Lecture 5: Limb Development PDF

Summary

This lecture details the development of limbs, integumentary systems, and body cavities. The lecture covers the early stages, positional information, and final stages of limb development, including the role of the Apical Ectodermal Ridge (AER) and the Progress Zones. The stages of limb development are explained through diagrams.

Full Transcript

Development of Limbs, Integumentary System & Body Cavities
Lecture 5

Vrushank Davé, MS/Ph.D.
Director, Biotechnology Graduate Program
Associate Professor Dept. of Pathology & Cell Biology
Dept. of Molecular Medicine & Oncologic Sciences
USF Morsani College of Medicine
Office: 813-974-0930
E-mail: [email protected]
Part I: Limb Development

Learning Objectives:

1. Mechanism driving early establishment of Limb Development

2. Understand the final stages of Limb Development

3. How are Cutaneous Innervation of Limbs established?

4. Study the Blood Supply of Limbs

5. Comprehend the Major Birth Defects of Limbs

6. Summary of Limb Development
Four Cellular Processes that promote Limb Formation
fore limbs comeout calier
than the hind limbs bu
there's abundant well division

limbs get sculpted and
&
separate we
fingag
-

b do
apoptosis
-

wntled
need
Hig

cignaling PAX3 serise
pathways 6 asser
creimportant
for proper of
migration
limb
bed
He
Early Stages of Limb Development limb buds appear from the
which i
&

body wall conate a Day 28 4 pharyngeal
wonesformed
S

log
§ By Day 24 (upper limb) & Day 26 (lower limb) buds appears from the day 28

& somatic lateral mesoderm (body wall or parietal wall)
forms

§ Buds have a mesenchyme core + outer epithelial ectoderm

§ Muscle cells migrate into the bud from the somites.
this is internal once made migrates its called a
progress the

§ A(progress zone (PZ) under the tip of the bud has proliferating
C proliferate
mesenchyme, which elongates the limb buds.
He fastest and cases the limbs to more toward

§ The epithelial Apical Ectodermal Ridge (AER) lies above the PZ &
initiates limb bud formation. is form as the mesoderm quotes who the skin

§ Upper limb buds appear low as the cranial half grows faster.

§ Upper limb buds form opposite to the caudal cervical segments.

§ Lower limb buds form opposite to the lumbar/upper sacral segments.
they're very how of the comitestvatebrae
Limb patterning: Regulation by Positional Information:
bore madels
vede
and blood
Two developmental fields are formed in the early limb bud:

§ ANTERIOR: Apical Ectodermal Ridge (AER) at the limb bud tip
He internal reahas
§ POSTERIOR: TWO PZs (Progress Zones)à Proximal PZ & Distal PZ by
aggregation/condensation of mesenchymal cells
&
§ AER at the distal tip, induces proliferation of the underlying undifferentiated
mesenchyme, elongating the limb bud.
§ Later, 2 Progress Zones; PZs begin differentiation and condense into the
cartilage precursors, initiating limb bone formation

§ Proximal PZ differentiate into [blood vessels + cartilage bone models]
Sand
-
plates
foot plates
§ Distal PZ (tip) of the limb buds flatten into Hand plates + Foot plates
He AER rignal He underlying
vnto
mewdam to differentiate a
urtain fate.

then they signal to the
difeet
proximal merodam to has a

fatt
Early Embryonic Limb development
Day 32–56:
Note: Upper limbs develop earlier than the lower limbs.
it has
1. Day 44: Mesenchyme in the hand plates condense internally
models formed
bore
cells are
to form digital rays, forming fingers b
and the
undergoing apoptosis

2. Day 48: Footplates develop in the same way.

3. At the tip of each digital ray, the AER induces the
mesenchyme to become bone primordia
(phalanges).
4. Mesenchyme between the digital rays apoptose,
forming fingers & toes by end of week 8. these why we
undergoing apoptosis

y hands , elbow
now apoptosis and arch of
multirent enough S
I by
is
y separate Tay↑.
there now
 - about of proliferation
Final Stages of Limb Development in
in the
so
internal Pt is
much that itverve
arusion He distal ot
mesedge
look
takes meserchipe
over He

condensing
Mesenchymal cellular condensation forms bone models:
bore primordia
End of 5th Wk (D35): Chondrification centers appear. We formed

