr or 2.5
mL/min/70kg.

Cl crfor females (ml/min)=(0.85)× (140-(Age)(Weight)
(72)scrss)
Correct estimates of creatinine clearance can only be
obtained if :

• Ignored in most patients,
• Significant in patients whose renal function is
significantly diminished.

Patient's weight represents normal ratio of muscle
mass to total body weight
Serum creatinine is at steady state.
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d

distribution

• After 5 years of age

Cl cr for males (ml/min)=(140-Age)(Weight)/(72)scrss)

more

bl

• Amino glycoside V (L)=(0.5 L/kg-{age in
years/5x 0.25})(weight in kg)

25

,

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• ICU patients :
Elimination rate

• Often hyper metabolic

AG elimination exhibits a close linear correlation
with creatinine clearance.

• Eliminate AG's more rapidly.

● Cystic fibrosis patients :

• Not possible to predict the exact effect of
disease state on drug elimination,

50% increase in elimination rate.
● A major body burn :

• Special populations require intensive
monitoring, usually on a daily basis

Increases the basal metabolic rate resulting in a
marked increase in AG elimination.
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Objectives

Elimination half life.
● Function of the volume of distribution and
clearance.

• To study the exact time to sample
aminoglycosides.
• To find the acceptable range for the
infusion period.
• To know the precautions taken during
sampling period

● Renal function varies considerably among
individuals : half life also variable
● Initial aminoglycoside dose and dosing
interval should be selected with care

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Ideal Body weight

• TIME TO SAMPLE
• Relatively short half-life

Ideal body weight for males in kg = 50+(2.3)(
Height in inches >60)

• Small but significant distribution phase.
• Correct timing of the sample collection
important.
• Samples for peak serum conc. be obtained 1
hour after the maintenance dose has been
initiated.

Ideal body weight for females in kg =
45+(2.3)( Height in inches >60)
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When sampled at a time that extends beyond
the expected peak,
• Drug infused over about 30 minutes ;
• Acceptable range for the infusion period : 20-40
minutes.

Calculate plasma concentration at the earlier
time by simply rearranging the Eq.
C =C°ekt

• If longer than 40 minutes,

Where C°: Initial plasma concentration,

• Peak concentrations should be obtained
approximately 30 minutes after the end of the
infusion to ensure that distribution is complete.

C :concentration at some time t later,
C°: = C / ekt
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• This equation used to back-extrapolate
plasma concentration to the clinical peak
which is 1 hour after the start of the
infusion.

• T= time from the measured plasma
concentration (C) to the earlier plasma
concentration (C°)

• Pharmacokinetic parameters can be
estimated using a

• One-compartment model and
• Two plasma samples in most cases.
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Conclusion

Precautions
• Proper timing of serum sampling is critical.
• Measure the peak level 15 to 30 minutes after
completion of the IV infusion to avoid the distributive
phase.
• Measure the peak level 90 minutes after an IM
injection.

• Drawing the peak too soon will result in inaccurate
analysis.
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• Aminoglycosides are poorly absorbed
when administered orally.
• Must be administered parenterally for
treatment of systemic infections.
• When given by IV infusion over 30
minutes, amino glycosides follow a 3compartment pharmacokinetic model;
alpha (distribution), ß (elimination), and
gamma (tissue release).
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