Regulation and Assessment of Fetal Growth

Question 1

Why is fetal growth so important to track?

Answer 1

fetus’s that are less than the 3rd percentile in growth for gestation age have a very high risk for intrauterine death (still born, miscarriage)

Question 2

What factors help regulate fetal growth?

Answer 2

• genetics
• endocrinology
• environment
• placentation

However it is not perfectly understood how growth is regulated in the fetus

Question 3

Maternal and intrauterine environment contribute to about 60% of fetal weight. Fetus genotype is account for 15%, the maternal genome 20% and the Y chromosome only 2%.

Why does the maternal genome contribute more significantly than the paternal genome in regards to fetal growth?

Answer 3

Fetus needs to maintain appropriate size for mores pelvis and birthing canal for delivery hence the disproportionate parental genetic distribution

Question 4

What are the genetic factors that contribute to fetal growth?

Answer 4

1. maternal vs paternal genome
   - maternal more heavily contributed
2. ethnic influences
   - customised growth charts
3. Chromosomal abnormalities
   - aneuploidy
   -uniparental disomy

Question 5

How does the endocrine system contribute to regulating fetal growth?

Answer 5

1. Thyroid
   - both hyper and hypo thyroidism can contribute
2. Pituitary
   - GH/TSH/prolactin
3. Growth hormone
   - lower growth hormone leads to reduce IGF-1
4. Insulin/IGF/IGF-BP
   - particularly IGF binding proteins (IGF-BP)
   - increased IGF-BP then there is less freely available IGF
   - IGF-BP1 increases with excess maternal inflammation and malnutrition

Question 6

How does the environment contribute to fetal growth?

Answer 6

1. uterine size (dictated by maternal genome)
   - fibroids, multiple gestation and malformation all take up space within the uterus which could obstruct the room needed for fetus to grow
2. nutrition
   - pre-pregnancy and pregnancy
3. Altitude
   - at higher altitudes there is reduced O2 binding to haemoglobin and the fetus will not recieve as much oxygen
4. Drugs
   - therapeutic (ACE, anticonvulsants)
   - social (smoking, cocaine, alcohol)
5. Infection
   - viral (Covid, CMV, HIV)

Question 7

How does placentation contribute to fetal growth?

Answer 7

1. primary (placenta damage)
2. secondary (irregular placentation secondary to other pathologies):
   - SLE
   - diabetes
   - hypetension
   - lupus
   - nephropathies
   All cause abnormal vascularisation of the placenta
   - inflammation resulting in disordered placentation from endotheliopathy/vasculopathy
   - causes oxidative stress

Question 8

The placenta is key for transporting nutrients across to the fetus. If this placenta is damaged, inflamed or scarred how does this affect fetal growth?

Answer 8

there is a decreased surface area that occurs lowering the effect of transportation across the placenta

Question 9

What are the 3 kinds of feta growth abnormalities?

Answer 9

1. macrosomia
   - larger than the 90th percentile for gestational age
2. small for gestational age (SGA)
   - fetus under the 10th percentile for gestational age
   - these babies are small but are still healthy
3. fetal growth restriction
   - asymmetric
   - symmetric

Question 10

What is the difference between asymmetric and symmetric fetal growth restriction and what parameters are used to measure FGR?

Answer 10

parameteres:
- head circumference
- abdominal circumference
- femur length

asymmetrical FGR
- if one or two of the 3 parameters are measuring smaller for gestation age

symmetrical FGR
- all thee parameters measure small for gestational age

Question 11

Asymmetrical FGR is more common and usually if left untreated will become symmetrical FGR. Why does this occur?

Answer 11

usually abdominal circumference is the first to decrease in size due to fetus malnourishment with head circumference last to decrease in size
- this is due to the brain being the most valuable organ and all of the sparse nourishment the fetus receives the brain takes it

Question 12

Why is the abdominal circumference usually the first to decrease in size in FGR?

Answer 12

Due to malnourishment the fetus will use up the glycogen stores in the liver and covert to glucose for nutrition.

Long term use of glycogen stores causes the liver to become smaller and therefore the abdominal circumference decreases in size.

Question 13

What is the broad definition of FGR?

Answer 13

an estimated fetal weight or abdominal circumference less that the 10th percentile for gestational age

Question 14

What is the definition for severe FGR?

Answer 14

an estimated fetal weight or abdominal circumference less than the 3rd percentile for gestational age

Question 15

What is the definition of FGR for the College of ObGyn?

Answer 15

AC or EFW less than 10th percentile for gestational age

Question 16

What is the definitional of FGR for International society of ObGyn?

