Development of blood vessels, fetal circulation.pptx

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EMBRYOLOGY.
DEVELOPMENT OF THE MAJOR BLOOD VESSELS.
BLOOD SUPPLY OF THE FETUS

Dr Viktoriia Yerokhina,
Lecturer in Medical Sciences

[email protected]
 LEARNING OUTCOMES –
Continuation of the topic ‘Development of the heart’
EMBR.07 - Cardiovascular and Lymphatic system development
EMBR.07.01 - Be able to explain the sequential formation of hemangioblasts, blood islands, endothelial lined tubes a
EMBR.07.02 - Be able to explain the similarities between the heart tubes, dorsal aorta and the vitelline veins
EMBR.07.03 - Be able to explain how lateral folding modifies the developing heart tube, dorsal aorta, and vitelline veins
EMBR.07.04 - Be able to explain the components of the heart tube and there derivatives
EMBR.07.05 -Be able to explain cardiac looping and clinical correlations
EMBR.07.06 - Be able to explain the development of the atrioventricular canals
EMBR.07.07 - Be able to explain the septation and further modification of the primitive atria and their clinical correlations
EMBR.07.08 - Be able to explain the importance of the right-left blood shunt
EMBR.07.09 - Be able to explain the septation and further modification of the primitive ventricles and their clinical correlations
EMBR.07.10 - Be able to explain the formation and modification of Sinus Venosus and Truncus Arteriosus and their clinical
correlations
EMBR.07.11 - Be able to explain the difference between the membranous ventricular septum and the conotruncal septum
EMBR.07.12 - Explain the veins of the sinus venosus- umbilical, vitelline, and cardinal
EMBR.07.13 - Be able to explain the tributaries of the posterior cardinal vein and how they are modified
EMBR.07.14 - Be able to explain the tributaries of the anterior cardinal vein and how they are modified
EMBR.07.15 - Be able to explain how the common cardinal veins are modified
EMBR.07.16 - Be able to explain how the truncus arteriosus is modified
EMBR.07.17 - Be able to explain the formation and modification of fetal circulation and its shunts
EMBR.07.18 - Be able to explain the development of the lymphatic system
 OVERVIEW
Blood vessels develop from mesenchymal cells derived from mesoderm.
These are formed by two processes: vasculogenesis and angiogenesis.
1. Vasculogenesis: process of formation of new vessels by coalescence (assembly) of
angioblasts (specialised mesenchymal cells).
2. Angiogenesis: process of formation of new vessels by budding and branching from
preexisting vessels.
 OVERVIEW
Major blood vessels of the vascular system of the body, i.e., dorsal aortae and
cardinal vessels are formed by vasculogenesis, and remaining vessels are formed
by angiogenesis.
Both the processes of vasculogenesis and angiogenesis are patterned, and guided by
vascular endothelial growth factor (VEGF) and other growth factors.
 DEVELOPMENT OF ARTERIAL SYSTEM
Arteries of body develop from two main sources:
pharyngeal (aortic) arch arteries,
dorsal aorta.
Aortic arches give rise to the arteries of head and neck region.
Dorsal aorta gives rise to the arteries of rest of the body.
 PHARYNGEAL ARCH ARTERIES AND THEIR DERIVATIVES
1. First arteries to appear in a developing embryo are the right and left primitive aortae.
2. These become continuous with two primitive heart tubes.
Each primitive aorta is divided into three parts:
a) Part lying ventral to foregut is called ventral aorta.
b) Part lying dorsal to gut is called dorsal aorta.
c) Arched portion connecting the ventral and dorsal aortae lies in the first pharyngeal
arch. It forms first aortic arch artery.
 PHARYNGEAL ARCH ARTERIES AND THEIR DERIVATIVES
After fusion of two primitive heart tubes, the two ventral aortae partially fuse to form
aortic sac.
Unfused parts of ventral aortae form right and left horns of the aortic sac.
 PHARYNGEAL (AORTIC) ARCH ARTERIES
Aortic arches are blood vessels that run in between
the pharyngeal pouches and form the major head and
neck arteries.
The arches develop in craniocaudal order.
As the pharyngeal arches develop during 4th and 5th
weeks, each arch is supplied by an artery – pharyngeal arch
artery derived from the aortic sac (i.e., aortic sac contributes
a branch to each new arch as it forms).
Aortic sac gives rise to six pairs of aortic arch arteries.
Fifth either never developing or also obliterating without giving
rise to a vessel.
Five aortic arch arteries are numbered as I, II, III, IV, and VI.
Aortic arch arteries are embedded in the mesenchyme of
the pharyngeal arches.
 DERIVATIVES OF AORTIC ARCH ARTERIES

