Download The Placenta and Fetal Membranes

 The extravillous and villous traphoblasts
 Placental arm
 The fetal membranes (the amnion-chorion leave)
 Paracrine arm
 Human placenta : hemochorioendothelial type
Embryonic
Ectoderm
Amniotic Folds
Extraembryonic Ceolo
m
Yolk S
ack
Trophectoderm
Chorion
Mesoderm
Endoderm
 Yolk Sack
 In birds to nourish embryo
 In mammal atrophies but source of blood cells and
primordial germ cells
 Amnion
 Non-vascular, fluid filled
 Fluid produced by fetus
 Protective cushion
 Ruptures at birth (not breaking of water)
 Allantois
 Blood vessels
 Fuses with chorion
 Allantochorion or chorioallantois
 Brings blood vessels to chorion
 Chorion
 Outermost membrane
 Attachment to mother
 Zygote
 Blastomeres
 Morula
 Blastocyst
 Embryo
 Fetus
 Conceptus
 Moore, fig3-5
 58-cell blastocyst
 107-cell blastocyst
 Fig 5-1
 Implantation
 Moore, fig 3-4
 Biology of trophoblast
 Trophoblast is the most variable in structure, function
and development
 invasiveness provides for attatchment of blastocyst to
decidua of uterine cavity
 nutrition of the conceptus
 function as endocrine organ in human pregnancy
 essential to maternal physiological adaptations & maintenance of
pregnancy
 Differentiation
 Cellular, syncytial/ uninuclear , multinuclear
 Formation of the Syncytium
 Cytotrophoblasts are the cellular progenitors of the
syncytiotrophoblast
Cytotrophoblast
Syncytiotrophoblast
Morphologically
uninuclear cells
multinuclear giant cells
cell boders
well demarcated
lacking
single, distinct
multiple & diverse
present
absent
germinal cell
cytotrophoblast
nucleus
miotic figure
Origin
 after apposition & adherence, intrusion of
cytotrophoblast between endometrial epithelial
cells
 this process is facilitated by degradation of the
extracellula matrix of endometrium /decidua catalyzed
by
 urokinase-type plasminogen activator
 urokinase plasminogen activator receptor
 multiple metalloproteinase
 These functions of cytotrophoblasts invading
the endometrium are indistinguishable from
those of metastasizing malignant cells
 Previous Theories
 antigenic immaturity of the embryo-fetus
 diminished immunological responsiveness of the
pregnant woman
 Decidua : immunologically privileged tissue site
 The acceptance and the survival of conceptus in
the maternal uterus must be attributed to
immunological peculiarity of the trophoblasts,
not the decidua
 Expression of the HLA system in trophoblast unique set
of lymphocytes
 > may provide explanation for immunological acceptance of
the conceptus
 trophoblast HLA expression (monomorphic HLA-G class
I) uterine large granular lymphocyte (LGL)
 Many researchers focused on the expression of the major
histocompatibility complex (MHC) antigens in
trophoblast
 MHC class II antigens are absent from trophoblasts at all
stages of gestation
 Normal implantation is dependent upon
controlled trophoblast invasion of maternal
endometrium/decidua and the spiral arteries
 a mechanism for permitting and then for limitting
trophoblast invasion
 Such a system involves the uterine large granular
lymphocytes(LGSs) and the unique expression
of specific nomomeric HLA class I antigens in
the trophoblasts
 HLA genes
 the products of multiple genetic loci of the MHC within
short arm of chromosome 6
 17 class I genes have been identified
 three classical genes
 A, B, C => major class I(a) transplantation antigens
 three other class I(b) genes
 E, F, G => class I HLA antigen
 HLA-G gene
 Believed to be lymphoid and of bone marrow
origin and natural killer cell lineage.
 Present in large numbers only at the midluteal
phase of the cycle-at the expected time of
implantation in the human endometrium.
 Near the end of luteal phase of nonfertile
ovulatory cycles, the nuclei of LGLs begin to
disintegrate.
 With blastocyst implantation, these cells persist in
the decidua during the early weeks of pregnancy.
 speculated that LGLs are involved in the regulation
of trophoblast invasion.
