MOA

Question 1

Ramipril
Lisinopril

Answer 1

Limits conversion of Angiotensin I to Angiotensin II by inhibiting circulating and tissue ACE

-> reduction in Angiotensin II activity ->
- vasodilation (reduces peripheral resistance & afterload
- reduced aldosterone release (increased Na & water excretion)
- reduced vasopressin (ADH) release (increased water excretion)
- reduced cell growth and proliferation

Question 2

Losartan
Candesartan

Answer 2

Selective inhibition of angiotensin II by competitive antagonism of the angiotensin II receptors

Directly targets AT1 receptors which is more effective at inhibiting Angiotensin II mediated vasoconstriction than ACEi

AT1 receptors are important in CVS regulation but also antagonises AT2 receptors

No effect on bradykinin, dry cough and angioedema much less likely than with ACEi

Question 3

Amlodipine
Nifedipine
Nimodipine

Answer 3

Dihydropyridine Ca Channel Blockers are selective for peripheral vasculature with little chronotropic or ionotropic effects - Acts primarily on vascular smooth muscle

CCBs are often 1st choice antihypertensive in pts with low renin

Amlodipine has a long half life

Cerebral vs peripheral selectivity
Nimodipine is selective for cerebral vasculature - useful for ischaemic effects of SAH

Question 4

Verapamil

Answer 4

Prolongs AP/effective refractory period

Less peripheral vasodilation, -ve chronotropic and ionotropic effects

Question 5

Diltiazem

Answer 5

Inhibits the inflow of calcium ions into the cardiac muscle during depolarization. Reduced intracellular calcium concentrations increase smooth muscle relaxation, resulting in arterial vasodilation and decreased blood pressure.

Action in between phenylalkamines and dihydropyridine CCBs

Question 6

Bendroflumethiazide
Indapamide

Answer 6

Inhibits Na+/Cl- co-transporter in distal convoluted tubule -> decreases Na+ and water reabsorption (RAAS compensates with time)

Question 7

Spironolactone
Eplerenone

Answer 7

Aldosterone antagonist -> reduced ENaC (and Na/K/ATPase) expression in late DCT and collecting duct -> decreased Na+ uptake and therefore water
K sparing

Question 8

Bisoprolol
Labetalol
Metoprolol

Answer 8

Decrease sympathetic tone by blocking NA and reducing myocardial contraction
resulting in reduced cardiac output

Suppresses renin secretion (β1 on JG cells) -> antihypertensive

Cardiac effects:
- Increases AP duration and refractory period in AV node to slow AP conduction velocity
- Reduce phase 4 depolariasation
- Lowers BP

Effects on ECG:
- Increase PR interval
- Reduce HR - less automacitity

Question 9

Doxazosin

Answer 9

Selective antagonism of α-1 adrenoceptors
Reduces peripheral vascular resistance

Question 10

Tamsulosin

Answer 10

Highly selective antagonism of the urinary tract α-1 adrenoceptors

Question 11

Furosemide
Bumetanide

Answer 11

Inhibits the N+/K+/2Cl- co-transporter
Reduces N+/K+/2Cl- into epithelium -> water follows
Direct dilation of capacitance veins - reduces preload (likely primary benefit in HF)

Question 12

Amiloride

Answer 12

Blocks ENaC channels
Reduces Na+ reabsorption in DTC and reduces K+ excretion

Question 13

Mannitol

Answer 13

Remains in tubular lumen, increases osmotic pull -> water follows in proximal tubule and descending limb and excreted in urine
Can lead to hyperNa

Question 14

Sacubitril

Answer 14

Inhibits natriuretic inactivating enzyme -> potentiates effects of ANP/BNP -> natriuresis (Na loss)
Stops breakdown of bradykinin -> vasodilation