The greater part of the first and second arch arteries disappear

Fifth pair appears to disappear
DERIVATIVES OF AORTIC ARCH ARTERIES
DERIVATIVES OF AORTIC ARCH ARTERIES
 DEVELOPMENT OF OTHER ARTERIES OF THE BODY

These develop from primitive dorsal aortae.
 DEVELOPMENT OF OTHER ARTERIES OF THE BODY
Primitive dorsal aorta gives off three sets of branches:
1. Dorsolateral (somatic intersegmental) branches form arteries of upper and lower limbs,
intercostal lumbar, and lateral sacral arteries.
2. Lateral splanchnic branches form phrenic, suprarenal, renal, and gonadal vessels.
3. Ventral splanchnic branches form vitelline (celiac, superior, and inferior mesenteric) and
umbilical arteries. The arteries for bronchi and esophagus also arise from ventral
splanchnic branches.
BRANCHING PATTERN OF DORSAL AORTA AND ITS ANASTOMOSES
SOURCE OF DEVELOPMENT OF MAIN ARTERIES
 DEVELOPMENT OF VENOUS SYSTEM
In the 5th week of intrauterine life (IUL), three pairs of major primitive veins are seen in the
developing embryo.
1. Vitelline veins, which return poorly oxygenated blood from yolk sac.
2. Umbilical veins, which carry well-oxygenated blood from placenta.
3. Common cardinal veins, which return poorly oxygenated blood from the body of the embryo.
Cardinal = important
N.B. Common cardinal vein on each side is formed by the union of anterior and posterior cardinal veins.
 DEVELOPMENT OF VENOUS SYSTEM
Veins of developing embryo can be grouped as visceral and somatic veins.
Visceral veins
1. Vitelline or omphalomesenteric veins - for draining yolk sac.
2. Umbilical veins - for placenta.

Somatic veins
These are cardinal veins for draining body wall:
1. Anterior cardinal veins (right and left)
2. Posterior cardinal veins (right and left)
3. Common cardinal veins or ducts of Cuvier (right and left)
Anterior and posterior cardinal veins join to form common
cardinal veins.
Anterior cardinal veins drain:
– cranial half of embryo
– upper limb buds
Posterior cardinal veins drain
– caudal half of embryo
– lower limb buds.
DEVELOPMENT OF VENOUS SYSTEM. FLOWCHART
 DEVELOPMENT OF VENOUS SYSTEM
Visceral and somatic veins finally drain into the sinus
venosus.
These visceral and somatic veins later in adult form
– portal veins
– caval veins
– azygous veins
 FETAL CIRCULATION. OVERVIEW
Fetal circulation is different from that of adult circulation in the following three ways:
1. Blood in the fetus is oxygenated by placenta and not by the lungs.
2. During fetal life, the lungs are collapsed; hence, the resistance to blood flow through the lung
is much higher. As a result, only minimal amount of blood passes through the lungs to
supply oxygen and nutrients to the lungs.
3. Portal circulation is of little significance.
 FETAL CIRCULATION. OVERVIEW
In the placenta, maternal blood does not directly mix with fetal blood; it is
separated from it by the placental barrier.
Oxygen and nutrients are exchanged across this barrier.
Oxygenated blood from the placenta flows through the single umbilical vein to the
fetus.
Less oxygenated blood from the aorta flows through the common iliac arteries,
internal iliac arteries and the two umbilical arteries to the placenta for oxygenation.
Fetal shunts maintain the highest possible oxygen concentration for the brain and
other organs.
 BASIC PATHWAY OF THE FETAL CIRCULATION
Deoxygented blood
Oxygenated blood: placenta  umbilical vein  ductus venosus  inferior vena
cava
Mixed blood (high oxygen concentration): inferior vena cava  right atrium 
foramen ovale  left atrium  left ventricle
Mixed blood (low oxygen concentration): descending aorta  common iliac
arteries  internal iliac arteries  umbilical arteries  placenta.
 FETAL SHUNTS

