2. Objectives
1. To understand the concept of origin and
developmental processes of human eye
2. To know the pathogenesis of congenital
anomalies of eye that may occur as a result of
defective embryogenesis
3. Presentation lay out
First session –
1. Development of primordial structures- general
embryology
2. Embryogenesis of anterior segment of eye
3. Congenital anomalies
Second session-
1. Embryogenesis of posterior segment of eye
2. Congenital anomalies
4. Introduction
The eyeball and its related structures are derived from
following primordia ;
1. Optic vesicle
2. lens placode
3. Mesoderm surrounding the optic vesicles
Derived from germ layers
Ectoderm
Mesoderm
Endoderm
5. Embryology and regularity factors
In embryology various endogenic regulatory factors controls
cellular differentiation, proliferation, cell migration and inductive
interaction for the specific organ development.
Three groups of regularity factors are identified
1.Growth factors
2.Homeobox genes/ master
genes
3.Neural crest
cells
fibroblast
growth
factors(FGF)
transforming
growth factors
Bs
insulin
like growth
factors (IGF-I)
control subordinate genes
in regulation of patterns
of anatomical
development(morphogen
esis) eg. PAX6-marks the
location of lens, HOX
( HOX8.1 –corneal
epethelium,HOX7.1-
ciliarybody)
Transient
population of
pluripotent cells,
originated from
neuroectoderm
which latter
transforms into
mesenchymal cell
6. General Embryology
1. To understand the formation of germ layers
2. To know about the origin and formation of
ocular primordia
7. General embryology
After fertilization of ovum it undergoes series of
cellular division/cleavage(1st
cell division-meiosos
followed by mitotic division)
Forms morula ( 16 cell) stage by 4th
day
Blastocyst (single cavity cell mass without zona
pellucida) by 5th
day
Implantation of blastocyst occurs by 6th
day after
fertilazation
10. Bilaminar embryonic disc-8th
day
Formation of double layer cell from
embryoblast( Inner cell mass)
With the formation of blastocyst , cells are
divided into inner cell mass call embryoblast
and out cell mass the tropoblast
By 8th
day inner cell mass (embryoblast) is
divided into two layer ; epiblast and
hypoblast- the Bilaminar disc
12. GASTRULATION-early 3rd
week
Process of formation of three germinal
layers
Begins with invagination of epiblastic cells
to form primitive streak by 16th
day
Primitive streak is a central narrow groove
on the surface of epiblast formed by the
invagination of epiblastic cells
Cells from epiblast starts migrating towards
the primitive streak
14. GASTRULATION-early 3rd
week...
Cells of primitive streak invaginates the
hypoblast and forms endoderm,
Cells between epiblast and endoderm forms
mesoderm
Cell remaining in epiblast becomes ectoderm
16. Trilaminar disc- germ layer and ocular derivatives
NSR,RPE, pigmented ciliary
epithelium,nonpigmented
ciliary epithelium,pigmented
iris epithelium,smooth muscle
of iris,optic
nerve,vitreous,corneal stroma
and
endothelium,sclera,trabecular
meshwork,ciliary
muscle,melanocytes,meningeal
sheath,ciliary
ganglion,connective tissue of
orbit,lens,lacrimal gland and
drainage system,conjunctival
epithelium,connective tissue of
orbit, muscle layer and
connective tissue sheaths of all
ocular and blood vessels,
cartilage, choroidal
stroma,schwann cells
Fibers of extraocular muscle,
endothelial lining of all orbit and
ocular blood vessels, temporal
portion of sclera, vitreous
17. Neuraltion and neural tube formation-22th day
Neural tube is an important primitive structure
from which ocular primordia-the optic vesicle, the
progenitor mesenchymal cell and neural tissue
develops
Begins by proliferation of the surface ectodermal
cells to forms neural crest cells
The crest cell moves medially to form neural
groove. Elevation of two side of neuroectoderm
forms neural fold and ultimately it fuses to become
neural tube
18. Neuraltion and neural tube
formation-22th day Neural
crest cell
Gartrula Neural grove
19. Neuraltion and neural tube formation-22th
day
1.Neural
plate
2.Neural
grove
3.Neural
tube Neural crest cell-
proginater cells for
mesenchymal cells
Surface
ectoderm
20. Formation of eye primordia-
3rd
week
Primitive eye starts in 3rd
week of gestation when
anterior portion of neural tube is folding
As the neural tube is folding 3 dilatation appears
at the anterior portion of neural tube-forebrain,
midbrain and hindbrain
Primitive eye originates as Optic pit on either
side of midline in venterolateral region of
primitive forebrain
22. Formation of optic and lens
vesicle Begins with the proliferation of
neuroectodermal cell of neural tube of
forebrain.
