Clinical Pharmacokinetics
Part 2
Medical Pharmacology
1994
G.L. Coppoc
Overview
- Why need "pharmacokinetics" and some general principles
- Important pharmacokinetic variables
- IV Constant Infusion
- Bolus & Multi-dose Regimens
- Two Major Approaches to Pharmacokinetic Analysis (Compartment
models)
Bolus
&
Multi-Dose Regimens
Multi-Dose Regimens --
Additional Considerations
Two Major Approaches To Pharmacokinetics
- Model Dependent
- One compartment model
- Two compartment model
- Three compartment model
- etc.
- Model Independent
- Dosing rate = Clearance * Css
One Compartment Model -- Diagram
One Compartment Model -- Assumptions
- Instant mixing in body (relative to other process rates and
time of first measurement of drug concentration)
One Compartment Model -- Plot
Cp(t) = A * e-(Ke * t)
One Compartment Model -- Formula
- A = 0-time intercept of line drawn through data points
- Ke = negative slope of line
- t = time elapsed
- e = base of natural logs
- Cp(t) = Plasma drug concentration at time = "t"
Two Compartment Model -- Diagram
Two-Compartment Model Assumptions
- Instant mixing in each compartment (relative to other process
rates and frequency of measurement)
- Input and output from central compartment
Two Compartment Model -- Plot
Two Compartment Model -- Formula
Cp(t) = A * e-(a * t) + B * e-(b * t)
Multi-Dose -- Similarities to Constant Infusion
Multi-Dose Adjust -- Css(ave)
Multi-Dose -- Use Which Css??
Css(min)!
Multi-Dose Adjust -- What about the Peak?
- If peak concentration is too high, could produce toxicity
- Must be concerned about degree of oscillation in dose schedule
- If route is other than IV, the degree of oscillation will
always be less than predicted by calculation of Css(max) and (min)
Effect of Regimen on Oscillation
- If dose interval (T) = elimination half-life, then
Peak is 2x Trough!
- Increased T, increases oscillation
- Decreased T, decreases oscillation toward that of IV infusion.
- Calculation of oscillation requires ability to estimate peak
and trough at SS.
Estimation of Css(max) -- PEAK
- Css(max) = (F*D/Vd) * { 1 / [1- e(-Ke * T) ] }
- Note similarity to --
Cp(t) = Cp(0) * Accumulation factor
- Terms:
- F = Bioavailability Vd = vol distr. (L)
- D = Dose (mg) T = Dose interval (hr)
- Ke = Elimination rate (1/hr) e= base natural log
Estimating Css(min)
- First estimate Css(max) using appropriate equation
Then use old standby for predicting Cp(t), but now "t"
is defined as "T", the dose interval.
Css(min) = Css(max) * e(-ke * T)
- Similar to --
Cp(t) = Cp(0) * e(-ke * t)
Determining Dose Interval (T)
- Refer to literature recommendations
- Make "T" something easy for patient / staff to comply
with, e.g., q1d, q12h, q8h, q6h
- Keep "T" as long as possible consistent with reasonable
oscillation
- Do multiple computations of Peak and Trough with various "Doses"
and "T" to obtain appropriate regimen
- First recommendations will be close to literature values,
but after have "MEASURED" Cp from patient, may be very
different
Determining Dose Rate for Oral Dose forms, e.g., Tablets
- Using liquid dose forms has theoretical advantage of allowing
"continuously variable" dosing.
- In practice, this is true only for injections
- For oral dose forms, nearly always some step function, e.g.,
teaspoon, tablespoon, for liquids
- For tablets, manufacturers prepare range of weights appropriate
for most patients, e.g., 5 mg, 25 mg, 50 mg, 100 mg, etc.
- NOTE: In many cases, the drug is a small percentage of a tablets
weight
Sample Calculation using Theophylline for Asthmatic
- Patient
- Drug
- Pharmacokinetic data
- IV Infusion
- Oral Dosage Regimen
- Oscillation
- Loading Dose
Multi-Dose