Control of blood flow

Question 1

What is perfusion pressure?

Answer 1

Arterial bp - venous bp

Question 2

What is equation for tissue blood flow?

Answer 2

Perfusion pressure/resistance

Question 3

What is equation for resistance?

Answer 3

Poiseuille’s law

8 x viscosity x l / pi x r^4

Question 4

What are the two ways that blood flow can be controlled?

Answer 4

Change blood pressure

Change resistance

Question 5

3 ways of changing pressure?

Answer 5

Cardiac contraction (i.e. hormones, nerve, Starling)

Water/salt balance (i.e. blood volume through kidney, sweating)

Vessel compliance and tension

Question 6

Why does increasing volume increase pressure?

Answer 6

Blood virtually incompressible unlike air

Question 7

Normally increasing blood volume increases pressure, Why is increase in blood volume dampened in circulatory system?

Answer 7

Arteries are compliant and stretch to accommodate more fluid without proportional increase in pressure

Question 8

Why does bp increase with age (how do arteries change)?

Answer 8

Vessels more stiff and less compliant e.g. atherosclerosis

Question 9

What is problem with controlling blood flow by changing blood pressure?

Answer 9

Changes in bp often associated with pathology, and doesn’t allow local regulation to be achieved.

Question 10

What is after-load?

Answer 10

The resistance against which heart has to work to pump blood into arteries

Question 11

What is resistance to blood flow determined by (i.e. afterload)?

Answer 11

Diameter, total cross sectional area and blood viscosity

Question 12

Why are arterioles resistance vessels?

Answer 12

Greatest drop in blood pressure as blood flows through arterioles.

Question 13

Which vessel is mainly responsible for resistance to flow?

Answer 13

Arterioles

Question 14

How does blood flow change going from arteries through to veins?

Answer 14

Stays the same, from artery, arterioles, capillary etc

Question 15

How do pressure and resistance change as you go from artery to venules?

Answer 15

In arterioles, large rise in resistance and thus drop in pressure (to maintain constant flow)

Resistance then drops by the time you’ve reached capillaries and remains low, as does pressure.

Question 16

How can large arteries change to increase bp?

Answer 16

Large artery contraction reduces their compliance and increases bp

Question 17

Describe the state of the muscles of arterioles?

Answer 17

Most in tonic constriction due to symp stimulation

Question 18

How does increase in diameter by factor 2 change bp?

Answer 18

By factor 16

2^4

Question 19

Same flow throughout given vascular bed so greatest fall in pressure in region…

Answer 19

Of greatest resistance

Question 20

How can arteriole resistance be altered?

Answer 20

Modulate vascular tone

Question 21

Describe how control of vascular tone of arteries and arterioles differ

Answer 21

Artery under extrinsic control only, arterioles both intrinsic and extrinsic

Question 22

High basal tone of arterioles in areas where….

Answer 22

Blood flow needs to be changed to greater degree e.g. skeletal muscle

Question 23

What happens when you vasoconstrict arterioles (to larger vessels and capillaries)?

Answer 23

Pressure upstream increases (hence hypertension in large vessels)

Also decrease capillary perfusion downstream

Question 24

What happens to capillaries as you vasodilate?

Answer 24

Increased capillary recruitment and increase capillary perfusion

Question 25

How do arterial and capillary bp change with vasoconstriction of arterioles?

Answer 25

Arterial bp increases

Capillary pressure decreases

Question 26

How does capillary recruitment occur, which tissue is it important for?

Answer 26

Some capillaries only recruited at higher perfusion pressures
important in skeletal muscle

Question 27

Describe relationship between arterial bp and blood flow

Answer 27

Directly proportional

Question 28

Where is high basal flow needed (which organs), what’s the consequence?

Answer 28

Vascular beds of kidneys and brain (otherwise renal failure, coma)

Question 29

What does perfusion normally match?

Answer 29

Metabolic rate

Question 30

Which organs are overperfused (greater than metabolic need, why?

Answer 30

Other/non-metabolic need for high blood flow

Kidney: blood needed to be filtered

Skin: blood to lose heat

Question 31

Which organs are usually underperfused?

Answer 31

Brain and heart

Question 32

What are some extrinsically triggered factors that can affect local flow?

Answer 32

Sympathetic: Adrenaline, noradrenaline

Parasympathetic: Acetylcholine

Angiotensin

Question 33

What are some local autocoids that control blood flow locally?

Answer 33

Histamine
Bradykinin
Prostaglandis
Leukotrienes
Endothelins
NO

Question 34

What are metabolic factors that control blood flow locally?

Answer 34

High extracellular K+
Acidity
Adenosine
Temp
Hypoxia

Question 35

Where do we not see autoregulation?

Answer 35

Pulmonary, cutaneous

Question 36

What does autoregulation allow?

Answer 36

Tissues to control/stabilise perfusion independent of arterial bp

Question 37

What is the Bayliss effect?

Answer 37

Myogenic autoregulation keeps blood flow constant. as blood pressure distends vessels, they undergo sustained contraction (maintains basal tone)

Question 38

What is the mechanism behind the Bayliss effect?

