Twinning PDF

Summary

This document provides an overview of twinning, covering causes, classifications, and stages of development. It also touches upon the different types of twins, such as monozygotic and dizygotic, and the events involved during fertilization, cleavage to gastrulation.

Full Transcript

TWINNING OR EMBRYONIC DUPLICATION

Causes of multiple births

Fertilization of separately ovulated egg
Complete or partial separation
cleavage/blastocyst blastomeres
Duplication during gastrulation
 CLASSIFICATION

1. Free or unattached to each other
2. Cojoined to each other
3. Symmetrical or asymmetrical
Free or separate twins – are dizygotic twins (most
common) developing independently with their
own EEM.
Free,symmetrical twins- are monozygotic derived from a single
zygote which separates or duplicate at different stages
▪During late cleavage to blastocyst , bisection may lead to the
development of two identical embryos with their own EEM
▪When z. pellucida ruptures causing escape of some
blastomeres may develop into two embryos provided that
part of the embryonic disc is bisected also
▪An instance when the blastodisc splits immediately prior to
gastrulation, the embryos formed usually shares EEM
Free, asymmetrical twins – may originate from a
monozygotic or dizygotic embyros, one member is normal
and the other is rudimentary surviving by sharing the
blood supply of the normal one
▪Abnormal twin has its own amnion but has no
recognizable body form consisting of skin, muscle
teeth,etc; sometimes ,the craniofascial structures can be
identified also
▪Abnormal twin is termed amorphous globosus,
anidian,acardiac or holocardiac fetus
▪Acardiac twin is common in cow
▪Abnormal twin is different from mummified or lithopedion (
still birth)
Cojoined or fused symmetrical twins – are
monozygotic in origin and generally termed
diplopagus but popularly known as siamese
twin
▪Incomplete division of the embryo occur
▪sometime during the primitive streak stage and
are identified according to the site of attachment
such as:
▪Thoracopagus- fused at the thorax facing each
other
▪Abdomonopagus- joined at the abdomen with
often partially fused intestines
▪ Pygopagus- fused back to back at the pelvic or
sacral region
▪ Cephalopagus – joined at the head region.
Duplication at this region uses prefixes (di, tri,
tetra) to describe the anomalies such as:
▪Dicephalus – two heads
▪Diprosopus –two faces
▪Dicaudatus – two tails
▪Tetrabrachius- 2 pairs of thoracic limbs
▪Tetrascelus – 2 pairs of pelvic limbs
Cojoined, asymmetrical twins – are unequal in
size, consisting of one normal individual, the
autosite and an extra body part only, the
parasite such as extra limbs attach at the back
or at the schial region projecting caudally

▪Asymmetrical twinning usually happens
when the specific organ forming regions
are already established ( limb, heart,eye
etc. fields)
FERTILIZATION TO GASTRULATION

Human prenatal development can be divided into 3 stages: pre-
embryonic, embryonic, and fetal development. Fertilization usually occurs in the
ampulla of the fallopian tube. The fertilized egg, referred to as the conceptus at
this stage, immediately travels toward the uterus. During the journey, it undergoes
several mitotic cell divisions, producing daughter cells, called blastomeres. This
process is known as cleavage, because the cells divide without growing in
volume. After about 3 days, the conceptus arrives in the uterus: it now contains
about 16 cells and is called a morula. Cells of the morula are totipotent, they are
capable of differentiating into all cell types, both embryonic and extra-
embryonic. The morula continues to divide while floating freely in the uterus for
several more days. During this time, it consumes nutrients stored in the egg
cytoplasm, and “uterine milk” secreted by the endometrium. When there are
about 100 cells, the cells start to arrange themselves around a fluid-filled cavity,
forming a blastocyst.
The blastocyst consists of a pluripotent inner cell mass, called the embryoblast,
destined to be the embryo; and an outer shell, called the trophoblast, which
nourishes the embryo. The trophoblast later becomes the chorion - the fetal
portion of the placenta. The trophoblast secretes an enzyme that dissolves the
membrane (zona pellucida) surrounding the conceptus, enabling it to “hatch”,
ready to be implanted. At the end of the first week, the blastocyst becomes
attached to the endometrium. At the site of contact, superficial cells of the
trophoblast fuse together to form the syncytiotrophoblast, which grows into the
endometrium and derives nutrition from it. The endometrium responds by growing
over and eventually enveloping the blastocyst. The syncytiotrophoblast secretes
the hormone named “human chorionic gonadotropin”, HCG (luteinizing hormone
in animals), to instruct the corpus luteum to continue the production of
progesterone. Progesterone is the hormone that maintains pregnancy. Among its
many functions, progesterone stimulates the growth of nutrient-rich decidual cells
to feed the early embryo. Around the middle of week 2, the embryoblast starts to
form a two-layered embryonic disc - hypoblast and epiblast, at the mid-plane of
blastocyst, with a cavity on either side.
 This bilaminar disc sets the dorsal/ventral axis of the embryo, with the epiblast being
the dorsal side. By the end of second week, the 2 layers grow around the cavity
on their respective side and form the yolk sac (hypoblast) and amnion (epiblast),
respectively. The yolk sac provides nutrients absorbed from the trophoblast, as
well as gas exchange for the embryo during weeks 2 and 3, before the placenta
takes over these functions at week 4. It is also the first site of embryonic blood
cell production, before the liver. In week 3, the two-layered disc transforms into 3
germ layers, through the process of gastrulation, during which the cells lose their
pluripotency and become committed to a smaller number of cell types.
Gastrulation begins with the emergence of the primitive streak on epiblast
surface. This event sets the cranial/caudal, or head/tail axis, of the embryo. A so-
called primitive node at the cranial end of primitive streak produces
signaling factors that control the movements of cells. Epiblast cells migrate
toward and through the primitive streak into the embryo.

Amnion - a thin membrane forming a closed sac about the embryo or fetus of a reptile, bird, or
mammal and containing a watery fluid in which the embryo or fetus is immersed
 The first set of cells displaces the hypoblast and forms the endoderm. The second set
of cells fills in the space between the endoderm and epiblast, creating the
mesoderm. The remaining epiblast cells form the ectoderm. Each of the 3 germ
layers differentiates to become different organs and tissues. All organ systems
are present in their primitive form by the end of the embryonic period, but most
of them are not yet functional, or only partially functional. The yolk sac gives rise
to the allantois, a primitive urinary bladder and part of the umbilical cord. The
amnion grows to surround the embryo 4 by week 4. It is filled with amniotic fluid
which protects the embryo from trauma and temperature fluctuations. The fluid
also allows the fetus to move freely and prevents adhesion of body parts. The
yolk sac, amnion, allantois and chorion are the 4 embryonic membranes.

The embryos of reptiles, birds, and mammals produce 4 extraembryonic membranes -
amnion, yolk sac, chorion and allantois. In birds and most reptiles, the embryo with
its extraembryonic membranes develops within a shelled egg. The amnion protects the
embryo in a sac filled with amniotic fluid.