SNS Agonists Flashcards
From which region of the spinal cord do sympathetic fibres originate?
Thoracolumbar
Most sympathetic post-ganglionic neurones release noradrenaline. State two exceptions.
Adrenal medulla – adrenaline (80%) and noradrenaline (20%)
Sweat glands – acetylcholine
State the difference between directly and indirectly acting sympathomimetics.
Directly acting – binds to the adrenoceptor and mimic the action of adrenaline and noradrenaline by stimulating the receptors
Indirectly acting – inhibits the uptake and breakdown systems leading to the accumulation of neurotransmitter in the synaptic cleft
Describe the mechanism of action of the four different types of adrenoceptor.
ALL adrenoceptors are G-protein coupled
Alpha 1 = PLC -> IP3 + DAG
Alpha 2 = decrease cAMP
Beta 1 + Beta 2 = increase cAMP
State the main actions of beta-1 receptors.
HEART – increase heart rate + increase contractility
KIDNEYS – increase renin release -> increase blood pressure
Lipolysis
State the main actions of beta-2 receptors.
Bronchodilation
Hepatic glucose output – glycogenolysis + gluconeogenesis
Vasodilation of vessels to skeletal muscle
Relaxation of the uterus (in women)
State some effects that are mediated by both alpha and beta-receptors.
Exocrine secretions (e.g. salivary gland secretions become thick) GIT motility – decreased muscle motility and tone + contraction of sphincters
What receptors are responsible for the production of aqueoushumour by the ciliary body?
Beta receptors
State some effects of alpha-1 receptors.
Mydriasis (contraction of radial muscles of the iris)
Vasoconstriction
Constriction of trigone and sphincter in the bladder
Increased motility and tone of the ureters
Stimulates ejaculation (in males)
Lacrimation
Contraction of pilomotor muscle + increased localised secretion of sweat glands e.g. palm of hands
Hepatic glucose output (glycogenolysis and gluconeogenesis)
Lipolysis
What is the principle action of beta-blockers?
KIDNEYS – it inhibits the beta-1 mediated increase in renin secretion
It also decreases heart rate and contractility but its main action in reducing blood pressure is through the kidneys
Describe the relative selectivity of adrenaline and noradrenaline.
Noradrenaline is more selective for ALPHA-receptors
Adrenaline is more selective for BETA-receptors
Describe the action of pre-synaptic alpha-2 receptors.
Pre-synaptic alpha-2 receptors have a negative influence on noradrenaline synthesis and release
State five directly acting SNS agonists.
- What happens if you increase their concentration
Phenylephrine – alpha-1 Clonidine – alpha-2 Dobutamine – beta-1 Salbutamol – beta-2 Isoprenaline – beta 1+ beta 2 - these are relatively selective at low concentrations but with increased concentrations will also bind other receptors
Describe the development of hypersensitivity following first exposure.
After the first exposure you generate antibodies to the antigen andthese circulate around the body and bind to mast cells.
In the subsequent exposure, the mast cells are primed with the antibody on its surface.
Cross-linking of these antibodies on the surface of mast cells causes massive release of the stored mediators leading to the symptoms of hypersensitivity.
State some symptoms of hypersensitivity.
Increase in capillary permeability leads to increased movement of fluid into the tissues. This depletes the circulating fluid volume leading to adrop in blood pressure -> ANAPHYLACTIC SHOCK (and collapse the circulatory system leading to unconsciousness)
This can also lead to contraction of bronchial smooth muscle and constriction of muscles around the throat causing respiratory distress. It can also constrict GI smooth muscle causing vomiting and diarrhoea.
Why is adrenaline more effective than noradrenaline in dealingwith hypersensitivity?
During the hypersensitivity reaction, the most important problem to deal with is BREATHING.
Adrenaline is more selective for beta receptors than noradrenaline so is better at causing beta-2 mediated bronchodilation, thus opening up the airways.
Adrenaline also stimulates the heart via beta-1 to support blood pressure.
Adrenaline also acts on the alpha-1 receptors to cause vasoconstriction and an increase in TPR and blood pressure. Adrenaline can also slow down the release of histamine from mast cells via beta-2.