Neural tube of forebrain grows laterally and
forms 2 globular structure at either side called-
primary optic vesicle
With the formation of optic vesicle it induce
surface ectodermal cells to proliferate
Surface ectoderm in contact with Optic vesicle
becomes lens plate/placode.
23. Ocular primordia
Cross section of neural
tube
ectoderm
mesoderm
endoderm
Lateral outgrowth of
neuroectoderm forms optic
vesicle
Neural tube
Lens plate
24. By end of 3rd
week gestation
Three primordial structure are
formed:
1. Lens placode
2. Optic vesicle
3. Mesoderm surrounding
the optic vesicles
25. Concept of congenital anomalies
Developmental anomalies Occurs due to
disturbance in embryonic events by various factors
in 1st
-3rd
months of pregnancy, ocular structures are
most at risk in the period of organogenesis from 18
– 60 days
1. Intrinsic factors 2.extrinsic factors(teratogen)
Altered, defective or imperfective
genes
Impaired cellular
induction/proliferation
Defective cell migration
Inadequate differentiation & cell
death
Infection (Rubella, syphilis,
cytomegalovirus, herpes simplex
virus
radiation
Maternal diseases(eg.Diabetes)
Drugs/toxins-
alcohol,thalidomide,antiseizure,retino
ic acid ets
27. Formation of lens
Derived from surface
ectoderm
With the formation of optic
vesicle the surface ectoderm
in contact with optic vesicle
thicken and forms lens
plate/lens placode-27th
day
Eventually the lens plate
invaginates and separates
from surface ectoderm and
forms lens vesicle -33rd
day
28. Lens vesicle
Lens vesicle has anterior wall with cuboidal
epithelial cell and posterior columnar epithelial
cells
Synthesize type 1v collagen
& gylcosaminoglycans to
form lens capsule,
maintains homeostatic
fuction of cell and serves as
progenitors for 2ndary
lens
fibers
Forms primary lens fiber-
embryonic nucleus
29. Cells of posterior wall lengthens
and form elongated fiber that
projects into the lumen and
specific lens protein(crystalline)
are synthesized
Posterior cell contributes for
most of the growth of lens for
first 2 month- embryonic
nucleus.
Posterior
epithelial cell
Primary lens fiber-
embryonic nucleus
30. From 2nd
month the anterior progenitor
cells proliferates and produce 2ndary
lens
fibers also called fetal nucleus
In 3rd
month inner most fibere mature
with increase in cytoplasmic fibrillar
materials and the cell nuclei and
organelles decreases
Secondary fibers are displaced inward
between the capsule and embryonic
nucleus and meets on vertical planes to
form Y shape suture anteriorly and
inverted Y posteriorly
31. Lens
At birth it weighs 90 mg (adult-255mg) with
thickness of 3.5mm ( adult-5mm)
Lens fiber are formed throughout the human life
developing into different layers of lens fibers
32. Lens anomalies
!
1.Congenital aphakia-absence of lens at birth
primary aphakia Secondary aphakia(more common)
Occurs due to failure of
surface ectoderm to
proliferate
Occurs due to spontaneous
absorption of developing lens
Associated with Alports syndrome-
X-linked disease characterized by
defective genes for production of
type 1V collagen
33. Lens anomalies
Most are Idiopathic
Herediatery-AD(most common),AR,X linked
Genetic and metabolic disorders-Down
syndrome, marfans syndrome,galactosaemia
etc.
