Hemodynamics PDF

Summary

This document contains lecture notes on hemodynamics, specifically covering the relationship between flow, pressure, and resistance, as well as different aspects of blood circulation in the body. It includes explanations, outlines, and objectives, and is likely part of a course focused on physiology and medical sciences.

Full Transcript

 Outlines
Relationship between flow, pressure and resistance
and other physical property of blood circulation.
Blood flow: types, regulation
Blood vessels: types
Arterial Blood Pressure & regulation
Microcirculation
– Trans-capillary exchange
– Regulation
Characteristics of the venous system

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 Objectives
At the end of this session the students will be able to:
State the relationship among blood flow, blood pressure,
and vascular resistance.
Describe blood flow types & its regulation.

Identify characteristics of blood circulation in various

vascular segments.
Discuss about arterial blood pressure & its regulation.
Describe microcirculation and characteristics of venous
system.
 HEMODYNAMICS
Hemodynamics is the study of the relationship
between flow, pressure, resistance and other physical
principles of blood circulation.
It addresses the properties of both blood and blood
vessels.
Poiseuille and Hagen described factors governing
non-pulsatile flow of a homogeneous viscous fluid
through a rigid cylindrical tube with constant circular
cross-section.
Rate of flow, Q, is given by: L length
Q = Pr4 /8L R radius
/8 proportionality constants
P pressure
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 HEMODYNAMICS…
Though blood is a non-homogeneous and has a
pulsatile flow through distensible vessels, the law on
flow through rigid tubes:
– Is a good approximation to the flow of blood through the
vascular system.
– Facilitates our understanding on hemodynamics of the in
vivo circulation.
Therefore, the relation of geometry of vascular net
work, nature of blood (viscosity) , mean BP, can be
explained using Poiseuille’s law of laminar flow:
Q = Pr4 /8L
Blood flow (Q) is volume of blood that passes a given
point in the circulation per time.
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 Methods of Estimating Blood Flow
1. Electromagnetic Flow Metre
2. Indicator Dilution Method
3. Venous Occlusion Plethysmography
Venous Occlusion Plethysmography is the method
used for recording the curve of filling or enlargement
of organs.
Conventional methods used to estimate flow in the
extremities
It include air or water-filled plethysmographs.
Principle: the flow to part of the extremity measured
by venous occlusion plethysmography is equal to the
arterial inflow.
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Venous Occlusion Plethysmography
In estimating blood flow to the extremity, the part to
be
studied is enclosed in a plethysmograph (oncometer)
connected to a float or piston recorder to which is
attached a writing lever (Fig...).
Air-filled plethysmograph
When measurement is to be made, for example using
an air-filled plethysmograph, a pneumatic cuff is
placed around the part of extremity proximal to the
plethysmograph and quickly inflated to 70-80 mmHg.
This pressure is maintained for 15-20 seconds so that
an inflow curve (Fig..) is recorded on a moving drum.
The initial swelling rate (tangent to inflow curve)
measures flow to the enclosed part of the arm. 8
Application of Plethysmography
1. Assessment of:
 Intermittent claudication
 Vascular impotence
 Diabetic angiopathy
2. As a research tool on blood flow

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 Resistance to Flow (r)
This is an impediment to flow provided by a vessel or
circulatory bed.
Resistance to BF is:
– Directly proportional to the length of the vessel and
viscosity of blood.
– Inversely proportional to the 4th power of radius of the
vessel.
R=P/Q, analogous to Ohm’s law
=P÷Pr4 ÷8L Resistance progressively increase
from aorta to arterioles (due to
length &radius)
= 8L/ r4
 The r/ship of radius & R shows, organ blood flow is
effectively regulated by small changes in the caliber of the
arterioles.
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 Resistance to Flow (r)
 Variations in arteriolar diameter have such a
pronounced effect on systemic arterial pressure.
Using (R=P/Q) relationship one can assess resistance
in different vascular beds.
E.g. TPR  Aortic pressure  rt. Atrial pressure
Cardiac output
 Mean aortic pressure = 100mmHg
 Rt. Atrial pressure = 0mmHg
 Cardiac output =100mL/sec.
– Total peripheral resistance=100/100 =1 (mmHg/ml/sec) or
PRU
– Normal TPR range from 1-1.4 PRU
 Resistance to Flow (r)
E.g. Total pulmonary vascular resistance
– Mean pulmonary arterial pressure averages 16 mm
Hg and
– The mean left atrial pressure averages 2 mm Hg
– 16-2 mm Hg/100ml/sec0.14 PRU
Analogous to electrical circuits, vascular resistances
may be arranged in series or parallel.
 If in series, resistances are additive.
– E.g Renal vasculature where peritubular capillaries
are in series with glomerular capillaries),

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 Resistance to Flow (r)
 When in parallel (like in pulmonary and systemic
circulations) they are additive as reciprocals.
 1/RT= 1/R1+1/R2+1/R3, etc. i.e. in a parallel circuit,
RT is less than any of the individual R terms.
Majority of vascular resistances of organs and tissues
in the body are in parallel.
This provides a significant advantage leading to
greater flow.

