Foetal Circulation PDF

Summary

This document is a set of lecture notes on fetal circulation. The lecture notes describe the fetal circulatory system's modifications, contrasting it to adult circulation. Key points include the functions of the foramen ovale, ductus arteriosus, and ductus venosus, along with the changes in blood circulation at birth. The notes also cover topics like placenta and umbilical cord.

Full Transcript

Fetal circulation

Fraser Chisholm
[email protected]

Learning Outcomes
After this lecture, time spent in the dissecting room, and further private study you

should be able to:
1. Explain in detail how blood circulates through the foetal heart
2. Explain in general terms the circulation of blood in the foetus and placenta

3. Explain the functions of the foramen ovale, ductus arteriosus and ductus venosus
4. Explain the changes that occur in the circulation of blood in the foetus at the time of birth
5. Explain briefly the consequences of non-closure of foramen ovale and ductus arteriosus
6. Review and describe the development of trilaminar disc, the 3 germ layers (ecto, endo and
mesoderm), and folding

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Adult Circulation
• Involves separate pulmonary and systemic
circulations
• No mixing of oxygenated and deoxygenated
blood
• Oxygenation of the blood occurs in the
lungs
• There is extensive hepatic blood supply

• Are the latter 2 going to occur in the
foetus?
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Foetal Circulation
• A developing foetus has special needs

RA

– Lungs are not functioning as in adults
– Digestive system is not functioning as in adults so
has a restricted hepatic circulation

• The foetal circulation is modified by
three shunts or by-passes to avoid the
lungs and the liver
– By-pass of the hepatic circulation via ductus
venousus
– By-pass of the pulmonary circulation via the
foramen ovale
– By-pass of the pulmonary circulation via the
ductus arteriosus

RV

IVC

Foramen
ovale

Body

PA

Lung
Ductus
Arteriosus

Aorta

PV
LV

LA

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Placenta
• O2 and nutrients diffuse
across the placental barrier
from mother to foetus while
CO2 and metabolic waste
are removed via the
placenta
• Maternal and foetal blood
never mix
• Usually posterior-fundal
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Placenta

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Umbilical cord
• The umbilical cord is surrounded by the
foetal membrane, amnion, and contains
Wharton’s jelly.
• Embedded in this jelly are two umbilical
arteries and single umbilical vein

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Umbilical vein to Ductus Venosus
• Umbilical vein, carries oxygen- and nutrientrich blood from the placenta
• Divides into two branches:
• Smaller branch to the liver
• Larger branch, ductus venosus by-passes
liver and drains into inferior vena cava
• Oxygenated blood mixes with venous blood
from the lower limbs.

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Foramen ovale
• Most of the blood coming through inferior
vena cava passes from right atrium into left
atrium through foramen ovale
• Then onward to L. ventricle and aorta
• Remember valve of the inferior vena cava?

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Foramen ovale

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Ductus Arteriosus
• Blood carried by superior vena cava (deoxygenated)
→ RA
→ RV
→ pulmonary trunk
→ ductus arteriosus (90%)
→ aorta
• Small amount
• pulmonary trunk
• pulmonary arteries (10%)
• Lungs
• pulmonary veins
• LA → LV → aorta

Note!
Where does DA
open?
Why here?

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Umbilical arteries
• One third of the blood in the descending
aorta is distributed in the abdomen, pelvis
and lower limbs
• Two thirds of the blood goes to the placenta
via internal iliac artery → umbilical arteries
→ Placenta

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Foetal Circulation

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Post natal circulation
• Shunts (by-passes) must be obliterated at birth when the pulmonary circulation
comes on stream!!
• The umbilical cord is tied and cut
– Loss of the blood flow through the placenta
– Increased systemic vascular resistance
– Increased aortic → left ventricular → left atrial pressures

• First breath
– Expansion of the lungs (alveoli)
– Decreased pulmonary vascular resistance
– Reduced pulmonary arterial → Reduced right ventricular → Reduced right atrial pressures

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Closure of Foramen ovale
• Once pulmonary circulation is established,
blood from the pulmonary circulation (lungs)
is returned to the LA
• Pressure rises in the LA

• Valve of the foramen ovale is pushed
rightward and closes the foramen
• It becomes structurally closed by 4 months →
fossa ovalis and falx septi
15

Patent foramen Ovale
• Patent foramen ovale (PFO) is a
consequence of non-closure
– Usually asymptomatic
– May cause paradoxical emboli

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Obliteration of Ductus Arteriosus
• Functional closure (first hour):
• Constriction of the smooth muscle on the wall
of ductus arteriosus
– Increased oxygen
– Fall in Prostaglandins

• Structural closure (between 1 and 4 months):
Anatomical closure by thickening of the tunica
intima