End of 6th Wk (Day 42): The limb skeleton is cartilaginous

End of 7th Wk: Osteogenesis of long bones begins in the primary
ossification centers.
catilage remains
until day She
End of 12th Wk: Ossification centers are present in all long bones
by week
12 treel
be enough
orviscation
 52 days:
Elbows, Knees & Digit Formation
end of 8 weeks
52 days:
digits separated
-- Fingers separate due to web-apoptosis for forelimbs
but not hindlimbs
-- Feet are fan shaped & toes are fused

56 days:

56 days:
-- Elbows , Knees & separated hand & feet digits
visible.
-- Embryo becomes a fetus, and the limb
&
M
position changes day 56 tree demoration
separated
now -

see where
-
of elbow
can
you
knees und
one
where the elbows are
Upper & Lower Limb Rotation is Complete by Day 56 (end of 8th-week)

§ Upper limbs rotate laterally by 90 degrees:
Elbows come to point Dorsally & Caudally

§ Lower limbs rotate medially by 90 degrees;
Knees come to point Ventrally & Cranially knees point
cranialy elbaus point
caudally

I
S
Dermatome Patterns & Cutaneous Innervation of Limbs

5th Week me
&
See
1. Motor & Sensory Spinal axons grow in the dorsal &
ventral muscles of the limb buds. - &

mites S
2. Neural crest cells give rise to Schwann cells, &
myelin sheath surround motor/sensory nerve fibers, makes cone of
14
toot and
forming Neurolemma (Sheath of Schwann). we
calf

t
gas He
stal
I u
3. Every dermatome originates from a single somite &
has area of skin innervated by a single spinal nerve & & ↳ 9
C T

its spinal ganglion. Cloves between each verlebel ↑ L5 hims He
S

/
for each spiral ganglia you -and
Lord pat
have a spiral neve
calf
aes of the
4. Dorsal dermatome…. (preaxial border)
§ Medial rotation of the lower limb: Original ventral surface of the lower
5. Ventral dermatome…. (postaxial border) limb goes to the back of the adult limb.
§ L5 and L2: Rotated to the posterior aspect
§ S1, S2, S3: Rotates to the center at the ventral axis
Developing Blood Supply to Upper Limbs:
Dorsal Aorta à Intersegmental A.

Primary axial A.
Anterior interosseous
Brachial A. à Common interosseous
Posterior interosseous
Ulnar A. Radial A.

Superficial Palmar Deep Palmar
Arch (SPA) Arch (DPA)

a lot ofoiling
degenerate be there's
a lot of
'remodeling
"regenerals
& S

bu Hey remodel
Developing Blood Supply to Lower Limbs:

Dorsal Aorta à Common Iliac A. àBifurcates into:
(1) Primary axial artery à profunda femoris (Deep artery of the thigh)
(2) Ext. Iliac à Femoral artery

Popliteal artery

Posterior Tibial A. Anterior Tibial A.

im-§ Fibular (peroneal) A. [center]
th

§ Lateral Planter A.
Foot & toe
§ Medial Planter A. Capillaries
Birth Defects of Limbs
Week 4-
&
§ D24 -36: Limb defects occur during the most critical period of limb
development. Common: 1:500 neonates.
datented
&

§ Thalidomide (teratogen) is most potent at 3-5 week stage & causes.
Sirenomelia
§ Amelia: Absence of limbs à Quadruple Amelia: all 4 limbs missing!! (A) (C)

§ Meromelia: Partial limb formation (B)

§ Sirenomelia (Mermaid Syndrome): Caudal dysgenesis: lower limbs
fused; appears like a mermaid's tail : Exact cause unknown; sporadic! (C)

J Clin Neonatol. 2012 Jul;1(3):146-8.
NORD: https://rarediseases.org/rare-diseases/sirenomelia/
Split-hand/foot malformations (SHFMs)
into e modern
happens when AER doesn't
signal properly
§ Bifurcated (forked) hand
Fingers missing
§ Cleft foot
§ Absence of one or more central digits
§ Fingers missing (D)
§ Toes missing (E)

Cause: Failure of development of one or more digital rays
Toes missing
Brachydactyly & Polydactyly
Brachydactyly: Shortness of the digits (fingers or toes)
due to reduction in the length of the phalanges slubby and
S

short ,

-- Dominant inherited trait urved

-- Shortness of body or overall short stature

Polydactyly: Shows more than five digits on the hands or feet.
-- Extra digits are called “supernumerary digits”.
-- Dominant inherited trait.

