Control of Blood Flow PDF

Summary

These lecture notes cover the control of blood flow, including the role of the autonomic nervous system, the endothelium, and local metabolites. The document also discusses related topics, such as flow auto-regulation, active/reactive hyperaemia, and coronary blood flow.

Full Transcript

Life Sciences & Medicine

Control of blood flow
Dr Greg Knock
(after PI Aaronson)

Dpt. of Physiology

PHYSIOLOGY AND ANATOMY OF
SYSTEMS
4MBBS102/1B1
 Learning Objectives

After studying this lecture, you should be able to:

Describe the mechanisms which regulate vascular tone, including the role of the
autonomic nervous system, the endothelium and local metabolites

Describe other local mechanisms regulating vascular tone: flow auto-regulation, and
active/reactive hyperaemia

Describe the important factors which control coronary blood flow and the effects of
increased heart rate and coronary stenosis
 Common diseases of the vasculature

Hypertension Atherosclerosis

Heart failure Kidney disease Coronary Vascular dementia
heart
disease

Cerebral Stroke
Retinopathy
haemorrhage

Excessive vasoconstriction contributes to hypertension Narrowing of arteries due to
Many anti-hypertensive drugs are vasodilators plaque/thrombosis reduces blood flow
 Regulation of vascular tone

Adjustment of vascular tone maintains appropriate blood flow to tissues.
1. Cardiac output and arterial BP drives the blood through all the organs.
2. Appropriate dilatation/constriction of resistance vessels directs blood flow as needed.
For example:
Coronary arteries dilate during exercise to supply the heart with more blood (this lecture)
Veins and arteries/arterioles in the lower extremities constrict to maintain central BP
during orthostasis (Integrated CV responses lecture)
Most vascular beds constrict during haemorrhage to maintain blood flow to the brain and
heart (Integrated CV responses lecture)
Tubuloglomerular feedback in the kidney adjusts afferent arteriolar resistance to stabilise
glomerular pressure (sem B renal lectures)
Vascular tone is the result of a balance between constricting and dilating influences
Under both central and local control

Adventitia
(P1-P2) r 4 Tissue metabolites
Flow = Smooth muscle
(local)
8VL
Endothelium

Blood-borne
hormones
* adrenaline constricts Constriction
(Adrenaline*,
most arteries but NO
angiotensin II) Direct dilation
dilates those in heart
and skeletal muscle Flow Indirect dilation
Pressure/stretch
Sympathetic
nerves
(noradrenaline)
Central Local hormones
control
 (1) The endothelium: Nitric oxide

The endothelium releases a substance which relaxes the surrounding smooth muscle.
This was initially termed endothelium derived relaxing factor (EDRF). Furchgott & Zawadzki (1980)

In 1987, EDRF was identified as the gas nitric oxide (NO)

NO release is stimulated by bradykinin, ATP, histamine, CO2, acetylcholine.

NO is also released by blood flow, thus it acts tonically to reduce BP.

The endothelium also releases prostacyclin (PGI2) which inhibits platelet aggregation,
and endothelin (a vasoconstrictor at ETA receptors).

Endothelin tends to be released by a different set of stimuli (e.g. Ang 2, thrombin),
often associated with pathological conditions.
 Mechanism of nitric oxide release
Vasodilating substances,
eg bradykinin, histamine
shear forces (flow)

+ L-arginine
[Ca2+]i eNOS Endothelium
+
NO

Smooth Muscle
 NO - mediated vasorelaxation

NO
(from endothelium)
SERCA

+
GC Ca2+ PMCA
K+
K+ GTP
channel + cGMP + GC = guanylate
cyclase
PDE SERCA = sarco/ endoplasmic
reticulum Ca2+ ATPase
Ca2+
desensitisation GMP PMCA = plasma
VGCC
membrane hyperpolarisation membrane Ca2+ ATPase

PDE = phosphodiesterase
Ca2+
cGMP activates protein kinase G
NO strongly enhances resting blood flow
blood flow restored

eNOS inhibitor
Blocks NO production
blood flow
falls
Applying substrate
restores NO
production
(2) The endothelium: endothelium-derived hyperpolarisation (EDH)
Vasodilating substances, EDH may be more important
eg bradykinin, histamine than NO in arterioles and
shear forces (flow) may be upregulated if the NO
system is impaired

[Ca2+]i
+ Endothelium
+
releases
hyperpolarisation

gap EETs, H2O2
junctions
K+

Smooth Muscle hyperpolarisation
 Oxidative stress causes endothelial dysfunction

Cardiovascular diseases are associated with inflammation leading to oxidative stress –
the overproduction of reactive oxygen species

NADPH oxidase superoxide hydrogen peroxide
O2.- H2O2
mitochondria

Superoxide reacts with nitric oxide to form peroxynitrite, thus preventing nitric oxide-
mediated vasodilatation.

