18. Physiology of pregnancy

Question 1

How does the foetus (and the placenta) affect physiological demands?

Answer 1

An increase in physiological demands for the foetus (& placenta):

• Nutrients (e.g. O2, amino acids, glucose)
• amniotic fluid production
• Removal of foetal waste products (e.g. CO2, nitrogen compounds)

Requires increased:

• Nutrient content (Gastro intestinal)
• Oxygen content (Pulmonary & cardiovascular)

Question 2

List the changes that occur as a result of pregnancy

Answer 2

Plasma volume changes
 Cardiovascular changes
 Respiratory changes
 Renal changes
 Gastro-intestinal
 Endocrine changes

Question 3

Effect of pregnancy on volume homeostasis?

Answer 3

A rapid increase in plasma volume by 40%
2.5 L to 3.7 L by end of pregnancy
11-13 kg weight gain (8-10kg fluid)
Plasma colloid osmotic (oncotic) pressure falls

Question 4

What is the effect of decreased plasma colloid osmotic (oncotic) pressure in pregnancy?

Answer 4

Plasma colloid osmotic (oncotic) pressure falls
Causes a shift of fluid into extra cellular space
Increased hydration of connective tissue
Oedema (lower limbs, hands and face)

Question 5

What is the mechanism of increased plasma volume in pregnancy?

Answer 5

Oestrogen positive feedback effect on angiotensinogen
Progesterone positive feedback effect on aldosterone
resulting in more RAAS system and aldosterone and consequently more Na+ and water reabsorption at the kidney.

There is also:

• a slight decrease in ANP
• decreased thirst threshold (so more fluid intake)
• resetting osmostat

this results in increased plasma volume

Question 6

Red blood cells and oxygen availability in pregnancy

Answer 6

Haemoglobin;
red cell mass increased by 25% (1.3L to 1.7L)
plasma volume increased by 40%
13.3 to 10.9 g/dL at 36 weeks
dilutional anaemia
Iron is required for the increased red cell mass
fall in ferritin levels
increased iron absorption from gut
No need for routine Fe supplementation except for twins
Delivery of blood to the uterus; uterine artery blood flow increases 3.5 fold from 95 to 342 ml/min

Question 7

Haemostasis in pregnancy

Answer 7

Hypercoagulable state:

• Increase plasma fibrinogen (increased ESR (erythrocyte sedimentation rate))
• increased platelets
• increased factor VIII & von willebrand factor

Marked effect at delivery:

• 500 ml/min blood loss at placental separation
• myometrial contraction - 10% of all fibrinogen used up

Evolutionary balance between thrombosis and haemorrhage

Question 8

White blood cells in pregnancy

Answer 8

Concentration does not fall during pregnancy
Total WBC increases in pregnancy
Increase in neutrophils (reduced apoptosis)
Marked increased around delivery

Question 9

What are the implications of the increased blood volume during pregnancy

Answer 9

Increased blood volume has implications on:

• cardiac output (SV x HR)
• peripheral resistance
• blood pressure

Question 10

Heart changes during pregnancy

Answer 10

Increased cardiac output needs increased stroke volume
increased stroke volume needs increased heart volume

Heart enlarges by 12% (increased venous return)

Innocent systolic murmurs are common (~90%)

Diastolic murmurs (~20%) – require investigation to rule out other pathologies,

• may be innocent – reflecting increased flow across atrioventricular valves
• will require further investigation to rule out cardiopathies – but be aware…
• change in cardiac axis/position result in changes on ECG and xray

Also… Uterus pushing up against the diaphragm can cause the maternal heart to shift up in the chest cavity

Question 11

Peripheral resistance during pregnancy

Answer 11

Peripheral vasodilatation (effect of progesterone)
Peripheral resistance decreases by 35%

Question 12

Blood pressure during pregnancy

Answer 12

Decrease in resistance is partly compensated by increase in cardiac output

Results in a small change in blood pressure

Systolic dips slightly then increases again
Diastolic dips by about 20mmHg from around week 8 then starts to increase again at around week 16 back to normal at around week 38

Question 13

Respiratory system in pregnancy

Answer 13

Increased pulmonary blood flow matched by -
Increase tidal flow

Decrease maternal pCO2 & increase maternal pO2
->
Increased availability of O2 to tissues and aids passive diffusion at the placenta i.e. higher concentration gradient

Question 14

What is the effect of cardiovascular and respiratory changes in pregnancy?

