CVS - autonomic system

Question 1

On what basis is the autonomic system divided into parasympathetic and sympathetic?

Answer 1

On anatomical grounds - where the spinal nerves exit.

Question 2

Some textbooks also divide the autonomic nervous system into a third division: sympathetic, parasympathetic and …

Answer 2

Enteric nervous system - a network of neurones surrounding the GIT. It is normally controlled by a mixture of parasympathetic and sympathetic fibres.

Question 3

Describe the general set up of the neurones in the parasympathetic nervous system e.g. start, middle and finish.

Answer 3

Two neurones arranged in parallel.

1. Pre-ganglionic neurone (cell body is in the CNS)
2. Post-ganglionic neurone
3. Target cell

Question 4

Where do the preganglionic neurones arise from in the sympathetic nervous system?

Answer 4

Thoracolumbar origin ( T1 to L2 or L3)

Question 5

Where do the pre-ganglionic and post-ganglionic neurones synapse in the sympathetic nervous system?

Answer 5

Most synapse in the paravertebral chain of ganglia but some synapse in a number of prevertebral ganglia (between paravertebral chain and target organ).

Question 6

Where do the preganglionic neurones arise from in the parasympathetic nervous system?

Answer 6

Craniosacral origin ( cranial nerves 3,7,9 and 10; S2-S4)

Question 7

Where do the cranial nerves arise from?

Answer 7

They are twelve pairs of nerves which arise directly from the brain, not from the spinal cord, and pass through separate apertures in the skull.

Question 8

Where do the pre-ganglionic and post-ganglionic neurones synapse in the parasympathetic nervous system?

Answer 8

They synapse with neurones in ganglia close to the target tissues. Then have short post-ganglionic neurones (these can actually be embedded within the wall of the target organ)/

Question 9

What neurotransmitters are released by the pre-ganglionic neurones and post-ganglionic neurones of the sympathetic system? What receptors are present for these neurotransmitters?

Answer 9

Pre-ganglionic: ACh (bind to nAChR)

Post-ganglionic NA (bind to adrenergic receptors)

Question 10

The sympathetic input to sweat glands is an exception - what type of neurotransmitter does this use?

Answer 10

Cholinergic (though some like hands are triggered by adrenaline too).

Question 11

Describe the specialisations of chromaffin cells of the adrenal medulla:

Answer 11

They are specialised postganglionic sympathetic neurones, with no axons. In response to ACh binding to their nAChRs they release adrenaline which circulates in the blood stream.

Question 12

What type of receptors does adrenaline and noradrenalin e work upon?

Answer 12

Adrenoreceptors = G protein-coupled receptors e.g. alpha1,2; beta1,2 (and others)

Question 13

Why do different tissues have different sub-types of adrenoreceptors? How is this useful to practitioners?

Answer 13

This allows them diversity in their actions/response to the same neurotransmitters. This can be used to selectively target drugs to specific tissues.

Question 14

What co-transmitters can also be released with NA or adrenaline at the synapse of post-ganglionic neurones with effector cells?

Answer 14

Neuropeptide Y (NPY) and ATP

Question 15

What neurotransmitters are released by the pre-ganglionic neurones and post-ganglionic neurones of the parasympathetic system? What receptors are present for these neurotransmitters?

Answer 15

Preganglionic - ACh (nAChR)

Post-ganglionic - ACh (mAChR)

Question 16

What type of receptors are muscarinic receptors?

Answer 16

G-protein coupled receptors - unlike nAChR they do not have an integral ion channel

Question 17

When is the sympathetic system dominant over the parasympathetic system and vice versa?

Answer 17

Sympathetic activity is increased under stress.

Parasympathetic system is more dominant under basal conditions.

Question 18

What is the sympathetic and parasympathetic actions on the pupil of the eye? Which receptors mediate these actions?

Answer 18

Sympathetic = pupil dilation (radial muscle contraction), mediated by alpha-1 receptors
Parasympathetic = pupil contraction (sphincter muscle contraction), mediated by M3 receptors.