Katarina Lehmann et al. PNAS 2003;100:12277-12282
Syndactyly both can be fixed with surgery
Syndactyly (2 Types): top but are used at the bottom
might
be open on.

1. Cutaneous syndactyly: Simple webbing between digits is frequently
found in the foot than in the hand.
§ Cause: Failure of the webs to degenerate between two or more digits due
to blockade of cell apoptosis; thus, the digits do not separate. (two arrows
on webbing)

2. Osseous syndactyly: Fusion of bones (synostosis): painful
§ Notches between the digital rays fail to develop & digits do not separate
§ Seen frequently between the:
bore models trse
§ 3rd & 4th fingers (fore-limb)
§ 2nd and 3rd toes (hind-limbs)
 in growing of the fook
S
Congenital Clubfoot
Talipes equinovarus (Latin talus (ankle) + pes (foot)) or clubfoot is a common birth defect
with musculoskeletal deformation (1:1000 births). Cause: Multifactorial inheritance

Characteristics:
-- Abnormal position of the foot does not
allow normal weight bearing.
-- The sole of the foot is turned medially,
-- The foot is inverted (incurving)
-- Seen bilaterally in 50% of cases
-- Occurs twice as frequently in males

TREATMENT: Casting or taping & physiotherapy Neonate with bilateral talipes equinovarus (clubfeet)
will near achive normal structure Observe the hyperextension and incurving of the feet
Summary of Limb Development

§ Limb buds appear 24-28th day of gestation as slight bulges on the ventrolateral body wall.

§ Upper limb buds develop 2 days ahead of lower limb buds from mesoderm + ectoderm.

§ The limb buds elongate by proliferation of the mesenchyme.

§ Cell apoptosis degenerates tissues in the notches between the digital rays.

§ Limb muscles are derived from mesenchyme (myogenic precursor cells; myoblast) originating in the somites.
Myoblast convert to myotubes to form mature muscles.

§ Myoblasts migrate and form dorsal and ventral muscle masses. Nerves grow into these muscle masses.

§ Blood vessels in the limb buds arise from the intersegmental arteries.

§ Most birth defects of the limbs have hereditary influence; many arise as a result of interaction of genetic &
environmental factors (multifactorial inheritance).
Development of the Integumentary System

surface etoderm

mesoderm

Integumentary System
Skin and its appendages
that protects the body

Cat is don't divds they just get bigger a
Objectives: Integumentary System

1. Understand the development of Skin and its Appendages
2. Epidermis: structure, function and formation & derivatives
3. Dermis: structure, function, formation & derivatives
4. Sweat Glands & Sebaceous Glands
5. Mammary Glands: Origin, structure and function
6. Hairs: Origin, formation & structure

7. Nails: Origin, formation & structure
Development of the Skin

Skin has two layers derived from two different germ layers:

§ Epidermis: Superficial epithelial tissue derived from surface ectoderm

§ Dermis: Deeper layer of connective tissue derived from mesoderm
Development of the Epidermis in Early Embryo
At 4 Weeks:
the
§
for
Surface ectoderm of the skin (primordium of the epidermis)
§ Made of simple cuboidal epithelium unelage
Y
At 7 Weeks:
Simple cuboidal epithelial cells start to proliferate and form TWO layers of made
squamous epithelium: periderm and basal layer
we made out of ectodom two layus 3out of
eutodem

First layer: The Periderm:
§ Undergoes Keratinization à Desquamation (shedding) à à Later, by week 20
complete Exfoliation of peridermal cells forming vernix caseosa

Second layer: The Basal layer:
§ Replaces the periderm and forms the “future stratum germinativum”
gemination our ner
Successive stages of skin development.