Answer 16

EARLY (less than 32 weeks)
- AC or EFW less than 3rd percentile for gestational age or umbilical artery absent end diastolic flow
OR
- AC or EFW less than 10th percentile for gestational age

combined with one of the following:
- uterine artery pulsatility index above the 95th percentile
- umbilical artery pulsatility index above the 95th percentile

LATE (at or after 32 weeks)
AC or EFW less than the 3rd percentile for gestational age
OR any two of the following:
- AC or EFW less than 10th percentile for GA
- AC/EFW crossing centiles more than 2 quartiles on growth centiles
- cerebroplacental ratio less than the 5th percentile or umbilical artery pulsatility index above the 95th percentile

Question 17

FGR/ intrauterine growth restriction aetiology is caused by:

Answer 17

fetal anomaly
- chromosomal 5%
- structural 7% (congenital heart/ kidney disease)

infection 5%

environment 10% (smoking, drugs, alcohol, nutrition, physical activity)

placental (majority of cases)

Question 18

FGR percentage by aneuploidy status compared to normal chromosomal numbers

Answer 18

normal chromosome amount
5-7% have FGR

trisomy’s
50% of trisomy fetuses have FGR

Question 19

What are the placentation causes of FGR?

Answer 19

1. idiopathic (cause unknown)
2. hypertensive disorders
   - pre-eclampsia
   - chronic hypertension
3. antiphospholipid syndrome (APLS)
   - greater risk for developng blood clots
4. Thrombophilias
   - cause blood clots in microvasculature
   - reduced gas/nutrient exchange
5. Other medical disorder
   - diabetes
   - renal disorders
6. Being male
   - Y chromosome is not as efficient as second X chromosome

• blood clots cause lack of transport across the placenta due to specific area not working due to lack of blood flow

Question 20

What is the normal pathology of blood vessels in the placenta?

Answer 20

high capacitance
low resistance to increase blood flow

Question 21

In pre-eclampsia, the vessels in the placenta are altered. What changes that affects the placentas function?

Answer 21

high resistance in vessels

low capacitance
- poor perfusion
- reduced nutrient/gas-exchange
- inflammation
- vascular shear stress/ endothelial dysfunction

Question 22

Why is umbilical artery waveforms measured by doppler used as a factor to determine FGR?

Answer 22

umbilical artery goes from baby back to placenta

umbilical artery waveforms help identify pulsitility index.

If placenta is dysfunctional there is an increased resistance to blood flow back to placenta

Question 23

What does reversed diastolic flow on umbilical artery waveforms display?

Answer 23

demonstrates that there is reversal of umbilical cord flow
- there is back flow meaning that deoxygenated blood is going back to the fetus due to resistance in cord and/or placenta
- causes the babys heart to over work to overcome the resistance

Question 24

With doppler umbilical artery waveforms increased resistance is seen first then followed by absent end diastolic flow then reversal end diastolic flow. What happens to the fetus during the decreasing placental function?

Answer 24

increased resistance:
- reduced fetal growth

if increased resistance continues:
- fetal hypoxia

absent end diastolic flow:
- fetal acidaemia (acidosis)
- decrease in pH due to lack of oxygen and increased CO2

reversed end diastolic flow:
- severe fetal acidosis and demise

Question 25

What are the long term consequences of FGR?

Answer 25

FGR results in fetal adaptations like:
- organ adaptations
- cardiovascular/endothelial dysfunction
- altered neurodevelopment and possible neuro-behavioural adversity

Question 26

What is the relationship between SGA and FGR

Answer 26

most SGA fetuses are not FGR fetuses

a significant number of inter-uterine growth restriction fetuses have a birth weight within the normal range

Question 27

How is FGR detected

Answer 27

1. clinical examination (not as accurate as ultrasound assessment):
   - abdominal palpation
   - symphyisiofundal (SFH) height
   +50-75% detection rate
   +30% specificity
   - maternal subjective assessment
2. Ultrasound assessment
   - fetal biometry
   - doppler studies
   + umbilical artery
   + uterine artery
   - amniotic fluid assessment

Question 28

What is fetal biometry measured in ultrasound assessment for FGR detection?

Answer 28

AC = abdominal circumference
HC = head circumference
BPD = biparietal diameter
FL = femur length

Question 29

How is FGR managed

Answer 29

management depends on:
- severity of FGR
- onset of disease (early vs late)
- aetiology
- overall ‘trend’
- doppler and amniotic fluid findings

Question 30

What diagnostic tools are used to differentiate between IUGR and SGA?

Answer 30

doppler ultrasound of umbilical artery pulsitility index and measurement of amniotic fluid

Question 31

If fetuses around to be under the 10th percentile for weight what diagnostic testing should be offered as the first step?

Answer 31

anatomical surveying and karyotyping

Question 32

How is fetal/maternal surveillance and delivery planning clinically determined?

Answer 32

should be tailored to gestation and severity