Question 19

What is the sympathetic and parasympathetic actions on the airways of the lungs? Which receptors mediate these actions?

Answer 19

Sympathetic = relaxation of bronichole smooth muscle -> vasodilation of bronchioles, mediated by Beta-2 receptors
Parasympathetic = vasoconstriction, mediated by M3 receptors.

Question 20

What is the sympathetic and parasympathetic actions on the heart? Which receptors mediate these actions?

Answer 20

Sympathetic = increased chronotropy and ionotropy, mediated by beta-1 receptors
Parasympathetic = decreased chronotropy, mediated by M2 receptors.

Question 21

What is the sympathetic and parasympathetic actions on the sweat glands? Which receptors mediate these actions?

Answer 21

Sympathetic =
1. localised secretion (e.g. palms), mediated by alpha-1 receptors
2. Generalised secretion -> temperature control, mediated by M3 receptors
Parasympathetic = NO EFFECT!

Question 22

Sympathetic drive to different tissues is independently regulated. When is this not the case?

Answer 22

On some occasion (fight and flight) there can be a more co-ordinated sympathetic response.

Question 23

What does the ANS control in the cardiovascular system?

Answer 23

1. Heart rate
2. Force of contraction of heart
3. Peripheral resistance of blood vessels

Question 24

What is the affect of the ANS on electrical activity in the heart?

Answer 24

It does not initiate electrical activity - the heart has its own automaticity (a denervated heart still beats but at a faster rate (~100bpm)). Therefore the parasympathetic NS dominates (vagal influence) at rest -> a decrease in this natural heart rate set by SA cells.

Question 25

Describe the pre-ganglionic neurones of the parasympathetic input to the heart and where they synapse. What neurotransmitters and receptors do they use?

Answer 25

Preganglionic fibres = 10th cranial nerve (vagus). They synapse with the post-ganglionic cells on the epicardial surface or within the walls of the heart at SA and AV node.
Post-ganglionic cells release ACh which acts on M2 receptors.

Question 26

What is the effect of parasympathetic input at the SA and AV node?

Answer 26

Decreased chronotropy (heart rate)
Decreased AV node conduction velocity (it enhances the natural slowing down of conduction that occurs anyway at the AV node).

Question 27

Describe the pre-ganglionic neurones of the sympathetic input to the heart and where they synapse. What neurotransmitters and receptors do they use?

Answer 27

Pre-ganglionic fibres synapse with post-ganglionic at the sympathetic trunk/chain. The post-ganglionic fibres then innervate the SA node, AV node and myocardium. They release NA and act mainly on B1 receptors (B2 and B3 are also present but the main effect is mediated by B1).

Question 28

What is the effect of parasympathetic input at the SA, AV node and myocardium?

Answer 28

Positive chronotropy
Positive ionotropy (force of contraction).

Question 29

Why does the parasympathetic nervous system not cause a change in ionotropy?

Answer 29

The parasympathetic NS, unlike the sympathetic NS, does not innervate much myocardium.

Question 30

Where is the cardiovascular centre, that coordinates autonomic control of the heart, situated?

Answer 30

Medulla oblongata - lowest part of the brain stem

Question 31

What are the sensory receptors which input information on blood pressure to the cardiovascular centre?

Answer 31

baroreceptors in the carotid sinus and arch of aorta

Question 32

What is the pacemaker potential?

Answer 32

The slow depolarisation of SA cells by Na+ conductance through HCN channels, called the funny current (I(f)).

Question 33

What causes the upstroke of the SA node action potential?

Answer 33

Opening of fast VOCC

Question 34

What causes the downstroke of the SA node action potential?

Answer 34

1. Closing of VOCC

2. Opening of V-gated K+ channels

Question 35

What effect does sympathetic active have on the pacemaker potential?