At 11 Weeks:

§ Intermediate layer: several cell layers thick between the basal
squamous epithelinn
layer & the periderm.
equamous
§ Intermediate layer cells invade the dermis (mesoderm) to

↳ form epidermal ridges, which form future fingerprints
grown fast inside the modern
estodem and
is invading into the
NOTE: Moderm is
ectoderm unrading into mederm
·

Chromosomal defects (Down Syndrome):
§ Abnormal and unique epidermal ridge pattern is used for
diagnosis unique hand live and fingerprint pattern
Formation & differentiation of Melanoblasts into Melanocytes

§ Early fetal period:
melanoblasts one from neural rest wells
-

§ Melanoblasts move from the dermis mesoderm
to the epidermis (ectoderm)
§ Melanoblasts lodge into dermoepidermal
junction and differentiate into melanocytes
(pigment-producing cells) between day 40-50

§ Melanocytes (Neural Crest Cell derived) with Red heads
Black/brown heads
distinct melanin pigments invade the dermis.
 messderm and
come ene
from epider mis
J
§ Melanoblasts differentiate into dendritic
Melanocytes containing Pigmented Melanin
Granules” in Melanosomes, which are taken up
by keratinocytes, called Melanokerasomes
Greg
Glie woud the nucleus
T

S

go who the relatinocytes
§ Melanocytes reside in epidermis with their
dendrites

-
melanosomes
Nu
Development of the Multiple Layers of the Epidermis
21st Wk – Neonate: e
melano
sayatt don't
ustes go up

§ Periderm disappears
§ Multiple layers of the epidermis are formed by differing stages of
keratinization.

§ At birth all adult epidermis layers are present

Mesoderm
1. Stratum corneum (Horney top layer; dead corneocytes)
2. Stratum lucidum (Smooth layer; Eleidin a product of Keratohyalin)
& will continue
3. Stratum granulosum (Granular layer) has me making more
Abes allo love
as we
4. Stratum spinosum (Spinous polyhedral or prickle cell layer)
S(Two mesodermal layers of the dermis)top
(
9 M the well from the
5. Stratum basale (Stratum germinativum cell layer) I ,

wall
Formation of the Mature Definitive Epidermis
Continuous inductive interactions with the dermis gives rise to two distinct type of epidermis
depending on its thickness.

Thick skin: Covers the palms of the hands and soles of the feet.
-- Has sweat glands only
-- No hair follicles or hair
-- No arrector muscles of hairs
no silglaney -- No sebaceous glands. name (Sweaty palms!)

Thin skin: Covers most of the rest of the body & it contains:
-- Hair follicles & hair
-- Arrector muscles of the hairs
-- Sebaceous glands
-- Sweat glands
Origin & Development of the Dermis
11th week
§ Mesenchyme underlying the epidermis forms the Dermis
§ Two origins of the Dermis mesenchyme:
o most
§ Somatic layer of the Lateral mesoderm contributes
§ Dermatomes of the Somites forms Skin fibroblasts

11th week: Mesenchyme secrete connective tissue, forming: Birth
§ Collagen fibers
§ Elastin fibers Sous reticular cases

Dermis
At birth: the dermis is made up of 2-layers.
§ The papillary layer
§ The reticular layer
Formation & Function of the Dermal Papillae
only the epidermis on top
dernis grows fast and pusks between the danis and epidermis
interdigitation
-

stratum germinative is also growing to there's

§ Between the descending epidermal ridges, the
dermis (the papillary layer) interdigitates upward
and forms the dermal papillae. Epidermis

§ Sensory nerve endings invade into the dermal Ep
ide
papillae. rm
al
ri dg
e

§ Capillary loops of blood vessels also simultaneously
invade the dermis and provide nourishment. Dermis

the dermal papillae below the spidermal ridge
form the tingerprints
 Development of the Hair bulb
unvades central
portion lees
blood
does apoplois
·

unrade
↑

He and forele
mederm canty Keratinglyb
S

b laye
only are but
invades stay
6 weeks: Hair bud develops but the hair is
visible only later, by 20th week.

