Transcript Slide 1

Blood Vessels
Blood Vessels
• hollow structures for
carrying blood
• form closed system
beginning & ending at
heart
• Arteries
• Arterioles
• Venules
• Veins
• Capillaries
Vessel Structure
• 3 layerstunicas
• surround central
space or lumen
• Tunica intima
• Tunica media
• Tunica
adentitia
Tunica Intima or Tunica Interna
• innermost layer
– in contact with
blood
– consists of layer
of simple
squamous cellsendothelium
• fit closely together
forming slick surface
• minimizes friction as
blood moves
through lumen
Tunica Media
• middle layer
• usually thickest
• consists of smooth muscle,
collagen and in some cases
elastic tissue
• strengthens vessels to prevent
rupture
• provides vasomotion or
changes in diameter of blood
vessel
• impulses cause muscles to
contract vasoconstriction
– reduction in size of lumen
• impulses inhibitedmuscle
fibers relaxdiameter
increases-vasodilation
Tunica Adventitia or Tunica Externa
• outermost layer
• composed of
loose
connective
tissue
• responsible for
attaching
vessels to
surrounding
tissues
Arteries
• carry blood away
from heart
• progressive
diminution in
diameter as recede
from heart
• branch, diverge, &
fork
Arteries
• resistance vessels
• relatively thick muscular walls containing
elastic & contractile fibers
• change diameters by expanding (elasticity)
as pressure increases & by constricting
under sympathetic nervous control
(contractility)
• vasoconstriction & vasodilation affect:
afterload, peripheral blood pressure &
capillary blood flow
Types of Arteries
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
Elastic
– conducting arteries
largest
transport large amounts of blood away from
heart
elastin in all layers
withstand large pressure fluctuations
Muscular
– distributing arteries
deliver blood to organs & skeletal muscles
named arteries
thickest media
active in vasoconstriction
Resistance arteries
– arterioles
poorly defined external tunicas
diameters change in response to local
conditions, sympathetic innervations &
hormonal stimulation
more pressure is needed to push blood through
constricted vessels
force opposing blood flow is called resistance
major site of resistance to blood flow.
Capillaries
• do work of cardiovascular system
• walls permit exchange between blood interstitial
tissues
• smallest blood vessels
• consist of endothelium & basement membrane
• several types
• Continuous
• Fenestrated
• Sinusoids
Continuous Capillaries
• complete endothelium
lining forming a
continuous tube
• cells joined by tight
junctions
• in all tissues except
epithelia & cartilage
• permit diffusion of
water, small solutes
and lipid-soluble
materials into
surrounding interstitial
fluid
Fenestrated Capillaries
• have oval poresfenestrations
• allow for rapid transport
of molecules through
capillary wall
• found in organs that
engage in rapid
absorption or filtration
• kidneys, exocrine
glands & choroid
plexus of brain
Sinusoids
• endothelial cells are
separated by wide
gaps with no basal
lamina
• proteins & blood
cells can pass
through
• found only in certain
organs such as liver,
bone marrow, &
spleen
Capillaries
• connect
arteries to veins
• do work of
cardiovascular
system
• found in beds
Capillary Beds
• blood flow through bedsmicro circulation
• one arterioledozens of
capillariesvenules
• arterioles linked to capillaries
via metarterioles
• surrounded by band of
smooth muscle-precapillary
sphincter
• contraction-narrows diameter
of capillary entrance
reducing blood flow
• relaxation increases blood
flow
Sphincter Open
• capillaries
exchange
materials with
tissues
Sphincter Closed
• blood bypasses
capillaries
• flows through
thoroughfare
channel to
venule
Mechanisms of Movement
• Diffusion
• Bulk Flow
–Filtration
–Reabsorption
• Transcytosis
Diffusion
• most important
• net movement of ions &
molecules from areas of
higher to areas of lower
concentration
• difference between
concentrations isconcentration gradient
• most rapid diffusion
occurs where
• distances are small
• concentration gradients
are large
• molecules are small
Bulk Flow
•
•
•
•
Filtration & Reabsorption
across capillary walls
between blood & interstitial tissues
due to hydrostatic & osmotic pressures
Bulk Flow
• Filtration
• direction of flow is out
of the capillary into
the interstitial fluid
• at arterial end
• Reabsorption
• direction of flow is out
of interstitial fluid into
the capillary
• at venous end
Capillary Exchange Pressures
•
•
•
•
•
•
•
•
•
•
•
•
•
two main factors promote filtration
blood hydrostatic pressure (BHP) & interstitial fluid osmotic pressure
(IFOP)
primary pressure promoting reabsorption-blood colloid osmotic pressure
(BCOP)
in vessels hydrostatic pressure is due to pressure that water in blood exerts
against vessels walls (BHP)
BHP is about 35mm of Hg at arterial end of capillary & 16mm Hg at venous
end
BHP pushes fluid out of capillary into interstitial fluid.