Answer 35

It increase the slope of the pacemaker potential therefore causing faster depolarisation to threshold. Therefore increased chronotropy.

Question 36

What effect does parasympathetic active have on the pacemaker potential?

Answer 36

It decreases the slope of the pacemaker potential therefore causing slower depolarisation to threshold. Therfore decreased chronotropy.

Question 37

How does the sympathetic system cause a faster pacemaker potential and therefore increased heart rate?

Answer 37

1. Release of NA from post-ganglionic fibres at the SA binds to B1 receptors
2. These GPCRs (Gs) cause an increase in cAMP in the SA node cells which bind to and open HCN channels
3. Faster influx of Na+ occurs and therefore faster depolarisation to threshold.

Question 38

How does the parasympathetic system cause a slower pacemaker potential and therefore slower heart rate?

Answer 38

1. Release of ACh from post-ganglionic neurones at the SA bind to M2 receptors
2. The beta-gamma subunit of the Gi- protein of these GPCRs increases K+ conductance
3. The alpha subunit decrease cAMP levels which deactivates HCN channels
4. Therefore the fewer open HCN channels and increase in K+ conductance out of SA cell, causing a slower rate of depolarisation and therefore a slower action potential.

Question 39

How does the sympathetic system increase inotropy?

Answer 39

1. NA acting on B1 receptors in myocardium causes an increase in cAMP ->activation of PKA
2. PKA phosphorylates L-type Ca2+ channels, increasing Ca2+ entry during phase 2 of the AP (plateau-phase) and consequently Ca2+ entry from the SER via Ca2+ activated ryanodine receptors
3. Over several cycles this builds up the Ca2+ store and means that more Ca2+ can be released (and the higher the [Ca2+]the stronger the contraction)
4. Phosphorylation of phospholamban by PKA stops its inhibition of SERCA, leading to faster Ca2+ uptake, enhancing the amount of Ca2+ in stores and shortening systole.
5. It also causes an increase in troponin C sensitivity to Ca2+

Question 40

How are most blood vessels innervated by the autonomic NS?

Answer 40

By sympathetic innervation - with the exception of some specialised tissues e.g. erectile tissues which have parasympathetic innervation

Question 41

What type of adrenoreceptors are found in most arteries and veins? What about the arteries and veins in coronary and skeletal muscle?

Answer 41

Most - alpha-1 receptors

Coronary and skeletal muscle - ALSO have B2 receptors

Question 42

What is vasomotor tone? What determines the vasomotor tone?

Answer 42

Is the amount of tension of smooth muscle cells in the walls of blood vessels, particularly arteries. It is determines by the level of sympathetic input to alpha-1 receptors in the smooth muscle. Increased input .-> vasconstriction (increased vasomotor tone). Decreased input -> vasodilation (decreased vasomotor tone).

Question 43

Skeletal muscle, myocardium and the liver have B2 receptors as well as alpha-1 receptors in smooth muscle cells in blood vessel walls. What are the consequences of this?

Answer 43

Physiological concentrations of circulating adrenaline has a higher affinity for beta-2 receptors than alpha-1. Binding of adrenaline to beta-2 receptors causes vasodilation

Question 44

How does activation of B2 receptors cause smooth muscle vasodilation?

Answer 44

1. Gs-type GPCR is activated by circulating adrenaline
2. alpha-s subunit dissociates and activates adenyl cyclase
3. Activation of adenyl cyclase increases cAMP levels
4. cAMP inhibits MLCK
5. Phosphorylation of myosin light chain is decreased which results in a decrease in smooth muscle contraction = vasodilation

Question 45

At high circulating concentrations what receptor, other than B2, will it now bind to?

Answer 45

It will bind to alpha-1 receptors (which normally have a higher affinity for noradrenaline).

Question 46

What is the role of local metabolites on vascular tone?

Answer 46

They have a strong vasodilatory effect. This is more important for ensuring adequate perfusion of skeletal and coronary muscle than activation of B2-receptors.

