FTK 4: Pharmacokinetics Terms

Question 1

ADME?

Answer 1

A = absorption, BIOAVAILABILITY (how much of the drug reaches systemic circulation)

D = distribution, how much of the drug from the VASCULATURE gets into TARGET TISSUE

M = metabolism, the BIOTRANSFORMATION of a drug into metabolites, often done by the liver

E = elimination, REMOVAL of drug from the body, often done by the kidney

Question 1

2 main routes of administration, 6 sub-categories for second one & drug administration

Answer 1

1. INTRAVENOUS (IV)
2. EXTRAVASCULAR
   - IM
   - PO
   - RECTALLY
   - INTRATHECAL
   - TRANSDERMAL
   - INHALATION
   ** MUST BE ABSORBED before we can do DISTRIBUTION, METABOLISM, & ELIMINATION OF DRUGS

Question 2

volume of distribution
basic definition?
how is it measured?
formula?
what does it mean to have a SMALL Vd/what kinds of drugs have this?
what does it mean to have a LARGE Vd/what kinds of drugs have this?

Answer 2

= Parameter that describes how widely drug distributes within an APPARENT volume

Measured based on DOSE it was given and the plasma concentration we’re measuring

Vd = dose / plasma concentration

SMALL Vd = HIGH plasma concentration, drug is SEQUESTERED in plasma and doesn’t exit to tissues
HYDROPHILIC, ACIDIC, LARGE

LARGE Vd = LOW plasma concentration, drug DOES NOT STAY IN PLASMA LONG & goes to TARGET TISSUE
HYDROPHOBIC, BASIC, SMALL

Question 3

half life, Vd, and Cl relationship & what it means
formula?

Answer 3

HIGHER HALF LIFE = HIGHER VD, LOWER CL

The longer a drug remains in plasma, the higher distribution it will participate in and lower amount of time for it to be cleared by the body (eliminated)

T1/2 = 0.693 x Vd (L) / Cl (body, L/min)

Question 4

2 factors that affect drug ABSORPTION and 4 that affect drug ADME

Answer 4

ABSORPTION?
1. SURFACE AREA (GI/SKIN)
2. ENZYMES (acting locally PRIOR to absorption)

ADME?
1. LIPOPHILICITY = more lipophilic, higher Vd
2. IONIZATION = must have NO CHARGE to penetrate membranes
3. MOLECULAR WEIGHT = LARGER, higher Vd
4. TRANSPORTERS

Question 5

Clearance (CL)
defines what 2 parameters?
total body clearance is..?
2 formulas?

Answer 5

defines BIOTRANSFORMATION & ELIMINATION

total body clearance = clearance from liver, kidney, and any other organ that performs clearance

formulas
1. CL = blood flow (L/min) x extraction ratio
2. extraction ratio = (concentration of drug IN - concentration of drug OUT) / concentration of drug IN

Question 6

7 reasons we use pharmacokinetic (PK) models?

Answer 6

1. to predict PLASMA concentration levels for ANY DOSE or DOSAGE REGIMEN given by the SAME ROUTE
   - can we maintain therapeutic concentrations if we only change dose or dosage regimen?
2. calculate OPTIMUM DOSAGE REGIMEN for an INDIVIDUAL via THERAPEUTIC DOSAGE MONITORING
3. estimate the possible ACCUMULATION of DRUGS or METABOLITES when REPEATED DOSING
4. correlate DRUG CONCENTRATIONS with PHARMACOLOGIC or TOXICOLOGIC activity
5. evaluate DIFFERENCES in BIOAVAILABILITY
6. describe how changes in PHYSIOLOGY/DISEASE affects ADME
7. explain DRUG INTERACTIONS

Question 7

how do we make PK models?

Answer 7

EMPIRICALLY DETERMINED via IN VIVO ADMINISTRATION STUDIES

Question 8

MOST substances follow what kind of PATTERN of elimination?

Answer 8

ONE-COMPARTMENT ELIMINATION MODEL

Question 9

why are one-compartment elimination models considered linear?

Answer 9

because if you take the ln of both sides, it’s linear! OTHERWISE, EXPONENTIAL DECLINE

Question 10

compartmental modeling
= definition
2 parts of graph?

Answer 10

= divides up the distribution of a drug THROUGHOUT THE BODY into COMPARTMENTS THAT ARE KINETICALLY IDENTICAL but NOT PHYSIOLOGICALLY IDENTICAL

Question 11

what’s the BIG differentiation in non-compartmental modeling vs. compartmental?

Answer 11

non-compartmental modeling IGNORES THE ABSORPTION PHASE and takes a BEST FIT –> ONLY LOOKING THROUGH ELIMINATION PHASE

Question 12

pros & cons of compartmental & non-compartmental modeling (2 each!)

Answer 12

COMPARTMENTAL
Pros?
1. Provides information about the COMPLETE PLASMA CONCENTRATION vs. TIME curve
2. Allows for SIMULATING DIFFERENT DOSES & DOSING INTERVALS but for ONE individual is best

Cons?
1. Variable profiles between subjects can make choosing a single model difficult or impossible
2. LOTS OF DATA POINTS NEEDED to enable the fitting process to succeed

NON-COMPARTMENTAL
Pros?
1. DOES NOT REQUIRE A CONSISTENT MODEL STRUCTURE
2. Requires FEWER data points

Cons?
1. CANNOT EXTRAPOLATE from ONE DOSE TO ANOTHER because we DO NOT HAVE THE COMPLETE CURVE –> CANNOT DO SIMULATIONS
2. Accuracy of pharmacokinetic parameters are COMPROMISED because ONLY FITTING TERMINAL (elimination) phase of the curve

Question 13

If giving a drug to MULTIPLE ANIMALS and taking MANY BLOOD SAMPLES, what kind of modeling should we use?

Answer 13

NON-compartmental modeling

Question 14

SINGLE bolus technique
formula?
mostly concerned with what parameter?

Answer 14

formula?
Dose (ug/kg) = Vd (L/kg) x Target Concentration of Plasma (ug/L)

mostly concerned with Vd (dose/target concentration of plasma)

Question 15

REPEATED dosing (multiple boluses)
formula?
definition of MINIMUM concentration of drug in plasma? (CplasmaMIN)

Answer 15

formula?
Dose Interval (min) = 1.44 x T1/2 (min) x ln (Target CplasmaMAX / CplasmaMIN)

CplasmaMIN = lowest amount of drug before you give the NEXT DOSE

Question 16

steady state definition

Answer 16

when the rate of ADMINISTRATION of a drug is equal to the rate of ELIMINATION/REMOVAL by the body

Question 17

constant rate infusion (CRI)
formula?
mostly concerned with what parameter?
delayed induction?

Answer 17

formula?
CRI (ug/kg/min) = Cl (L/min/kg) x Target Cplasma (ug/L)

mostly concerned with CLEARANCE

delayed induction = time it takes for drug to ACCUMULATE until STEADY STATE is reached

Question 18

loading dose
= definition
formula?

maintenance dose
formula?

Answer 18

loading dose = single bolus injection that gets us to TARGET PLASMA CONCENTRATION

loading dose formula?
Loading dose (ug/kg) = Vd (L/kg) x Target Cplasma (ug/L)

maintenance dose formula?
MAINTENANCE CRI (ug/kg/min) = Cl (L/min/kg) x Target Cplasma (ug/L)