Epidermal cells proliferate inwards, forming
hair buds that invade the dermis

E
16 wks: The root of the hair bud becomes
cup-shaped, forming a hair bulb with a hair
the epidermis will invade into
shaft multiple layersafterofmission
the mesoderm.
the central portion will do
cavity When apoptosis happens, the
apoptosis and form a
als die but the.

16 wks: The hair bulb gets filled by Keratin stays
mesenchymal “hair papilla”.

6
He keratin
gets getter
and bors ahai

migrating melcounts
memounts will go
the more
you have
the int He hai
& how
daller the hair papilla and
S

a hair shaft
Hair & Sebaceous gland

16 Wks: Central epithelial cells in the hair
bulb grows Hair shafts
withn
&

20 Wks: Hair shaft invades upwards in the
sproduced
epidermal des
epidermis and “protrudes” out of the skin

20 Wks: Peripheral hair bulb cells form the
epidermal/dermal root sheath, forming
secondary epithelial layer / muscle layer).

Laterally: the cells of the epithelial root
derived from
sheath proliferate to form a sebaceous the dermisand
gland bud that produces oily Sebum. forms a muscle dermis
layer has
first hair fors by week to -

/ fat cells
Development of the Hair
& arrector pili muscle

Mesenchymal cells surrounding the
lower shaft differentiate into dermal root
sheath.

Arrector pili muscle differentiates from
the dermal root sheet mesenchyme
For goose bumps
For sebum secretion

Melanoblasts migrate into the hair bulb
& differentiate into melanocytes.
Development of the apoptosis so
ahollow
Sweat Glands itLong
stute
20th wk
lands
I
sweak intoG
Invade
machinge
S

the
16th wk

Sweat glands develop by ~20th wk.
16 Week: Solid growth of epidermal cells invades the dermis
20th Week: Epidermal Terminus coils & body of the gland is formed
Apoptosis of the central cells form the lumen of the gland àSweat duct
Peripheral epithelial cells of the sweat duct differentiate into 2 types:
1. Secretory cells (sweat) Myoepithelial cell
Coiled-coil region 7

2. Contractile myoepithelial cell vone from epidems
s freule from superficial
cutoderm.
Development of the Mammary Glands

Mammary glands are modified & highly specialized
types of sweat glands.

By 4th wk Mammary Crests (ridges) develop along
each side of the ventral surface of the embryo.

I -
Mammary Crests spans the axillary region (armpit)
to the inguinal region

The Crest regress in most locations & proliferate
around pectoral muscles

alpopti under e

top region
Development of the Mammary Glands
12th Week to birth: state germinatin
dow
goes
-T

§ Down-growth of epithelial tissue continues to proliferate into 16-24 solid
out-buddings which give rise to the lactiferous ducts (milk producing)

§ Surrounding mesenchyme forms:
§ Fibrous connective tissue
§ Fat or adipose tissue of the mammary gland all apoptore
I formy a cavity
ne
Or
vises is
§ Epithelial lactiferous ducts at first open into a small mammary pit.

§ After birth: Nipples rise from the mammary pits because of
proliferation/pushing of the surrounding connective tissue mesenchyme
3 Wbula &
strukes
tors
below the Areola, (melanocyte rich region) surrounds the nipples.
milk will be
produced here
 nail originates from eponychium
/
Development of the Nails
10th Wk: Toenails and fingernails develop as
thickened areas of the epidermis (nail fields) at the
tips of the digits.

Nail fields extend to the dorsal surface and is
surrounded by the lateral nail folds. in

Cells from the proximal nail fold grow over the nail
field and form keratinized nail plate, the
primordium of the nail, which grows toward the tip
of the finger. nai
where
is not
diebut attacked
By 32 weeks the fingernails formed all
cliectly
↓ the skin
He eaan
(keratinized)
By 36 weeks the toenail formed x
stay
Eponychium (corneal layer of epidermis; proximal cuticle)
thatnail plate
for
Hyponychium (skin under the free margin of the nail)
Mavacademy (Switzerland)
 Part-III
Development of the Body Cavities, Mesenteries, & Diaphragm

2

untembryOn
-

codon
 Five Adult Body Cavities

1

2

3

Five Adult Body Cavities:
1. Cranial cavity
2. Vertebral cavity Dorsal
cavity
3. Thoracic cavity
4. Abdominal cavity Ventral 4
5. Pelvic cavity cavity

