1. Autonomic drugs: Adrenoceptor Agonists and Sympathomimetics
Lecture 4

2. Introduction (review)
5 key features of neurotransmitter function, which can be targets for pharmacotherapy
Synthesis
Storage
Release
Termination of action
Receptor effects

4. Sympathetic agents MOA Direct acting Indirect acting
Directly stimulate the receptor
Indirect acting
Displace/release stored catecholamines from the nerve (ex. tyramine)
Decrease clearance of NE by
Inhibiting reuptake of catecholamines (ex. cocaine and TCAs)
By inhibiting NET (norepinephrine transporter)
By altering NET to become a reverse transporter
Preventing the metabolism of NE (ex. MAO inhibitors)
MAO – mono-amine oxidase

5. Normal activity of NET

6. Blockage of NET by cocaine

7. Blockage of and reverse transport of NET by amphetamine

8. MAO inhibitors

9. Sympathetic agents
NET EFFECT = increase NE activation or supply to the receptors
Binding of agonist or drug to receptors

10. Sympathetic agents MOA to the adrenoceptors
Act on G-protein coupled receptors, which then activates the 2nd messenger system
Receptor subtypes
Alpha
Beta
Dopamine

11. Adrenoceptors Receptor Location Alpha 1
Postsynaptic effector cells, especially smooth muscle
Alpha 2
Presynaptic adrenergic nerve terminals, platelets, lipocytes, smooth muscle
Beta 1
Postsynaptic effector cells (heart, lipocytes, brain)
Presynaptic adrenergic and cholinergic nerve terminals
Juxtaglumerular (JG) apparatus
Beta 2
Postsynaptic effector cells (smooth and cardiac muscles) D1
Brain, effector tissues, kidney vascular bed D2
Brain, effector tissues, smooth muscles

12. Sympathetic agents Alpha receptors Beta receptors Dopamine receptors

13. Sympathetic agents Selective
Majority of the drugs are selective (will preferentially bind to a specific receptor). But as concentration increases, the other receptors will also be stimulated.
Ex.
Phenylephrine is a selective α1 agonist. If given at higher doses, it may eventually stimulate α2 and even β receptors at toxic doses.

14. Relative receptor affinities
Alpha agonists
Phenylephrine, methoxamine
α1 > α2 >>>>> β
Clonidine
α2 > α1 >>>>> β
Mixed alpha and beta agonists
Norepinephrine
α1 = α2; β1 >> β2
Epinephrine
α1 = α2; β1 = β2
Beta agonists
Dobutamine
β1 > β2 >>>> α
Isoproterenol
β1 = β2 >>>> α
Albuterol, terbutaline
β2 >> β1 >>>> α
Dopamine agonist (Dopamine)
D1 = D2 >> β >> α

15. Sympathetic agents Receptor regulation
More for adrenoceptors than cholinoceptors
Down regulation or desensitization
There will be less response to the agonist
2 mechanisms
Slow desensitization (hours to days)
Decrease in receptor production (down regulation)
Rapid desensitization (minutes)
Decrease in function of a receptor thru phosphorylation (rapid negative-feedback effect)

16. Sympathetic agents Chemistry of catecholamines
Basic chemistry is that of phenylethylamine
Benzene ring + ethylamine side chain

17. Sympathetic agents
Substitution of H by OH at the 3 and 4 carbon atoms in the benzene ring will produce the group Catechol- amines
Epinephrine, Norepinephrine, Isoproterenol, Dopamine
Further substitutions or removal of OH among the different carbon atoms will alter the characteristics of the succeeding drugs.
Non-catecholamines: phenylephrine, methoxamine, ephedrine, amphetamine

18. Catecholamines

19. Non-catecholamines

20. Catecholamines Maximal alpha and beta activity
Inactivated by COMT (catechol-O- methyltransferase)
Found in the gut and liver = does not allow oral administration of epi and norepi
Absence of one or both OH groups on the phenyl ring
 susceptibility to COMT   bioavailability after oral adminstration   duration of action
 entry of drug to the CNS
Ex. non-catecholamines = phenylephrine and amphetamine

22. Catecholamines Alterations in the amine side-chain
Increasing the size of the amino group tends to increase βreceptor activity, with corresponding decreased α receptor activity (ex. NE  Epi  Isoproterenol)

23. Relative receptor affinities
Alpha agonists
Phenylephrine, methoxamine
α1 > α2 >>>>> β
Clonidine
α2 > α1 >>>>> β
Mixed alpha and beta agonists NE
α1 = α2; β1 >> β2
Epi
α1 = α2; β1 = β2
Beta agonists
Dobutamine
β1 > β2 >>>> α
Isoproterenol
β1 = β2 >>>> α
Albuterol, terbutaline
β2 >> β1 >>>> α
Dopamine agonist (Dopamine)
D1 = D2 >> β >> α

24. Catecholamines and non-catecholamines
Alterations in the amine side-chain
Substitution at the αcarbon  blocks metabolism by monoamine oxidase (MAO) =  duration of action
Ex. Ephedrine and amphetamine

25. MAO metabolizes 5HT and NE into inactive metabolites.
MAOI = inhibits destruction of serotonin and NE  increasing 5HT and NE stores.