Blood in umbilical vein has a Po2 of ≈ 30 mm Hg
and is ≈ 80% saturated with O2.
Umbilical arteries have low O2 saturation.
3 important shunts:
1. Ductus venosus / Arantius’ duct – shunt between
the umbilical vein and the inferior vena cava,
bypassing the liver.
2. Foramen ovale - shunt between the right and left
atria, bypassing the pulmonary circulation.
3. Ductus arteriosus / ductus Botalli – shunt
between the pulmonary trunk and the initial
segment of the descending aorta, bypassing the
pulmonary circulation and the aortic arch.
 FETAL CIRCULATION
In fetus (i.e., before birth), the highly oxygenated
(80% saturated with O2), nutrient-rich blood from the
placenta returns to the fetus by umbilical vein.
Umbilical vein traverses through the umbilical
cord, enters the abdomen through umbilicus, and
passes to the liver through falciform ligament.
In the liver, the umbilical vein joins the left branch
of portal vein.
Here, most of blood from umbilical vein (about 85%)
bypasses the sinusoids of the liver by passing
through ductus venosus – a channel that connects
left branch of portal vein to the IVC.
Only small amount of blood of umbilical vein (about
25%) enters the liver sinusoids and mixes with the
blood from the portal circulation. IVC – inferior vena cava
SVC – superior vena cava
 FETAL CIRCULATION
In the IVC, richly oxygenated blood mixes
with the deoxygenated blood returning from
the lower limbs.
After a short course, the IVC opens into the
right atrium.
As this blood enters in the right atrium, it is
guided by the valve of IVC toward foramen
ovale.
Most of blood from the IVC passes through
foramen ovale into the left atrium.
Only small amount of blood from the IVC
remains in the right atrium.
Here, it mixes with the deoxygenated blood
from the SVC and passes to the right
ventricle.
 FETAL CIRCULATION

Blood from the right ventricle
passes through pulmonary trunk,
and right and left pulmonary arteries.
But due to high resistance in
pulmonary tissue during fetal life, only
a small amount of blood enters the
pulmonary circulation.
Most of blood passes into the aorta
through the ductus arteriousus – a
channel that connects the left
pulmonary artery to arch of aorta.
 FETAL CIRCULATION
Left atrium receives mainly rich
oxygenated blood from the right atrium
through the foramen ovale.
Only a small amount of deoxygenated
blood enters the left atrium from the lungs
through the pulmonary veins.
Blood from the left atrium passes to the
left ventricle.
Blood from the left ventricle enters into
the ascending aorta, which through its
three large branches (brachiocephalic
artery, left common carotid artery, and left
subclavian artery) supply oxygenated
blood to the head, neck, brain, and
superior extremity.
 FETAL CIRCULATION

Since the coronary and carotid arteries are
the first branches of the aorta, the heart
musculature and brain are supplied by well-
oxygenated blood.
Arch of aorta receives poorly oxygenated
blood from the pulmonary trunk through the
DA.
Then the blood is distributed by the aorta
and common iliac arteries to the lower
part of the body.
Lower part of the body is thus supplied
with relatively less oxygenated blood as
compared with the upper part of the body.
 FETAL CIRCULATION

Two umbilical arteries arising from internal
iliac branches of common iliac arteries pass
through umbilicus and enter the placenta
through the umbilical cord, where it is
oxygenated.
O2 saturation in umbilical arteries is about
58%.
FLOWCHART: FETAL
CIRCULATION
CIRCULATORY CHANGES AT BIRTH

Following birth, 3 shunts will close
because of changes in the pressure
gradients and in oxygen tensions.
Umbilical vein closes and reduces
blood flow into the right atrium.
Ductus venosus also closes.
Lung expansion reduces pulmonary
resistance and results in increased flow
to the lungs and increased venous return
to the left atrium.
 POSTNATAL CLOSURE OF SHUNTS

Closure of the foramen ovale occurs as a
result of the increase in left atrial pressure and
reduction in right atrial pressure.
Closure of the ductus venosus and ductus
arteriosus occurs over the next several hours
as a result of the contraction of smooth
muscles in its wall and increased oxygen
tension.
Release of bradykinin and the immediate
drop of prostaglandin E at birth also facilitate
the closure of the ductus arteriosus.
CIRCULATORY CHANGES AT BIRTH
 FOLDS OF INTERNAL SURFACE OF THE ANTERIOR ABDOMINAL WALL
1. Median umbilical fold (plica umbilicalis mediana) – an unpaired fold formed by the
median umbilical ligament (a remnant of the urachus)
2. Medial umbilical fold (plica umbilicalis medialis) – a paired fold formed by the
medial umbilical ligament
3. Lateral umbilical fold (plica umbilicalis lateralis) – a paired fold formed by the
inferior epigastric vessels.
COMPARISON OF THE FETAL AND POSTNATAL CIRCULATION
REFERENCES