Maternal infection and toxicity- rubella,
CMV,varicella,radiation etc
4.Congenital cataract-etiology
3.Lens coloboma-
flattening/notching of lens due to
absence of zonular fibers, associated with
defect in iris, optic nerve/ retina as a result
of abnormal closure of embryonic fissure
34. Development of cornea
Development of cornea is
induced by lens and optic
vesicle formation
With the separation lens vesicle
the surface ectodermal cell
proliferates to form epithelium
of cornea
Basal lamina of epithelium cells
secrets collegen fibers and
gycosaminoglycans to form
primary stroma
Corneal
epithelium
Lens vesicle
Surface
ectoderm
35. Corneal embryogenesis-5th
week
By early 5th
week gestation there
are 3 waves of mesenchymal
cells migrating towards the
corneal epithelium.
1st
mesenchymal wave forms the
corneal endothelium.
Desment’s membrane is derived
from the basal lamina of
endothelium
36. Ctn…
3rd
mesenchymal wave
migrates between epithelium
and endothelium and forms
keratocytes
The keratocytes synthesis type
1 collagen fibers and
proteoglycans which are
organized as lamellae to form
stroma of cornea
37. Corneal derivatives
Diameter at birth –( 9.5-10.5)mm reaches adult
size 12 mm by 2 years
Derived from surface
ectoderm
Derived from
mesenchyme(neural
crest cell)
Derived from
mesenchyme(neural
crest cell)
38. Developmental anomalies-cornea
Due to fetal arrest of corneal growth in 5th
month or
related to the overgrowth of anterior tips of optic cup
which leaves less space for cornea to develop
Inherits as autosomal dominant/recessive trait
Due to failure of optic cup to grow leaving large space
for cornea to fill
Associated with abnormal collagen production-
Marfan syndrome
Inherits as X-linked recessive pattern
1.Microcornea:
Corneal diameter is less than 9mm in
newborn or less than 10mm in adult
2.Megalocornea
Corneal diameter more tha 12mm at birth or more
than 13mm after 2 years
39. Disorder of 2nd
wave mesenchymal migration
90% bilateral
Sporadic but both autosomal dominant and
recessive inheritance pattern are reported
Endothelial dystrophy-Primary dysfunction of 1st
mesenchymal wave/corneal endothelial cell
degeneration. Autosomal recessive>dominant.
Stromal dystrophy –dysfunction of corneal stroma
causing corneal opacity.
3.Sclerocornea-
Sclera like clouding of cornea with ill-defined limbus.
Difficult to differentiate cornea and sclera
4.Corneal Dystrophy
Diffuse,ill defined flaky/featheary/blue-gray ground
glass opacification of cornea. Cornea is clearer
peripherally
40. Corneal thinning and bulging due stromal and epithelium
thinning, fragmentation of Bowman’s layer and folds or break
in Descement’s membrane
Etiology unknown, usually multifactorial associated with Down
syndrome, mental retardation and atopic diseases
5.keratoconus-
Condition in which central cornea assume a conical shape
42. References
1.American Academy of Ophthalmology
(BCSC-section 2, 2012-2013)
2.Langmans medical embryology
3.Oxford Text Book of ophthalmology
(volume 11-section2.16.1-Embryology of eye
and orbit by Garry N.Shuttleworth)
4.Internet resources
44. Recap
General embryology
Development of embryoblast from inner cell mass of blastocyst which
differentiate into bilaminar disc (epiblast and hypoblast)
Formation of three germ layers and neuralation
Ocular origin and primordia
Derivatives of ocular structure (ectoderm and mesoderm)
Formation of optic vesicle, lens placode/plate
Embryogenesis of lens and cornea
Developmental anomalies of cornea and lens
45. Session 11-Outline
Origin and developmental processes of
anterior and posterior segment of eye
Developmental anomalies
46. Anterior chamber and angle formation
By beginning of 3rd
week there are three successive
in growth of mezenchymal cell surrounding the
optic cup
1st
wave of mezenchye forms corneal endothelium,
2nd
waves forms pupillary membrane and 3rd
wave
forms the keratocytes of cornea
Anterior chamber is first recognized as split like
space between developing corneal endothelium and
iris epithelium as a result of selective mezenchymal
cell atrophy/cleavage
47. Anterior chamber and angle formation
1st
Mesenchymal
wave form corneal
endothelium
2nd
wave forms
pupillary membrane
3rd
wave forms
keratocytes of
cornea
Primitive
anterior
chamber-slitlike
space
48. By 15th
week of gestation corneal
endothelial cells extend into the angle
recess and meets with iris epithelium
By 3rd
month angle recess deepens and
forms iridocorneal angle
In 7th
week – the angle of the anterior
chamber is occupied by the
mesenchymal cells of neural crest origin-
forms trabecular meshwork
Schlemm canal develops from small
plexus of venous canaliculi of
endodermal origin and forms
uveoscleral outflow/tract.