26. Sympathomimetic agents
General Effects
Cardiovascular system
Compensatory reaction by the parasympathetic system
Alpha1
Arterial and venous vasoconstriction
Reflex response of HR
Skin, nasal mucosa and GIT vessels constrict
Alpha2
Mild vasoconstriction
More prominent CNS effect = vasodilation and chronotropy = BP

27. Sympathomimetic agents
General Effects
Cardiovascular system
Beta receptors
Heart = inotropy, chronotropy, dromotropy
Beta2 = vasodilation
Net effect = systolic but diastolic pressure
Dopamine receptors
D1 = Vasodilation of renal, splanchnic (GIT), coronary, cerebral
Improve perfusion to kidneys = urine output
Dopamine activates beta receptors in the heart
Dromotropy = AV conduction speed is increased

28. Sympathomimetic agents
Noncardiac effects
Lungs = beta2 = bronchodilation
Eye
alpha
pupillary dilation and increase outflow of aqueous humor
Beta antagonism
Decrease aqueous humor production
Genito-urinary
Alpha
Increase urinary sphincter tone (improve continence)
Ejaculation and detumescence

29. Sympathomimetic agents
Noncardiac effects
Fat cells
Beta2 = glycogenolysis and increase insulin secretion
Beta3 = lipolysis
Diabetogenic
Potassium
Beta2 = promote uptake of potassium into cells
Treatment for hyperK (salb, insulin, calcium)
Renin
Beta1 = increase secretion  blood volume  BP

30. Sympathomimetic agents
Noncardiac effects
CNS
Most seen among non-catecholamines
Increased alertness, attentiveness
Elevation of mood, insomnia, euphoria and anorexia

31. Adrenoceptors - Functions
Type
Tissue location
Action α1
Most vascular smooth muscle
Contraction
Pupillary dilator muscle
Contraction (dilates pupil)
Pilomotor smooth muscle
Erects hair
Prostate
Heart
inotropy α2
Post synaptic CNS neurons
Probably multiple (BP)
Platelets
Aggregation
Adrenergic and cholinergic nerve terminals
Inhibits transmitter release
Some vascular smooth muscle
Fat cells
Inhibits lipolysis
Dromotropy = passing thru AV node. Faster or shorter duration.

32. Type
Tissue location
Action β1
Heart, juxtaglomerular cells
chronotropy and inotropy
renin release β2
Respiratory, uterine and vascular smooth muscle
Smooth muscle relaxation
Skeletal muscle
Potassium uptake
Human liver
Activates glycogenolysis β3
Fat cells
lipolysis D1
Smooth muscle
Dilates renal blood vessels D2
Nerve endings
Modulates transmitter release

33. Sympathomimetic drugs
Endogenous catecholamines
Receptor activity
Effect
Epinephrine
α1 = α2; β1 = β2
Vasoconstrictor (except in muscles = vasodilation)
inotropy, chronotropy in heart
Norepinephrine
α1 = α2; β1 >> β2
BP
+ Inotropy, chronotropy
Dopamine
D1 = D2 >> β >> α
+ inotropy, chronotropy
Reward stimulus
renal perfusion

34. Sympathomimetic drugs
Direct Acting
Receptor activity
Effect
Phenylephrine
α1 > α2 >>>>> β
Mydriasis, decongestant, slight inc in BP
Methoxamine
Vasoconstriction and vagally mediated bradycardia
Alpha2 agonists
Clonidine,
methyldopa
α2 > α1 >>>>> β
BP.
Mild sedative
Oxymetazoline
α2 >>> α1
Topical decongestant (constrict nasal mucosa)
Isoproterenol
β1 = β2 >>>> α
Vasodilator, with increase in cardiac output with a fall in diastolic pressure

35. Direct Acting
Receptor activity
Effect
Beta agonists
Isoproterenol
β1 = β2 >>>> α
Vasodilator, with increase in cardiac output with a fall in diastolic pressure
Dobutamine
β1 > β2 >>>> α
CO with less reflex tachycardia

36. Sympathomimetic drugs
Mixed acting
Receptor activity
Effect
Ephedrine
β1 > β2 >>>> α
Mild stimulant
Phenylpropanolamine
α1 > α2 >>>>> β
Appetite suppressant
Cocaine
Affects pleasure centers

37. Uses Treatment of acute hypotension
Fluids first before sympathomimetic agents
Temporary emergency management of complete heart block
Drug induced cardiac stress test (dobutamine injection)
Local vasoconstriction
Mucous membrane decongestants  rebound hyperemia may follow.