5
Learning Objectives

1. Origin & Division of the Embryonic Body Cavities

2. Mesenteries derived from mesoderm surround the organs

3. Development of the Diaphragm & Septum Transversum

4. Pleuro-peritoneal Membranes

5. Dorsal Mesentery of Esophagus

6. Muscular Ingrowth from Lateral Body Walls

7. Positional Changes and Innervation of Diaphragm

8. Birth defects due to aberrant formation of the diaphragm
 Development of the intraembryonic cavity

§ Day 20: Vacuoles formed in the Lateral mesoderm lamme
te
hom in
S

§ Day 21: U- or Horse-shoe-shaped body cavity forms in untraembryonic
I

the lateral mesoderm in a flat trilaminar disc meerdem
lones
>
- from the splitting of He
§ FLAT EMBRYO splits àU-shaped cavity (Intraembryonic lateral
S

Coelom) surrounded by two layers: mederm

-
22 will amnion

A
-

develop
neefrom
cardiac -S
somatoplane Lateral
mesoderm
mesoderm zurands the
roof
S

amnios

floor
Two Layers of the Developing Body Cavities:
Two layers: -- Visceral layer – Covers organs
-- Parietal layer – Lines the body wall

& attached to lung
Serous membranes (inner/outer)
(Single mesothelial cell layer)
Pleura
Pericardium
Peritoneum
Perineum
*mesothelium is the
just lyer that projects
S

an organ
Serous membranes: Functions to preclude adhesions
among organs so that organs can grow & move freely to be
Frees netline
vineral
on the
the
positioned & sculpted. side and on
side
pactal
Continuity of Intraembryonic & Extra Embryonic Cavity at lateral edges
this cancel is inside
the
embryo but it
also goes outside exteembryonic
mesderm

S
intoHe

&
Chario1

&

red is
↳
extrevembryonic
meesderm
2.
diret communication
belved the 2 in early stages
S
Formation of the Pericardial Cavity

Crucial
to head
-

&

now brun T

cranial to
22
Intra- & Extraembryonic Coelom, Amniotic folds, Chorion & the Yolk Sac
intraembryonic welor communicates w the.

extraembryonic welom , which fors the choion.
Sagittal Sections
interm bryonic
trucking
-

D inside Sif He
cardiac coalom embryo
b

extraembryonic

t
-- all He
at this poul Ipoblas
alle have come down and He
form chorion
-
Formation of the Dorsal Mesentery & Ventral Mesentery
Inver wall of the amnion
S

is splaichnophare
§ Coelom is lined by the mesothelium (serous membrane)

4
derived from the:
§ Somatic mesoderm (inner lining of the parietal layer)
-

§ Splanchnic mesoderm (outer lining of the visceral layer)

·
§ Junction of the somatic (parietal) & splanchnic
(visceral) layers of the mesoderm forms:
sinlestres M
§ Dorsally à Dorsal Mesentery held by dosal
resentery
§ Ventrally à Ventral Mesentery
He doe mesenting is more muscular is
it for
than the ventral resentary bu muscular

the body wall
Formation of the Dorsal and Ventral Mesenteries
these louds are the
ling bud ,
hier bud
and panueatic land.
1. Descending amnion closes intra / extra-embryonic annutic

~
communication between two coeloms (arrows). callby

2. The arrows in Fig. F indicate the junction of the somatic
& splanchnic layers of mesoderm.
3. Somatic mesoderm forms the parietal-peritoneum lining
3
the abdominal wall. O
4. Splanchnic mesoderm forms the visceral-peritoneum
covering the organs.

Ex oelo
c
tra m
5. Disappearance of the ventral mesentery & formation of

-em
bry
the ventral body wall (F).

on
ic
6. Septum transversum moves dorsally and begins to split
S
the thoracic and abdominal cavities
now that the amnion has closed in like this GG His
L
communication between the intra and
disappears.

there's no
extraembryonic
welom. Now there's no open communication w.

the choice
Embryo in 3-D with Defined Canals & Cavities convection between pericordial
and
carity
peritoreal carily

gut tibe
goes between
a
the 2
cavities

E
coextra-
lomemb
r yon
ic

I
hasn't demacated t
peritoneum
is
 this has to lift
Pericardioperitoneal canals: up

I
,

Cranial folding brings the pericardial cavity to the
ventral side of the foregut.

