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Flashcards in 10 Regulation of the Cardiovascular System Deck (41)
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1
Q

Q: What are veins considered? What do they have? What does central venous pressure determine?

A

A: storage vessels for blood volume - they have capacitance

the amount of blood flowing back to the heart

2
Q

Q: What is venous volume distribution affected by? (4)

A

A: -Peripheral Venous Tone

  • Gravity
  • Skeletal Muscle Pump
  • Breathing
3
Q

Q: What does venous return to the heart determine? (2) according to?

A

A: stroke volume- Starling’s law

the amount of stretch and hence determines the force of contraction

4
Q

Q: What do the arterioles determine? How?

A

A: -flow control (main control)

-varying constriction by altering vessel radius

5
Q

Q: What determines the extent of constriction? What does constriction determine?

A

A: the pattern of organisation of innervation to particular vascular beds i.e. the number of adrenoreceptors will affect the blood flow to an organ

-determines compliance and hence venous return

6
Q

Q: What are the 3 ways of regulating flow? Summarise.

A

A: Local Mechanisms
-Intrinsic to the smooth muscle itself or closely associated

Hormonal
-Circulating hormones

Autonomic Nervous System
-Innervates arterioles and veins to produce constriction or dilation

7
Q

Q: What do local mechanisms to regulate blood flow involve? define. Describe how this works when blood pressure drops. Draw a graph to show what happens without this mechanism.

A

A: autoregulation= the intrinsic capacity to compensate for changes in perfusion pressure by changing vascular resistance

there will be a gradual decrease in resistance and hence a gradual increase in flow

REFER 2 graphs- one for resistance and one for flow

8
Q

Q: What are the 2 theories behind the mechanism of ‘autoregulation’ to regulate blood flow?

A

A: Myogenic Theory = smooth muscle fibres respond to stretch (stress operated ion channels) - as pressure rises, the muscle fibres start contracting to keep flow constant

Metabolic Theory = if the vessels supplying a particular vascular bed contract, the flow to the vascular bed decreases and the vascular bed produces MORE METABOLITES - as more metabolites are produced, it feeds back on the vessel that’s supplying the bed and causes vasodilation and hence allows more flow to the vascular bed and the metabolites which triggered this response are washed away

9
Q

Q: How can autoregulation be changed?

A

A: by injury to the vessel - when a vessel is injured, platelets aggregate and they release serotonin which is a powerful vasoconstrictor which will constrict the injured vessel

10
Q

Q: In local mechanisms that regulate flow, what else is involved? 4 examples.

A

A: Substances released from the endothelium

Nitric Oxide - plays a key role in vasodilation

Prostacyclin + Thromboxane A2 (vasodilator and vasoconstrictor respectively)

Endothelins - potent vasoconstrictors

11
Q

Q: Which 3 substances are involved in the systematic regulation of blood flow by hormones? 1-interactions with? tend to? 2- secreted from? cause?

A

A: Kinins

  • Have complex interactions with the Renin-Angiotensin System
  • Tend to relax vascular smooth muscle

ANP (Atrial Natriuretic Peptide)

  • Circulating peptides that are secreted from the cardiac atria
  • As the atria stretch they release more ANP which causes vasodilation

Circulating Vasoconstrictors

12
Q

Q: Name 3 circulating vasoconstricters.

A

A: -Vasopressin

  • Angiotensin II
  • Noradrenaline
13
Q

Q: What do parasympathetic nerves consist of? (3)

A

A: LONG preganglionic fibre and a short postganglionic fibre - the parasympathetic ganglion will be right beside the sinoatrial node

14
Q

Q: Why are the parasympathetic and sympathetic systems important? (2)

A

A: Sympathetic - generally controls the FLOW

Parasympathetic - important in regulating HEART RATE

15
Q

Q: What do sympathetic nerve fibres innervate? Distribution? What does this mean?

A

A: ALL VESSELS EXCEPT CAPILLARIES (and precapillary sphincters and some metarterioles)

Distribution of sympathetic nerve fibres is NOT even - more sympathetic nerve fibres innervate vessels supplying the kidney, gut, spleen and skin and fewer innervate the skeletal muscle and the brain

there is more potential to constrict the blood going to these places so that we can divert blood to the organs that we need more

16
Q

Q: What is the relationship between circulating adrenaline and smooth muscle? causes? What can adrenaline bind to at high concentrations? result?

A

A: Circulating adrenaline binds with high affinity to smooth muscle beta-2-adrenoreceptors to cause vasodilation in some organs, however the effect is very concentration-dependent

At high concentrations, adrenaline can bind to ALPHA adrenoreceptors which can override the vasodilatory effects of the beta-2-adrenoreceptor stimulation and produce vasoconstriction

17
Q

Q: The constriction you see in blood vessels is the effect of which receptors?

A

A: alpha-1-adrenoreceptor

18
Q

Q: Where is the vasomotor centre VMC located? What does it consist of? (3) What does it allow in terms of exercise? due to?

A

A: bilaterally in the reticular substance of the medulla and the lower third of the pons

  • Vasoconstrictor Area (Pressor)
  • Vasodilator Area (Depressor)
  • Cardioregulatory Inhibitory Area

anticipatory response to exercise - your heart rate and ventilation rate will go up slightly before exercise because of these higher sensors in the brain

19
Q

Q: What can exert excitatory and inhibitory effects on the VMC? What do the lateral portions of the VMC control? how? (2) What do the medial portions control?

