Lecture 11 Fetal Physiology

From Iusmphysiology

• continued here from Lecture 10 Coronary Artery Disease on 01/31/11 at 9:45AM.

Contents 1 Fetal and Neonatal Cardiovascular Physiology 1.1 Objectives 1.2 I. Fetal blood flow pathways 1.2.1 A. The fetal placenta receives approximately 45% of the fetal cardiac output 1.2.2 B. Oxygenated venous blood from the placenta does not completely mix with vena cava blood 1.3 II. Exchange across the placenta 1.4 III. Maternal Cardiovascular Consequences of Pregnancy 1.5 IV. Circulatory changes at birth 1.6 Clinical case 1.7 Clinical case

Fetal and Neonatal Cardiovascular Physiology

Objectives

• In the fetus, why does the head, heart, and upper torso receive blood with a higher oxygen content than in the lower body?
• What two anatomical structures are open to blood flow in the fetal circulation but close after birth? What is the function of each of these structures? By what mechanism does each of these open structures close after birth has occurred?
• How does the right ventricle contribute to perfusion of the fetal body? How does blood from the right ventricle reach the aorta?
• What unusual property of fetal hemoglobin compared to adult hemoglobin makes oxygenation of the fetus possible?
• At what point during the birth process does the neonate stop receiving oxygen from the mother? What is the stimulus for the fetal placental circulation to shut down?
• How does the mother's cardiac output, vascular resistance, and mean arterial blood pressure change during the course of pregnancy? What are the three major reasons that the cardiac output increases? How much does pregnancy increase oxygen usage by the mother?
• How does the fetus receive glucose, amino acids, and monoglycerides from the mother's blood? Which of these materials is the major source of nutrition?
• Why cardiac output decrease in the supine position as pregnancy advances and the fetus/uterus enlarges? How do women compensate for this problem?
• How much does the mother's blood volume increase on average during pregnancy? How much does total extracellular volume increase in support of the fetus?

I. Fetal blood flow pathways

    1. Prior to birth, oxygenation of the fetal      blood and removal of carbon             dioxide and other wastes depends  upon the placental circulation. 

A. The fetal placenta receives approximately 45% of the fetal cardiac output

CURIOUS THINGS TO REMEMBER

   1.  PA is pulmonary artery and receives 66% of total cardiac output:  Right ventricle dominates fetal life 
    2.  About 7% of total cardiac output goes into lungs 
    3.  Left ventricle pumps about 34% of total cardiac output 
    4.  FETAL PLACENTA – 45% OF FETAL CARDIAC OUTPUT 
 

fetal blood flow lamb data % of Cardiac Output in various regions

B. Oxygenated venous blood from the placenta does not completely mix with vena cava blood

and passes through the atrial septum (foramen ovale) such that left ventricular blood oxygen content is higher than right ventricular oxygen content by about 20% 

Head, neck and upper limbs receive blood with higher oxygen content than that of the lower body because of shunt across foramen ovale and DA ductus arteriosus entering aorta after the arch is completed

To ensure the best possible oxygenation of blood to the fetus, fetal hemoglobin has much greater affinity for oxygen than adult type hemoglobin at low oxygen concentrations.

  1.  Allows fetus to readily take oxygen    from mother’s placental tissues 
  2.  Hemoglobin unloads oxygen very  readily to fetus 
   

fetal oxygen saturation lamb % Saturation of Hemoglobin with O2

II. Exchange across the placenta

A. Non-insulin dependent GLUTs primarily used to move glucose across membranes - glucose is main energy source for fetus

       B.  Amino acid transport from mom to baby by active transporters - fetal blood  has higher amino acid concentration for most amino acids than mother's  blood 
       C.  Free fatty acids and glycerol enter baby by diffusion, something slows  diffusion of triglycerides 

cardiac output increase during gestation

III. Maternal Cardiovascular Consequences of Pregnancy

A. Cardiac out increases about one-third - comparable to slow walking B. Supine position limits cardiac output: uterus presses on abdominal vena cava. Women usually learn to lie on their sides. C. Heart rate steadily increases with fetal growth, but change should be small D. Stroke volume first increases and then either levels off or lowers a bit. Heart rate increase over time maintains increased cardiac output E. Mother's blood volume increases about 1 liter (25% for most women) and total body extracellular water increases 6-7 liters: Mom, baby, amniotic fluid F. Total body red cell mass increases but hematocrit tends to decrease because plasma volume increases more than red cell mass.

G. Ideally, the mean arterial blood pressure should be relatively constant. H. Increased cardiac output offset by lowered system vascular resistance (SVR): A new, large organ is forming plus heat dissipation by skin vasodilation is needed. At term pregnancy, uterus receives about 17-20% of cardiac output. I. Gradual increase in SVR after 20 weeks is not well understood. Possibly due to stress of supporting the enlarging fetus? J. Mother's oxygen consumption increases about 50% to support fetus and her increased cardiovascular performance, body mass, and renal function to clear fetal wastes.

IV. Circulatory changes at birth

The switch from placental to pulmonary vasculatures for gas exchange.

         1.  When the lung expands with air, pulmonary vascular resistance   dramatically decreases and allows increased blood flow. 
         2.  The ductus arterious closes as PGE2 decreases as the tissues   become less hypoxic: also increased bradykinin may constrict 

3. Placental perfusion continues during birth process but stops once ventilation increases blood plasma oxygen. Placental vessels constrict to avoid fetal hemorrhage 4. The decrease in pulmonary vascular resistance upon ventilation increases blood flow through right ventricle to lung. Lowers right atrial pressure and raises left atrial pressure such that foramen ovale flap mechanically seals and eventually anatomically fuses with atrial septum in >95% of humans.

5. After birth occurs, fetal hemoglobin will be gradually replaced with the

     adult form of hemoglobin .   
6.  Pulmonary arterioles lose their heavy muscle layer which allows         pulmonary vascular resistance to decrease 

Clinical case

A sustained pulsing murmur is heard in the upper chest of a 12 hour old full term neonate.  The child is not cyanotic or hypoxic, but heart rate is high and arterial pressure is below normal.  A probable diagnosis and treatment would be 
 

• A. aortic valve incompetence requiring valve replacement/repair.
• B. open atrial septum defect requiring catheter placement of patch.
• C. mitral valve stenosis requiring valve replacement/repair.
• D. open ductus arteriosus treated with cycloxygenase blocking drug.
• E. coarctation of the ascending aorta requiring aortic resection.

Clinical case

A 27 year old pregnant woman having her first child is seen for her 36 week checkup. She is having light-headed episodes when lying down, particularly when trying to go to sleep at night. Her arterial pressure and heart rate while standing is 120/70 mmHg and 87 beats/min, sitting is 115/65 mmHg and 79 beats/min, and lying down is 90/50 mmHg and 107 beats/min. The most likely cause of the supine hypotension is

• A. failure of baroreceptor function.
• B. vena cava compression by the uterus/fetus.
• C. early heart failure due to pregnancy demands.
• D. relative hypovolemia for her stage of pregnancy.
• E. a pulmonary artery clot that blocks by body position.

• stopped here on 01/31/11 at 10AM.
• started here on 01/31/11 at 11AM.

• stopped here on 01/31/11 at 12PM.