Interstitial fluid hydrostatic pressure (IFHP) pushes fluid from interstitial
spaces back into capillaries- value is close to zero
Blood colloid osmotic pressure (BCOP) is determined by proteins present in
plasma
BCOP pulls fluid from interstitial spaces into capillaries-averages 26mm Hg
Opposing BCOP interstitial fluid osmotic pressure (IFOP)
IFOP pressure pulls fluid out of capillaries into interstitial fluids- value i0.1 –
5mm Hg
Net Filtration Pressure = (NFP) = (BHP + IFOP) – (BCOP + IFHP)
NFP is equal to pressures promoting pressure minus pressures promoting
reabsorption
Net Filtration Pressure
• Net Parterial end = (35 mm Hg + 1)
- (26mm Hg + 1) = 10mm Hg
• value tells there is a net
outward pressure
• fluid moves out of capillaries
into interstitial fluid-net filtration
• Net P venous end = (16mm Hg )+
1) + (26 mm Hg + 1) = -9 mm
Hg
• value tells net absorption is
taking place
• there is a net inward pressure
forcing fluid into capillaries
from interstitial fluid
Veins
• carry blood back to
heart
• join, merge, &
converge
• diameters small in
venules
• become
progressively larger
as approach heart
Veins
• thin walls
• can distend
• capable of holding a great
deal of blood
• capacitance vessels- blood
reservoirs which can be
drawn upon in time of need
• many especially in arms &
legs, have flaps or valves
• composed of 2 leaflets
• close if blood begins to
back up in veins
Distribution of Blood
• blood volume
unevenly
distributed
• heart, arteries &
capillaries account
for 30-35% total
volume
• venous system
contains 64% total
volume
Cardiovascular Physiology
• blood must circulate
• heart provides force &blood vessels are conduits
• blood flow is the volume of blood that flows
through a tissue in a given time (ml/min)
• total blood flow is CO
– volume of blood that circulates through systemic or
pulmonary circuits each minute
• CO = SV X HR
• how CO becomes distributed into circulatory
routes depends on two more factors
• pressure differences & resistance to flow
Pressure Differences & Resistance
• pressure gradient
• difference in pressure from one end of vessel
to another-P
• largest-from base of aorta to proximal ends of
peripheral capillaries
• greater P more blood flow
• resistance
• any force opposing movement
• due mainly to friction of blood with blood
vessel walls
• greater resistanceslower blood flow
Blood
Pressure
• produced by contraction of
•
•
•
•
ventricles
determined by: CO,
resistance & blood volume
measured by using a
sphygmomanometer &
brachial artery
highest in arteries during
systole
lowest in arteries during
diastole
– expressed as mmHg
Blood Pressure
• systemic arterial pressure
ranges from 100mm Hgaorta to 35mm Hgcapillaries
• venous end of capillaries,
pressure 16 mmHg
• pressure continues to drop
as blood enters systemic
veins
• reaches zero mm Hg as
blood flows into right
ventricle
MAP
• Mean arterial pressure
• value for arterial pressure representing it driving
process
• average blood pressure in the arteries
• MAP = diastolic pressure + 1/3(systolic pressure
– diastolic pressure)
• If normal: MAP = 80mm Hg + 1/3(120-80mm Hg)
= 93mm Hg
• CO = MAP/R or MAP = CO X R
• shows that if CO rises due to HR or SV then so
does MAP since CO = SV x HR
Blood Pressure & Blood Volume
• blood pressure also
depends on total
volume of blood in
cardiovascular
system
• anything that
increases blood
volume will increase
blood pressure
• kidney helps with long
term regulation of
blood pressure
Peripheral Resistance
Systemic Vascular Resistance
•
•
•
•
•
•
•
•
•
•
•
resistance of entire arterial system
F = P/R
Flow = change in pressure divided by resistance
equation shows blood flow is directly proportional to