Question 15

Atorvastatin
Simvastatin

Answer 15

Competitive inhibition of HMG-CoA reductase (rate controlling enzyme in HMG-CoA to mevalonate pathway)
- contributes to upregulation of LDL receptors
-> increased clearance of circulating LDL

Undergo Phase I metabolism by the CYP3A4 isoenzyme (substrate) - not all statins are the same CYP

Question 16

Fenofibrate

Answer 16

Activation of nuclear transcription factor - PPARalpha
regulates expression of genes that control lipoprotein metabolism - increases production of lipoprotein lipase

Main effects:
- increased removal of triglycerides from lipoprotein in plasma
- increased fatty acid uptake by liver
Other effects:
- increased levels of HDL
- increased LDL affinity for receptor

Rarely used alone, co-prescribed with statins in mixed hyperlipidaemias

Question 17

Ezetimibe

Answer 17

Inhibits NPC1L1 transporter at brush border of small intestine
Reduces cholesterol absorption in the gut by ~50%
Hepatic LDL receptor expression increases
Reduction in total cholesterol by ~15% and LDL by ~20%

Prodrug - hepatic metabolism -> enterohepatic circulation which limits systemic exposure

Question 18

Alirocumab
Evolocumab

Answer 18

Inhibits action of PCSK9 (normally binds to LDL-R directing it for degredation) which significantly reduces LDL cholesterol level in primary hyperlipidemia

Not routinely used as still very expensive and must be injected sub-cut

Question 19

Inclisiran

Answer 19

siRNA - inhibits hepatic translation of PCSK9 (normally binds to LDL-R directing it for degredation) so less is produced

Question 20

Lidocaine
Mexiletine

Answer 20

IV Lidocaine
PO Mexiletine - swap to this after multiple lidocaine doses -> preventative

Effects on cardiac activity:
- Fast binding offset kinetics so need to keep giving frequently
- No change in phase 0 in normal tissue (no tonic block)
- AP duration slightly decreased in normal tissue
- increase threshold for Na+
- AP decreased in phase 0 conduction in fast beating (VT) or ischaemic tissue

Effects on ECG:
- None in normal heart
- Increased QRS in fast beating (VT) or ischaemic

Question 21

Flecainide
Propafenone

Answer 21

Propafenone less used

Effects on cardiac activity:
- Substantially decreases phase 0 by blocking Na+ channels in normal
- reduces automaticity by increasing threshold
- increases AP duration (K+) and refractory period esp. in rapidly depolarising atrial tissue e.g. in A fib or Atrial flutter

Effects on ECG:
- prolonged PR, QRS and QT interval

Question 22

Amiodarone

Answer 22

Prolong repolarization

Cardiac effects:
- increases refractory period and AP duration by affecting K+ channels
- reduces phase 0 and conduction through Na+ channels
- increase AP threshold
- decreases phase 4
- decreases speed of AV conduction

Effects on ECG:
- increases PR, QRS, QT intervals
- reduces HR

Question 23

Verapamil
Diltiazem

Answer 23

Calcium channel blockers

Cardiac effects:
- slows conduction through AV by affecting Ca2+ intake
- increases refractory period in AV node
- increases slope of phase 4 in SA node to slow HR

Effects on ECG:
- Increase RP interval
- Mainly reduce HR but can increase depending on BP response and baroreflex

Question 24

Adenosine

Answer 24

Rapid IV bolus, T1-2 seconds

Cardiac effects:
- decreased HR
- decreased Ca2+ currents -> increased refractory period in AV node
- stops heart for ~10s

Impending doom

Question 25

Digoxin

Answer 25

Enhances vagal activity - increasing refractory period
Slows AV conduction and HR

Reduces ventricular rates in A fib and A flutter

Rarely used as dependant on renal function - if low can lead to bradycardia and death

Question 26

Atropine

Answer 26

Selective muscarinic antagonist

Blocks vagal activity to speed up AV conduction and increase HR

Treats vagal bradycardia (helps with fainting)