 HLA-G antigen
 identified only in extravillous cytotrophoblast in decidua
basails and chorion laeve
 not present in villous trophoblast, either in syncytium or in
cytotrophoblasts.
 expressed in cytotrophoblast that are contiguous with
maternal tissue (decidual cell)
 It is hopothesized that HLA-G is immunologically
permissive of antigen mismatch between mother and
fetus.
 as gestation progresses, cells from inner cell mass of
blastocyst gradually develop both class I and II HLA
antigen
 these tissuee are not in direct contact with maternal
tissue or blood
 Apposition, adherence, then intrusion and invasion of the
endometrium/decidua by cytotrophoblast(implantation)
appears to be dependent upon
 trophoblast elaboration of specific proteinases
 degrade selected extracellular matrix proteins of the
endometrium/decidua
 coordinated and alternating process referred to as "integrin
switching“
 facilitates migration and then attachment of trophoblasts in the
decidua
 Integrin
 one of four families of cell adhesion molecules (CAMs)
 cell-surface receptors that mediate the adhesion of cells
to extracellular matrix proteins
 onfFN(oncofetal fibronectin)
 unique glycopeptide of the trophouteronectin molecule
 trophouteronectin or trophoblast glue
 formed by extravillous trophoblast, including those of
chorion laeve
 Function
 a critical role for migration and attachment of the trophoblasts to
maternal decidua
 facilitates separation of extraembryonic tissues from the
uterus at delivery
 Early Blastocyst
 Trophoblast
 hCG
 Grow & expand
 Capillary network
 arterioles
 Spiral arteries
Fetal
Maternal
Capillary
Capillary
Endothelium
Endothelium
Connective
Tissue
Chorionic
Epithelium
Connective
Tissue
Endometrial
Epithelium
Tissues
epithelialchorial
syndesmo- endothelialchorial
chorial
hemohemochorial endothelial
Maternal
endothelium +
conn. tissue +
epithelium
+
+
+
-
+
-
-
-
Fetal
epithelium
+
conn. tissue +
endothelium +
+
+
+
+
+
+
+
+
+
+
*ruminant
dog
cat
human
rat
rabbit
Species
pig
horse
ruminant
 Several curious features
 trophoblasts in the vessels lumen do not appear to
replicate
 these cells are not readily dislodged by flow of blood
 these cytotrophoblast appear to migrate against
arterial flow and pressure
 no obvious adhesion of these cells one to the other
 invasion of maternal vascular tissue bt trophoblasts
involves only the decidual spiral arteries, not the veins
 Trophoblast Ultrastructure
 Prominent microvilli of the syncytial surface (brush
border)
 pinocytotic vacuoles and vesicles
 absorptive and secretory placental function
 Chorionic Villi
 12th day
 Primary villi
 proliferation of cytotrophoblast extend into
syncytiotrophoblast
 Secondary villi
 mesenchymal cord, derived from cytotrophoblast, invade
solid trophoblast column
 Tertiary villi
 after angiogenesis occurs from the mesenchymal cores in
situ
 17th day에 fetal blood vessels are functional &
placental circulation이 establish됨.
