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Chapter 23
Vessels and Circulation
Types of Blood Vessels
• Arteries travel away from the heart
– Arterioles are smallest arteries
• Capillaries are smallest vessels
– one red blood cell wide
– thin walls so oxygen, carbon dioxide, and water can move in or out of
vessels
• Veins return to the heart
– Venules are the smallest veins
2
Fig. 23.1 Walls of a Blood Vessel
• Arteries and veins
have 3 tunics
(layers)
• Tunica intima is
inner layer
– endothelium
(simple squamous)
– areolar connective
tissue
– in muscular
arteries, includes
internal elastic
lamina
Vein
Artery
Tunica intima
Endothelium
Subendothelial layer
Internal elastic lamina
Tunica media
Tunica externa
Vasa vasorum
Valves
Fig. 23.1 Walls of a Blood Vessel
Vein
Artery
• Tunica media
– layers of smooth
muscle
– in muscular
arteries, includes
external elastic
lamina
Valves
Tunica media
External elastic
lamina
Fig. 23.1 Walls of a Blood Vessel
• Tunica media in arteries
– thickest layer; mostly smooth muscle
– enables vasoconstriction and
vasodilation
Artery
Lumen
Tunica media
External elastic
lamina
Fig. 23.1 Walls of a Blood Vessel
• Tunica externa
– areolar connective
tissue with elastic
and collagen fibers
– anchors vessel to
other structures
– includes vasa
vasorum, blood
supply for very
large blood vessels
– thickest layer in
veins
Artery
Vein
Tunica intima
Tunica media
Tunica externa
Vasa vasorum
Fig. 23.1 Walls of a Blood Vessel
• Arteries
Tunica intima
– lumen is narrow
– lots of elastic and collagen
fibers in tunics
• stay open; withstand
changes in blood
pressure
Endothelium
Subendothelial layer
Internal elastic lamina
Tunica media
External elastic lamina
Tunica externa
Vasa vasorum
• Veins
– lumen is wide
– valves within lumen
prevent blood flow in
wrong direction
Valves
Capillary bed
Lumen
Lumen
Artery
Endothelium
Basement
membrane
Capillary
Lumen
Vein
Fig. 23.1 Walls of a Blood Vessel
Artery
Vein
Capillary bed
Lumen
Endothelium
Basement
membrane
Capillary
• Capillaries
– connect arteries
and veins
– only have tunica
interna
• thin walls enable
gas exchange
Fig. 23.2
Vein
Tunica externa
Tunica media
Tunica intima
Blood
in the
lumen
Artery
Tunica intima
Tunica media
Tunica externa
LM 100x
Fig. 23.3
Types of Arteries
• Elastic arteries
– largest
– AKA conducting arteries—
conduct blood from heart
to smaller arteries
– ex. aorta, pulmonary,
brachiocephalic, common
carotid, subclavian,
common iliac arteries
Ascending aorta
Pulmonary trunk (artery)
Arteries
Elastic artery
Tunica intima
Tunica media
Tunica externa
Descending
aorta
Fig. 23.3
Types of Arteries
Lumen
Tunica intima
• Elastic arteries
– very thick tunica
media with elastic
fibers throughout
– elastic fibers enable
stretching during
ventricular
contraction, return to
original shape
Tunica media
Elastic fibers throughout
tunica media
LM 100x
23.4 (a) Elastic artery
Tunica externa
Fig. 23.3
Types of Arteries
Muscular artery
Tunica intima
Internal elastic lamina
Tunica media
External elastic lamina
Tunica externa
• Muscular arteries
– AKA distributing arteries—distribute blood to body organs and tissues
– most named arteries, ex. brachial, anterior tibial, coronary, inferior
mesentery
Fig. 23.3
Types of Arteries
Arteriole
Tunica intima
Tunica media
Tunica externa
• Arterioles
– smallest
– larger arterioles have 3 tunics; small arterioles
have endothelium and one layer of smooth muscle
Fig. 23.3
Capillaries
• Connect arterioles to venules
• usually 1 mm long, 8-10 micometers wide
– diameter of one red blood cell
– erythrocytes must pass through one at a time
Capillary
Basement
membrane
Endothelium
Fig. 23.3
Capillaries
• Basement membrane
and endothelium only
– gases and nutrients
diffuse easily across
capillary wall into
extracellular fluid
– gases then move from
ECF to cells
Fig. 23.5
Arterial end
Endothelium
Smooth
muscle
cells
Metarteriole
Arteriole
Capillary
True
capillaries Venous end
beds
• Metarteriole
flows into capillary
Endothelium
bed, venule flows
out
• White blood cells
travel through
Thoroughfare
