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BIOL30001 Reproductive Physiology
PlacentationGeoff Shaw
Reading:EssRep7 Ch 13 (+ Ch 14,15)Johnson & Everitt 6 Chapter 10, 11, 12Stevens DH (1975) “Comparative Placentation”Renfree MB (1982) Implantation and placentation.
In Austin & Short: Reproduction in mammals, Book 2.
Mossmann HW (1987) “Vertebrate fetal membranes”
This illustration was made by Luc Viatour http://commons.wikimedia.org/wiki/File:Da_Vinci_Studies_of_Embryos_Luc_Viatour.jpg
Viviparity - birth of live-young• advantages - fetal development & survival
• requires specialised maternal-fetal interface - placenta
– fetal and maternal components
– exchange of gases, nutrients & wastes
– hormones
– limits fetal invasion
– immunological interface
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Role of placenta• Nutritive exchange
– histotrophic vs haemotrophic– gas: O2 and CO2
– sugars, amino acids, lipids etc– waste products, eg. urea
• Hormones– maternal recognition of pregnancy– uterine contractility and secretion– modulation of maternal and fetal physiology
• Immunological interface– fetus has “foreign” paternal genes MHC etc so
fetus is an allograft. Why isn’t it rejected by an immune response?
fetal membranes and placentation - complex endpoint …
… but really arises from a series of simple steps, like origami
Formation of extra-embryonic membranes (mouse/human)
trophectoderm
trophectoderm chorionic ectoderm
extraembryonic ectoderm
extraembryonic mesoderminner cell mass extraembryonic endoderm (pluriblast) embryonicectoderm
mesoderm
endoderm
chorion and placenta
amnion
yolk sac and allantois
embryo and fetus
also see EssRep7 13.1
mesoderm
epiblast
hypoblast
Formation of extra-embryonic membranes
EssRep7 13.1
extra-embryonic coelom
pro-amniotic cavity
pro-embryonic disc
yolk sac cavity
Formation of extra-embryonic membranes
extra-embryoniccoelom
embryonic disc(embryonic ecto-, meso- and endo-derm
amniotic cavity
amnion
chorion
developing chorio-vitelline placenta
yolk sac
EssRep7 13.1
Formation of extra-embryonic membranes
J&E – 10.8
chorio-allantois
allantoisallantoic mesoderm
chorion
regressing yolk sac
primitive umbilical cordextra-embryoniccoelom
amnioticcavity
embryo
EssRep7 13.1
Classification of placentation
• Tissues– chorio-vitelline– chorio-allantoic
• macroscopic structure• microscopic relationship between fetal and
maternal tissues - invasiveness– non-invasive eg pig, horse, sheep, cow– invasive - eccentric eg. dog, rat, rabbit– invasive - interstitial eg. human
Major placenta types
discoid,eg. human, mouse
zonary,eg dog
cotyledonary,eg sheep, cow
diffuseeg. pig, horse, camel
see J&E6 - 10.5
Grosser’s classification: placental typesFetal
Maternal
epithelio-chorial
synepithelio-chorial
endothelio-chorial
haemo-chorial
humandoghorse sheep
see J&E6 – 10.6
Placental blood flow -- human
EssRep7 13.4
haemochorial
EssRep7 13.3
basal decidua
Cast of fetal placental capillary bed
see EssRep7 13.5
Placenta of sheep
EssRep7 13.3
synepithelio-chorial
EssRep7 13.3
fetal chorionic epithelium
binucleate cellmicrovillus junctional zonematernal syncytium
maternal capillary
Placental Hormones• hCG
– LH activity - maintains CL– immune suppression
• hPL (hCS) – prolactin / growth hormone activity– increased breakdown of adipose tissues
• Progesterone & oestrogen- – modulates endometrium: MRP; implantation;
secretory activity; immunological modulation; etc.– suppresses gonadotrophins– myometrium; mammary development– maternal amino acid metabolism
see also EssRep7 13.7
placental oestrogens
oestrone
oestradiol
oestriol
testosterone
placental steroidogenesis – e2
Johnson & Everitt 6, Fig 11.3
steroidogenesis in pregnancy is a combination of maternal, placental and fetal activity
see Johnson & Everitt Table 12.1
pH 7.4
pH 7.3 pH 7.2
pH 7.4
consumes 30% of O2 supplied
Placenta• Placental transfer
– main energy from glucose and lactate in humans– active transfer of specific materials - amino acids, lipids,
vitamins etc.
• placental metabolism– uses 30% of glucose and oxygen supplied by mother– highly active in protein synthesis– conjugation and inactivation of maternal hormones
EssRep7 14.5
Ut Art
Ut Vein
Umb Vein
Umb Art
pH 7.43
pH 7.2 pH 7.26
pH 7.35
• Fetal haemoglobin• Bohr effect – pH
change as CO2 ex-changed increases O2 transfer
note: placenta highly metabolically active – uses 30% of O2 supplied
BODY
FO
LUNG
PLACENTA
DA
Lung is fluid filled and has low O2. It has constricted arterioles restricting blood flow
Most blood shunts through foramen ovale and ductus arteriosus.
oxygenated blood draining from placenta mixes with depleted blood from body
Circulation before birth
BODY
FO closes
LUNG
DA closes
Oxygen opens capillaries in lung increasing blood flow
increased oxygenation of blood in ductus arteriosus causes contraction and closure
increased flow into Left Atrium closes flap over Foramen ovale
Circulation after birth
Johnson & Everitt Fig 12.5
indicator of lung surfactant production
Actions of fetal adrenal glucocorticoids
lung surfactant; water resorptioncentral respiratory mechanisms
metabolism glucose storage and gluconeogenesis
endocrine induced insulin secretioninduced adrenaline secretionconversion of T3 to T4placental steroidogenesis
blood switch from fetal to adult haemoglobinswitch haematopoiesis to bone marrow
salt balance stimulation of GFR and Na+ resorption?activation of ANF
lactogenesis ductal-lobule-alveolar growth in pregnancy
Summary – Placenta structure and function
• nutrition, gas exchange, hormones, immune control• folding and budding yolk sac (choriovitelline)
allantois (chorioallantoic)• morphology: discoid, zonary, cotyledonary, diffuse• Grosser’s classification by degree of invasion:
epitheliochorial haemochorial• sophisticated countercurrent blood flow mechanisms• hormones – gonadotrophins, lactogens,
progesterone, oestrogens• fetal gas exchange – fetal haemoglobin• shift of circulation at birth from placental to lung gas
exchange• role of glucocorticoids in fetal ot neonatal transition