Question 27

Ivabradine

Answer 27

Blocks funny current in SAN
Slows SAN but does not affect BP

Question 28

Tiotropium

Answer 28

Blocks muscarinic ACh R in airway smooth muscle
Prevents vaguely mediated contraction

Side effects: anticholinergic effects e.g. dry mouth/eyes, urinary retention

Question 29

Sotalol

Answer 29

Prolong repolarization

Cardiac effects:
- Increased AP duration and refractory period in both atrial and ventricular tissue
- Slow phase 4 (beta blocker action too)
- Slows AV conduction

Effects on ECG:
- prolongs QT interval
- reduce HR

Question 30

Alteplase

Answer 30

Converts plasminogen to the proteolytic enzyme plasmin, which lyses fibrin as well as fibrinogen

Question 31

Anaesthetics

Answer 31

Can be local or general
General anaesthetic is normally inhaled or IV

• Anaesthetic drugs bind to the GABA receptor to potentiate the action of GABAA. GABAA is a major inhibitory neurotransmitter. This leads to the anaesthetic state of unconsciousness, muscle relaxation and analgesia.
• Anaesthetic drugs also work by opening K+ channels that modulate neuro-excitability. Opening these channels reduce membrane excitability. (Remember your action potential curve where Na+ goes in and K+ goes out. Opening K+ channels will lead to more negative resting potential, making it more difficult to start an action potential).
• Anaesthetic drugs inhibit opening of ligand-gated ion channels that allow Na+ to enter the cell.

Question 32

Propofol

Answer 32

Propofol is a general anaesthetic given intravenously. It is often used as an induction agent and in intensive care for ventilated patients. Propofol decreases the rate of dissociation of GABA from its receptor, which increases the duration of the GABA-activated opening of the chloride channel leading to hyperpolarization of cell membranes. This leads to increased inhibitory tone in the central nervous system. There is pain on injection (due to activation of the pain receptor transient receptor potential ankyrin 1 - TRPA1).

Question 33

Thiopental

Answer 33

Thiopental is a general anaesthetic given intravenously. It is a type of barbiturate that works by decreasing neuronal activity which decreases cerebral metabolic rate of oxygen consumption and decreases the cerebrovascular response to carbon dioxide, which will decrease intracranial pressure. It is very lipid-soluble so affects the brain quickly but can also cause laryngospasm.

Question 34

Halothane

Answer 34

Halothane is an inhaled general anaesthetic which works by activating Gamma-aminobutyric acid (GABA) and glycine receptors, antagonising N-methyl-D-aspartate (NMDA) receptors and inhibiting voltage gates sodium channels and twin pore potassium channels. This leads to depressed nerve conduction, breathing and cardiac contractility. Adverse effects include hepatotoxicity, myocardial depression and malignant hyperthermia.

Question 35

Atypical anti-psychotics e.g.
Clozapine
Risperidone
Olanzapine
Quetiapine
Aripiprazole

Answer 35

5HT2 and D2 receptor antagonists

Antagonising dopamine D2 receptors in the mesolimbic pathway blocks dopamine from acting at post-synaptic receptors. The binding is dissociable so some dopamine neurotransmission still takes place. Action on the serotonin 5HT2A receptors in the frontal cortex decreases adverse effects (compared to typical antipsychotics).

Question 36

Carbamazepine

Answer 36

Carbamazepine is chemically similar to the tricyclic antidepressants. It binds to voltage-dependent sodium channels and increases their refractory period, thus preventing the action potential. It is used in epilepsy and bipolar disorder.

Can cause hyponatraemia. Carbamazepine acts on voltage-dependent sodium channels which carry inward membrane current. This reduces the likelihood of the delopment of an action potential

P450 enzyme inducer

Question 37

Amitriptyline

Answer 37

Tricyclic antidepressants (TCAs) inhibit a membrane pump mechanism responsible for the re-uptake of transmitter amines (e.g noradrenaline/serotonin) into the presynaptic cleft. Thus, their concentration at the synaptic clefts is increased, and they restimulate post-synaptic receptors. Noradrenaline and serotonin are important in regulating mood, and their increased concentration in the synaptic cleft helps to reduce depressive symptoms.

