M&R 9.1/9.2 Pharmacokinetics

Question 1

Describe the difference between the pharmaceutical process, the pharmacokinetic process, the pharmacodynamic process, and the therapeutic process

Answer 1

Pharmaceutical process = is the drug getting into the patient
Pharmacokinetic process = is the drug getting to the site of action (what the body does to the drug)
Pharmacodynamic process = is the drug producing the desired effect (what the drug does to the body)
Therapeutic process = is this translated to a therapeutic effect

Question 2

Which process describes whether the drug is getting into the patient?

Answer 2

The pharmaceutical process

Question 3

Which process describes whether the drug is getting to the site of action?

Answer 3

The pharmacokinetic process (what the body does to the drug)

Question 4

Which process describes whether the drug is producing the desired effect?

Answer 4

The pharmacodynamic process (what the drug does to the body)

Question 5

Which process described whether the desired effect is translated to a therapeutic effect?

Answer 5

Therapeutic process

Question 6

Describe how properties regarding how patients take drugs can affect the pharmaceutical process (whether the drug gets into the patient)?

Answer 6

Formulation (solid vs liquid, if solid - acid stability, solubility)

Compliance (fewer doses/day - more patient compliance)

Site of administration (focal/systemic, if systemic - enteral/parenteral)

Question 7

What are some sites of focal drug administration?

Answer 7

Eyes
Skin
Ears
Inhalation

Question 8

What are 2 advantages of focal drug administration?

Answer 8

Concentrates drug at site of action

Less systemic absorption –> less off target effects/side effects

Question 9

What are 3 routes of enteral drug administration?

Answer 9

Oral
Sublingual
Rectal

Question 10

What are 4 routes of parenteral drug administration?

Answer 10

Subcutaneous
Intramuscular
Intravenous
Transdermal

Question 11

Define ‘oral bioavailability’ of a drug

Answer 11

The proportion of a drug given orally (or by any route other than IV) which reaches the systemic circulation in an unchanged form

Question 12

In what 2 ways can you measure oral bioavailability of a drug?

Answer 12

1. By amount (depends of GI absorption & first pass metabolism) - measure area under curve of a plasma drug level vs time plot (then (AUC oral/ AUC injected) x 100)
2. By rate of availability (depends on GI absorption and pharmaceutical factors) - measured by peak height and rate of rise of drug level in blood

Question 13

Does everyone have the same bioavailability for the same drug?

Answer 13

No!

Question 14

How do you calculate therapeutic ratio?

Answer 14

LD50/ED50

=maximum tolerated dose/minimum effective dose

Question 15

What does it mean if there is a large therapeutic window/index?

Answer 15

There is a wider gap between the effective conc of the drug and the toxic conc of the drug

Therefore a mistake in dose is less likely to have a negative effect on the patient

Question 16

Name a drug with a large therapeutic window

Answer 16

Penicillin

Question 17

What does it mean if a drug has a small therapeutic window/index?

Answer 17

There is a narrow gap between the effective conc of the drug and the toxic conc

Therefore any mistake in dose can have severe effects

Question 18

Name a drug with a small therapeutic window

Answer 18

Warfarin

Question 19

What could we alter to stop a drug entering the toxic window?

Answer 19

The formulation
E.g. if a fast-release formulation causes plasma concentration to rapidly rise and enter the toxic window, then could formulate a slow-release preparation that causes plasma levels to rise slower so the toxic window is not reached

Question 20

What is first pass metabolism? Why does it happen?

Answer 20

Because blood from the gut goes straight to the liver via the portal system, drugs that are absorbed through the gut can get metabolised by the liver before ever reaching the systemic circulation

(e.g. opiates)

Question 21

Name 3 routes of administration which would avoid first-pass metabolism

Answer 21

Parenteral routes (e.g. IV, IM, SC)

Sublingual (e.g. use of GTN in angina)

Rectal (rectum has drainage to both portal and systemic systems - so only some of the drug would undergo first-pass metabolism by liver

Question 22

What is the volume distribution of a drug?

Answer 22

The theoretical volume into which the drug is distributed, assuming that this occurred instantaneously

Question 23

How would you calculate volume distribution of a drug?