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Patent Ductus Arteriosus
• Postnatally the aortic pressure is greater than
in the pulmonary trunk
• Blood will flow back into the pulmonary
circulation
– Left to right shunt
– Increased pulmonary blood flow → pulmonary
hypertension
– Congestive cardiac failure

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Obliteration of Ductus Venosus
• Blood flow through the umbilical vein ceases.
• The muscle wall of the ductus venosus contracts
• Portal venous blood flows through the hepatic
sinuses
• Functionally closes within 1 to 3 hours of birth
• Obliterates and becomes Ligamentum venosum

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Obliteration of Umbilical Vessels
• Umbilical vein obliterates and forms the round ligament of the liver (lig. teres
hepatis)
• Distal parts of the umbilical arteries atrophy around 2-3 months to become the
medial umbilical ligaments (within medial umbilical folds)

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Before and after

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First three weeks
• The morula travels down the Fallopian tube, enters the
uterine cavity and implants into the endometrium
• At about the time of implantation, fluid begins to
accumulate in the intracellular spaces of the morula
• Gradually the intercellular spaces merge to form a single
cavity.
• If we take a section from the blastocyst, that is how it looks
(right
• figure) This cavity is called blastocele (blastocyst cavity)
•
We have an “inner cell mass” at one pole and these cells
start to
• differentiate to form the primary germ layers (endoderm
and ectoderm)
• – This process is called gastrulation
•
At this stage the embryo is called a blastocyst

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Morula to blastocyst
• If we take a section from the blastocyst, that is
how it looks This cavity is called blastocele
(blastocyst cavity)
• We have an “inner cell mass” at one pole and
these cells start to differentiate to form the
primary germ layers (endoderm and ectoderm)

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Day 9
• Implanting in uterine
mucosa
• Forming bilaminar disc
with
– Hypoblast and yolk sac
– Epiblast and amnion

• 0.2mm across

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End of week 2
•
•
•
•
•

Bilaminar disc with connecting stalk
Within chorionic sac
Amniotic sac on “dorsal” side
Yolk sac on “ventral” side
Epibalst and Hypoblast are in contact

• Day 14 Primitive streak appears –
cells start to move
• Gastrulation has begun
• Next 3-4 days a lot happens

13/09/2023

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Gastrulation
• The process of turning the bilaminar disc into a tri-laminar disc
• Epiblast cells migrate through the primitive streak displacing the hypoblast cells
– New layer is Endoderm

• Later more epiblast cells migrate and fill in between the two layers*
– Mesoderm

• Epiblast is now know as Ectoderm
• 3 Germ layers
• Sets up definitive body axis
• Allows cells to move then induce
differentiation
13/09/2023

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Notochord
• Notochordal process grows from
primitive pit
• Changes from tube to disc to solid rod
(17 -20 days)
• Induces changes in overlying ectoderm
– Forms neural plate

• Differentiation of mesoderm
–
–
–
–

Paraxial (somites)
Intermediate
Lateral plate
→ somatic and splanchnic

13/09/2023

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Mesoderm
•
•
•
•
•
•
•
•
•
•

The mesoderm has 3 parts: paraxial mesoderm, intermediate
mesoderm and lateral plate mesoderm
– Paraxial mesoderm will differentiate into somites
(sclerotome, myotome, dermatome) and head
mesenchyme
– Intermediate mesoderm will develop into the urogenital
system
– Lateral plate mesoderm will become the walls of the body
cavities, serous membranes (parietal and visceral
peritoneum) and differentiate into vascular system
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Sources of figures and Images
•
•
•
•
•
•
•

•
•

DAFFNER: Daffner & Hartman. Clinical Radiology. The Essentials ,4th Ed, 2014 ©
Lippincott Williams & Wilkins.
DRAKE: Drake et al. Gray’s Atlas of Anatomy 2nd Ed, 2018 © Elsevier.
GILROY: Gilroy et al. Atlas of Anatomy 2nd Ed, 2012 © Thieme
KELLEY: Kelly&Petersen. Sectional Anatomy for Imaging Professionals, 3rd Edition,
2013 © Mosby, Elsevier Inc
MOORE: Moore et al. Clinically Oriented Anatomy 8th Ed, 2018 © Wolters Kluver.
NETTER: Hansen. Netter's Clinical Anatomy, 3rd Edition, 2014 © Saunders, Elsevier
Inc
SOBOTTA: Putz&Pabst. Sobotta Atlas of Human Anatomy, 14th Edition, 2006 ©
Urban and Fischer Verlag, Elsevier Inc
ONI: Soni et al. Point-of-care Ultrasound, 2015 © Saunders.
Langmans Medical Embryology 14th ed. 2019. © Lippincott Williams & Wilkins

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