Question 47

Name some metabolites which act as local vasodilators:

Answer 47

adenosine, K+, H+, increase pCO2.

Question 48

What is the difference in blood pressure detection of baroreceptors and atrial receptors?

Answer 48

Baroreceptors detect the high pressure side of the system whereas atrial receptors detect the low pressure side of the system.

Question 49

Describe how the CVS is controlled overall?

Answer 49

Changes in the state of the system (detected by baroreceptors and atrial receptors) are communicated to the medullary centers via afferent nerves. Higher centre of the brain also feed into the medullary centers. It alters activity of efferent nerves (sympathetic to blood vessels and sympathetic and parasympathetic to the heart) to change vascular resistance and cardiac output.

Question 50

How do baroreceptors detect changes in blood pressure?

Answer 50

They are nerve endings in the carotid sinus and aortic arch. When arterial pressure is increased it stretches these receptors.

Question 51

What is the baroreceptor reflex to an increase in mean arterial pressure?

Answer 51

1. Stretching of the baroreceptors sends signals down afferent pathways to the medulla.
2. The medulla decreases its sympathetic ouput to the the heart and blood vessels along its efferent pathway
3. This results in decreased chronotropy and vasodilation.

Question 52

What are sympathomimetrics?

Answer 52

They are drugs which mimic the action of the SNS e.g. alpha-adrenoceptor agonists, beta-adrenoceptor agonist

Question 53

What types of drugs act on the ANS?

Answer 53

1. Sympathomimetrics
2. Adrenoceptor antagonists
3. Cholinergics (muscarinic agonists and antagonists)

Question 54

Why is adrenaline administrated in a cardiac arrest?

Answer 54

1. Peripheral vasoconstriction ensures that blood is concentrated to the vital organs - brain and heart
2. Increases HR and force of contraction of heart

Question 55

Why is a beta-1 agonist (dobutamine) given in cardiogenic shock (pump failure)?

Answer 55

This is caused by not enough blood being pumped to maintain blood pressure. The B1 agonist will increase rate and force of contraction.

Question 56

Why is adrenaline administered for anaphylactic shock?

Answer 56

In shock blood vessels dilate and therefore blood flow to vital organs cannot be maintained. High concentrations of adrenaline activate alpha-1 receptors causing vasoconstriction.

Question 57

Why is adrenaline administrated in a cardiac arrest?

Answer 57

1. Peripheral vasoconstriction ensures that blood is concentrated to the vital organs - brain and heart
2. Increases HR and force of contraction of heart

Question 58

Why is a beta-1 agonist (dobutamine) given in cardiogenic shock (pump failure)?

Answer 58

This is caused by not enough blood being pumped to maintain blood pressure. The B1 agonist will increase rate and force of contraction.

Question 59

Why would you not give a non-selective B1/B2 antagonist to treat angina/ hypertension/ arrythmias in an asthmatic?

Answer 59

Becuase although it would work block B1 receptors in the heart and therefore decrease inotropy and chronotropy, it would also block B2 receptors in the bronchioles and cause bronchioconstriction.

Question 60

Why is salbutamol used as a treatment for asthma?

Answer 60

It is a beta-2 agonist - it causes relaxation of bronchiole smooth muscle and thereofre vasodilation of airways.

Question 61

Why are muscarinic agonist, such as pilocarpine, used in the treatment of glaucoma?

Answer 61

It activates M3 receptors in the sphincter of the eye which results in contraction of the sphincter muscles and therefore contraction of the pupil. This allows the aqueous humour to drain more and therefore reduces pressure in the eye.

Question 62

What would you give an asthmatic with hypertension instead of a non-selective B1/B2 antagonist?

Answer 62

A selective B1 antagoinst. This is cardio-selective and therefore there is less risk of bronchioconstriction.

Question 63

Why is a topical solution of muscarinic antagonist given to examine the eye?

Answer 63

It blocks M3 receptors and therefore causes pupil dilation.