Exercise and Coronary Blood Flow

Question 1

Learning outcomes

Answer 1

• To explain the limits of cardiac perfusion and the difficulties in matching the body’s demand for cardiac output versus cardiac tissue demand.
• To predict and explain the changes in cardiovascular parameters in response to dynamic and static exercise.
• To relate the major systems and effectors of blood pressure together and explain their dependencies.

Question 2

Where do the coronary arteries start? When is the window for coronary flow?

Answer 2

• The coronary arteries are found on the coronary sinuses (aka aortic sinuses) of the right and left cusps of the aortic valve
• The window for coronary flow is during diastole, as this is when blood is able to flow through the coronary arteries

Question 3

What are 3 ways we can decrease the window for coronary flow?

Answer 3

1) Heart rate increase
* Increasing the heart rate will cause the periods of systole and diastole to be shorter
* This will result in less amount of time for coronary flow, which will decrease the size of the window of coronary flow

2) Ventricular pressure increase
* An increase in ventricular pressure from incomplete emptying, resulting in a decrease in the size of the window of coronary flow

3) Aortic pressure decrease
* This is the pressure that pushes blood into the coronary arteries
* If aortic pressure drops, this will decrease the size of the window of coronary flow

Question 4

What are 2 issues with coronary blood flow?

Why are these issues?

Answer 4

• Issues with coronary blood flow:

1) The myocardium cannot function anaerobically
* Anaerobic glycolysis causes an increase in lactic acid production

2) Arterioles of coronary arteries close mechanically during systole
* This results in a decrease in diastolic filling period during exercise, even though oxygen demand and metabolic demand increase during exercise

Question 5

How much does work output of the heart increase during strenuous exercise?

How much of coronary artery blood flow O2 is used at rest?

What must an increase in demand be met by?

Answer 5

• Work output of the heart increased 6-9x during strenuous exercise
• 70-80% of coronary blood flow O2 is used at rest
• An increase in demand must be met by increase blood flow

Question 6

What is the primary controller of coronary blood flow?

What is it in proportion with?

What does it stimulate the release of?

Answer 6

• The primary controller of coronary blood flow is the local metabolism, which controls coronary artery radius
• Local metabolism is in proportion to the need of the cardiac musculature for O2 e.g more local metabolism leads to greater cardiac musculature need for O2
• Local metabolism leads to the release of vasodilators (e.g adenosine - present through breakdown of ATP), which increase blood flow.

Question 7

How does sympathetic stimulation indirectly and directly affect the coronary flow of the heart?

Answer 7

• Indirect Sympathetic stimulation of coronary blood flow:
• Sympathetic stimulation indirectly affects coronary flow by increasing heart rate and contractility, which increases metabolism and metabolic demands (O2)
• This will lead to an increase in coronary blood flow
• Direct sympathetic stimulation of coronary blood flow:
• The heart has a high degree of sympathetic innervation
• The role of this is unclear, but may contribute to pathophysiologies
• There is no reason we would want sympathetics to cause vasoconstriction of the coronary vessels, so it doesn’t make a lot of sense

Question 8

Where is noradrenaline released from?

What effect does noradrenaline have on skeletal muscles?

What receptors does it act on?

Answer 8

• Noradrenaline is released predominantly from the ends of sympathetic nerve fibres
• Noradrenaline causes vasoconstriction of skeletal muscle arterioles by acting on alpha1 receptors (α1 receptors)

Question 9

What is adrenaline (epinephrine)? What is it released by?

What is adrenaline part of?

What is it released in response to?

Answer 9

• Adrenaline (epinephrine) is a hormone and a neurotransmitter that is released by the adrenal medulla
• Adrenaline is part of the sympathetic nervous system and is released in response to fight or flight

Question 10

What 2 things does adrenaline act on?

Answer 10

• Adrenaline can act on:
  1) Alpha 1 (α1) receptors, which causes vasoconstriction of skeletal muscle arterioles
  2) Beta 2 (β2) receptors, which causes vasodilation of skeletal muscle arterioles

Question 11

How does vasodilation affect skeletal muscles?

How is vasodilation of skeletal muscle arterioles favoured during fight or flight responses?

Answer 11

• How vasodilation of skeletal muscle arterioles is favoured during fight or flight responses:
• Prolonged periods of fight or flight responses are mediated by circulating adrenaline
• Adrenaline has a higher affinity for Beta 2 receptors, which will favour vasodilation of skeletal muscle arterioles during the fight or flight

Question 12

How does moderate and intense exercise affect cardiac output?

How does exercise change the distribution of the cardiac output?

How and why is this done?

Answer 12

• During exercise the cardiac output increases from 5L/min at rest to 15L/min at moderate intensity and 30L/min at maximum intensity for highly trained athletes
• Exercise changes the distribution of the cardiac output to:

1) The heart and muscle
* Done through active hyperaemia
* Blood is shunted from the digestive viscera and skin to the heart, brain, and skeletal muscles
* This is due to the types of receptors found on each tissues type
* e.g more beta 2 receptors present in the brain, so adrenaline will cause vasodilation to the brain during fight or flight
* e.g more alpha 1 receptors in the skin, so adrenaline will cause vasodilation to the skin during fight or flight
* Blood is directed towards

2) Skin
* The core temperature increases
* Detected by the hypothalamus
* Decreased sympathetic innervation to the skin

Question 13

What is pulse pressure?

Answer 13

• Pulse pressure is the difference between systolic and diastolic pressure

Question 14

how does moderate excursize effect pulse pressure?

