How long can the embryo grow in vitro without a placenta?
13-14 days
What are the two main functions of the placenta?
- Implantation: so the pregnancy proceeds
2. Maintaining the pregnancy: (transport, endocrine, metabolism)
What is the role of the following extra-embryonic structures and from which cell mass are they all derived? A) yolk sac B) amnion C) allantois D) chorion
Derived from the trophoblast cells:
A) Provides nutrients until the placenta is ready to take over (degenerates after a few weeks)
B) membrane surrounding the amniotic fluid
C) waste disposal system, future umbilical cord
D) forms the placenta
When does the development of the placenta start?
Embryo reaches blastocyst stage and a maternal-fetal connection must be formed to support the pregnancy
What are the two distinct cellular layers arising from the trophectoderm that form the placenta and what does this inner cell mass cells form?
- Syncytiotrophoblast
- Cytotrophoblast
—> these two layers become the placenta
Inner cell mass cells become the bilaminar disc: Epiblast (future ectoderm) and hypoblast (future endoderm)
What are the major differences between the syncytiotrophoblast cells and the cytotrophoblast cells?
Include how one of the cell types nourishes the embryo prior to when links with maternal capillaries are made
Cytotrophoblast: layer of cells
Syncytiotrophoblast: derived from cytotrophoblasts, mesh of cell materials and one big nuclei: invades uterine epithelia and reaches uterine glands; the engulfed and degraded contents of uterine cells feed the embryo until links with maternal capillaries made
When should implantation be complete?
How should the embryo looks at this point? (3 things)
By end of the second week:
- Two cavities: An amniotic cavity and a yolk sac
- Suspended by a connecting stalk; precursor of the umbilical cord, formed by mesenchymal cells and connects the amnion cavity and extracoelomic cavity
- Be within the supporting sac/chorionic cavity
What happens to the three embryonic spaces as development progresses?
- Yolk sac disappears
- Amniotic sac enlargers (fluid filled)
- Chorionic sac is occupied by the expanding amniotic sac
Name three ways monozygotic twins can form
A blastocyst can separate in many ways to produce different numbers of chorion and amnions
- One zygote can split into two; resulting in two amnions, two chorion and separate implantation sites
- One morula can have two inner cell masses and bilaminar discs; so there are two amnions but one shared chorion
- One blastocyst has one bilaminar disc but TWO primitive streaks form, so there is a shared amnion and chorion between two fetuses
Why is implantation called ‘interstitial’?
Since the embryo goes from the ovaries, down Fallopian tubes to the uterine cavity and then through the uterine lining and into the interstitial space
Why is the human placenta haemomonochorial?
This means there’s only one layer of trophoblast cells that ultimately separates the maternal blood from the fetal capillary wall. This is important since as the placenta develops the membrane becomes progressively thinner as the needs of the fetus increase (easier diffusion between maternal-fetal blood)
What are the three major aims of implantation?
- Establishing a basic unit for exchange
- Anchoring the placenta
- Establishing maternal blood flow within the placenta
Explain what is occurring at each of these three stages:
- Primary villi
- Secondary villi
- Tertiary villi
- Early finger-like projections of the syncytiotrophoblast
- Invasion of mesenchyme into the core of the villus (between the epiblast and hypoblast is the mesoderm layer which eventually produces the mesenchyme)
- Fetal vessels invade the mesenchyme core (now there is a proper blood supply to the middle of the villus)
How would the endometrium appear histologically when it is preparing for implantation (3 things)? Which hormone is responsible for this?
Signalled by progesterone release from the ovary (i.e corpus luteum)
- Thicker
- Many glands (releasing nutrients for the fetus) and elaboration of spiral arterial blood supply
- “Pre-decidual” cells
What is decidualisation? What is the role of endometrial stromal cells and uterine NKC in this process?
The process of changing the endometrium to promote implantation of the embryo
- Endometrial stromal cells; secrete GFs and signalling molecules
- Uterine NKCs; Regulate the immune response against the embryo (since it has chromosomes from dad it will express foreign proteins)
What are two consequences of an incorrect balance between the invasive force of the trophoblast and the maternal structures?
- Ectopic pregnancy
2. Conditions characterized by excessive invasion
Why is the remodelling of the spiral arteries important and how does it happen?
Normal smooth muscle cells and endothelial cells that line blood vessels in the uterus are replaced by the trophoblast (they’re signalled to undergo apoptosis)
This broadens the vessels forming a low resistance vascular bed that maintains the high flow required to meet fetal demands (fast diffusion rates)
What is the most common implantation site in an ectopic pregnancy and why are they so dangerous generally?
In the Fallopian tubes, but can be anywhere (peritoneal, ovarian, etc)
If the embryo implants anywhere but through the uterine lining there will not be the correct spiral arteries and structures that form an appropriate placenta
Define placenta previa, why is it less dangerous than an ectopic pregnancy but still problematic?
Implantation at the bottom of the uterus; not an initial problem since the correct structures for implantation are still present but as the baby grows pressure in this area can cause
- Haemorrhaging
- Blockage of the route out, if the whole passageway is blocked a C section may be required
Name two ‘implantation defects’
- Placental insufficiency
2. Pre-eclampsia; no meeting between the invading trophoblast cells and the spiralling arteries (maternal vessels)
Describe the placenta in the first trimester. How does it change as the pregnancy progresses to e.g; 9 months?
1st trimester: placenta has been established but the “barrier” is still relatively thick and there is still a complete cytotrophoblast layer that can produce more syncytiotrophoblasts
As the pregnancy progresses the surface area increases, the placental barrier thins (ultimately to a single layer, for fast easy diffusion) and the cytotrophoblast layer is lost (very few remnants throughout the whole placenta)
What is the role of the umbilical cord? How many arteries and veins does it hold and how do they work? Do you need all of them?
Acts as the transport link between the developing fetus and placental blood vessels
The umbilical arteries and veins are longer than the umbilical cord and twist around it to add strength and protection against compression and tension.
- Two umbilical arteries: carrying deoxygenated blood from the fetus -> placenta *not impossible to survive with one. The contents are then carried to maternal lungs (gas exchange), kidneys (waste), etc to go back to the uterus and umbilical cord to the…
- One umbilical vein carrying oxygenated blood from the placenta -> fetus
Define cotyledons
Structures that transmit fetal blood and allow exchange of oxygen and nutrients with the maternal blood
Name three metabolic things the placenta creates
- Glycogen; stores maternal glucose for transfer to fetus later if necessary
- Cholesterol; precursor of progesterone and estrogen
- Fatty acids; synthesized from the breakdown of various fats in maternal circulation
-
Embryology44
-
4.1: Hormonal control of repro and menstruation49
-
4.2: Puberty and Menopause29
-
5.1: Coitus and Fertilisation37
-
5.2: Infertility and Contraception35
-
Clinical anatomy of female repro tract35
-
Clinical anatomy of male repro tract43
-
6.1: Placenta39
-
6.2: Physiological adaptations in pregnancy37
-
Parturition41
-
7.1: Fetal Growth and Development40
-
7.1: Fetal Physiology32
-
9.1: Breastfeeding and Human Lactation43
-
9.2: Breast Disease46
-
10.1: Infections of the Repro Tract57
-
10.2: PID27
-
11.1: Gynaecological Tumours57
-
11.2: Male genital tract tumours39
