Pharmacokinetics I (Herbert Ho, MD)

Question 1

What are the two steps other than ADME that some sources include in pharmacokinetics?

Answer 1

1. Liberation

2. Response

Question 2

Why aren’t liberation and response included in pharmacokinetics?

Answer 2

Liberation is part of biopharmaceutics, while response is part of pharmacodynamics.

Question 3

Enumerate the enteral routes of drug administration

Answer 3

1. Oral
2. Nasogastric tube
3. Gastrostomy tube

Question 4

Enumerate the parenteral routes of drug administration

Answer 4

1. Intravenous (IV)
2. Intramuscular (IM)
3. Subcutaneous (SC)
4. Intradermal (ID)
5. Intra-arterial (IA)
6. Topical (controversial)

Question 5

If drug A is transformed into metabolite B, what is the mode of elimination?

Answer 5

Metabolism

Not excretion because the drug was changed

Question 6

T/F: If Drug X is metabolised into an inactive metabolite and this inactive metabolite is excreted by the kidneys, the mode of elimination is both metabolism and excretion.

Answer 6

True

Question 7

In enterohepatic recirculation, where is the compound (1) conjugated, (2) excreted, (3) deconjugated, and (4) reabsorbed?

Answer 7

(1) liver
(2) bile
(3) intestines
(4) into the circulation

Question 8

T/F: Enterohepatic circulation decreases the half-life of a drug.

Answer 8

False

It actually increases it.

Question 9

Bile acids are conjugated to what in the liver?

Answer 9

Taurine and glycine

Question 10

T/F: 100% of bile salts are reabsorbed and used in cholesterol synthesis.

Answer 10

False

Only 95% are reabsorbed.

Question 11

What may cause lower oestrogen circulating concentration leading to breakthrough pregnancy when taking oral contraceptive pills?

Answer 11

Antibiotic use, which leads to elimination of natural bacterial flora in the GIT

Question 12

Enumerate the properties that make certain substances better absorbed

Answer 12

1. Non-ionized
2. Small
3. Lipid-soluble

Question 13

Enumerate the properties that make certain substances poorly absorbed

Answer 13

1. Ionized

2. Large

Question 14

Why are penicillin G and insulin poorly absorbed?

Answer 14

They are destroyed by stomach acid and/or digestive enzymes.

Question 15

Why are tetracyclines poorly absorbed?

Answer 15

They are chelated to food components to form insoluble complexes.

Question 16

Give examples of polar drugs that won’t cross cell membrane.

Answer 16

Aminoglycoside antibiotics such as streptomycin and gentamycin

Question 17

What compounds undergo extensive metabolism, which is the reason for their poor absorption?

Answer 17

1. Nitroglycerin
2. Adrenaline
3. Dopamine

Question 18

Is distribution reversible or irreversible?

Answer 18

Reversible

Question 19

Enumerate the factors affecting drug distribution

Answer 19

1. Ionization
2. Capillary permeability
3. Blood flow
4. Plasma protein binding

Question 20

What is the only scenario where displacement of a drug from plasma protein binding will cause adverse effects?

Answer 20

When it has a very small volume of distribution or nowhere to go

Question 21

Would the impact be greater if there’s a change in plasma protein binding (decrease of 1% bound protein) for a drug that’s 90% protein bound or 99% protein bound?

Answer 21

99% protein bound

This is because a 1% change equates to 2% free drug, which is a 100% increase in the amount of free drug.

Question 22

What is the main organ of metabolism?

Answer 22

Liver

Question 23

Where are the capillaries very leaky?

Answer 23

Liver and spleen

Question 24

T/F: Drugs leave the capillaries regardless of whether they are poorly lipid soluble, charged or polar.

Answer 24

True

Question 25

How do glucose and amino acids pass the blood brain barrier?

Answer 25

They have specific carrier-mediated transport systems.

Question 26

What substances are tightly controlled in the brain?

Answer 26

Potassium, hydrogen and bicarbonate ions

Question 27

In order to use dopamine and serotonin for treatment of nervous system disorders, what should you administer?

Answer 27

Precursors (L-DOPA and 5-hydroxytryptophan)

These are prodrugs.

Question 28

What are the advantages of administering a prodrug?

Answer 28

1. More stable
2. More favorable PK
3. Simpler dosage regimen
4. May increase bioavailability

Question 29

Describe: Acyclovir

Answer 29

1. Used to treat chicken pox

2. Prodrug is only administered 2 times compared to 5 times for the active drug

Question 30

How can radioactive iodine-labeled albumin help detect brain tumours?

Answer 30

Newly formed capillaries to tumours are leaky

Question 31

Describe the hierarchy of organs in terms of the rate at which they receive the administered drug

Answer 31

Brain, liver, kidneys, and lungs > skeletal muscle > fat

Question 32

Where is the drug concentration normally measured?

