Pharmacology

Question 1

What is the difference between pharmacodynamics and pharmacokinetics?

Answer 1

• Pharmacodynamics - what the drug does to the body
• Pharmacokinetics - what the body does to the drug

Question 2

Drugs which act on receptors can be either _________ or ______________

Answer 2

Agonists

Antagonists

Question 3

What is affinity?

Answer 3

The strength at which a ligand will bind to its receptor

Question 4

What is efficacy?

Answer 4

The ability of an agonist to evoke a cellular response

Question 5

What is EC₅₀?

Answer 5

The concentration of agonist that elicits half maximal response

This is the Michaelis-Menten constant

Question 6

What is competitive antagonism?

Answer 6

The antagonist and agonist compete for the same binding site

Question 7

What is non-competitive antagonism?

Answer 7

The agonist binds to the orthosteric site and the antagonist bings to a separate allosteric site

Activation cannot occur when the antagonist is bound

Question 8

What is potency?

Answer 8

The effectiveness of a drug at a given concentration

Question 9

How do competitive antagonists affect the concentration response curve?

Answer 9

Competitive antagonists cause a parallel rightward shift of the agonist concentration response curve with no depression of the maximal respons

Question 10

How do non-competitive antagonists affect the concentration response curve?

Answer 10

Non-competitive antagonists depress the slope and maximum of the concentration response curve, but do not cause a rightward shift

Question 11

Label A, B and C on the concentration response graph

Answer 11

Question 12

What is the therapeutic window?

Answer 12

Any concentration of drug between the minimum effective concentration (MEC) and maximum tolerated concentration (MTC)

Question 13

How is the therapuetic ratio calculated?

Answer 13

TR - MTC/MEC

Question 14

Drugs with ____ therapeutic ratios are unsafe

Answer 14

Low

Question 15

When a drug is given by IV, how is the initial concentration calculated?

Answer 15

C₀ = D/V_d

• D - dose (mg)
• V_d = volume of body plasma

Question 16

The drop in concentration of a drug in the body over time depends on what?

Answer 16

The rate of removal or elimination (K_el)

Question 17

What is first order kinetics?

Answer 17

Most drugs express this

It is when the rate of elimination is directly proportional to drug concentration

Question 18

What is “clearance”?

Answer 18

This is the volume of plasma filtered clear of the drug in unit time

Question 19

How is rate of elimination calculated?

Answer 19

Rate = C_l x C_p

• C_l - clearance
• C_p - plasma concentration

Rate of elimination is measured in l/hr

Question 20

At a stead state the rate of drug administration will equal what?

Answer 20

The rate of elimination

(drug concentration remains constant)

Question 21

Changing the rate of drug administration does not change the time to reach a steady state, it will change what instead?

Answer 21

It will change the concentration of the steady state

Question 22

How many half lives does it take to reach a steady state?

Answer 22

5

Question 23

What is a loading dose?

Answer 23

An initially higher administered dose given at the beginning f treatment.

It accelerates the time at which a steady state can be reached and when plasma concentration becomes adequate

Question 24

How does a larger V_d affect half life?

Answer 24

It increases it

Question 25

How can half life be shortened?

Answer 25

If C_l is reduced

Question 26

What is zero order kinetics?

Answer 26

This describes drugs that are eliminated at a constant rate, regardless of their concentration

An increase in drug concentration will have no effect on the rate of elimination

(at very low concentrations some drugs may initially function at first order kinetics because concentration is the limiting factor)

Question 27

What is the reason for some drugs functioning at zero order kinetics?

Answer 27

The enzyme that breaks them down has a Km that is lower than the concentration of the drug in the body

Question 28

What is a ganglion?

Answer 28

A group of cells at which a synpase is present

Question 29

Why is the sympathetic innervation of the adrenal gland unusual?

Answer 29

It is innervated by a preganglionic neurone

Acetylcholine is released

The adrenal gland acts as the postganglionic neurone, by releasing adrenaline

Question 30

Where does the sympathetic outflow originate?

Answer 30

The sympathetic chain (thoracolumbar outflow)

Between the levels of T1 and L2

Question 31

Where does parasympathetic outflow originate?

Answer 31

• Cranial nerves III, VII, IX and X
• Cranio-sacral outflow
• Thoraco-lumbar outflow
• Sacral spinal nerves

Question 32

How is noradrenaline cleared from the synaptic cleft?

Answer 32

It is reabsorbed

Question 33

How is acetylcholine cleared from the synaptic cleft?

Answer 33

Broken down and re-synthesised

Question 34

Describe how action potentials are sent via the sympathetic system

Answer 34

• The action potential causes volatge gated calcium ion channels to open allowing for calcium influx into the preganglionic neurone
• Acetylcholine is released into the synaptic cleft
• Acetylcholine bins to receptors (nicotinic) on the postsynaptic neurone and ligand gated ions channels open
• The postsynaptic neurone becomes depolarised and calcium ions enter via voltage gated ion channels
• Noradrenaline is released at the effector site
• Noradrenaline activates G-protein coupled adrenoceptors

Question 35

How is transmission of an action potential different in the parasympathetic system when compared with the sympathetic system?

Answer 35

• Acetylcholine is released at effector sites
• Acetylcholine activates muscarinic acetylcholine receptors on the target cell instead of nicotinic receptors - this is a slower process

Question 36

Which is faster, ligand gated ion channels or G-protein coupled?