Question 38

Bleomycin
Teicoplanin
Vancomycin

Answer 38

Glycopeptides target the bacterial cell wall by binding to acyl-D-alanyl-D-alanine in peptidoglycan. This prevents the addition of new units to the peptidoglycan in the cell wall.

Question 39

Tamoxifen

Answer 39

Tamoxifen is a selective oestrogen receptor modulator (SERM) which acts partially as an oestrogen receptor antagonist, blocking oestrogen from binding to breast cancer cells causing them to grow and divide, and a partial agonist in tissues such as the uterus and bones.

Question 40

Metformin

Answer 40

Reduces hepatic glucose production by inhibiting gluconeogenesis

Limited weight gain - supresses appetite

Question 41

Gliclazide

Answer 41

Stimulates beta cell pancreatic insulin secretion
(needs residual pancreatic function)

Risk of hypoglycaemia

Weight gain - anabolic effects of insulin

Question 42

Dapagliflozin

Answer 42

Reduces glucose absorption from tubular filtrate
Increases urinary glucose excretion

Modest weight loss

Low risk of hypoglycaemia

Increases risk of uti

Question 43

Semaglutide

Answer 43

GLP-1 receptor agonist

Increases glucose dependent synthesis of insulin secretion from beta cells
Activates GLP-1 receptor
Resistant to degradation by DPP-4

Subcut injection

Promotes satiety - GLP-1 reduces peristalsis in the gut

Question 44

Aspirin

Answer 44

COX-1 inhibitor

Prevents COX-1 mediated production of TXA2 and irreversibly reduces platelet aggregation

Platelet lifespan is 7-10 days

Avoid in children <16 years old due to Reye’s syndrome and pregnancy 3rd trimester due to premature closure of ductus arteriosus

High dose inhibits endothelial prostacyclin (PGI2)

Question 45

Clopidogrel

Answer 45

Acts independently of COX pathway

Inhibits binding of ADP to P2Y12 receptor
-> inhibits activation of GPIIb/IIIa receptors

Irreversible inhibitor of P2Y12

Prodrug -> CYP inhibitors e.g. omeprazole reduce efficacy

Hepatic metabolism

Question 46

Ticagreglor

Answer 46

Acts independently of COX pathway

Reversible inhibitor of P2Y12

Rapid onset of action compared to clopidogrel

Question 47

Alteplase

Answer 47

Fibrinolytic (clot buster)
Dissolve the fibrin meshwork of thrombus

Activate plasmin (plasminogen -> plasmin -> increased fibrinolysis)

Question 48

Streptokinase

Answer 48

Fibrinolytic (clot buster)
Dissolve the fibrin meshwork of thrombus

Activate plasmin (plasminogen -> plasmin -> increased fibrinolysis)

Can only be used once as antibodies develop

Question 49

Transexamic acid (TXA)

Answer 49

Inhibits fibrinolysis

Stops bleeding

Question 50

Celecoxib

Answer 50

Selective COX-2 inhibitor
No antiplatelet action but inhibits PGI2

Less analgesic affect but useful in sever osteo/RA long term

All NSAIDs increase risk of MI including in low risk people (reduced PGI2 protective function)

NSAIDs displace other bound drugs -> increase free drug conc e.g. supfonurea -> hypoglycaemia, methotrexate -> hepatotoxicity, warfarin -> increased risk of bleeding

Question 51

Paracetamol

Answer 51

MOA is unknown
non-NSAID, non-opiate analgesic and antipyretic

Risk of overdose
Paracetamol -> NAPQI (conjugated by glutathione -> harmless metabolite
Treat OD with N-acetylcysteine (glutatione replacement)