Answer 38

Stretch creates tension, opens non-specific cation channels, opens voltage gated Ca2+ channels, raised concentration of Ca2+ leads to contraction of the vessel.

Question 39

What can override autoregulation?

Answer 39

Local metabolic control

Question 40

How can high perfusion pressure contribute to autoregulation?

Answer 40

Increased perfusion pressure increases blood flow, flushing away vasodilators so vascular tone increases

Question 41

How can local metabolic control allow flow to a individual vascular bed to be controlled?

Answer 41

Flow altered based on tissue’s metabolic demand. Arterioles sensitive to metabolic demands of tissue

Question 42

What can trigger increase in local factors?

Answer 42

Increased metabolites, ischaemia, increased sheer stress to elevated blood flow

Question 43

What do metabolic byproducts cause, why is this important?

Answer 43

Vasodilation, increased blood flow through vascular bed for increased oxygen supply and waste removal

Question 44

What is metabolic hyperaemia?

Answer 44

Increase in blood flow to a more metabolically active tissue

Question 45

Where is adenosine release important?

Answer 45

Coronary circulation, less so skeletal

Question 46

How does adenosine cause vasodilation?

Answer 46

Increased ATP demand in coronary vessels as oxygen consumption increases

Less ATP available as it’s used up, AMP builds up released from cells

Forms adenosine (primary product of ATP breakdown)

Stimulates A2A receptors on smooth muscle

Increases cAMP

Decreased MLCK activity (PKA phosphorylates) vasodilation

Question 47

What does adenosine do to kidney circulation?

Answer 47

Vasoconstriction (A1 adenosine receptor)

Question 48

Where is acidity an important local factor?

Answer 48

The brain

Question 49

How does acidity lead to increased cerebral circulation?

Answer 49

Increased rate of metabolism/respiration/oxidative phosphorylation

Increased pCO2

Increased carbonic acid concentration

Increased acidity decreases open probability of ion channels in membrane and inhibits MLCK

Vasodilation

Question 50

What does low pCO2 cause to vessels in brain, what are the symptoms?

Answer 50

Vasoconstrict, so dizziness

Question 51

Where is accumulation of K+ important metabolic factor?

Answer 51

Skeletal muscle and brain

Question 52

What is the mechanism for increased K+ extracellularly and blood flow?

Answer 52

K+ release by action potentials in active muscle fibres

In intense exercise, high frequency of AP fired, not all of K+ can go back into cell

Small increase in extracellular potassium conc

Leads to Increased potassium permeability

Hyperpolarisation as Ek is neared

Vasodilation

Question 53

Where does reactive hyperaemia occur?

Answer 53

Skeletal muscle

Question 54

What is reactive hyperaemia?

Answer 54

If you contract muscle, muscle compresses arterioles and capillaries, TPR increases, leading to ischaemic tissue then you accumulate metabolites,

When you release compression, leads to massive increase in blood flow as these vasodilator metabolites cause vasodilation

Question 55

How can metabolic demand be coupled to blood flow given arterioles are upstream of capillary beds?

Answer 55

Arteriole can affect capillary perfusion

Intracellular signal in response to vasoactive substance propagating through gap junctions.

Paracrine signalling, e.g. in nephron, cells of macula densa which sense metabolic demand and are stuck on top of afferent arteriole.

Question 56

Why is local control systems better than sympathetic stimulation to control vascular tone?

Answer 56

Sympathetic system can’t be used as well to respond to needs of a particular tissue/organ

Question 57

How is endothelium important in control of blood flow, what does it respond to?

Answer 57

Produce modulators of local vessel tone in response to changes in local environment

Question 58

What does endothelium produce (gas) and when?

Answer 58

NO produced in response to hypoxia, shear stress, circulating neuroendocrine factors (e.g. Ach, bradykinin)

Question 59

How is NO made?

Answer 59

Stimuli increases intracellular calcium, binds calmodulin and activates eNOS (produces NO)

Question 60

What happens to NO after it’s made?

Answer 60

Diffuses into vessel wall, activation of guanylyl cyclase, cGMP made, activates PKG

Question 61

What does PKG phosphorylate?

Answer 61

MLCP which is activated to inhibit MLCK

K+ channels (which open) so reduced Ca2+ influx through VGCC

SERCA - so Ca2+ removal from cytosol

Ca2+ channels so they open less

Question 62

What else apart from NO does endothelium produce?

Answer 62

Prostacyclin 2
PGE2
Endothelium derived hyperpolarising factor

Question 63

What are some vasoconstrictors?

Answer 63

Thromboxane AE, endothelins

Question 64

What are some autacoids that are vasodilators?

Answer 64

Prostaglandis
Leukotreienes
Histamine
Bradykinin
NO

Question 65

What produces Thromboxane A2?

Answer 65

Platelets

Question 66

Why is extrinsic control of blood flow important?

Answer 66

Fulfil wider CV functions and anticipate future demand (e.g. coordinated response to exercise)

Question 67

How does SNS lead to vasoconstrition?

Answer 67

NA acts on alpha 1 on vascular smooth muscle.