 Characteristic of development of H-mole
 some villi, in which absence of angiogenesis results in
a lack of circulation, may distended with fluid and form
vesicles
 Placental Cotyledons
 Certain villi of the chorion frondosum extend from
chorionic plate to the decidua and serve as anchoring
villi
 Each of the main stem villi(truncal) and their
ramifications (rami) constitute a placental cotyledon
(lobe)
 For each cotyledon, a 1:1:1 ratio of artery to vein to
cotyledon
Increase placental surfac
e area
Microcotelydon
(Fetal)
Microcotelydon
Epithelium
Endometrial
Glands
Endometrium
Microcotelydon
(Maternal)
Uterine Art
eries
Uterine Veins
 Breaks in the Placental " Barrier“
 Numerous findings of passage of cells between
mother and fetus in both directions
 ex) erythroblastosis fetalis
 A few fetal blood cells are found in the mother's blood
 Fetal leukocytes may replicate in the mother and
leukocyte s bearing a Y chromosome have been
identified in women for up to 5 years after giving birth
to a son
 Placetal Size and Weight
 Total number of cotyledons remains the same
throughout gestation
 Individual cotyledones continue to grow
 Placental weights vary considerably
 Placental Aging
 As villi continue to branch and terminal ramifications
become more numerous and smaller
 > volume and prominence of cytotrophoblasts decrease
 As syncytium thins and forms knots
 > vessels become more prominent and lie closer to the
surface
 The stroma of the villi
 in early pregnancy
 branching connective ts. cells are seperated by abundant loose
intercellular matrix
 later
 stroma becomes denser, and the cells more spindly and more
closely packed
 Histologic changes that accompany placental growth
and aging are suggestive of increase in the efficiency
of transport to and exchange to meet increasing fetal
metabolic requirements




decrease in thickness of the syncytium
partial reduction of cytotropholastic cell
decrease in the stroma
increase in the number of capillaries and approximation of
these vessels to the syncytial surface
 By 4 months
 the apparent continuity of the cytotrophoblast is broken
 the syncytium forms knots on the more numerous, smaller
villi
 At term
 Covering of villi may be focally reduced to a thin layer of
syncytium with minimal connective tissue
 Fetal capillaries seem to abut the tropohoblast
 Villous stroma, Hofbauer cells, and cytotrophoblasts are
markedly reduced
 villi appear filled with thin-walled capillaries
 Other changes suggestive of a decrease in the
efficiency for placental exchange
 thickening of the basement membrane of trophoblast
capillaries
 obliteration of certain fetal vessels
 fibrin deposition on the surface of villi in basal and chorionic
plates as well as elsewhere in the intervillous space
 A section through the
placenta in situ
 amnion → chorion→
cho
rionic villi → intervillous
space → decidual
plate → myometrium
 2 umbilical arteries
 deoxygenated, or "venous-like" blood flows to the
placenta
 1 umbilical vein
 with a significantly higher oxygen content
 Hyrtl anastomosis
 Two umbilical a. separate at the chorionic plate to
supply branches to the cotyledons
 Intervillous space -> chorionic plate -> vein
 Spiral a., vein
 Ut. Contraction vein
 Intervillous space
 Ramsey's concept
 The principle factors regulating the flow of blood in
the intervillous space
 arterial blood pressure
 intrauterine pressure
 pattern of uterine contraction
 factors that act specifically upon the arteriolar walls
 Innermost fetal membrane and is contiguous with
amnionic fluid
 Avascular structure
 Provide almost all of the tensile strength of the fetal
membranes
 protect against rupture or tearing
 single layer of cuboidal epithelial cells
 basement membrane
 acellular compact layer
 fibroblast-like mesenchymal cells
 zona spongiosa
 Missing element of human amnion
 smooth muscle cell, nerves, lymphatics, blood vessels
 Amnion epithelial cells
 derived from fetal ectoderm (embryonic disc)
 active metabolically; synthesis of tissue inhibitos of
metalloproteinase-1
 Amnion mesenchymal cells
 derived from the embryonic mesoderm
 synthesis of interstitial collagens that make up the compact
layer of the amnion
 highly capable of synthesizing cytokines - IL-6, IL-8, MCP-1
 increased in response to bacterial toxin and IL-1
 Reflected amnion
 Placental amnion
 Umbilical amnion
 decidua and chorion laeve are quite elastic and can
expand to twice normal size during pregnancy
 Amnion provides the major strength of the membrane
 Tensile strength of amnion resides almost exclusively in
the compact layer
 composed of cross-linked interstial collagens I, III, and
lesser amounts of V and VI
 solute and water transport to maintain amnionic fluid
homeostasis
 produces a variety of bioactive compounds
 vasoactive peptides, growth factors, cytokines
 Amnionic Fluid
 normally clear fluid that collects within the amnionic cavity
increases in quantity as pregnancy advances until near
term, when it normally decreases
 Average volume of about 1,000 mL is found at term
 Development
 Umbilical cord, or funis
 fetal umbilicus -fetal surface of the placenta
 diameter: 0.8 - 2.0 cm
 average length: 55 cm (usual length: 30 - 100 cm)
 nodulation , false knot
 Extracellular matrix: Wharton's jelly
 In all cases, fetal and maternal blood does not mix.