Physiology: Arterial Blood Pressure and its Control (short & long term)

Question 1

Define blood pressure

Answer 1

The outward hydrostatic pressure exerted by blood on the vessel walls

Question 2

Define the systolic and diastolic blood pressures

Answer 2

Systolic:
- blood pressure exerted on systemic arteries when the heart contracts

Diastolic:
- blood pressure exerted on systemic arteries when the heart relaxes

Question 3

Define hypertension

Answer 3

A Bp > 140/90 mmHg in clinic
or
A daytime average Bp > 135/85 mmHg

Question 4

Define pulse pressure

Answer 4

The difference between the systolic and diastolic blood pressures

(systolic)-(diastolic)

Question 5

What is the range for a healthy Bp in adults?

Answer 5

90/60 to 120/80

Question 6

Describe how a sphygmomanometer measures Bp

Answer 6

• Cuff pressure is made to completely occlude the artery (cuff pressure > systolic pressure)
• Pressure is decreased until sound can be heard (1st Korotkoff sound)
• Sound is due to the turbulent flow of blood through the semi-occluded artery
• Pressure is decreased further until no sound can be heard (5th Korotkoff sound)
• Laminar flow restored

Question 7

What blood pressure is represented by the first Korotkoff sound?

Answer 7

The MAX systolic pressure

Question 8

What blood pressure is represented by the fifth Korotkoff sound?

Answer 8

The diastolic Bp

Question 9

What pressure gradient drives blood through the systemic circulation?

Answer 9

The pressure gradient between the right atrium (pressure nearly 0) and the aorta (high pressure)

Thus it is the MAP that drives blood in the systemic circulation

Question 10

Define mean arterial blood pressure (MAP)?

Answer 10

The average arterial blood pressure during a single cardiac cycle

Question 11

Give the 2 formulae for calculating the MAP from blood pressures

Answer 11

MAP = [(2x Diastolic)+(systolic)]/3

MAP = Diastolic + (1/3 Pulse Pressure)

Question 12

Give the range for a healthy MAP in an adult at rest

Answer 12

70 –> 105 mmHg

Question 13

What is the MAP required to perfuse the vital organs?

Answer 13

60 mmHg

Question 14

Give the formulae for calculating the MAP from cardiac output and systemic vascular resistance

Answer 14

MAP = CO x SVR

Question 15

Define cardiac output

Answer 15

The volume of blood being pumped by each ventricle of the heart per minute

Question 16

Define systemic vascular resistance (SVR)

aka TPR

Answer 16

The sum of resistance of all vasculature in the systemic circulation

Mainly from arterioles (~50%)

Question 17

Give the equation for calculating the cardiac output

Answer 17

CO = SV x Heart rate

Question 18

Define Total Peripheral Resistance (TPR)

Answer 18

The sum of resistance of all vasculature in the systemic circulation

The same as systemic vascular resistance

Question 19

Describe the effect of parasympathetic stimulation of the heart on MAP

Answer 19

Vagal stimulation
-->
heart rate decreases
-->
cardiac output decreases
-->
MAP DECREASES

Question 20

Describe the effect of sympathetic stimulation of the heart on MAP

Answer 20

Sympathetic stimulation
-->
heart rate increase
-->
cardiac output increase
-->
MAP increase

Question 21

Describe the effect of sympathetic stimulation of the arterioles on MAP

Answer 21

Sympathetic stimulation
-->
vasoconstriction
-->
SVR increases
-->
MAP increase

Question 22

Describe the effect of sympathetic stimulation of the veins on MAP

Answer 22

Sympathetic stimulation
-->
vasoconstriction
-->
venous return increases
-->
stroke volume increases
-->
Cardiac output increases
-->
MAP increases

Question 23

Define postural (orthostatic) hypotension

Answer 23

• Failure of Baroreceptor responses causing a drop in Bp

- Due to gravitational shifts in blood, when moving from horizontal to vertical position

Question 24

What mechanism manages acute changes in MAP?

Answer 24

The baroreceptor reflex

Question 25

Is the baroreceptor reflex a +ve or -ve feedback mechanism

Answer 25

Negative feedback control

Question 26

Describe a baroreceptor

Answer 26

• Mechanoreceptors
• Sensory neurons
• Detect ‘stretch’

Question 27

Where can baroreceptors be found

Answer 27

• Carotid sinuses (carotid baroreceptors)

- Aortic arch (aortic baroreceptors)

Question 28

Which nerves innervate the baroreceptors?

