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
→No sympathetic innervation/smooth muscle in capillaries so cannot alter radius.
→Less resistance is capillaries because bolus flow reduces viscosity

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.

Question 42

How does a cardiac output help venous return?

Answer 42

• the circulation is a closed system so the heart pushes the blood further through the vascular system via the arterial side of the capillary system into the venules and veins in the direction of the right side of the heart.

Question 43

How does breathing help venous return?

Answer 43

the pressure in the chest is negative on inhalation at the same time intra-abdominal pressure rises as the diaphragm moves downwards causing the venous valves in the pelvic veins to close, and the blood moves up into the thorax.

On exhalation, the intra-abdominal pressure decreases and the pelvic veins and inferior vena cava refill.

Question 44

How does muscle pump help venous return?

Answer 44

every muscle contraction squeezes the veins to push the column of blood in them in the direction of the heart.

When the muscle relaxes, the venous valves prevent the retrograde flow of blood towards the capillaries.

Question 45

How does venous tone help venous return?

Answer 45

the blood in the veins exerts pressure on the vein’s wall generating tension & maintain pressure.

sympathetic vasoconstriction can mobilise more blood back to the heart.

Question 46

What are the clinical implications of viscosity factors?

Answer 46

Haematocrit (45% rbc)
Typical blood  is 4-5 x H2O- Polycythaemia (high ) - Increased TPR & BP. Decreased flow.
Anaemia (low ) - Low TPR & BP. High HR (baroreceptor reflex) because low blood pressure. High HR to return heart rate to normal

2.Tube diameter(Fahraeus-Lindqvist effect)- Blood viscosity falls in narrow tubes (< 100 m vessels) cells move to centre reducing friction. Blood behaves as if it has a low viscous because cells are concentrated in the centre
Decreased resistance, increased flow, ie low resistance in micro vessels such as capillaries.

3. Red cell deformability reduced- Increased , reduced flow eg. sickle cell anaemia crises. Blood behaves as if it has a high viscous. Static flow= high viscocity
4. Velocity of blood- Slow venous flow in immobile legs – increased viscosity due to partial clotting.