Fetal circulation Dr. S. Parthasarathy MD., DA., DNB, MD (Acu), Dip. Diab.DCA, Dip. Software...

Fetal circulation

Dr. S. Parthasarathy MD., DA., DNB, MD (Acu),

Dip. Diab.DCA, Dip. Software statistics PhD (physio)

Mahatma gandhi medical college and research institute, puducherry, India

What are the needs of the CVS ??

• Give oxygen to tissues

• Give metabolic nutrients to tissues

Fetus to neonate

Placenta to lungs

Fetus

Essence

• The entire cardiac output cannot go to the lungs

• Hence we have shunts in the circulation

• But adequate oxygen supply has also be there

• After delivery, lungs take over, shunts disappear• The foramen ovale, ductus arteriosus, and ductus

venosus

Some changes take place

• That is transitional circulation

• Word is important – transitional !!!

• If it is permanent – think of preterm, critically ill neonate or congenital cardiac illness

Special characters • Parallel arrangement of two main arterial

systems and their respective ventricles.• But series in adults • Mixing of venous return and preferential

streaming.• High resistance, low flow of pulmonary

circulation.• Low resistance and high flow of placental

circulation.• Presence of shunts

The pathway

• Deoxygenated blood of fetus

• Descending aorta

• Umbilical arteries Placenta

• Intervillous spaces - gas exchange oxygenated blood

Then what happens

• Umbilical vein

• Preferably through ductus venosus to IVC

• Streaming

• Liver bypassed

From the IVC, it bypasses the right atrium through foramen ovale to Left atrium

Streaming • Eustechian valve helps to direct the IVC blood to cross the

foramen ovale to left atrium

• The lower margin of septum secundum [crista dividens] helps

to direct the left posterior stream to preferentially across the

foramen ovale.

• Posterior and left stream of IVC blood carries oxygenated

blood while anterior and right stream carries poorly

oxygenated blood

• SVC blood is directed across the TV to right ventricle

• Left atrium to left ventricle through mitral valve

• LV to ascending aorta

• Supplies oxygenated blood to three main arteries

• Mixes with ductus arteriosus blood

• most highly oxygenated blood is delivered to the myocardium and brain.

The pathway

• Deoxygenated blood from the SVC and part of IVC enter Right atrium,

• Tricuspid valve • Right ventricle • Pulmonary artery • Then lungs ?? No • But through ductus arteriosus to descending

aorta

• Left to right (blue)

• And

• Right to left shunt (Pink)• follows

SVC and IVC

80 %

65

25%

50

60

RV vs LV

• The RV receives about 65% of the venous return and the LV about 35%.

• Thus, in the shunt dependent circulation of the fetus, the situation is much more complex and cardiac output must be defined in different terms.

• Hence CVO = combined ventricular output• 45 % to placenta 8 % to lungs

The big three

• high hemoglobin (16gm%)• fetal haemoglobin • high CVO

• help maintain oxygen delivery in the fetus despite low oxygen partial pressures

HbF

Normal Hb

• The transition from fetus to neonate

Transition

• Gas exchange function is transferred from placenta to the lungs.

• Shunts closure • Separation of systemic and pulmonary

circulations.• LV output must increase • Increased metabolism to maintain body

temperature

What is done

• Placenta removed • Cord clamped • Baby cries and lung starts to inspire

Cord clamped and placenta removed

• The umbilical vessels are reactive and constrict in response to longitudinal stretch and the increase in blood PO2.

• Obviously external clamping of the cord will augment this process.

• Placenta removed • No flow through ductus venosus

The ductus venosus closes passively3–10 days after birth.

Placenta (low resistance) cut off, SVR increases

Lungs expand • At birth, after expansion of the lungs, there is

a dramatic fall in PVR and an 8–10-fold

increase in pulmonary blood flow.

• Expansion stimulation of stretch receptors

vasodilation

• Not oxygen , even any gas

LA flow increase – RA flow decrease FO closes

• Initial closure of the foramen ovale occurs within minutes to hours of birth.

• Anatomical closure occurs later via tissue proliferation.

• Ductus venosus is closed FO closed , what next

• Ductus arteriosus

• Concomitant with the drop in PVR, the shunt at the level of the DA becomes bi-directional.

• The exact mechanism of ductal closure is not known

• increased PO2 in neonatal blood- direct constriction of smooth muscle within the duct.

• concentrations of PGE2, produced in the placenta, fall rapidly after birth, causes ductal constriction.

PVR change

Ductus arteriosus

• Functional closure by 96 hours

• anatomical closure via endothelial and fibrous tissue proliferation later

• Hemoglobin • HbF becomes adult Hb – better oxygen delivery

Cardiac output

• Term fetus -- CVO = 400 ml / kg/min.• Neonate CVO = upto 400 ml / kg/min.

• Upto 4.0 litres / sq. metre • Necessary for increased metabolic demands

• LV and RV outputs equalize

Persistent fetal circulation

By then-- why we should know about fetal circulation

• Take for example – A case of truncus or transposition of vessels come for other surgery – It should be known to us that Ductus arteriosus should be kept patent –

• Yes they need shunts • We can start PGE1 infusions

• Congenital diaphragmatic hernia – PVR has not come down – What should be done to make fit !!

• Thank you all