pressure gradient & inversely proportional to resistance
higher PRlower rate of blood flow
pressure gradient must be greater than total peripheral
resistance for blood to flow
vascular resistance is the opposition to blood flow due to
friction between blood vessel walls & blood
depends on
vessel lumen
blood viscosity
total vessel length
Blood Viscosity
thickness of blood
greater viscositymore friction
greater resistance
anemia & polycythemia will change
hematocrit changes viscosity
changes resistance
under normal conditions negligible
•
•
•
•
Vessel Length
longer vesselsgreater resistance
length increases friction
two vessels-equal diameters
if one is twice length of other-longer
vessel has twice resistance of
shorter vessel
• factor is usually constant
Vessel Diameter
• most important factor
contributing to resistance
• significant effects
• smaller vesselsgreater friction
• more fluid in contact with vessel
wallmore frictionmore
resistance
• friction in larger vessels is low
because blood comes into
contact with vessel wall less
oftenless less friction less
resistance
Vessel Diameter
• two vessels-equal
lengths
• One- twice diameter of
other
• using formula: R-  1/r4
• vessel with twice
diameter of other has
1/16 as much resistance
as smaller diameter
vessel
• or-smaller vessel has
16X as much resistance
Blood Velocity
•
•
•
•
•
•
•
•
•
•
•
•
•
•
depends on flow rate & cross sectional
area
flow rate
volume of blood passing one point in
system/unit time
given as Liters/minute or ml/min
Velocity
distance fixed volume of blood travels in
given time period
measured in cm/sec
inversely related to cross sectional area
slowest where total cross sectional area
is greatest
fastest where cross sectional area is leas
cross sectional area of aorta-3 – 5cm2
average velocity - 40cm/sec
Capillaries-total cross sectional area4500 – 6000cm2 - velocity is less than
0.1 cm/sec
slows down for capillary exchange
Control of Blood Pressure &
Flow
• Nervous
System
• Hormones
• Autoregulation
Neural Mechanisms
• CV center regulates HR & SV
• controls blood vessels via ANS
• exert sympathetic &
parasympathetic control over
blood vessels throughout body
• Sympathetic input reaches heart
via cardiac accelerator nerves
• increase in sympathetic
stimulation increases HR &
contractility.
• decrease in sympathetic
stimulation decreases HR &
contractility
• Parasympathetic stimulation is
conveyed along vagus nerve
• results in decreased HR
•
•
•
•
•
•
•
Nervous
System
Control
cardiovascular center integrates
nerve impulses from cerebral
cortex, limbic system &
hypothalamus
Proprioceptors
– monitor joint movements
Barorecepetors
– monitor pressure changes
Chemoreceptors
– monitor chemical changes in
blood
regulates via negative feedback
loops & 2 major reflexes
Baroreflexes
Chemoreflexes
•
•
•
•
•
•
•
•
•
•
•
•
Baroreflex
autonomic negative feedback response to
change in blood pressure
detected by baroreceptors
located in carotid arteries & aorta
monitor stretch in walls due to pressure of
blood flowing to brain
two types-carotid sinus reflex & aortic reflex
carotid reflex
regulates bp in brain
aortic reflex regulates systemic bp
blood pressure rises walls stretch
increases rate of baroreceptors signals over
glossopharygeal nervesinhibits
sympathetic neurons & increases
parasympathetic firing reduces HR & force
of contraction which decreases CO
blood pressure drops back to normal
slows rate sympathetic stimulation is sent to
vasomotor nerves that cause
vasoconstriction results in vasodilation
SVR, lowers CO & lowers blood pressure
Baroreflex
•
•
•
•
•
Baroreceptors in walls of ascending aorta
&aortic arch begin aortic reflex
Once stimulated send impulses over
vagus nerve to CV center.