metarteriole,
channel
bypass
capillaries
Postcapillary venule
Relaxed precapillary sphincters
(a) Sphincters relaxed; capillary bed well perfused
Fig. 23.5
Capillary beds
• Precapillary sphincter is
circle of smooth muscle
around proximal end of
capillary
– can cut off blood flow
– cycle on and off to meet
tissue’s nutrient need
Contracted precapillary sphincters
(b) Sphincters contracted; blood bypasses capillary bed
Fig. 23.3
Veins
Tunica intima
Ascending aorta
Pulmonary trunk (artery)
Superior
vena cava
Arteries
Large vein
Elastic artery
Inferior
vena cava
Valve
Tunica media
Tunica intima
Tunica media
Tunica externa
Tunica externa
Descending
aorta
Muscular artery
Small to mediumsized vein
Tunica intima
Valve
Tunica media
Tunica externa
Tunica intima
Tunica intima
Internal elastic lamina
Tunica media
External elastic lamina
Tunica externa
Venule
Arteriole
Tunica intima
Tunica media
Tunica externa
Tunica media
Tunica externa
Basement membrane
Endothelium
Capillary
Fig. 23.3
Types of Veins
Venule
Tunica intima
Tunica media
Tunica externa
Postcapillary venule
• Venules
– smallest veins
– travel with and correspond
to arterioles
– smallest are postcapillary
venules
• drain capillaries
• similar to capillaries but
slightly wider lumen
– largest venules have all 3
tunics
Fig. 23.1
• Veins
– Lumen is wide
– Thick tunica externa
– Contain valves to prevent backflow
of blood
• formed from tunica intima
strengthened by elastic and
collagen fibers
Tunica intima
Vein
Endothelium
Subendothelial layer
Valves
Tunica media
Tunica externa
Vasa vasorum
Lumen
Fig. 23.3
Veins
Veins
Large vein
Tunica intima
Valve
Tunica media
Superior
vena cava
Inferior
vena
cava
Tunica externa
Small to mediumsized vein
Tunica intima
Valve
Tunica media
Tunica externa
• Large veins
– Travel with and correspond
to elastic arteries
• Small to medium-sized
veins
– Travel with and correspond
to muscular arteries
Fig. 23.7
To heart
Increased
pressure
opens valve
Contracted
skeletal
muscles
Valve closed
(to prevent
blood backflow)
Vein
Skeletal muscle pump
• Contraction of muscles squeezes
veins, forcing blood through
• Works more efficiently when a
person is active
• When a person is inactive, blood
may pool in lower extremities
Blood flow from tissues
Fig. 23.7
Respiratory pump
Respiratory pump
• contraction of diaphragm
compresses abdominal
cavity, squeezes
vessels, pushes blood
through
• relaxation of diaphragm
decreases pressure in
abdominal cavity, draws
blood into vessels of
abdomen
Thoracic cavity
Abdominopelvic cavity
Inhalation
Increases
blood flow into
thoracic
veins
Exhalation
Increases blood
flow into heart
and abdominal
veins
Decreased
intrathoracic
pressure
Increased
intrathoracic
pressure
Diaphragm
contracts
Blood
moves
superiorly
Increased
intra-abdominal
pressure
(b)
Diaphragm
relaxes
Compression
Decreased
intra-abdominal
pressure
Release of
compression
Fig. 23.3
Veins
Tunica intima
Ascending aorta
Pulmonary trunk (artery)
Superior
vena cava
Arteries
Large vein
Elastic artery
Inferior
vena cava
Valve
Tunica media
Tunica intima
Tunica media
Tunica externa
Tunica externa
Descending
aorta
Muscular artery
Small to mediumsized vein
Tunica intima
Valve
Tunica media
Tunica externa
Tunica intima
Tunica intima
Internal elastic lamina
Tunica media
External elastic lamina
Tunica externa
Venule
Arteriole
Tunica intima
Tunica media
Tunica externa
Tunica media
Tunica externa
Basement membrane
Endothelium
Capillary
Page 688
Varicose veins
• Veins with nonfunctional valves
• Blood pools in one area, vein swells
• Causes: genetics, aging, long periods of
standing, obesity, pregnancy
• Compression stockings prevent the vessels from
swelling
• Treatment:
– sclerotherapy—irritant injected into vein; vein
scars and seals off
– phlebectomy—vein removal
Varicose veins
Systemic circulation
Right common carotid artery
• From heart, blood pumped through
ascending aorta
• Right and left coronary arteries
branch off first
• Brachiocephalic trunk is first
of 3 large branches on
aortic arch
• Branches into
– right common carotid: supplies