49. Trabecular meshwork
The anterior chamber angle continuous to recede until 6-12
month after birth when it become adult type appearance.
Anterior chamber depth is 2.3-2.7 mm at birth (adult-3mm)
In the final week gestation the
trabecular meshwork undergoes
fenestration and communicates with
anterior chamber
Congenital glaucoma may occur as a
result of defect in terminal
differentiation of trabecular tissue
leading to excessive formation of
meshwork collegen preventing
formation of iridocorneal angle
50. Ciliary body and iris- outline
By 3rd
week gestation there is
extension of 2 layers of
neuroectoderm from the edge of optic
cup
Its has outer pigmented
epithelium(PE) and inner non
pigmented epithelium(NPE)
Distal part of advancing
neuroectoderm becomes an iris
Proximal part of neuroectoderm
extension becomes the ciliary body
51. Ciliary body-ctn..
Cellular proliferation of proximal 2 layers of
neuroectoderm forms longitudinal indentation
of outer pigmented epithelium
By 12 weeks Inner non pigmented layer forms
radial fold(75) and become ciliary processes
At 10 week mezenchymal cells get condensed
at its anterior surface to form the stroma of
ciliary body
At 12 weeks there is Myofillament proliferation
of mezenchyme and forms smooth muscles of
ciliary body by 5th
month
Ciliary muscle continues to develop for at least
1year after birth.
52. Ciliary body
By 4th
month ciliary body is
functional and secrets
aqueous humour which fills
up anterior and posterior
chamber
Ciliary epithelium synthesis
collagen fibers which
becomes suspensory
ligament/zonules of lens
53. Development of iris-3rd
month
Developed from 2 layers;
1. Mesenchyme-anterior stroma
2.Neuroectoderm of optic cup–
- iris pigment epithelium
-sphinchte and dilater muscles
Iris begins to develop by condensation
of 2nd
wave mezenchymal to form
Pupillary membrane
54. Formation of pupillary membrane-early 3rd
month Pupillary membrane is formed by Condensation of 2nd
wave
mesenchymal cell forms pupilary membrane
Lens
vesicle
Optic cup
Condensation of
mesenchymal cells
cornea
Pupillarey membrane
55. Iris epithelium-end of 3rd
month
2 layers of neuroectoderm from
the edge of optic cup extend to
the posterior surface of pupillary
membrane.