Question 52

Opiates:
Codeine
Fentanyl
Morphine
Tramadol

Answer 52

CNS depressant

Binds to opioid receptor Gai (AC cAMP)

Decreased Ca2+ influx in presynaptic terminal in response to incoming AP
Decreases release of excitatory neurotransmitters e.g. glutamate

Also dampens response to excitatory neurotransmitters at post-synaptic neuron (increases K+ efflux)

In OD use naloxone

Question 53

Gaviscon

Answer 53

Antacid - buffers stomach acid
Alginic acid - increases stomach content viscosity and reduces reflux

Magnesium salts -> diarrhoea
Aluminium salts -> constipation
Balanced

Question 54

Omeprazole

Answer 54

PPI
Irreversibly inhibits the H+/K+ ATPase in gastric parietal cells
Significantly reduces acid secretion

Question 55

Ranitidine

Answer 55

H2 receptor antagonist - competitive inhibition in gastric parietal cells

Question 56

Lactulose

Answer 56

Osmotic laxative
Draws fluid into bowel

Question 57

Macrogols

Answer 57

Osmotic laxative
Limits loss of fluid from stool

Question 58

Metaclopramide

Answer 58

Anti-emetic, D2 receptor antag
Increases intestinal motility (prokinetic)

Question 59

Hyoscine hydrobromide

Answer 59

Muscularinic receptor antag
Competitive inhibition of muscularinic ACh receptors

Some action through central trigger zone (via CN8)

Sedative effect

Question 60

Meropenem

Answer 60

Inhibits bacterial cell wall synthesis (stops building and repairing)
Very broad spectrum
Generally safe in penicillin allergy

Question 61

Vancomysin

Answer 61

Inhibits bacterial cell wall synthesis
Generally gram +ve

Question 62

Flucloxacillin

Answer 62

Inhibits bacterial cell wall synthesis

Question 63

Metronidazole

Answer 63

Antibiotic, MOA not fully understood but affects bacterial nucleic acid synthesis
Can’t take with alcohol

Question 64

Gentamycin

Answer 64

Inhibits bacterial protein synthesis - acts on ribosomes

Profound activity against gram -ve

Nephrotoxic, ototoxic

Question 65

Ceftriaxone

Answer 65

Inhibits bacterial cell wall synthesis

Question 66

Aciclovir

Answer 66

Inhibits viral DNA polymerase

Question 67

Oseltamivir

Answer 67

Viral neuraminidase enzyme inhibitor
- Prevents budding from the host cell, viral replication, and infectivity

Question 68

Amoxicillin

Answer 68

Inhibits bacterial cell wall synthesis

Question 69

Trimethoprim

Answer 69

Dihydrofolate inhibitor

Interferes with folate synthesis -> inhibits bacterial DNA synthesis

Avoid in pregnancy (1st trimester) -> neural tube defects

Question 70

Nitrofurantoin

Answer 70

Own class
Converted by bacterial nitroreductases to electrophilic intermediates which inhibit the citric acid cycle as well as synthesis of DNA, RNA, and protein.

Question 71

Doxycycline

Answer 71

Inhibits bacterial protein synthesis - acts on ribosomes

Question 72

Co-amoxiclav

Answer 72

Beta-lactam antibiotic (inhibits cell wall synthesis) +
Clavulanic acid - beta-lactamase inhibitor, stops bacteria inhibiting antibiotic

Question 73

Clarythromycin

Answer 73

Inhibits bacterial protein synthesis - acts on ribosomes

Question 74

Erythromycin

Answer 74

Inhibits bacterial protein synthesis - acts on ribosomes

Question 75

Azithromycin

Answer 75

Inhibits bacterial protein synthesis - acts on ribosomes

Question 76

Ofloxacin

Answer 76

Inhibiting two enzymes involved in bacterial DNA synthesis (DNA topoisomerase)