A

A: (vasomotor centre)
Higher centres in the brain (such as the hypothalamus)

heart activity by influencing heart rate and contractility

transmits signals via the vagus nerve to the heart that tends to decrease heart rate

20
Q

Q: What do blood vessels receive in terms of the nervous system? Which neurotransmitter is involved? What is there always? At baseline?

A

A: sympathetic postganglionic innervation

NORADRENALINE

  • some tonic activity
  • there is a certain frequency of the impulses which maintains vasomotor tone
21
Q

Q: What happens if you increase nerve traffic to blood vessels? Decrease? What is there not much of in the vascular system?

A

A: constrict the vessel

dilate the vessel

There is NOT much parasympathetic innervation of the vascular system

22
Q

Q: Which 3 areas control the vessel radius?

A

A: -Local Controls (Autoregulation)

  • Circulating Hormones
  • Sympathetic Vasoconstrictor Nerves
23
Q

Q: In terms of cardiac innervation, how can we change heart rate? What part of the heart receive innervation? which kind? What is normal resting heart rate? With no innervation?

What damage can be done so we lose the ability to increase heart rate? result?

A

A: by dual innervation - sympathetic and parasympathetic

sinoatrial nodal cells receive sympathetic and parasympathetic innervation

70, 100bpm

cut the sympathetic nerves and heart rate falls

24
Q

Q: What slows down heart rate? how? What increases heart rate? how?

A

A: Parasympathetic slows heart rate down because acetylcholine decreases the gradient of the pacemaker potential - this means that the potential takes longer to reach threshold and fire

Sympathetic increases heart rate because adrenaline and noradrenaline increases the gradient of the pacemaker potential so threshold is reached more quickly

25
Q

Q: By which law can force of contraction be increased? What kind of activity can increase the force of contraction? what can it control as a result? What can’t change the force of contraction?

A

A: Starling’s

  • sympathetic
  • heart rate

parasympathetic activity

26
Q

Q: What are the 2 ways noradrenaline increases heart contraction?

A

A: -Noradrenaline binds to Adrenoreceptors (eg beta 1) which increases the amount of cAMP which activates PKA which phosphorylates the L-type calcium channels and the SR calcium release channel and SERCA => get MORE CALCIUM INFLUX and more calcium taken back up into the stores

can also act on beta-1-receptors in heart

27
Q

Q: What can stroke volume be increased by? (2)

A

A: Increased Sympathetic Activity

Plasma Adrenaline

28
Q

Q: Describe intrinsic control of stroke volume. What else can affect this? (2)

A

A: venous return which sets the end-diastolic volume (stretch) which increases the force of contraction

  • can get more blood back to the heart (increase venous return) if we increase respiratory movements
  • decreasing intrathoracic pressure helps the filling of the heart
29
Q

Q: What can we get rapid changes in as part of the fight or flight response? (3)

A

A: RESPIRATORY MOVEMENT

PLASMA ADRENALINE

INCREASE SYMPATHETIC ACTIVITY

30
Q

Q: Where are baroreceptors? (2) What do they do? What are they?

A

A: aortic arch and in the carotid sinus (carotid bodies)

Baroreceptors in the carotid bodies feedback to the vasomotor centre via the glossopharyngeal nerve

The aortic arch baroreceptors feedback to the vasomotor centre via the vagus nerve

feedback nerves to the VMC

31
Q

Q: What are the 2 feedback nerves to the VMC?

A

A: (vasomotor)

Aortic Arch Baroreceptor = Vagus Nerve

Carotid Sinus Baroreceptors = Glossopharyngeal Nerve

32
Q

Q: Between which pressures do carotid sinus baroreceptors respond to? Between which pressures is the baroreceptor reflex most sensitive?

A

A: 60 and 80 mmHg

90-100mmHg

33
Q

Q: How do baroreceptors respond to an increase in pressure? result? (2)

A

A: fires more

Increase in baroreceptor firing = Increase in in parasympathetic activity AND DECREASE in sympathetic activity

34
Q

Q: Draw the reciprocal innervation diagram.

A

A: REFER

35
Q

Q: What connects sympathetic nerves? what do these structures do?

A

A: via a series of inhibitory interneurones which slows down the tonic activity

36
Q

Q: Parasympathetic stimulation of the heart occurs via? causes? What does parasympathetic activity reflect?

A

A: vagus nerve, decreased heart rate

exactly what happens in terms of baroreceptor activity

37
Q

Q: What does a decrease in sympathetic stimulation to the heart cause? (2) to the blood vessels?

A

A: decreased heart rate and stroke volume

vasodilation

38
Q

Q: What does nerve activity from the baroreceptors reflect? What results in increased blood pressure? fed back? triggers? Result?

A

A: rise or fall in pressure

huge increase in firing activity from the baroreceptor

increase in baroreceptor firing -> fed back to the vasomotor centre = triggers increased traffic in the vagus nerve

= brings about a decrease in heart rate

39
Q

Q: What does an increase in parasympathetic activity cause?

A

A: an increase in acetylcholine production in the SAN which decreases the gradient of the pacemaker potential and causes a decrease in heart rate

40
Q

Q: What does less innervation from sympathetic nerves lead to in terms of the heart? vessels? Overall result?

A

A: decrease in the force of contraction

increase in vessel radius

DECREASE IN BLOOD PRESSURE

41
Q

Q: What’s the equation for mean systemic arterial pressure?

A

A: Cardiac Output x Total Peripheral Resistance