Also ATP and neuropeptide Y often cotransmitters with NA which cause rapid and long lasting vasoconstriction respectively

Question 68

What underpins resting tone of most arteries and arterioles?

Answer 68

Tonic activity of sympathetic vasoconstrictor fibres

Question 69

How does stimulation of beta receptors in kidney lead to vasoconstriction?

Answer 69

Activate renin angiotestin aldosterone system (RAAS)

Angiotensin 2 production and vasoconstriction through stimulation of AT1 receptors on smooth muscle

Question 70

How can sympathetic stimulation cause vasodilation?

Answer 70

Beta 2 receptors in arterioles (and some veins) supplying skeletal muscle. activated by NA

Question 71

How can parasympathetic fibres cause vasodilation?

Answer 71

In cerebral and coronary arteries, ACh released acting on M2 receptors on VSM. Hyperpolarisation and vasodilation

Question 72

What does ADH get produced in response to?

Answer 72

Fall in blood volume

Question 73

What releases ADH?

Answer 73

Posterior pituitary

Question 74

What does vasopressin do to blood vessels?

Answer 74

Vasoconstriction in most tissues but vasodilation in cerebral and coronary tissue (redistribute blood)

Question 75

When is renin secreted?

Answer 75

Fall in blood pressure and fall in Na+ in distal tubule

Question 76

What does renin do help to maintain bp and thus blood flow?

Answer 76

Converts angiotensinogen to angiotensin 1, which is converted to angiogensin 2 in lungs (by ACE). Angiotensin 2 causes vasoconstriction.

Also causes increased aldosterone secretion leading to greater salt and water reabsorption from distal tubule so increased blood volume

Question 77

What is ANP, where is it made?

Answer 77

Atrial natriueretic peptide made by atrial myocytes

Question 78

When is ANP made?

Answer 78

In response to high cardiac filling pressures. Triggers excretion of salt and water by renal tubules and weakly vasodilates resistance vessels

Question 79

How is coronary circulation mainly controlled?

Answer 79

Metabolic hyperaemia (adenosine)

Sympathetic stimulation
and circulating adrenaline (beta 2 receptors on VSM causes vasodilation)

Question 80

Why does oxygen extraction for heart need to be very high?

Answer 80

During periods of high cardiac work as contraction more forceful and frequent.

High pressure in ventricular wall in systole shuts off coronary circulation

Question 81

What are the 2 resistance vessels in cutaneous circulation, what controls them?

Answer 81

Arterioles (sympathetic and local metabolic control)

Arteriovenous anastomoses AVAs (sympathetic vasoconstrictors control only)

Question 82

How does fall in temp affect cutaneous circulation?

Answer 82

Receptors in hypothalamus detect it.
Sympathetic signalling increases so AVA constrict so high resistance shunt created and reduced cutaneous flow.

Directs blood away from surface of skin

Question 83

What is the effect of dilating AVAs?

Answer 83

Increased heat loss

Question 84

What are the different ways skeletal muscle circulation can be altered?

Answer 84

Metabolic hyperaemia (esp K+, some adenosine)
Capillary recruitment
Reactive hyperaemia
(autoregulation affects flow too)

Question 85

How does TPR fall in exercise, what stops it completely falling in exercise?

Answer 85

Metabolic hyperaemia (e.g. K+) causes vasodilation, TPR decreases.

Fall in bp detected by baroreceptors which trigger sympathetic activation to further increase perfusion of active muscle and prevent excessive fall in TPR.

Question 86

How is renal circulation controlled?

Answer 86

Autoregulation keeps flow constant

Angiotensin 2 and ADH (vasoconstrictors regulate renal blood flow)

Sympathetic stimulation: vasoconstriction

Question 87

What alters pulmonary circulation?

Answer 87

Hypoxia/hypercapnia arterioles constrict, diverting blood to well oxygenated areas (better V/Q mismatch). Pulmonary hypoxic vasoconstriction

Question 88

Why is there no autoregulation in pulmonary circulation?

Answer 88

If excessive vasoconstriction occurred in pulmonary regulation, blood from RHS of heart would not be able to bypass lungs to reach LHS and also lungs vulnerable to hypertension (oedema)

Question 89

What does 5HT do?

Answer 89

Vasodilator via NO production

Question 90

What does vagus stimulation to coronary resistance vessels do?

Answer 90

Dilates them

Question 91

True of false, lowered pH, and hypoxia causes relaxation of coronary vessels?

Answer 91

False, adenosine is the only real coronary vasodilator

Question 92

How do you calculate mean arterial blood pressure?

Answer 92

Estimated using a formula in which the lower (diastolic) blood pressure is doubled and added to the higher (systolic) blood pressure and that composite sum then is divided by 3

Question 93

Is MAP calculated by arithmetic average of diastolic and systolic pressure?

Answer 93

No

Question 94

When do the heart sounds come relative to the ECG?

Answer 94

1st: After QRS
2nd: After T wave

Question 95

Describe ECG for 3rd degree heart block

Answer 95

Third-degree AV block exists when more P waves than QRS complexes exist and no relationship (no conduction) exists between them.

Question 96

What vessels have the greatest compliance?

Answer 96

Veins