Answer 23

On a time vs serum concentration graph, you would extrapolate back to time zero to find C0 (the hypothetical drug concentration predicted if the distribution had occurred instantly)

Then do: amount given/C0

Question 24

Do drugs which are bound to plasma proteins exert effects?

Answer 24

No - it is the FREE level of drug that exerts the effect, not the total level

Question 25

Drugs which have a very high volume distribution tend to be concentrated where?

Answer 25

They tend to concentrate into fatty tissue, which leads to a very high volume distribution

Question 26

In protein-binding interactions, what are Object (class I) drugs?

Answer 26

Drugs which are used at a dose much lower than the number of albumin binding sites

Most of the drug molecules are bound to albumin, so the concentration of free drug is low

Question 27

In protein-binding interactions, what are Precipitant (class II) drugs?

Answer 27

Drugs which are used at a dose much higher than the number of albumin binding sites

Most albumin molecules contain a bound drug
the concentration of free drug is significant

Question 28

What happens when an Object drug and a Precipitant drug are taken together?

Answer 28

The precipitant drug will displace the object drug from its albumin binding sites
This temporarily increases free levels of the object drug, leading to a higher risk of toxicity

Question 29

When are protein binding drug interactions most important?

Answer 29

1. For drugs that are highly bound to albumin (because there is a low amount of free drug - so any displacement leads to a big rise)
2. For drugs with a small volume of distribution (so if displaced the conc rise will be much greater)
3. For drugs with a small therapeutic window (therefore a rise in levels is more likely to lead to side effects)

Question 30

Name an object drug that is particularly susceptible to protein binding interactions. Why is it susceptible?

Answer 30

Warfarin
Highly bound to albumin
Has a low volume of distribution
Has a small therapeutic window

Question 31

Which precipitant drugs can displace warfarin?

Answer 31

Sulphonamides
Aspirin
Phenytoin

Question 32

Name the two main types of drug pharmacokinetics

Answer 32

First order kinetics

Zero order kinetics

Question 33

When does first order kinetics occur? What does it mean?

Answer 33

When a drug is used at a concentration [C] lower than Km

The rate of elimination is proportional to drug level

• > so the higher the drug level, the faster the rate of destruction
• > a constant FRACTION is eliminated per unit time - so can determine HALF LIFE

Question 34

When does first order kinetics appear linear on a graph?

Answer 34

When log(plasma concentration) is plotted against time

Question 35

If linear plasma concentration is plotted against time on a graph, which type of kinetics appears curved and which appears linear?

Answer 35

First order kinetics appears curved (only linear if log(conc) used)

Zero order kinetics appears linear

Question 36

When does zero order kinetics occur? What does it mean?

Answer 36

When a drug is used at a concentration [C] much higher than Km
The enzyme is saturated, so the rate of elimination is CONSTANT
Regardless of drug concentration, it will be eliminated at the same rate (e.g. 9g/hour)

Question 37

What is the significance of first order kinetics?

Answer 37

There is a predictable therapeutic response from dose increases
(Most drugs behave like this)

Question 38

What is the significance of zero order kinetics?

Answer 38

The therapeutic response can suddenly escalate as elimination mechanisms saturate

(different in different people, so need to monitor concentrations of the drug and only increase doses incrementally)

Question 39

Name 2 examples of drugs subject to zero order kinetics

Answer 39

Phenytoin

Alcohol

Question 40

During repeated drug administration, how long does it take to reach a steady state of the drug?

Answer 40

5 half-lives of that drug

therefore is a property of a drug itself

Question 41

If an immediate effect is required from a drug which has a long half life (so you can’t wait 5 half-lives), what do you do?

Answer 41

Give a loading does of the drug
This puts the drug concentration into the therapeutic range very quickly
Loading dose often determined by volume of distribution

Question 42

During drug elimination, drugs tend to be metabolised by…

Answer 42

…the liver

Question 43

During drug elimination, drugs tend to be excreted by…

Answer 43

… the kidneys

Question 44

What is the significance of the high volume of distribution of lipid-soluble drugs?

Answer 44

They concentrate in lipid, so when adipose tissue is high, their plasma concentration is lower.