Answer 14

High blood flow maximises pO2 on maternal side of the placenta

Foetal haemoglobin (HbF) has a higher affinity for O2 compared with maternal adult Hb (HbA)

Increased cardiac output may increase flow in skin aiding heat loss (high metabolic state)

Question 15

The effect of pregnancy on the renal system

Answer 15

Kidney increases 1cm in size during normal pregnancy

GFR and effective renal plasma flow increase 50+%

BUT tubular reabsorption capacity is unchanged
leads to a decrease in glucose reabsorption thus glycosuria (glucose excretion in urine) is common

Plasma levels of creatinine and urea decrease in pregnancy

All the increments are present by the second trimester

Reduction in GFR of 15 % during the third trimester

Dilatation of renal pelvis and ureters (progesterone) - increased urinary tract infections in pregnancy

Question 16

Effect of pregnancy on gastrointestinal system

Answer 16

Gastro-oesophageal reflux up to 70 %
due to increase abdominal pressure, reduced pyloric sphincter with back wash of bile secondary to hormonal changes
simple measures: avoidance of fat and alcohol
upright posture and antacids
Slowing of gut motility and constipation (progesterone effect)

Question 17

Glucose metabolism in pregnancy

Answer 17

First trimester: increased sensitivity to insulin thus mothers increase glycogen synthesis and fat deposition
Second trimester: insulin resistance
cortisol, progesterone, HPL (human placental lactogen), & oestrogen are all insulin antagonists
thus glucose levels may rise and there is an increase in fatty acids (another source of energy for the fetus)

Question 18

Folate in pregnancy

Answer 18

Needed for DNA synthesis, repair and regulation

• Important in rapid cell division (embryos)
• Deficiency in pregnancy associated with neural tube defects (NTDs)

Needed for RBC development
- deficiency can lead to macrocytic anaemia

Daily requirement increased from 50mg to 400mg (normal diet)

Plasma folate represents current nutritional status, but

Significant tissue stores (e.g. liver) – RBC folate is a good biomarker (no change in pregnancy)
- Dietary deficiency can take months to become significant

No need for folate supplementation but prevents neural tube defects thus routinely given preconception to 3 months

Question 19

Thyroid function during pregnancy

Answer 19

Increased iodine absorption
Increased serum T3 and T4 levels

Increase in thyroid binding globulin (oestrogen)

As only unbound T3 and T4 is active, levels of free T3 and T4 remain the same or fall slightly

In general thyroid function remains unchanged

If hypothyroid may need to increase dose due to increased TBG levels

Question 20

What hormones does the placenta, as an endocrine organ, secrete?

Answer 20

Protein hormones:

• hCG (human chorionic gonadotrophin)
• hPL (human placental lactogen)
• hPG (human placental gonadotrophin
• CRH (corticotropin releasing hormone)

Steroids:

• Progesterone
• Oestrogen (oestriol)

Question 21

Human chorionic gonadotrophin (hCG)

Answer 21

First detectable 8-9 days after ovulation & peaks at 8-10 weeks

Beta subunit used as the pregnancy test

Doubles every 48-72 hours

Produced by the trophoblast

Alpha subunit very similar to LH, FSH,TSH

Has LH type properties but longer half life (24 h)

Maintains corpus luteum secretion of progesterone & oestrogen

Decreases as the placental production of progesterone increases

Later in pregnancy may have a role in maternal oestrogen secretion and modulation of the maternal immune response

Question 22

When is hCG low and when is it high?

Answer 22

Produced in large quantities by hydatidiform molar pregnancy & choriocarcinoma

Usually significantly lower in ectopic pregnancy & risk of miscarriages

Decreases as the placental production of progesterone increases

Later in pregnancy may have a role in maternal oestrogen secretion and modulation of the maternal immune response

Question 23

Human placental lactogen (hPL)

Answer 23

Similar structure to prolactin and growth hormone

The bigger the placenta, the more hPL

Half life ~ 30 min

Not functioning as a stimulator of lactogenesis

Alters maternal carbohydrate and lipid metabolism to provide for foetal requirements:

• Mobilizing maternal free fatty acids
• Inhibits maternal peripheral uptake of glucose
• Increases insulin release from pancreas

Aim is a steady state of glucose for the fetus

Question 24

Placental growth hormone (hPG)

Answer 24

Placental Growth Hormone secreted by the placenta responsible for regulating fetal growth

Induces maternal insulin resistance

No evidence of that maternal GH or fetal GH required for fetal growth

Question 25

Placental corticotrophin-releasing hormone (CRH)

Answer 25

Stimulates production of maternal:

• adrenocorticotropin hormone (ACTH)
• cortisol

? Increased cortisol believed to be detrimental to the foetus ?

• High levels early linked to slower rate of cognitive development post-partum
• High levels late linked to accelerated cognitive development post-partum

Increased cortisol can result in increased maternal glucose

Question 26

Progesterone

Answer 26

Maintains uterine quiescence by decreasing uterine electrical activity
Immune suppressor ( HLA )
Lobulo-alveolar development in breasts
Substrate for fetal adrenal corticoid synthesis eg cortisol

Question 27

Oestrogen

Answer 27

Growth of the uterus, cervical changes
Development of ductal system of breasts
Stimulation of prolactin synthesis
Stimulation of corticol binding globulin (CBG), sex hormone binding globulin (SHBG), thyroxin binding globulin (TBG)
Both maternal & foetal dehydroepiandrosterone (DHEA-S) is converted to oestriol (aromatase)
90% as oestriol (to modulating uteroplacental blood flow)