Answer 28

Carotid baroreceptors:
- glossopharyngeal nerve (cranial nerve IX)

Aortic baroreceptors:
- Vagus nerve (cranial nerve X)

Question 29

Describe the afferent firing of baroreceptors

Answer 29

Usually fire at normal rate

When MAP increases, firing rate increases

When MAP decreases, firing rate decreases

Question 30

What region of the brain receives the afferent signalling from the baroreceptors?

Answer 30

The cardiovascular control centre in the medulla

Question 31

What is the role of the cardiovascular control centre in the medulla with regards to the baroreceptor reflex?

Answer 31

• Receives afferent signals
• Relays info to other brain regions
• Generates vagal outflow to the heart (if needed)
• Regulates spinal sympathetic neurons

Question 32

What effect can the baroreceptor reflex have on the heart?

Answer 32

• Modify heart rate

- Modify stroke volume

Question 33

What effect can the baroreceptor reflex have on the vasculature?

Answer 33

Modify systemic peripheral resistance

Question 34

How is heart rate modified by the baroreceptor reflex?

Answer 34

To increase heart rate:
- Sympathetic stimulation

To decrease heart rate:
- Vagal stimulation

Question 35

How is stroke volume modified by the baroreceptor reflex?

Answer 35

To increase SV:

• Sympathetic stimulation of heart
• Sympathetic stimulation of veins (venoconstriction increases venous return, increasing SV)

To decrease SV:

• decreased sympathetic stimulation
• vagal stimulation has little effect

Question 36

How is SVR modified by the baroreceptor reflex?

Answer 36

To increase MAP:

• Increased vasomotor tone
• Vascular smooth muscle contracts
• Causing vasoconstriction
• Increasing SVR

To decrease MAP:

• decreased vasomotor tone
• Vascular smooth muscle relaxes
• Vasodilatation
• Decreasing SVR

Question 37

What type of vessel accounts for the majority of SVR?

Answer 37

Arterioles (~50%)

Question 38

In the baroreceptor reflex what happens to the corrective mechanism after the change in MAP has been corrected?

Answer 38

Negative feedback control stops the overcorrection

Question 39

Describe the ‘resetting’ of baroreceptors

Answer 39

• Baroreceptors reset what they consider a normal range
• Only stimulating a response again if there is an acute deviation from their current normal range
• Slow changes in MAP can avoid detection of the reflex, and raise its considered normal range

Question 40

Explain why the baroreceptor reflex fails to deal with slow rises in blood pressure

Answer 40

The change is to slow to be picked up the the baroreceptors

Slow enough that the baroreceptors reset their considered normal MAP range to match the raised MAP

Question 41

Describe the constriction of vascular smooth muscle at rest

Answer 41

They are partially constricted

Due to the vasomotor tone

Question 42

What is the vasomotor tone?

Answer 42

The continuous of sympathetic stimulation to vascular smooth muscle

Results in a continuous release or noradrenaline

Can vary in strength to modify vasoconstriction and vasodilation

Question 43

Describe the parasympathetic innervation of arterial smooth muscle

Answer 43

There is no significant innervation of arterial smooth muscle

(except in the penis and clitoris)

Question 44

What type of control mechanisms control long-term changes on MAP

Answer 44

Hormonal control of blood volume

Question 45

Describe the fluid compartments of the body

Answer 45

Intracellular:
- Intracellular fluid

Extracellular:

• Interstitial fluid
• blood plasma

Question 46

Describe what happens to the interstitial fluid volume if the blood plasma volume decreases

Answer 46

It decreases as compensatory mechanisms shift fluid from the interstitium to the the plasma compartment

Question 47

List the 2 main factors that affect extracellular fluid (ECF) volume

Answer 47

• Water excess/deficit

- Na+ excess/deficit

Question 48

What do hormones regulate in order to control the ECF volume

Answer 48

Hormones control the extracellular fluid volume (including Plasma Volume) by regulating the Water and Salt Balance

Question 49

List the hormone systems that regulate ECF volume

Answer 49

• Renin-Angiotensin-Aldosterone system (RAAS)
• Natriuretic peptides (NPs)
• Antidiuretic hormone (ADH
  (aka Arginine vasopressin)

Question 50

Describe how aldosterone is produced by the Renin-Angiotensin-Aldosterone System (RAAS)

Answer 50

• Juxtaglomerular cells in the kidneys release renin
• Renin stimulates the formation of angiotensin I from angiotensinogen
• Angiotensin I is converted to angiotensin II by the enzyme ‘angiotensin converting enzyme (ACE)’
• Angiotensin II stimulates the release of aldosterone from the adrenal cortex

Question 51

Where is angiotensinogen produced?

