Difference between revisions of "Placenta - Anatomy & Physiology"
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===Microscopic Physiology=== | ===Microscopic Physiology=== | ||
− | As well as physiologic differences in the macroscopic appearance of the placenta between species, the microscopic structure of the interaction between fetal and maternal tissues also differs between species. | + | As well as physiologic differences in the macroscopic appearance of the placenta between species, the microscopic structure of the interaction between fetal and maternal tissues also differs between species. The interface between the chorion and uterus can consist of different numbers and arrangements of epithelial cells and basal laminae on both the fetal and maternal sides. Beneath the layers of basal laminae there are further layers of connective tissue that contain high densities of blood capillaries. |
== Exchange == | == Exchange == |
Revision as of 20:10, 11 July 2011
Introduction
The formation of the placenta is referred to as the "second" or "embryonic" period of pregnancy (after the implantation period) and describes the establishment of a fully functional placenta. The placenta is an apposition of foetal and parental tissue for the purposes of physiological exchange. There is little mixing of maternal and foetal blood, and for most purposes the two can be considered as separate.
Formation
The placenta consists of a foetal portion formed by the chorion and a maternal portion formed by the decidua basalis. The uteroplacental circulatory system begins to develop from approximately day 9 via the formation of vascular spaces called "trophoblastic lacunae".
Maternal sinusoids develop from capillaries of the maternal side which anastamose with these trophoblastic lacunae. The differential pressure between the arterial and venous channels that communicate with the lacunae establishes directional flow from the arteries into the veins resulting in a uteroplacental circulation.
Types of Placenta
Macroscopic Physiology
The physical contact surfaces used within the process of circulatory exchange are the fetal membranes and the endometrium and this exchange takes place via microscopic chorionic villi that invade the endometrium. These chorionic villi are covered by epithelium the extent and number of these contact areas forms the basis for the classification of different types of placenta.
For example, horses and pigs have many small contacts spread over the entire surface of the fetal membranes and this form of placenta is termed a diffuse placenta. Ruminants have 15-120 button-like contact regions between the fetal membranes and the endometrium and this type of placenta is called a cotyledonary placenta. Predatory species have chorionic villi arranged in a circular band around the fetus, called the "zona placenta".
Microscopic Physiology
As well as physiologic differences in the macroscopic appearance of the placenta between species, the microscopic structure of the interaction between fetal and maternal tissues also differs between species. The interface between the chorion and uterus can consist of different numbers and arrangements of epithelial cells and basal laminae on both the fetal and maternal sides. Beneath the layers of basal laminae there are further layers of connective tissue that contain high densities of blood capillaries.
Exchange
Histotrophic
- Nutrition supplied by uterine secretions/debris - 'Uterine milk'
- Often maintained by progesterone
- Nourishment of the embryo before implantation when there is no established placenta.
- Maintained for long period of time in ungulates, since implantation is late
- Horse: day 35
- Ruminants: day 15-20
- Pig and horse: pinocytosis persists via areolae
- Sheep,cow,dog and cat: pinocytosis persists via haemophagous zones that break down and release iron to the placenta.
Haemotrophic
- Direct transfer of nutrients from the maternal to foetal blood via the placenta. By Simple Diffusion, Facillitated Diffusion, Active Transport and Complex Diffusion
Placental Blood Supply and Drainage
Umbillical Arteries
- Arise from Iliac arteries along with vesicular arteries to the bladder.
- Form the ventral ligament of the bladder in the adult.
- Carry deoxygenated blood from the bladder.
Umbillical Veins
- Join the hepatic portal vein
Shunts
Vascular Dynamics
Protection
Physical
Teratogens
Immunological
Endocrine
This article is still under construction. |