38. Uses
Asthma
Anaphylaxis
Mydriatic agent

39. BREAK

40. Adrenoceptor Antagonists
Selectivity to a receptor depends on chemical structure and dose
MOA
Alpha blockers
Reversible: ex. phentolamine, prazosin, labetalol
Irreversible: covalent bond with receptor
Phenoxybenzamine
Beta blockers
Competitive antagonists
Well absorbed orally, but generally of low bioavailability
Extensive 1st pass effect in the liver
Affected by Cytochrome P450 inducers and inhibitors

41. Adrenoceptor Antagonists
Beta blockers
Average half life of 3-10 hours
Except esmolol = rapid effect and rapidly inactivated (10min) = good for hypertensive crisis

42. Adrenoceptor Antagonists
Receptor Affinity
Alpha antagonists
Prazosin, terazosin, doxazosin
α1 >>>>α2
Phenoxybenzamine
α1 > α2
Phentolamine
α1 = α2
Yohimbine, tolazoline
α2 >> α1
Mixed antagonists
Labetalol, carvedilol
β1 = β2 ≥ α1 > α2
Beta antagonists
Metoprolol, acebutolol, alprenolol
atenolol, esmolol, nevibolol, etc.
β1 >>> β2
Propanolol, carteolol, pindolol, timolol
β1 = β2
Butoxamine
β2 >>> β1

43. Adrenoceptor Antagonists = Opposite effect
Type
Tissue location
Action α1
Most vascular smooth muscle
Contraction
Pupillary dilator muscle
Contraction (dilates pupil)
Pilomotor smooth muscle
Erects hair
Prostate
Heart
inotropy α2
Post synaptic CNS neurons
Probably multiple (BP)
Platelets
Aggregation
Adrenergic and cholinergic nerve terminals
Inhibits transmitter release
Some vascular smooth muscle
Fat cells
Inhibits lipolysis
Dromotropy = passing thru AV node. Faster or shorter duration.

44. Adrenoceptor Antagonists = Opposite effect
Type
Tissue location
Action β1
Heart, juxtaglomerular cells
chronotropy and inotropy
renin release β2
Respiratory, uterine and vascular smooth muscle
Smooth muscle relaxation
Skeletal muscle
Potassium uptake
Human liver
Activates glycogenolysis β3
Fat cells
lipolysis D1
Smooth muscle
Dilates renal blood vessels D2
Nerve endings
Modulates transmitter release

45. Alpha Antagonists Phenoxybenzamine Irreversible alpha blocker
Also blocks histamine, Ach, and 5HT receptors
Reduces blood pressure when sympathetic tone is high useful for pheochromocytoma
ADR
orthostatic hypotension and tachycardia
Nasal congestion and inhibition of ejaculation

46. Alpha Antagonists Phentolamine Competitive blocker of α1 and α2
Vasodilation with direct and reflex tachycardia (due to antagonism to α2 receptors)
ADR: tachycardia, arrythmia
Used for tx of pheochromocytoma

47. Alpha Antagonists Prazosin, Terazosin and Doxazosin α1 blocker
Vasodilation with minimal effect on the heart
Relaxes prostate muscle (useful for BPH)
Half life
Half life (hours)
Prazosin 3
Terazosin
9-12
Doxazosin 22

48. Beta Antagonists Propanolol Metoprolol, atenolol
Non-selective beta blocker
Decreased chronotropy and inotropy
Mild bronchoconstriction
Metoprolol, atenolol
Selective beta1 blocker
Mild hypoglycemia and vasodilation

49. Beta Antagonist Nebivolol Esmolol Most selective beta1 inhibitor
Ultra short acting beta1 selective antagonist
Treatment for arrythmias, perioperative hypertension and myocardial ischemia

50. Mixed Antagonists Labetalol and carvedilol β1 = β2 ≥ α1 > α2
Decreased blood pressure, but with less reflex tachycardia due to low alpha antagonism

51. Uses – Alpha blockers Treatment for Other uses (not drug of choice)
Pheochromocytoma
Urinary obstruction and BPH
Other uses (not drug of choice)
Hypertensive emergencies
Chronic hypertension
Peripheral vascular disease
Erectile dysfunction

52. Uses – Beta blockers Treatment for
Angina and following myocardial infarction
Decrease work load and oxygen demand of heart
Heart arrythmias
Regulate heart rate and heart conduction speed
Chronic heart failure
Decrease cardiac remodeling
Glaucoma
Hypertension
Especially for patient with uncontrolled diabetes
In combination with a diuretic and a peripheral vasodilator

53. Uses – Beta blockers Treatment for Hyperthyroidism (for Propanolol)
Sympathetic antagonism and decreased peripheral conversion of T4 to T3 (more active to less active)

54. Precautions Beta blockers Beta2 blockers Hypercholesterolemia
May increase LDL and decrease HDL
Congestive heart failure?
Beta2 blockers
Patients with asthma
Use another anti-hypertensive drug
Patients with diabetes and inadequate glucose reserves
Inhibits lipolysis and glycogenolysis = available blood glucose = may promote hypoglycemia