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 Velocity of Blood Flow
Velocity (v) of blood flow is distance moved by RBCs per
unit time.
Velocity (V) is proportional to flow (Q) divided by the
area of the conduit (A):
V = Q ÷ Cross-sectional area (A=r2)
= (Pr4 ÷8L)÷r2
V = Pr2 /8L
Velocity (v) of blood flow is directly proportional to:
– The pressure difference (P) and
– Diameter of the vessels,
 Therefore, the average velocity of the blood is high in the
aorta (30-40cm/sec), declines steadily in the smaller
vessels, and is lowest in the capillaries (0.3mm/sec).
But inversely related to the viscosity of blood and length
of the blood vessel.
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 VISCOSITY
This is friction of molecules in the moving stream of
fluid.
It depends on:
– Concentration of suspended medium (e.g. RBC in blood).
Viscosity becomes high in polycythemia, and low in
anemia.
In anemia, decrease in O2-carrying ability of the
blood.
– But the improved blood flow due to decrease in viscosity
partially compensates for this.

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 Types of Blood Flow
1. Laminar or streamline blood flow
Flow of blood along a uniform tube at a fixed rate.
Laminar flow form infinite number of concentric
laminae or layers sliding upon one another are seen.
Innermost or axial layer has the highest velocity and
the outermost layer touching the lining of the tube
remains slow.
Laminar flow is silent
occurs throughout the normal CVS, except in the heart.

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 Types of Blood Flow
2. Turbulent Blood Flow
Blood flow indifferent directions in the vascular or heart
chamber.
Flow continues to be laminar (streamline) as long as the
product of velocity and diameter does not exceed a critical
value.
It becomes turbulent when the critical value is exceeded.
This value is determined by the Reynolds number Re.
It represents the ratio of inertia to viscous forces.
Re = ρVD/η,
where V= mean velocity
D=diameter of tube
η= viscosity
ρ=density of fluid
Laminar flow becomes turbulent when Re exceeds 2000.
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 Types of Blood Flow
Turbulent flow forms whirl.
Turbulent flow rarely occurs in the normal human
circulation.
It is not a feature of peripheral arterial or venous
circulation.
It may occur in the atria, ventricles and aorta under
conditions of severe exercise.

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 Types of Blood Flow
Turbulent blood flow produces sound.

Re may reach 5000 to 12,000; in such condition it is
associated with murmurs (bruits).
– E.g. bruits heard over arteries constricted by
atherosclerotic plaques and
– The sounds of Korotkoff heard when measuring
blood pressure

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 Regulation of Blood Flow
The vessels involved in regulation of the rate of tissue
blood flow throughout the body are mainly the
arterioles.
Altered demands of flow are met by adjusting vessel
calibre which is the acute tissue blood flow control
mechanisms.
Vessel calibre is adjusted by two general mechanisms:
1. Local regulation
2. Central regulation
 Centrally through the nervous system & hormones, and
 Locally by the conditions in tissues surrounding the blood
vessels & blood vessel it self.
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 Regulation of Blood Flow
 The relative importance of these two control mechanisms
varies in different tissues.
– In some areas of the body, such as the skin and splanchnic
regions, neural regulation of blood flow predominates.
– Whereas in other regions, such as the heart and brain, this
mechanism plays only a minor role.
– In skeletal muscle both mechanisms interact.

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 1. Intrinsic or local regulation of BF
This is the capacity of tissues to regulate their
own blood flow.
a) Myogenic Hypothesis
– BF stretch of blood vessels constriction to
normalize (decrease) blood flow.
– BF tension of blood vessel relaxation to normalize
(increase) BF.
b) Metabolic Hypothesis
– The metabolic changes that produce vasodilation
include, in most tissues, decreases in O2 tension and
pH.
– MR orO2 production of vasodilator metabolites.
Examples:
1) O2, H+; cause relaxation of blood vessels,
2) Adenosine…dilatation of arterioles
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 1. Intrinsic or local regulation cont’d
3) CO2 moderate vasodilatation in most tissues but
marked vasodilatation in brain.
4) K+ Inhibition of smooth muscle contraction
vasodilatation.
5) Lactate vasodilatation through increasing [H+].
6)Ca2+Smooth muscle contraction vasoconstriction
7) Carbon monoxide: produced from heme found in
cardiovascular tissues produces local vasodilatation.