Answer 14

1) Pulse pressure (increase)
* Moderate exercise increases pulse pressure
* This is due to an increase in systolic pressure, which is caused by an increase in stroke volume and speed of ejection

Question 15

how does moderate exercise effect cardiac output?

Answer 15

2) Cardiac output (increase)
* Big Increase in HR due to decreased parasympathetic innervation to SA node and increase sympathetic innervation to the SA node

Question 16

how is stroke volume effected during moderate exercise?

Answer 16

• Increase in stroke volume due to increased contractility and increases Frank Starling

Question 17

how does moderate excursize effect peripheral resistance?

Answer 17

peripheral resistance will decrease.

Question 18

What needs to happen for Cardiac output to increase during exercise?

Answer 18

• Cardiac output can only be increased to high levels if venous return is increased to the same degree

Question 19

What are 4 factors promoting venous return during exercise?

Answer 19

• 4 factors promoting venous return during exercise:
  1) Skeletal muscle pump activity
  2) Frequency and depth of inspiration
  3) Venous tone via sympathetic innervation
  4) Ease of flow from arteries to veins through dilated skeletal muscle arterioles

Question 20

What is dynamic exercise?

What does it initiate?

What are examples of dynamic exercises?

Answer 20

• Dynamic exercise is defined as rhythmic muscular activity resulting in movement
• it initiates a more appropriate increase in cardiac output and oxygen exchange
• Examples of dynamic exercise include running, swimming, cycling, weightlifting, as these all involve joint movement

Question 21

How does dynamic exercise affect the kidneys?

Answer 21

decreased distribution of blood to the kidneys = decreased urine output.
- feedforward release of ADH = further enhances fluid retention
- this is because of increased losses of fluids occur through sweating and increased respiration.

Question 22

How does dynamic exercise affect MABP?

Answer 22

• mean arterial blood pressure may increase slightly but is generally not elevated greatly due to the changes in cardiac output and total peripheral resistance balancing out.
• Pulse-pressure may increase, due to increased systolic pressure

Question 23

Other stuff to consider during dynamic exercise

Answer 23

• Other stuff to consider during dynamic exercise:
• During dynamic exercise, blood flow to exercising muscle becomes subject to similar problems seen in the myocardium: Contraction of skeletal muscle means blood perfusion is restricted to the time the muscle spends relaxed.
• If insufficient time is spent in the relaxed state, blood supply may not match demand. Lactic acid can also build up in skeletal muscle during anaerobic exercise

Question 24

Name the changes in these factors due to dynamic exercise:
* Skeletal muscle blood flow
* Total peripheral resistance
* Stroke volume
* Heart rate
* Cardiac output
* MABP
* Systolic arterial pressure
* Diastolic arterial pressure
* Renal blood flow
* Renin release
* Vasopressin release
* Urine production

Answer 24

Name the changes in these factors due to dynamic exercise:
* Skeletal muscle blood flow
* Total peripheral resistance
* Stroke volume
* Heart rate
* Cardiac output
* MABP
* Systolic arterial pressure
* Diastolic arterial pressure
* Renal blood flow
* Renin release
* Vasopressin release
* Urine production

Question 25

What is static (isometric) exercise?

What is an example of static exercise?

What are the physiological changes in cardiac output, total peripheral resistance and MABP during exercise?

How does the ANS changes involves in static exercises compare with that of dynamic exercises?

Answer 25

• Static (isometric) exercises are contractions of particular muscle for a long period of time without movement e.g planking
• During static exercise, the same changes in ANS input to the heart occur as in dynamic exercise – therfore cardiac output increases.
• However, the contraction of muscles for a prolonged period both (a) increases venous return to the heart and (b) occludes arteries and prevents tissue perfusion – therfore total peripheral resistance increases considerably.
• The net effect is a huge increase in mean arterial pressure.

Question 26

is salbutamol a B2 agonist or antagonist?

Answer 26

agonist
- helps to open the airways

Question 27

decrease In oxygen?
increase in oxygen?

Answer 27

decrease = vasodilation
increase = vasoconstriction

Question 28

is CO2 a vasodilator or constrictor?

Answer 28

vasodilator

Question 29

what happens to systemic vasculature resistance during moderate/dynamic exercise?

Answer 29

it would decrease = vasodilation

Question 30

what happens to water retention during exercise?

Answer 30

dye to the change in osmolarity (sweat is salty) we will need increased water retention so we have a decreased urine output.

Question 31

what happens to the cardiac output during dynamic exercise?

Answer 31

• cardiac output increases
• done by increasing the heart rate and the stroke volume.
• Venous return to the heart increases, due to compression of veins within the exercising muscles

Question 32

describe the feedforward system for physical activity?

Answer 32

• body prepares for physical activity to happen
• increased cardiac output and decreased peripheral resistance
• released of anti diuretic hormone to increase water retention and decrease urine output
• allows the resetting of baroreceptors upwards, to mute the effect of increased arterial pressure on the normal reflex mechanisms they would otherwise induce.

Question 33

how does blood flow during exercise increase?

Answer 33

• increased use of muscles
• increased metabolic factors causing vasodilation
• increased blood flow

Question 34

what does increased arterial dilation cause and how can it be restricted?

Answer 34

= decreased peripheral resistance
- can be restricted by the redirecting of blood from the organs = increased blood flow.

Question 35

describe physiological changes during static exercise?

Answer 35

the same changes in ANS input to the heart occur as in dynamic excerise.
- increased cardiac output.

Question 36

how does total peripheral resistance increase during static exercise?

Answer 36

• prolonged contraction of muscles
• increased venous return
• occlusion of arteries preventing tissue perfusion

Question 37

what is the net effect of static excersise?

Answer 37

huge increase in mean arterial pressure.