Therefore for the same dose, in a very thin person there would be loads in the plasma, whereas for a very fat person there would be loads in the adipose tissue and hardly any left in the plasma to act

Question 45

Briefly describe the 2 phases of liver metabolism of drugs

Answer 45

Phase 1 - oxidation, reduction and/or hydrolysis
(drug may get activated, unchanged, or (most often) inactivated

Phase 2 - Conjugation to conjugation products (usually inactive)
(NB - some drugs directly enter phase 2 metabolism)

Question 46

What kinds of enzymes carry out phase 1 metabolism of drugs in the liver?

What are some main features of them?

Answer 46

Mixed function oxidases (e.g. cytochrome P450)

Low substrate specificity
Affinity for lipid-soluble drugs
Inducible and inhibitable

Question 47

Regarding phase 1 liver metabolism, what is an enzyme inducer?

Answer 47

A drug which induces liver enzymes and therefore can cause other drugs to be metabolised more quickly

Question 48

What is an example of an enzyme inducing drug and what drugs does it affect?

Answer 48

Phenobarbitone (Causes warfarin & phenytoin to be metabolised more quickly)

Rifampicin (causes the OCP to be metabolised more quickly)

Question 49

Regarding phase 1 liver metabolism, what is an enzyme inhibitor?

Answer 49

A drug which can inhibit liver metabolism enzymes, causing other drugs to be metabolised more slowly

Question 50

Give an example of a drug which acts as a liver enzyme inhibitor, and which drugs it slows the metabolism of

Answer 50

Cimetidine

Causes warfarin and diazepam to be metabolised more slowly

Question 51

When are metabolism-related drug interactions most clinically important?

Answer 51

When drugs have a low therapeutic ratio (e.g. warfarin)
When a drug is being used at the minimum effective concentration (e.g. the OCP)
When the drug metabolism follows zero order kinetics

Question 52

Which drugs can potentiate warfarin’s actions and how?

Answer 52

Alcohol - inhibits warfarin metabolism
Aspirin, sulphonamides, phenytoin - displace warfarin from plasma proteins
Broad spectrum antibiotics - reduce vitamin K synthesis by gut bacteria (warfarin normally works against vitamin K to prevent clotting)

Question 53

Which drugs can inhibit warfarin’s actions and how?

Answer 53

Barbiturates and rifampicin - induce liver metabolising enzymes

Question 54

Which proportion of a drug is filtered by the glomerulus?

Answer 54

Only the free, unbound fraction

Question 55

Name a drug that can be actively secreted by kidney tubules

Answer 55

Penicillin

Question 56

What is the pK of a drug?

Answer 56

The pH at which half of it is ionized and half is non-ionized

Question 57

What is the key difference between the ionised and un-ionised part of a drug?

Answer 57

Only the un-ionised part is lipid soluble and can cross membranes easily
Therefore whether or not the drug is ionized affects how well it can be reabsorbed (and therefore how much is excreted)

Question 58

If a drug is a weak acid (e.g. aspirin) describe how the urine pH will affect its excretion

Answer 58

Alkaline urine will ionise the drug

Therefore alkaline urine = decreased reabsorption and increased excretion (more stays in the tubule lumen)
Acidic urine = increased reabsorption and decreased excretion (more leaves tubule lumen and gets reabsorbed)

Question 59

If a drug is a weak base (e.g. amphetamine) how will the pH of the urine affect its excretion?

Answer 59

Making the urine acidic ionises more of the drug

Therefore acid urine = decreased reabsorption so more excreted

Alkaline urine = increased reabsorption so less is excreted

Question 60

Explain one way in which the urine pH affecting drug excretion can be exploited clinically

Answer 60

Aspirin poisoning

Aspirin is a weak acid. Give forced alkaline diuresis
The alkalinity causes more of the aspirin to get ionized and therefore remain in tubule lumen to be excreted (rather than reabsorbed)

Question 61

How can renal disease affect drugs in the body?

Answer 61

Lower rate of excretion = longer half-life

• > = lower maintenance dose required
• > = longer time to reach steady state (5 half lives)

Protein binding of drugs is altered