-----Short Term Control of Blood Pressure READ Flashcards

1
Q

What formula describes mean arteriolar pressure?

A

MAP = CO x TPR

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2
Q

Why does mean arteriolar pressure (MAP) need to be regulated?

A

Too low leads to fainting (syncope)

Too high leads to hypertension

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3
Q

What is the medical name for fainting?

A

Syncope

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4
Q

What is syncope?

A

Fainting

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5
Q

What is the baroreflex?

A

One of the bodies homeostatic mechanisms that helps to maintain blood pressure at nearly constant levels

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6
Q

What is the process of the baroreflex?

A

1) Aortic arch baroreceptors detect changes in blood pressure and send this information to the medullary cardiovascular centres by the vagus nerve, carotid baroreceptors detect changes and sent this information by the glossopharyngeal nerve
2) Responds by innervating the parasympathetic nerve (vagus) or sympathetic nerve depending on what response is required to return blood pressure to normal

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7
Q

What do aortic arch baroreceptors send information to the medullary cardiovascular centre through?

A

Vagus nerve

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8
Q

What do the carotid baroreceptors send information to the medullary cardiovascular centres through?

A

Glossopharyngeal nerve

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9
Q

Where do the aortic arch and carotid baroreceptor sends information to?

A

Medullary cardiovascular centres

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10
Q

What are other inputs to the medullary cardiovascular centres other than aortic arch and carotid baroreceptors?

A

Cardiopulmonary baroreceptors

Central chemoreceptors

Chemoreceptors in muscle

Joint receptors

Higher centres

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11
Q

Can long term regulation of blood pressure be done by arterial baroreceptors?

A

No, revolves around blood volume

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12
Q

How is long term control of blood pressure achieved?

A

Main sensors are cardiopulmonary baroreceptors

Effects tend to be hormonal

Act on blood vessels and kidneys

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13
Q

Is long term control of blood pressure achieved neurally or hormonally?

A

Hormonally

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14
Q

Is short term control of blood pressure achieved neurally or hormonally?

A

Neurally

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15
Q

What do hormones act on to achieve long term control of blood pressure?

A

Blood vessels and kidneys

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16
Q

What are examples of things that are used to achieve long term control of blood pressure?

A

Renin-angiotensis-aldosterone system

Vasopressin (antidiuretic hormone)

Atrial natriuretic peptide and brain natriuretic peptide

17
Q

How does the renin-angiotensin-aldosterone system regulate blood pressure in the long term?

A

Angiotensin II causes arteriolar construction and increases total peripheral resistance

Aldosterone increaes Na+ reabsorption and therefore increases plasma volume

18
Q

What effect does angiontensin II have?

A

Causes arteriolar constriction and increases total peripheral resistance

19
Q

What effect does aldosterone have?

A

Increases Na+ reabsorption and therefore increases plasma volume

20
Q

What is another name for vasopressin?

A

Antidiuretic hormone

21
Q

How does vasopressin (antidiuretic hormone) achieve long term regulation of blood pressure?

A

Causes arteriolar constriction and increases total peripheral resistance

Increases water permeability of collecting duct and therefore increases plasma volume

22
Q

How does atrial natriuretic peptide and brain natriuretic peptide achieve long term regulation of blood pressure?

A

Causes arteriolar dilation which decreases total peripheral resistance

Increases Na+ excretion and therefore decreases blood volume

23
Q

What is natriuresis?

A

Excretion of sodium in the urine

24
Q

What is excretion of Na+ in the urine called?

A

Natriuresis

25
Q

What are examples of when the baroreflex response would be used?

A

Due to posture

During the valva manoeuvre

26
Q

What is the effect of standing?

A

Increases hydrostatic pressure causing pooling of blood in veins/venules of feet and legs:

Decreases venous return, EDV, preload, stroke volume, cardiac output and mean arterial pressure
Decreases baroreceptor firing rate

27
Q

What is the baroreflex response to standing?

A

Decreases vegal tone

Increases sympathetic tone

28
Q

What is the impact of decreasing the vagus tone by the baroreflex whilst standing?

A

Increases heart rate and cardiac output

29
Q

What impact does the baroreflex increasing sympathetic tone when standing have?

A

Increase heart rate and cardiac output

Increases contractibility and increases stroke volume and cardiac output

Increases vasoconstriction which increases venous return, EDV, stroke volume and cardiac output

Increases arteriolar constriction which increases total peripheral resistance

30
Q

What effect does vasoconstriction have?

A

Increases venous return, EDV, stroke volume and cardiac output

31
Q

What does the tone of a nerve refer to?

A

Activity of the nerve

32
Q
A
33
Q

What is the valva manoeuvre?

A

Forces expiration against a closed glottis

34
Q

What is the process of the baroreflex being used during the valva manoeuvre?

A

1) Increase in thoracic pressure is transmitted through the aorta
2) Increase in thoracic pressure causes decrease in venous return, EDV, SV, CO and MAP
3) Decrease in mean arterial pressure is detected by baroreceptors which initiates reflex which increases cardiac output and total peripheral resistance
4) Decrease in thoracic pressure is transmitted through to the aorta
5) Venous return is resorted, so is stroke volume but reflex effects are not worn of
6) Everything returns back to normal