What is the one-compartment IV bolus model?
State the assumptions
The body is simplified and represented as a single box, into which the dose of the drug is deposited instantaneously.
Drug is assumed to distribute evenly and instantaneously throughout this compartment
Outline the physiological basis for compartmental models.
Important to understand ADME of a compound and it allows us to make suggestions for the next stage of drug development. (Including dose selection, frequency of administration or decisions on formulation)
Compartmental pharmacokinetic models simplify complex human physiology by describing the concentration- time course of a drug with (relatively) simple mathematical equations.
What is the relationship between drug amount, concentration, ke, Vd, and Cl in the IV bolus model?
Ke = Cl/Vd
This kind of model can be applied to a drug regardless of whether elimination occurs through hepatic metabolism or renal excretion (or any other means of elimination), provided that the elimination is a first- order process.
What is a first order elimination process
A rate of elimination that is proportional to the amount of drug that is present.
relationship between drug concentration and elimination rate is
elimination rate = cl x cp (plasma concentration)
relationship between drug concentration and elimination rate is
elimination rate = cl x cp (plasma concentration)
relationship between elimination rate and amount of drug in the body is
elimination rate = Ke x Ab
State the concentration-time equation for the one-compartment IV bolus model
C(t) = C(o)e -ket
Half life equation
t1/2 = ln(2)/ke
Derive the half-life equation
What is a one-compartment IV bolus model
The one-compartment model is a basic pharmacokinetic model that assumes the body acts as a single, homogeneous unit where the drug distributes uniformly and instantaneously.
State the assumptions of the one-compartment IV bolus model
Drug is assumed to distribute evenly and instantaneously throughout this compartment
The volume remains constant during the period under study
The compartment is assumed to receive the drug instantly at the time of the intravenous dose.
The compartment has a volume π1, which in a one-compartment model is equal to the volume of distribution (ππ) of the drug.
State the assumptions of the one-compartment IV bolus model
Instantaneous Distribution:
This single compartment is assumed to receive the drug instantly at the time of the intravenous dose.
The drug is assumed to distribute uniformly and instantaneously throughout the compartment as soon as it is administered.
First-Order Kinetics:
The absorption and elimination processes are assumed to follow first-order kinetics. This means that the rate of drug absorption into, and elimination from, the compartment is proportional to the drug concentration present at any given time. For instance, as the drug concentration decreases, the rate of elimination also decreases proportionally.
Elimination rate constant = ππ
Define the elimination rate
fraction of drug eliminated per unit time (units are therefore h1).
Define clearance
The volume of compartment cleared entirely of drug per unit time
Explain the difference between the two methods:
Cl1<rnorm(mean=9.8, sd=2, n=4000)
and
Cl2<-9.8*exp(rnorm(mean=0, sd=0.3, n=4000))
(1 mark)
rnorm function generate 4000 random clearance values from a normal distribution.
The clearance values are symmetrically distributed around the mean of 9.8.
The distribution allows for negative values, which, although not physiologically plausible for clearance, can statistically appear due to the nature of the normal distribution, especially if the mean is close to zero and the standard deviation is relatively large.
exp and rnorm
This method uses the exp function applied to normally distributed values generated by rnorm.
The clearance values are log-normally distributed, meaning that the natural logarithm of these values is normally distributed.
This approach inherently restricts clearance values to be positive, aligning with the physiological reality where negative clearance values are not possible.
Clearance values are skewed to the right, typical for biological parameters where there is a lower boundary (zero), but potentially no upper boundary, reflecting a more realistic distribution for pharmacokinetic parameters.
Explain rnorm() and exp and rnorm
rnorm function generates values from a normal distribution.
exp and rnorm generate log-normally distributed random variables from normally distributed data.
one-compartment model oral absorption concentration equation:
C = (F.D.Ka)/(Vd (ka- ke )).(e^(-Ke t)-e^(-Ka t))
Explain why true drug clearance and volume of distribution cannot be estimated from data from a pharmacokinetic study of an orally administered drug:
Estimating true drug clearance (CL) and volume of distribution (Vd) from pharmacokinetic studies of orally administered drugs is challenging due to the influence of bioavailability (F) and first-pass metabolism.
Since F is often unknown without intravenous comparison, true CL and Vd cannot be directly estimated from oral data alone. Additionally, the absorption process complicates the plasma concentration-time profiles, making it difficult to distinguish the effects of drug absorption from those of clearance and distribution.
Concentration-time equation for the two-compartment IV bolus model:
C = Ae^(-Ξ±t)+Be^(-Ξ²t)
When using drug-data, πΌ is conventionally greater than π½ with Ae^(-Ξ±t) representing drug distribution and Be^(-Ξ²t) drug elimination in the majority of cases.
State the pk parameters in the two-compartment IV bolus model
Central Compartment (C1)
Peripheral Compartment (C2)
k12: The rate constant for drug movement from the central compartment to the peripheral compartment.
k21: The rate constant for drug movement from the peripheral compartment back to the central compartment.
k10 ( replaces ke) : The elimination rate constant, representing the rate at which the drug is cleared from the central compartment.
V1: Volume of distribution of the central compartment.
V2: Volume of distribution of the peripheral compartment.
Volume of distribution in the two-compartment model
At time π‘ = 0
ππ = π1 = Dose/c0 = Dose/(A+B)
Volume of distribution steady state in the two compartment model
πππ π = π1 + π2
Inter-compartmental clearance (π)
Replaces π12 and π21 parameters.
π12π1 = π = π21π2