Oxidative stress therefore tends to interfere with the ability of blood vessels to dilate.
 (3) Autonomic nerves
Smooth muscle cells in red SNS nerve fibres in green
Sympathetic nerves cause vasoconstriction,
especially in splanchnic, renal, cutaneous, and
muscle vascular beds.
Mainly noradrenaline via a1 receptors
Important in redistribution of blood flow and
for raising total peripheral resistance (TPR) to
raise MAP

Parasympathetic nerves causes vasodilatation
in salivary glands, pancreas, intestinal mucosa,
penis
Mainly acetylcholine via muscarinic receptors
The PNS regulates blood flow to these
organs, but its activation has no effect on
TPR since it affects so few vascular beds
 (4) Circulating hormones Dehydration
Posterior pituitary

Anti-diuretic hormone
(vasopressin)
Kidney
Renin/Angiotensin vasoconstriction

SNS
Angiotensin II raises TPR in response to reduced blood volume activation
Adrenaline
ANP lowers TPR in response to increased blood volume
Adrenal gland

Atria ANP vasodilatation
 Noradrenaline vs Adrenaline

Under normal (at rest)
conditions, noradrenaline is Noradrenaline Adrenaline
more important than circulating
adrenaline in mediating the
effects of the SNS on the
cardiovascular system.

The hormone adrenaline is
b1 a1 b2
secreted by the adrenal medulla.
This is increased during stressful
situations: fight or flight,
↑HR, cardiac Vasoconstriction vasodilatation in
hypotension & hypoglycaemia.
Contractility in most vascular beds skeletal muscle, heart
Blood levels rise 5-fold Via cAMP Via IP3/DAG Via cAMP
 (5) Local blood flow control: myogenic contraction
Important in vascular beds that need to maintain relatively constant blood flow (cerebral, renal)

Increased
perfusion Rat cerebral artery
pressure

Increased stretch
of smooth muscle

Depolarisation
and opening of
VGCC

[Ca2+]i
and contraction
Nimodipine = VGCC antagonist EGTA = Ca2+ chelator
 G-protein
Myogenic contraction Vasoconstrictor agonists coupled
involves stretch receptors

activated cation +
channels rho kinase
Stretch +
PIP2 Ca2+ sensitisation
Na+, Ca2+ phospholipase C
+ DAG + IP3
RGC +
sarcoplasmic
Na +
reticulum
+
SAC
Ca2+
Na+
Membrane VGCC
depolarisation +
Details in ‘Smooth
Ca2+ muscle function’
gap junction lecture
 (6) Local blood flow control: metabolic paracrine control

Important in vascular beds that need to increase blood flow to meet local metabolic demand
(skeletal and cardiac muscle)

During exercise, muscle O2 and ATP consumption is increased

Muscle metabolite production increases

Metabolites cause vasodilatation of nearby arterioles

The increase in blood flow is This vasodilatation washes away the metabolites
proportional to the increased and delivers more O2
metabolic demand
= ACTIVE HYPERAEMIA
 Tissue metabolites act directly on the vascular smooth muscle
Metabolising cell
↑ metabolism
K channels
+

K+ + ↑CO2 + H2O

Adenosine ATP
H2CO3

↑[K+]o
+ ↓O2 ↑H2O2
H+ + HCO3-
A2 receptor + +
inhibits
Na pump
+ K+ channels
2K+ Ca2+
3Na+ ↑cAMP
Voltage-gated
Hyperpolarisation Ca2+ channel
Hyperpolarisation

Smooth muscle Vasodilatation
 Mechanism of active hyperaemia in skeletal muscle
>START HERE<

Increased work being
done by muscle Activation of
sympathetic
nervous
Increased consumption of fuel and O2 system
+
Accumulation of CO2 and H+ in the muscle
Negative feedback