Answer 32

Blood

Question 33

What is the formula for volume of distribution?

Answer 33

Vd = Dose/Cp

Question 34

T/F: Correspondence of Vd with the volume of a certain body compartment may be purely coincidental

Answer 34

True

Question 35

T/F: Gentamycin does not enter cells.

Answer 35

True

It is lipid-insoluble.

Question 36

T/F: Ethanol Vd correspondence to total body water represents distribution in that compartment.

Answer 36

True

Question 37

T/F: Warfarin is present in large amounts in the different tissues.

Answer 37

False

It is extensively bound to plasma proteins.

Question 38

Give examples of drugs with physiologically impossible values.

Answer 38

Quinacrine - 300 L/kg

Amiodarone - 100 L/kg

Question 39

What are the implications of low and high Vd with respect to intravascular concentration?

Answer 39

Low Vd - highly protein bound

High Vd - highly tissue bound

Question 40

The smallest volume in which a drug may distribute is the (1).

Answer 40

Blood plasma volume

Question 41

Define: Biotransformation

Answer 41

It is the chemical modification of drugs by enzymes to make them more polar.

Question 42

Where can drug metabolising enzymes be found?

Answer 42

1. Liver
2. GIT wall
3. Lungs
4. Kidneys
5. Skin
6. Blood
7. Brain

Question 43

What are the two phases of metabolism or biotransformation?

Answer 43

1. Functionalization

2. Conjugation

Question 44

What are the processes involved in functionalization?

Answer 44

1. Oxidation
2. Reduction
3. Hydrolytic reactions

Question 45

What are the processes involved in conjugation?

Answer 45

1. Glucoronidation
2. Sulfation
3. Acetylation
4. Methylation
5. Amino acid conjugation (glycine, taurine and glutathione)

Question 46

T/F: Functionalization leads to inactivation, while conjugation does not.

Answer 46

False

It’s the other way around. Both, however, make the drug more polar.

Question 47

T/F: Conjugation may precede functionalization.

Answer 47

True

Question 48

T/F: Kidney can only eliminate polar substances.

Answer 48

True

Question 49

What enzymes are largely responsible for phase 1 or functionalization reactions?

Answer 49

Liver Microsomal Cytochrome P450 Monooxygenases (CYPs)

Question 50

What is the mechanism of action of CYPs?

Answer 50

They transfer electrons from NADPH to O2 and oxidise drugs (hydroxylation and dealkylation)

Question 51

Where in the cell are phase 1 enzymes located?

Answer 51

Endoplasmic reticulum

Question 52

Which enzyme makes drug interactions most probable?

Answer 52

CYP3A4

Question 53

Describe the hierarchy of CYPs in terms of percentage of drugs metabolised

Answer 53

1. CYP3A4
2. CYP2D6
3. CYP2C9 and CYP2C19
4. CYP2E1, CYP2A6 and CYP1A2

Question 54

Enumerate non-CYP biotransformation processes

Answer 54

1. Hydrolysis
2. Reduction
3. Oxidation (flavinemonooxygenase, monoamine oxidase and alcohol & aldehyde dehydrogenase)

Question 55

What processes lead to drug interactions?

Answer 55

Enyzme inhibition and activation.

Question 56

What is the effect of inducers on elimination rate?

Answer 56

Increase

Question 57

Why are inducers slower acting than inhibitors?

Answer 57

Transcription/translation and increased synthesis of heme must first take place.

Question 58

Give examples of inducers

Answer 58

Rifampicin, barbiturates and St. Johns wort (herbal antidepressant)

Question 59

Give examples of inhibitors

Answer 59

1. Grapefruit juice
2. Cimetidine
3. Erythromycin
4. Itraconazole

Question 60

Give an example of a phase 2 enzyme

Answer 60

N-acetyltransferase 2 (NAT2)

Question 61

Describe: N-acetyltransferase 2

Answer 61

1. Slow metabolism of drugs such as isoniazid, procainamide and caffeine
2. Slow acetylators have higher risk of bladder cancer
3. Fast acetylators have higher risk of colorectal cancer

Question 62

When taking a drug metabolised by C P450, what should be considered?

Answer 62

Interactions due to food items or herbal medicines

Question 63

What is phase 3 metabolism?

Answer 63

Transport of drug from one compartment to another

Question 64

Give examples of secondary or tertiary active transporters

Answer 64

1. Organic cation transporter (OCT)
2. Organic anion transporting polypeptide family (OATP)
3. Organic anion transporter (OAT)
4. Peptide transporter
5. Sodium phosphate co-transporter

Question 65

Give examples of primary active transporters

Answer 65

1. P-glycoprotein
2. Multidrug resistance associated protein 1 (MRP1)
3. Canalicular multi specific organic anion transporter (cMOAT/MRP2/cMRP/MRP3)

NOTE: They are implicated in resistance of cancers due to pumping out of anticancer drugs.