Answer 36

Ligand gated channels

Question 37

What is G-protein?

Answer 37

Guanine nucleotide binding protein

It is a peripheral membrane protein with 3 subunits, alpha, beta and gamma

It contains a binding site for GTP/GDP

Question 38

Describe how G-proteins function

Answer 38

• When the receptor is bound, the G-proteins couples with the receptor
• GDP dissociates from the G-protein (bound in inactive state) and will bind to the alpha subunit
• The alpha subunit then combines with the effector altering its activity
• The receptor and effector are not linked so the signal can still be exerted even after the agonist dissociates
• The signal stops when the alpha subunit hydrolyses GTP releasing energy to rembine to subunits and cause dissociation from the effector

Question 39

What are nicotinic acetylcholine receptors constructed of?

Answer 39

Up to 5 different glycoprotein subunits

They form a transmembrane channel that allows conduction of cations

Question 40

What are the peripheral variants of nicotinic receptors?

Answer 40

• Skeletal ((α1)₂βγε)
• Ganglionic (α3β4)

Question 41

What are the CNS variants of nicotinic receptors?

Answer 41

• α4β2
• α7

Question 42

Describe cholinergic transmission

Answer 42

1. Uptake of choline via transporter
2. ACh synthesisedvia choline acetyltransferase (CAT) – choline combines with acetyl CoA provided by mitochondria
3. ACh packaged into vesicles
4. Depolarization by action potential – must be present for exocytosis
5. Ca²⁺ influx through voltage-activated Ca²⁺ channels – must occur for exocytosis
6. Ca²⁺- induced release of ACh (exocytosis)
7. Activation of ACh receptors (nicotinic or muscarinic) causing cellular response
8. Degradation of ACh to choline and acetate by acetylcholinesterase (AChE) – terminates transmission
9. Reuptake and reuse of choline

Question 43

Which two receptors can ACh activate?

Answer 43

• Nicotinic (ligand gated receptors)
• Muscarinic (G-protein coupled receptors)

Question 44

What are the individual roles of muscarinic receptors M1, M2 and M3?

Answer 44

• M1 – signals to specific G-protein (Gq) which stimulates phospholipase C which causes increased acid secretion in the stomach.
• M2 – signal to specific G-protein (Gi) which stimulates inhibition of adenylyl cyclase which opens K+ channel causing decreased heart rate.
• M3 – signals to specific G-protein (Gq) which stimulates phospholipase C production which causes increased secretion of saliva or contraction of visceral smooth muscle.

Question 45

Describe noradrenergic transmission

Answer 45

1. Synthesis of NA (multiple steps) – L-Tyrosine is converted through a variety of steps to noradrenaline
2. Storage of NA by transporter (concentrates) – into vesicles
3. Depolarization by action potential
4. Ca²⁺ influx through voltage-activated Ca²⁺ channels
5. Ca²⁺-induced release of NA - exocytosis
6. Activation of adrenoceptor (receptors for noradrenaline) subtypes causing cellular response (tissue dependent)
7. Reuptake of NA by transporters uptake 1 (U1) or uptake 2 (U2)
8. Metabolism of NA by monoamine oxidase (MAO) and catechol-O-methyltransferase (COMT)

Question 46

What are the different G-protein coupled adrenoceptor subtypes and their functions at sympathetic neuroeffector junctions?

Answer 46

• B1 – stimulates through Gs stimulating adenylyl cyclase increasing heart rate and force
• B2 – stimulates through Gs stimulating adenylyl cyclase causing relaxation bronchial and vascular
• a1 – stimulates through Gq stimulating phospholipase C causing contraction of vascular smooth muscle
• a2 – stimulates through Gi stimulating inhibition of adenylyl cyclase causing inhibition of NA

Question 47

What are pre-synaptic autoreceptors and give an example?

Answer 47

• Pre-synaptic auto-receptors are either muscarinic or G-protein coupled (based on type of synapse)
• Instead of being present exclusively on the post synaptic neurone, they also occur on the pre-synaptic neurone
• This leads to the control of further neurotransmitter release by means of a negative feedback loop.
• When stimulated, the pre-synaptic muscarinic receptor for acetylcholine, causes the reduction of calcium influx into the pre-synaptic terminal through calcium channels.

Question 48

What is a prodrug?

Answer 48

An inactive precursor of a drug

Question 49

How many phases are there in drug metabolism?

Answer 49

2

Question 50

What is the purpose of the drug phases that result in a metabolised drug?

Answer 50

To increase polarity and add functional groups increasing chance of excretion

Question 51

Where may drugs be excreted from the body?

Answer 51

• Bile
• Sweat
• Breast milk
• Urine

Question 52

What is the name of the family of proteins in the liver responsible for metabolism of drugs

Answer 52

Cytochrome P450 monooxygenases

Question 53

Which two components make up the elimination step of a drug?

Answer 53

1. Metabolism
2. Excretion

Question 54

What is the pKa of a drug?

Answer 54

The pH at which 50% of the drug is ionised and 50% is not

Question 55

What is V_d?

Answer 55

The theoretical volume necessary to contain the total amount of drug at the same concentration that it is observed in the blood plasma