right side of head and neck
– right subclavian: supplies right
arm and some thoracic structures
Left common
carotid artery
Right subclavian
artery
Brachiocephalic
trunk
Right
coronary
artery
Left
coronary
artery
Left
subclavian
artery
Systemic circulation
Left common
carotid artery
Right common carotid artery
• Left common carotid is next branch
Right subclavian
off aortic arch
artery
Left
subclavian
artery
– supplies left side of head and neck
• Left subclavian is last
– supplies left arm and some
thoracic structures
Brachiocephalic
trunk
Aortic
arch
• After arch, aorta becomes
descending aorta
Right
coronary
artery
Left
coronary
artery
Fig. 23.10ab
Head and neck circulation
• Common carotid artery splits
above thyroid cartilage
Branches of
common carotid
artery
Internal carotid
artery
External carotid
artery
Common carotid
artery
(a) Arteries, right lateral view
– internal carotid artery
supplies internal skull
structures
– external carotid artery
supplies external skull
structures
Fig. 23.10ab
Systemic circulation
• Veins from head and neck drain through
internal and external jugular veins, into
subclavian, then brachiocephalic vein
External jugular vein
Internal jugular vein
Right subclavian vein
Right brachiocephalic vein
(b) Veins, right lateral view
Fig. 23.11
Venous draining from head
Superior sagittal sinus
• Dural venous sinus system
drains into internal jugular
veins
Inferior sagittal sinus
Straight sinus
Cavernous sinus
Occipital sinus
Marginal sinuses
Transverse sinus
Superior petrosal sinus
Inferior petrosal sinus
Ophthalmic veins
Sigmoid sinus
Facial vein
Internal jugular vein
(b) Cranial and facial veins, right superior anterolateral view
Fig. 23.19ab
Subclavian artery
• Subclavian arteries supply blood to
upper limbs
• After passing over first rib, becomes
axillary artery
• After passing teres major muscle,
becomes brachial artery
Axillary artery
Brachial artery
Fig. 23.19ab
• In cubital fossa, brachial artery splits
into radial artery and ulnar artery
Brachial artery
• anastomose into two arches in palm:
superficial palmar arch and deep
palmar arch
• digital arteries supply fingers
Radial artery
Ulnar artery
Deep palmar arch
Superficial
palmar arch
Digital arteries
(a) Arteries of right upper limb
Fig. 23.19ab
• On hand dorsal venous
network drains into basilic
vein and cephalic vein
Median cubital
vein
Cephalic vein
Radial veins
Basilic vein
Ulnar veins
• basilic veins becomes
axillary vein in armpit
• cephalic vein joins inferior to
subclavian
• Median cubital vein
connects cephalic and
basilic veins
Dorsal venous network
Superficial veins
Deep veins
(b) Veins of right upper limb
• usual site for blood
donations or samples
Fig. 23.19ab
Brachial veins
Cephalic vein
Radial veins
Basilic vein
Ulnar veins
Deep venous arch
Superficial venous arch
Superficial veins
Deep veins
• On hand superficial and
deep palmar venous
arches drain into 2 radial
veins and 2 ulnar veins
(deep)
• Radial and ulnar veins
merge at cubital fossa to
form 2 brachial veins
Fig. 23.19ab
Subclavian vein
• Brachial veins merge to form
axillary vein
Axillary vein
• Basilic vein joins at about level of
teres major
• Cephalic vein joins near clavicle
Cephalic vein
Basilic vein
• After passing lateral border of first
rib, renamed subclavian vein
Brachial veins
Median cubital vein
Cephalic vein
Radial veins
Dorsal
venous
network
Basilic vein
Ulnar veins
Deep palmar venous arch
Superficial palmar venous arch
Fig. 23.12
Major arteries
Descending
thoracic aorta
• Descending thoracic aorta
becomes descending
abdominal aorta below
diaphragm
Right renal
artery
Descending
abdominal
aorta
Left renal
artery
Common iliac
artery
Left internal iliac
artery
Left external iliac
artery
Left femoral
artery
Fig. 23.12
Right renal artery
Right gonadal artery
• Renal arteries
supply kidneys
• Gonadal arteries
supply gonads
• Blood returns through veins with same names
• Renal veins drain kidneys
• Gonadal veins drain gonads
Left renal artery
Left gonadal artery
Fig. 23.12
Major arteries
• Above sacrum, aorta splits into