Question 66

Describe: P-glycoprotein

Answer 66

1. ATP-requiring efflux pump
2. Broad drug specificity (digoxin, quinidine, etc.)
3. Located in cancer tissue among other sites
4. Induced by: rifampicin and St. Johns wort
5. Inhibited by: verapamil, quinidine, macrolides and antifungals

Question 67

T/F: In a one compartment model, drug distribution is assumed to be instantaneous.

Answer 67

True

Question 68

T/F: Most drugs support the two compartment model.

Answer 68

False

Most drugs support the one compartment model.

Question 69

T/F: In pharmacology, linearity is in the semilog sense.

Answer 69

True

Question 70

What is the equation for a one compartment model?

Answer 70

C = Coe^-kt

Question 71

What is the equation for a two compartment model?

Answer 71

C = Ae^-bt + Be^-at

Question 72

What is a first-order reaction?

Answer 72

Rates are linearly related to dose administered

Question 73

What is the rate of change for first-order equations?

Answer 73

dA/dt = -kA

Question 74

What is the value of e?

Answer 74

e = 2.718

Question 75

What is the semi-log equation for a one compartment model?

Answer 75

ln(C) = ln(Co) - kt

Question 76

Define: half-life

Answer 76

Amount of time required for a drug to be reduced to half its original concentration

Question 77

Give the formula for half-life of 1st order reactions

Answer 77

t1/2 = 0.693/k

Question 78

What are the important assumptions for a one compartment model with first-order input and first-order elimination?

Answer 78

1. Dose is gradually absorbed
2. Driving force is concentration gradient
3. There is a single homogenous compartment

Question 79

What is the formula for a one compartment model with first-order input and elimination?

Answer 79

Cp = [(F x dose x ka)/Vd(ka-k10)][e^-k10t - e^-kat]

Question 80

What is another way of expressing the rate of elimination?

Answer 80

CL x Cp

Question 81

What does it mean if a drug has low tmax?

Answer 81

It is absorbed quickly.

Question 82

What is the relationship between distribution and elimination?

Answer 82

Distribution precedes elimination, but both happen all throughout.

Question 83

Describe a “physiologically-based pharmacokinetic model”

Answer 83

It is derived from anatomy and physiology of the organism and not from drug data.

Question 84

In a multi-compartment model, what is the total distribution space for drugs?

Answer 84

1. Central compartment (organs with high blood flow)

2. Peripheral compartment (absorption > elimination; i.e. adipose tissues and muscles)

Question 85

T/F: Drug distribution is instantaneous in a multi-compartment model.

Answer 85

False

Volume bound to proteins > volume in steady state > volume in central compartment

Question 86

What do you call the clearance leaving the central component in a multi-compartmental model?

Answer 86

Central or metabolic clearance

Question 87

In the log concentration vs. time plot, the number of kinks varies with the number of (1)

Answer 87

(1) compartments

Question 88

What is the only assumption in the non-compartmental model?

Answer 88

First-order single exponential terminal phase is present. Terminal phase should resemble a 1C model.

Question 89

When is the non-compartmental model useful?

Answer 89

When little is known about the drug.

Question 90

T/F: Prior to the last 10 years, the method of choice was the 1C model.

Answer 90

False.

It was the non-compartmental model.

Question 91

Define: Area Under the Curve (AUC)

Answer 91

It is a measure of exposure of our body to the drug.

Question 92

What concept is used to compute for the area under the curve?

Answer 92

Trapezoidal concept

Question 93

What is the formula for AUC from 0 to t?

Answer 93

Sigma (0-t) [0.5(Ct1 + Ct2)] x delta time

Question 94

What is the formula for AUC from t to infinity?

Answer 94

AUC (t-infinity) = Clast/ke

Question 95

Why is the logarithmic trapezoidal method more accurate when concentrations are decreasing?

Answer 95

Drug elimination is exponential.

Question 96

What is the formula for AUC based on the logarithmic trapezoidal method?

Answer 96

AUC (t1 - t2) = [(Ct1 - Ct2)] x delta time/ln (Ct1/Ct2)

Question 97

T/F: For submissions to the FDA, using the linear trapezoid method will suffice.

Answer 97

True

Question 98

When is drug concentration assumed to be negligible?

Answer 98

After 4 - 7 half-lives

Question 99

What is the formula for clearance?

Answer 99

Cl = Vd x ke

Cl = 0.693Vd/t1/2

Cl = rate of elimination/C

Question 100

T/F: Clearance is the same as elimination.

Answer 100

False

Clearance is usually constant, while elimination rate is variable.

Question 101

Describe the relationship of ka, Cmax and Tmax.

Answer 101

A higher ka would lead to higher Cmax and shorter Tmax

Question 102

T/F: ka and Cpmax may be different for three graphs, but their AUCs may be equal.

Answer 102

True