Answer 51

The liver

Question 52

Name the enzyme that converts angiotensin I –> angiotensin II

Answer 52

Angiotensin converting enzyme (ACE)

Question 53

Where is aldosterone released from?

Answer 53

The adrenal cortex

Question 54

Describe the role of angiotensin II in regulating blood pressure

Answer 54

1) It causes systemic vasoconstriction, increasing the SVR, thus increasing the MAP
2) Stimulates the release of aldosterone from the adrenal cortex. Increases water and Na+ retention
3) Stimulates thirst. Water intake increases –> plasma volume increases –> MAP increases
4) Stimulates ADH release. Increasing plasma volume

Question 55

Describe the role of aldosterone in regulating blood pressure

Answer 55

Aldosterone:

• Increases Na+ and water reabsorption in the kidneys
• Decreases Na+ and water excretion
• Plasma volume increases, thus Bp increases

Question 56

What stimulates the release of renin from the juxtaglomerular cells in the kidneys (starting the RAAS)?

Answer 56

• Low plasma volume and low Bp
• Decreased [Na+] in the renal tubular fluid
• stimulation of renal sympathetic nerves

Question 57

Where is Angiotensin converting enzyme (ACE) produced?

Answer 57

pulmonary vascular endothelium

Question 58

What is the rate limiting step for RAAS?

Answer 58

The secretion of renin from the kidneys

Question 59

Describe the natriuretic peptide control of Bp

Answer 59

Increase Na+ and water excretion in the kidneys
-->
Reducing blood plasma 
-->
BP decrease

Also decrease renin release, decreasing Bp

Also act as vasodilators (decrease SVR, decrease Bp)

Question 60

What causes Natriuretic Peptides to be released?

Answer 60

• Cardiac distension (hypervolemic state)

- Neurohormonal stimuli

Question 61

What inhibits the release of renin from the juxtaglomerular cells in the kidneys?

Answer 61

Natriuretic peptides

Question 62

Describe the role of the Natriuretic Peptides

Answer 62

To lower blood pressure and plasma volume

Acts as a county-regulatory system for the RAAS

Question 63

Name the 2 types of Natriuretic Peptide released by the heart

Answer 63

• Atrial Natriuretic Peptide (ANP)

- Brain-type Natriuretic Peptide (BNP
aka ventricular-type)

Question 64

Describe Atrial Natriuretic Peptide (ANP)

Answer 64

• 28 amino acid peptide
• synthesised and stored by atrial myocytes
• released in due to atrial distension (hypervolemic state)

Question 65

Describe Brain-type Natriuretic Peptide (BNP)

Answer 65

• 32 amino acid peptide

- synthesised by heart ventricles, brain and other organs

Question 66

Describe the synthesis of BNP

Answer 66

Prepro-BNP
-->
Pro-BNP
-->
BNP

Question 67

Describe the role of BNP in diagnosing heart failure

Answer 67

• Serum BNP and NT-pro-BNP can be measured to diagnose heart failure

Question 68

Describe the synthesis and storage of antidiuretic hormone (ADH)

Answer 68

ADH is derived from a prohormone precursor that is synthesised in the hypothalamus

• ADH is stored in the posterior pituitary

Question 69

What is another name for antidiuretic hormone (ADH)

Answer 69

vasopressin

Question 70

What stimulates the secretion of ADH from the posterior pituitary?

Answer 70

1) increased extracellular fluid osmolality
2) reduced extracellular fluid volume
3) increased plasma osmolality
* (osmolarity increases due to loss of water volume, thus ADH responds to changing water levels)

Question 71

How is plasma osmolarity monitored?

Answer 71

By osmoreceptors

• Mostly in the brain close to the hypothalamus

Question 72

Describe the mechanism of action of ADH

Answer 72

Acts in the kidney tubules to increase water reabsorption
-->
Increases ECF and plasma volumes
-->
Cardiac output increases
-->
Bp increases

Also causes vasoconstriction
–>
Increases SVR and Bp

Question 73

Describe the main role of ADH

Answer 73

To regulate plasma and interstitial fluid volumes and osmolarities

Question 74

Describe the main role of RAAS

Answer 74

Long term regulation of MAP

Question 75

Why don’t you check both carotid pulses simultaneously?

Answer 75

It would generate enough baroreceptor stimulation to cause hypotension that would lead to syncope or presyncope

Question 76

Describe why checking the carotid pulse causes baroreceptor stimulation

Answer 76

finger pressure causes partial occlusion of the artery
–>
causes a back pressure
–>
back pressure reaches the carotid sinus, causing it to stretch
–>
The increased stretch is detected by carotid baroreceptors