common iliac arteries
• Common iliac branches into
internal and external iliac
arteries
• Below inguinal ligament,
external iliac artery renamed
femoral artery
Common iliac
artery
Left internal
iliac artery
Left femoral
artery
Left external
iliac artery
Fig. 23.20b
• Popliteal vein curves to anterior
thigh, becomes femoral vein,
becomes external iliac vein
above inguinal ligament
External iliac vein
Femoral vein
Posterior view
Fig. 23.13
• External iliac vein and
internal iliac vein
merge into common
iliac vein
• Left and right common
iliac veins merge to
form inferior vena cava
Inferior vena cava
Left common iliac vein
Left external iliac vein
Left internal iliac vein
Left femoral vein
Inguinal ligament
Digestive System
Fig. 23.15
Celiac trunk
Liver
• celiac trunk
branches off aorta
• arteries that
branch off celiac
trunk supply
stomach, part of
duodenum, liver,
part of pancreas,
spleen
Esophagus
Stomach
Spleen
Duodenum
Pancreas
Abdominal Arteries
• Celiac trunk
branches from
abdominal aorta,
branches into:
• Left gastric artery
supplies stomach
• Splenic artery
supplies spleen
• Common hepatic
artery supplies
liver
Celiac trunk
Common
hepatic artery
Hepatic
artery
proper
Right
gastric
artery
Inferior vena cava
Liver
Left gastric artery
Stomach
Splenic artery
Spleen
Superior
mesenteric artery
Descending
abdominal
aorta
Transverse colon
Superior mesenteric
artery
Fig. 23.15
Celiac trunk
Descending colon
• Superior
mesenteric artery
located inferior to
celiac trunk
• supplies most of
small intestine,
pancreas, proximal
large intestine
Inferior mesenteric
artery
Transverse colon
Superior mesenteric
artery
• Inferior mesenteric
artery branches
from aorta superior
to common iliac
arteries
• supplies inferior
colon and rectum
Fig. 23.15
Celiac trunk
Descending colon
Inferior mesenteric
artery
• Hepatic portal vein receives blood from GI tract; formed from
• inferior mesenteric vein drains from distal large intestine
• splenic vein drains spleen
• superior mesenteric vein drains small intestine and part of large intestine
Liver
Hepatic portal
vein
Superior
mesenteric
vein
Fig. 23.16
Splenic vein
Inferior
mesenteric vein
Page 702
The configuration
of the veins of the
hepatic portal
system
Hepatic
portal vein
resembles the
side view of a
chair.
Superior
mesenteric vein
Splenic vein
Inferior
mesenteric vein
Fig. 23.16
• Blood leaves liver through hepatic veins, drains into inferior
vena cava
Inferior vena cava
Hepatic veins
Diaphragm
Liver
Hepatic portal vein
Splenic vein
Page 706
Blood in
narrowed lumen
Atherosclerosis
• Affects elastic and muscular
arteries
• Tunica intima thickens; lumen
narrows
• Causes:
Lumen
LM 20x
Normal artery
LM 50x
Atheroma
occluding
lumen
Atherosclerotic artery
• injury to tunica intima: infection, trauma,
or hypertension
• injury attracts white blood cells and immune response
• cholesterol proteins (LDL and VLDL) enter tunica intima, stick to vessel wall
• other cells attracted, create foam cells, which develop into plaques
Page 706
Catheter
1
Atheroma
• Treatment: angioplasty
Artery
An uninflated balloon and compressed stent are passed through
a catheter to the area of the artery that is obstructed.
Balloon
2
Stent
• Stent inserted into artery and
expanded
• Stent compresses plaques,
becomes new wall of artery,
expanding artery
Balloon inflates, which expands the stent and inserts it in place
and also compresses the atheroma.
3
The stent remains in the vessel as the balloon is deflated and the
catheter is withdrawn.
Page 713
Aneurysm
• Localized, abnormal dilation of blood vessel
• May be caused by atherosclerosis
• Felt as pulsating mass if in abdominal aorta
• Visualized by x-ray or ultrasound
• If ruptures, rarely survived
Abdominal
aneurysm
Page 713
Aorta
Aneurysm
• Treatment
possible for
abdominal
aneurysm
• Stent graft
replaces inner
artery
Blood flows
through stent
graft
Stent graft
released
from catheter
Abdominal
aortic
aneurysm
Plaque
Abdominal
aneurysm
Catheter
insterted
into femoral
artery
Common
iliac artery
Endovascular
stent graft in
place