The pericardioperitoneal canals: has to uftup
to connect
-- Arise from the dorsal wall of the pericardial cavity with
He

-- Pass on each side of the foregut peritored culty
that over lifted conal
-- Lie dorsal to septum transversum up is He pericord"operitoc

-- Caudally, open into the peritoneal cavity
Transvers section to understand the origin and position
of pericardioperitoneal canals & the septum transversum
padxial comiles parxial

6
somites.

Notochord dorsal auti

this is the
-&
J
J
that is
P at
lifted up.
Dorsal mesentery: Pathway for blood vessels, nerves
& lymphatics to reach the Gut Tube connected to
He
urdian carity
&

5 week Embryo *
vontal If it was the heart

mesentery
liver only attached it's called
dorsal resocardin

to the mesentery
&

ventral

I inteste attached to
mesoderm-

dosul mesently
Pathway for blood vessels

1. Celiac arterial trunk (foregut)
2. Superior mesenteric artery (midgut) liver is still part of the
it's still
Gregut and
S

3. Inferior mesenteric artery (hindgut) attached to the body
wall.
Embryonic Cavities in a 5-week Embryo
Midgut:
Umbilical cord is attached to the mid-gut.
Peritoneal cavities remain separated.

directcomunication
between He 2
lateralities Peritorial

now
there's only
dosel
No
messen kely
-

ventral resentery
Hindgut: Peritoneal cavity is continuous
 -

Formation of the Pleuropericardial folds & Pericardioperitoneal canals

At 4 Weeks:
Pleuropericardial folds are formed

Pericardio-peritoneal canals forms &
O O
/
reated when
He bodywall
the septum transversum incompletely starts to invade inside the
coming from crity bode wall stats to golaterally
divides the cavity into two: this region iswall.

and medially.
Ne body
body wal
Thoracic cavity
Abdominal (peritoneal) cavity starts going
that'll.
medially
Primordial Plural Cavity forms demarcate He
pleural carity.
Pleuropericardial folds separate the thoracic cavity:

At 5 Weeks when the plus pencardial
Hold
S
rise , they'll
S

demarcate the
Two distinct cavities are evident: pleural cavity
§ Pericardial cavity common
cardinal veins
§ Pleural cavities phrenic nerves &
>
-

Pleuropericardial folds carry the phrenic nerves ↓
& common cardinal veins
heart descends to that plunpericidal fold confuse
Heart moves inferiorly for the Pleuropericardial
neut isolated from placral curity
folds to fuse

The pleuropericardial folds then forms the
fibrous pericardium.

Embryology at a Glance, 2nd ed.
Separation/formation of the pleural & the pericardial cavities & mediastinum

§ LUNGS grow inferiorly & expands the pleural cavities.
§ HEART moves inferiorly be you want lutral peropariol a
§ Pleuropericardial folds fuse to form fibrous pericardium,
isolating the pericardial cavity
When the lungs go down they split the
wal
body
lung and de

5 weeks: Pericardio-peritoneal canals & the protected by
2 layers
pericardial cavity are continuous (arrows). visivel carity
wall)
S
t way
6 weeks: Lung grows & the pleural cavities
expand into the body wall & splits the somatic
mesoderm (arrows).
Inserte
pericardium
is fibrous be
it's coming from the
body was
7 weeks: Pleural cavities expand ventrally around
the heart. Pleuropericardial folds fuse medially,
ventral to esophagus.
7 weeks
8 weeks: Lungs/pleural cavities expand & split

S
mesoderm further:
(1) Inner fibrous pericardium protecting/isolating be heat
now by
the heart
Prod opencardium
--

is
te
(2) Outer thoracic wall protects the lungs/pleural of
es layers
cavity. alo protects He newt & has
8 weeks
-

body wall layer polection
S
,
&
pencardium
Fibrous visceral
and perfordium
à Primordial mediastinum (mesenchymal
mass), extends
from the sternum to the vertebral column.
and keeps all He strckes in place
 S-shaped
cardiac tube
Pleuroperitoneal Membranes (folds) &
peritoneal cavity: has
septum Kansversum in A
invaded all the way
fold has
plun pericordial a
the
a
andup
demarcated euns
A). Left side view of the primordial body
cavities after the removal of the lateral
body wall.