blood pressure decreases
baroreceptors stretch lesssend
impulses at slower rate to CV center
decreases parasympathetic stimulation
& increases sympathetic stimulation via
cardiac accelerator nerves
Sympathetic nervous stimulation
increases secretion of epinephrine &
norepinephrine from adrenal medulla
causes the heart to beat faster & more
forcefully increases SVR, CO & blood
pressure
Baroreflexes
• important in short term
regulation of blood
pressure
• keep BP stable when
moving from reclining to
standing position
• quickly adapt to prolonged
or chronic episodes of high
or low blood pressure
• kidneys come in to restore
& maintain BP by
regulating blood volume
• major determinant of CO
through influences on
venous pressure, venous
return, EDV & SV
Chemoreflex
• autonomic response to changes in
blood chemistry
– especially pH, O2 & CO2
• Chemoreceptors-aotic & carotid
bodies
• negative feedback
• abnormal conditions cardiovascular
centers noticerespond in ways to
counteract abnormal condition
homeostasis restored
• low O2 (hypoxia), high CO2
(hypercapnia) & low pH (acidosis)
stimulate chemoreceptors CV
centerwidespread vasoconstriction
 increases BP
• also sends impulses to the respiratory
center
• primary response is to adjust
respiration
Hormones & Blood Pressure
• hormones help regulate blood pressure
& blood flow by altering CO, changing
SVR or adjusting total blood volume
• Renin-angiotensin aldosterone
system (RAA)
• Epinephrine & Norepinephrine
• ADH
• ANP-atrial natriuretic peptide
Renin-Angiotensin
Aldosterone system (RAA)
• blood volume falls or blood flow
to kidneys
decreasesjuxtaglomerular cells
in kidney secrete renin
• Renin & ACE (angiotensinconverting enzyme) make
angiotensin II
• affects blood pressure in two
ways
• Angiotensin II is a
vasoconstrictor
• increases BP by increasing
systemic vascular resistance
• stimulates secretion of
aldosterone form adrenal cortex
• causes increase reabsorption of
sodium & water by kidneys
• increases blood volume
increases blood pressure
Epinephrine & Norepinephrine
• stresshypothalamusfight-orflight responseadrenal medulla
norepinephrine & epinephrine
• cause vasoconstriction of
arterioles in skin veins & in
abdominal organ veins
• increase CO by increasing HR &
force of heart contraction via
generalized vasoconstriction
• increases blood pressure
• except skeletal & cardiac muscle
where they produce vasodilation
• enhances blood flow to heart &
skeletal muscle
ADH
• from posterior pituitary
• released due to lowered
blood volume
• increase in osmotic
concentration of plasma
• immediate effectperipheral
vasoconstrictionincreases
BP
• causes kidneys to conserve
water increases blood
volumeincreases BP
ANP
• made by right atrium in
response to excessive
stretchingdecreases BP
• increases Na excretion at
kidneyspromoting water
loss
• generalized vasodilation
effect
– helps to lower blood
pressure
Autoregulation-Myogenic
Regulation
•
•
•
•
•
ability of tissues to regulate their own blood supply
local factors changechanges pattern of blood flow in capillary beds
changes diameter of precapillary sphincters that feed capillaries
changing diameter varies resistance
Vasodilators:
–
–
–
–
–
–
–
–
•
•
relax smooth muscle cells of precapillary sphincters
Vasoconstrictors:
–
–
–
–
•
NO-nitric oxide
increased CO2
decreased O2
lactic acid
increased K
increased H
increased histamine
high temperatures
vasopressin
norepinephrine
angiotensin II
serotonin
contract smooth muscle cells in sphincters