Control of blood flow

Question 1

What three things mainly control TPR?

Answer 1

→Poiseulle’s Law
→ myogenic response
→blood viscosity

Question 2

What does an increase in resistance mean?

Answer 2

→ Pressure must be increased to maintain the same flow

Question 3

What is the equation for blood flow? (CO)

Answer 3

→ Pressure gradient / TPR

Question 4

What is hypertension?

Answer 4

→ over constriction of arterioles

→ Higher arterial BP but less capillary flow - under perfusion

Question 5

What are the changes in blood flow when sedentary?

Answer 5

→ Superior mesenteric dilated
increased flow to intestines

→ Common Iliac constricted
decreased flow to legs

Question 6

What are the changes in blood flow when exercising?

Answer 6

→Superior mesenteric constricted
decreased flow to intestines

→ Common iliac dilated
increased flow to legs

Question 7

What does Poiseuille’s Law describe?

Answer 7

→ Parameters that govern TPR

→Illustrates why the radius of a vessel is such an important determinant in changing blood flow.

Question 8

What is the state of the BP and blood flow in arteries and arterioles in a normal situation?

Answer 8

→In a normal situation, the arteries have a greater BP than the arterioles.
→The pressure drop between the arteries and arterioles causes blood flow.

Question 9

What is the state of BP and blood flow when the arterioles are dilated?

Answer 9

→With the arterioles dilated, there is a decrease in TPR. →These leads to decreased BP upstream, but greater blood flow.

Question 10

What is the state of BP and blood flow when the arterioles are constricted?

Answer 10

→With the arterioles constricted, there is an increase in TPR.
→ This leads to increased BP upstream, but less blood flow.

Question 11

What is the equation for conductance ?

Answer 11

Conductance (G) = (πr^4)/(8ηL)

r: radius of vessel
η: blood viscosity
L: vessel length

(blood vessel radius to the power of 4 controls TPR)

Question 12

What is Poiseuille’s and Darcy’s Law combined?

Answer 12

→CO = Pa - CVP x (πr^4)/(8ηL)

Question 13

What is the r^4 effect ?

Answer 13

→Double the radius of vessel 2 compared to vessel 1
→ The change in r^4 is 16 x
→ 16x greater flow in vessel 2 as flow is proportional to r^4

Question 14

How do vasoconstrictors or dilators have large effects on blood flow?

Answer 14

→ Vasoconstrictors or dilators produce small changes in the vessel radius by affecting smooth muscle
→ these have large effects on blood flow

Question 15

What is the pressure in arterioles?

Answer 15

→40-50 mmHg amongst vessels

→ largest pressure drop

Question 16

What is the arteriole radius controlled by?

Answer 16

→ Tightly controlled by sympathetic nerves providing constant tone
→dilate and constrict

Question 17

What parameters is TPR controlled by?

Answer 17

→ Radius r^4
→ Pressure difference across vessels (P1-P2)
→ Length (L)

Question 18

Why do arterioles control TPR and not capillaries?

Answer 18

→ Capillaries are arranged in parallel so they have a low total resistance
→ R total = 1/R1 + 1/R2
→ arterioles are in series so total resistance is greater
→ R total = R1+R2

Question 19

How is local blood flow through individual organs/ tissues controlled?

Answer 19

→ Controlled by changes in radius of arterioles supplying a given organ/ tissue

Question 20

What are the control mechanisms for the arteriole radius?

Answer 20

→Intrinsic
factors are within the organs or tissues

→Extrinsic
factors are outside the organ or tissue

Question 21

What is Baylis’s myogenic response?

Answer 21

→ Increased distension of a vessel makes it constrict

→ Decreased distension of a vessel makes it dilate

Question 22

What is the function of Baylis’s myogenic response?

Answer 22

→ It maintains blood flow at the same level during changing arterial pressure

Question 23

In what circulations is Baylis’s myogenic response important?

Answer 23

→renal, coronary and cerebral circulation

Question 24

What happens when the muscle is stretched to make it contract ?

Answer 24

→ Ion channels open which depolarize leading to muscle contraction

Question 25

What is blood viscosity?

Answer 25

→Viscosity is the measure of internal friction opposing the separation of the lamina.

Question 26

What does blood flow depend on?

Answer 26

→ Viscosity
→ Vessel diameter
→ Haematocrit

Question 27

How much of the blood volume is at rest in systemic veins and venules?

Answer 27

60%

Question 28

What do veins function as?

Answer 28

→ reservoir

→ blood can be diverted from it in times of need

Question 29

What are properties of veins?

Answer 29

→ they are thin walled and collapsible, voluminous vessels

Question 30

How much of the blood volume do veins contain?

Answer 30

→2/3rds of blood volume

Question 31

What are veins innervated by?

Answer 31

→ smooth muscle which is innervated by sympathetic nerves

Question 32

what is the difference between arterial muscle and vein muscle?

Answer 32

→ Vein muscle is thinner and more compliant so forms a reservoir

Question 33

What does contraction of venous vessels do?

Answer 33

→ Expels blood into central veins
→Increases venous return/CVP/ End-diastolic volume
→ Increases SV

Question 34

What are the venous pressures in the limb veins at heart level?

Answer 34

→ 5-10 mmHg

Question 35

What is the central venous pressure?

Answer 35

→ 0-7mmHg

Question 36

What is the venous pressure in the foot vein while standing?

Answer 36

→ 90mmHg

Question 37

Why is the venous pressure high at the feet?

Answer 37

→ so high pressure is generated for return to the heart

Question 38

What is venous pressure helped by in the feet?

Answer 38

→ thoracic pump and skeletal muscle contraction

Question 39

what does stimulation of sympathetic nerves causing venoconstriction cause?

Answer 39

→ Shifts blood centrally
→ Increase in venous return, CVP and end diastolic pressure
→ Increased CVP increases preload and so increases SV

Question 40

What is the Bernoulli theory?

Answer 40

→ Mechanical energy of flow is determined by pressure, kinetic + potential energies

Question 41

How does blood flow from the heart to the feet in terms of kinetic energy, potential energy + pressure?

Answer 41

→There is a -90 mmHg pressure gradient against the flow from the feet back to the heart.
→The ejected blood has greater kinetic energy at the heart than the feet (more velocity).
→greater potential energy at the heart than at the feet (more height).
→The greater kinetic/potential energies overcome the pressure gradient to maintain flow.