B) Transverse section through an embryo
as shown in figure A.
Peritoneal Cavity
B -
 Development of the Diaphragm
The diaphragm develops from 4 components (see Red #1-4):
1. Septum transversum
2. Dorsal mesentery of esophagus
3. Pleuroperitoneal folds
4. Muscular ingrowth from lateral body walls now that pleroperitorial
tured you nota
body
S
have
He
has demarcated
S

He
from

↓
5 weeks: Unfused pleuroperitoneal folds peritoneum
Morx

6 weeks: Migration of myoblasts fuse the pleuro-peritoneal folds
with septum transversum & esophageal mesentery
12-weeks: Muscular ingrowth from the body wall (4th component).

He last
thing that happen
in week 12 is
development ofthe muscles.
Diaphragm in a neonate:
Inferior view of the diaphragm of a neonate
indicates the embryologic origin of Ceptum
a
transvers
its components.

-- Septum transversum forms the
Central tendon of diaphragm
-- Muscular ingrowth thickens
-- Crura of the diaphragm: Two tendinous
fines

Cixes
all the
structures (left right & crus; leg like structure), wines
S

extends below the diaphragm to the vertebral column.
all the structures inside
&
Musculature and Innervation of the Diaphragm
phrenic neve
from
resund
Spinal nerves g
§ After the fusion of the 4 components of the diaphragm, Right phrenic nerve

the myoblasts from the pleuroperitineal folds and the
lateral body wall invade into the other parts forming the
diaphram & give rise to the muscles of the diaphragm.

§ During development the phrenic nerve descends from
spinal nerves (C3, C4, C5) & passes through the
pleuropericardial membranes/folds and innervates the
muscles of diaphragm
Congenital Diaphragmatic Hernia (CDH) or Posterolateral Defect of Diaphragm:

CDH occurs commonly through a posterolateral
defect in diaphragm (1: 2200 neonates).&
considered pretty common

Occurs mostly on left side.
Left lung hypoplasia is common hole in the diaphragm
Herniation of abdominal contents caud by asignificant
signaling
S
b in
56
Abroblast
growth factor
,

intestive will go
in here
and
up

↓.
Eventration of Diaphragm:
Because of defective musculature
development of the diaphragm the
abdominal viscera are displaced in the
thorax within a pouch of diaphragmatic
tissue. no muscular layer N
diaphragm is soft and
He infestives can push up.

Congenital Hiatal Hernia:
is
Herniation of part of the fetal stomach diaphragm
may occur through an excessively large weak
esophageal hiatus stomach pushes
put of the
towards.
the ecophages
up
 Summary of Development of Body Cavities, Mesenteries, & Diaphragm

1. The lateral mesoderm splits to form the intraembryonic coelom (Day 21)
2. Intraembryonic coelom circles cranially to form a U-shaped cavity in the cardiogenic mesoderm by day 28.
3. Cranially, the coelom forms the pericardial cavity and laterally, future pleural and peritoneal cavities.
4. Lateral parts of the intraembryonic coelom move medially towards the ventral aspect and merge to form
the peritoneal cavity.
5. The splanchnic layer of mesoderm encloses the primordial gut and suspends it from the dorsal body wall
by a double-layered dorsal mesentery (made of splanchnic & somatic layer)
6. Fusion of the caudal pleuroperitoneal folds during formation of the diaphragm separates the pleural
cavities from the peritoneal cavity.
7. The diaphragm develops from the (i) septum transversum, (ii) mesentery of the esophagus,
(iii) pleuroperitoneal folds & (iv) muscular outgrowth from the body wall.
8. The diaphragm divides the body cavity into thoracic and peritoneal cavities.
9. A birth defect (opening) in the pleuroperitoneal membrane on the left side causes CDH.