More adrenaline
arteriolar vasodilation in the muscle released into
Feed-fo circulation
r w ard Acting on b2
Increased blood flow to the muscle
receptors

More O2 and fuel delivered to muscle
+
Acid and CO2 removed more quickly
Reactive Hyperaemia in Skeletal Muscle Blood flow in leg muscle during
static exercise
Periods of compression
Compensation for periods of loss of blood flow

Periods of muscle contraction of increasing

Muscle arterial pressure
duration
During contraction, blood vessels are

(mm Hg)
compressed and blood flow ceases

After each period of compression, blood flow

Muscle blood flow
is increased above resting level

(ml/min)
(dotted line)

Extent of increase is proportional to the
duration of the compression
Time (min)
 Flow Autoregulation
‘Flow auto-regulation’ is when a tissue can regulate its own blood flow
Aim: To maintain tissue blood flow despite changing cardiac output or MAP

Flow auto-regulation has two complimentary mechanisms: Present in kidneys,
and heart at rest
Metabolic control - increases flow in response to
metabolite accumulation

‘Myogenic’ control - reduces flow in response to increased
pressure

The relative importance of metabolic compared to myogenic Especially important
regulation of arterial tone increases as resistance vessel diameter in the brain
decreases.
Special Requirements of the Cerebral Circulation

Brain metabolic demand remains
relatively constant, even during intense
physical activity

Not enough blood Too much blood
flow, neurons flow, vessels could
become starved of rupture – cerebral
O2 and quickly die haemorrhage

Thus cerebral blood flow must
remain relatively constant, despite
changes elsewhere in the body
How is this achieved? Flow Auto-regulation
 Cerebral blood flow is tightly controlled by flow auto-regulation

Cerebral arterioles respond to changes
Flow = P/R in perfusion pressure
(pressure within the blood vessels)
Flow = P/R immediate
Blood Flow (L/min/Kg)

increase
CO/MAP Haemorrhage
Flow = P/R in flow
increased

Constriction  Perfusion  Perfusion
pressure pressure

Arterioles Arterioles
constrict in dilate in
response response
Relaxation

Flow brought Flow brought back
back down to up to normal
immediate
fall in flow
P3 P1 P2 normal
if P falls Perfusion pressure (mm Hg)
 >START HERE<
Mechanism of cerebral
flow autoregulation cardiac output and/or
MAP increased

Cerebral blood flow Increased Cerebral perfusion pressure
more than needed increased
Negative feedback

CO2 washed away faster
Circumferential stretch of arterioles
than it is produced
myogenic
Opposite would occur if
CO2 in CO/MAP were reduced
metabolic Cerebral arteriolar
(E.g. after blood loss)
blood constriction

Brain blood flow remains
Cerebral blood flow decreased back to normal level matched to metabolic
demand in the brain
 Matching blood flow to metabolic demand in the coronary circulation

An increase in cardiac work requires a proportionate
Distribution of increase in cardiac muscle blood flow
blood flow at rest
Heavy Exercise
etc. 8%

Coronary blood flow (ml/min/Kg)
skin 8% liver and 800 ml/min
gut 25%
(splanchnic)
skeletal
muscle 20%
kidneys 20%
Moderate exercise
4%

400 ml/min
art

brain 15%
he

O2 consumption (ml/min/Kg)
4% of 5000ml/min At rest
= 200 ml/min 200 ml/min
Structural and functional adaptations of the coronary circulation
 High capillary density: ~ 1 capillary/myocyte

 Flow autoregulation at rest + strong active hyperaemia when
needed
 Adrenaline is a coronary vasodilator via b2 receptors.

 Left ventricular myocardium is only perfused during diastole
because intramyocardial arterioles are compressed during
LV RV
systole.