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 1. Intrinsic or local regulation cont’d
8) Endothelial products
 Nitric oxide (NO): endothelium-derived relaxing
factor (EDRF); it is synthesized from arginine in the
presence of the enzyme NO synthase.
Three isoforms are identified:
– NOS1,found in nervous system,
– NOS 2 found in microphages and other immune cells, and
– NOS 3 found in endothelial cells.

Play a key role in vasodilatation
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 1. Intrinsic or local regulation cont’d
 Bradykinin: vasodilator
Endothelins
Endothelin 1: one of the most potent constrictors;
primarily a local paracrine regulator of vascular tone.
Endothelin 2: produced primarily in kidneys and
intestine
Endothelin 3: found in high concentration in brain;
also found in kidney and GIT.

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29
 1. Intrinsic or local regulation cont’d
c) Tissue Pressure Hypothesis
Perfusion pressure blood volume net transfer of
fluid from intravascular to extra-vascular space tissue
pressure (turgor) compression on thin-walled blood
vessels blood flow to tissues.

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 2. Extrinsic (Remote) Regulation
A) Neural Regulation
ANS receiving impulses from higher centres to change
blood flow and arterial pressure through changing vessel
calibre.
Nor-epinephrine as transmitter of sympathetic NS causes
an increase in the tone of arterioles acting on an α-
adrenergic receptor on smooth muscle cells.
The fibers to the resistance vessels regulate tissue blood
flow and the fibers to the venous capacitance vessels
vary the volume of blood "stored" in the veins.

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 2. Extrinsic (Remote) Regulation cont’d
B) Hormonal Regulation
1) Catecholamines: EP & NEP, like nor-adrenaline
released from sympathetic nerves, through alpha
adrenergic receptors cause vaso-constriction.
Many arteriolar smooth muscle cells possess beta-
adrenergic receptors as well as alpha- adrenergic
receptors.
Epinephrine causes the muscle cells to relax rather
than contract through beta-adrenergic receptors.
In most vascular beds, the existence of beta
adrenergic receptors on vascular smooth muscle are
greatly outnumbered by the alpha-adrenergic
receptors. 33
 2. Extrinsic (Remote) Regulation cont’d
The arterioles in skeletal muscle have a large number
of beta adrenergic receptors.
Circulating epinephrine usually causes vasodilatation
in this vascular bed.
2. Angiotensin II constricts most arterioles.
This peptide is part of the renin-angiotensin system.
3.Vasopressin, when present at high plasma
concentrations, causes arteriolar constriction
4. Atrial natriuretic peptide is the hormone secreted
by the atria and is a potent vasodilator on arterioles
like the afferent arteriole where it increases GFR.

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 Balance b/n intrinsic and extrinsic regulation
of BF
In some tissues, the effects of the extrinsic and
intrinsic mechanisms are fixed; in other tissues, the
ratio is changeable.
This is important for directing BF to areas of greater
need.
1) Brain and Heart
The brain and heart are vital structures with a limited
tolerance for a reduced blood supply.
Intrinsic flow-regulating mechanisms are dominant to
regulate blood flow to these area.
2) Skin
Blood flow to the skin is mainly controlled by the
extrinsic (neural) control system.
Local control has some effect.
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 Balance b/n intrinsic and extrinsic regulation
of BF
3) skeletal muscle
 The extrinsic and intrinsic mechanisms interact.
– In resting skeletal muscle, neural control (vasoconstrictor
tone) is dominant.
– Start or anticipation of exercise such as running, activation
of sympathetic dilator system  blood flow in the leg
muscles.
– After the onset of exercise, the intrinsic flow-regulating
mechanism assumes control, and vasodilatation occurs in
the active muscles because of the local increase in
metabolites.
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37
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 Blood vessels: Classification
1. Elastic vessels:
 Example: Aorta, big arteries
 Pressure storing components
 High ability of recoiling
2. Resistance vessels
Example: small arteries and arterioles
 High muscular component
 Develop high resistance
– Small changes in their caliber cause large changes in the
total peripheral resistance.
 Regulate blood flow
3. Exchange vessels: Example, capillaries
made up of endothelium and basement membrane.
 3 types: continuous, discontinuous and fenestrated
capillaries.

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 Blood vessels: Classification
4. Capacitance vessels (big to small veins)
 Very high capacity of distension
– Veins are eight times more distensible than the
artery of comparable size.
 Low resistance system
 Can accommodate large volume of blood (65%
of blood volume)
 Have valves that assure blood return to the heart

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 ARTERIES
AORTA
Contain large amount of elastin expansion and
recoil pressure storage.
A velocity of 30-40 cm/sec at aorta