 It is vulnerable to ischaemia if coronary flow is reduced when:
Heart rate is increased (diastole shortens more than systole)
Coronary arteries are narrowed by stenosis
Diastolic pressure falls (eg. due to aortic stiffening)

 Formation of coronary collaterals promoted by ischaemia
 Mechanism of active hyperaemia in cardiac muscle
Resting metabolic Increased metabolic demand
demand Increased cardiac output
Resting cardiac
output Increased cardiac muscle work

High level of
contractile tone Increased O2 consumption
in coronary +
arterioles Increased metabolite production
(flow auto-

Negative feedback
regulation)
K+ From
adenosine ↑CO2
Activation of repeated cardiac
sympathetic nervous from ATP muscle Acid
Flow system metabolism repolarisations
maintained at
4% of cardiac Coronary arteriolar dilation (during diastole)
output Adrenaline
Acting on b2
receptors Increased flow in cardiac muscle
 Coronary blood flow varies during the cardiac cycle
It is at its peak
During It briefly rises
Blood can only flow when there is a during early
isovolumetric during the
pressure difference (P1-P2, DP) diastole when
contraction, ejection phase
myocardium is
coronary blood in line with
most relaxed,
flow falls to zero aortic
DP is at its lowest during systole when (or even briefly pressure
aortic pressure is
left ventricular arterioles are compressed still high and DP
reverses)
is high

And at its highest during diastole 100

120

Aortic pressure
80
mmHg

(ml/min)
DP Left coronary
40
blood flow
LV Pressure
0 0
systole diastole systole diastole
This becomes a major problem when heart rate is greatly increased
HR ~3-fold Therefore, diastole Therefore,
higher shorter perfusion time
shorter…
Heavy exercise: CO increased 4-fold

Mean Coronary
Cardiac Output Heart Rate Diastole Perfusion time
flow
L/min ml/min beats/min sec secs/min
REST 5.0 200 70 0.5 35
EXERCIS 20 800 180 0.13 23
E

…and yet mean coronary blood flow is still increased 4-fold, in line with cardiac output

Due to accumulated metabolites causing enhanced vasodilation during the shortened
diastole. There is a very large coronary flow reserve.
 Right ventricular blood flow continues throughout the cardiac cycle

120
DP remains substantive throughout the
Aortic pressure
80
cardiac cycle because RV pressure is so much
lower than LV pressure
mmHg

2
3 4
40
1

RV Pressure During systole, aortic pressure rises more
0
systole diastole than RV pressure, so DP actually increases
during systole
80

Right coronary Compression of vessels in the wall of the RV
(ml/min)

blood flow
is negligible

Blood flow is maintained
0 systole diastole
Stenosis impairs coronary blood flow – compensation by flow autoregulation
FLOW = DP /R Vasodilatory autoregulation compensates for
increased resistance caused by stenosis, but
Healthy coronary artery Stenotic coronary artery
only up to a point
resistance
≤ 50%
stenosis

coronary flow
reserve
plaque 70%

ia lic n
o
ra tab ilati
stenosis

pe e d
hy o m aso
em o
Flow

et mv
Du imu
≥90%
Microvasculature

ax
stenosis

M
pressure dilates in response

DP
DP
Large DP – strong flow Stenosis reduces DP
40 mM Hg DP
through microvasculature (and therefore flow) Chronic stenosis causes endothelial dysfunction,
through the impairing microvascular vasodilatation
Prolonged ischaemia causes the development of intra-arterial collaterals between
coronary arteries

Right coronary artery

Left anterior descending
coronary artery
↑ collateral Traupe T et al. Circulation. 2010;122:1210-1220
flow Copyright © American Heart Association, Inc. All rights reserved.
 Summary
Vascular tone is a function of vascular smooth muscle cell contraction/relaxation, which is controlled by multiple factors; these include ANS
activity, hormones, blood flow, internal pressure, metabolites, and autacoids, in particular those released by the vascular endothelium.
This combination of central and local influences allows the body to control the BP and regional vascular resistances in such way as to supply a
flow of blood to all of the organs which matches their metabolic needs and allows for renal regulation of the body fluid balance and
composition.
The vascular endothelium regulates vascular tone via NO, EDH and others. Endothelial dysfunction, often associated with oxidative stress,
tends to increase vascular tone, and makes an important contribution to cardiovascular disease.
Flow autoregulation, the ability of arteries to maintain a constant blood flow over a wide range of pressures, is mediated
by the myogenic response and metabolite washout. Metabolic hyperaemia allows tissues to regulate their own blood supply.
Coronary blood flow to the left ventricle occurs mainly during diastole due to a fall in the driving force for flow and compression of the
coronary branches which penetrate the ventricular wall
Under resting conditions, coronary blood flow is heavily autoregulated. When cardiac work increases blood flow to the heart can increase
greatly as a result of metabolic hyperaemia, which is especially pronounced in coronary arteries and arterioles with a diameter of