Three structures(PE,NPE and
pupillary membrane) ultimately
fuses to become an iris
Pupillary
membrane
56. Iris- 3rd month
At 3rd
month Cells of anterior epithelium
layer differentiates into myofobrills and
forms sphincter and dilator muscles of an
iris
Pupillary Membrane(PM)-cells of PM
differentiates into fibroblast like cell and
secrets collegen fibrills & extracelluler
matrix which is incorporated with PE to
form the anterior stroma of an iris
pigmentation of posterior epithelial
cell occurs begins at the pupillary
margin at midterm , by 7th
month
iris is fully pigmented
57. Iris and pupil-8th
month gestation
Pupillary membrane begins
to degenerate at about 8th
months of gestation
Opening in the central part
of iris forms the pupil
Iris stroma and dilator
muscle is still immature at
birth-pupil appears miotic
at birth
58. Iris anomalies
Can be Associated with syndromic presentation like trisomy 13,
klinefelter,turner, CHARGE association(ocular coloboma,heart defects, choanal
atresia, mental retardation, genitourinary and ear anomalies)
1.Hypoplasia/absence of an iris
Inadequate inductive interactive between optic cup, surface
ectoderm and neural crest cell due to Defect in PAX6 genes
Occurs as sporadic or autosomal dominant
2.Persistant pupillary membrane
Most common congenital iris anomalies
Failure to atrophy pupillary membrane
3.Iris Coloboma
Failure of embryonic fissure to close in 5th
week gestation
Pupil appears like inverted tear drop usually at the
inferonasal quadrant
Can be associated wit coloboma of choroid, retina, ciliary
body and optic nerve
59. Iris anomalies…
7.Conginatal mydriasis
Mlafoamation of iris sphincter muscle
4.polycoria -Accessory iris opening
Associated with Axenfeld-Reiger Syndrome ( autosomal
dominant disorder) due to mutation of PAX and FOXC1
gene
Present with ,malformation of face, teeth, skeletal
system
5.Corectopia-Displacement of pupil
Associated with sector iris hypoplasia or colobomatous
lession or lens subluxation(ectopia lentis et pupillae)
6.microcoria-congenital miosis
Occurs due to malformation of dilator pupillae muscle
Can be associated with microcornea,lens subluxation,
iris atrophy and glaucoma
60. Posterior chamber
Develops as a slit in the mesenchyme
posterior to the developing iris and anterior
to the developing lens
Anterior and posterior communicates when
the pupillary membrane disappears and the
pupil is formed
Aqueous humor fills these two chamber
62. Retina-originates from ectoderm
Neurosensory retina-
originates from the inner layer
of neuroectodermal cell of
optic cup
Retinal pigment epithelium-
Originates from the outer
neuroectodermal cell of an
optic cup
63. Neurosensory layer-1st
month(3-4 rows of
cells) Anterior 1/5th
– forms the posterior
surface of developing ciliary and iris
Posterior 4/5th
forms the primordial
sensory retina
Mitotic cellular differentiation at
primordial retina forms two 2 distinct
layers by 7th
week
Outer 2/3rd
–primitive nuclear zone has
rows of nucleated cells which will
forms neural cells
Inner 1/3rd
- marginal zone has cells
devoid of nucleus which will form
nerve fiber layers)
64. Neurosensory(NSR) retina
NSR begins to develop from outer primitive
nuclear zone(PNZ)
Cellular proliferation of PNZ forms nuclear
and glial cells which are organized as 2
distinctive zones
1. Outer neuroblastic layer(forms
photoreceptors)
2. Inner neuroblastic layer(Ganglion cell
layers)
3. Two neuroblastic layer are seperated by
transient nerve fiber layer of Chievitz which
become inner plexiform layer by 9th
week
gestation
Primitive nerve fiber
65. NSR formation…ctn…
Differentiation of outer neuroblastic layers
occurs(ONL)by 5th
week and form
photoreceptors(rods and cones)
Cellular differentiation of ONL also forms bipolar,
amacrine, horizontal cells and form inner nucleated
layers of retina
Ganglion cell appears in inner neuroblastic layers and
form ganglion cell layer
Axons from ganglion cell develops at 6th
week and
form primitive nerve fiber layers
66. Retina-cells and synapses formation
Optic cup
Primitive nuclear zone
Inner marginal
zone forms nerve
fiber layers
Inner
neuroblastic
layer
Outer
neuroblastic
layer
Primitive neurosensory
retina
67. Cellular proliferation and melanogenesis of outer wall of
optic cup begins by 6th
week and forms retinal pigment
epithelium
By 15 week gestation all cells types , synapses and
intercellular junction of neurosensory retina are
formed
Fovea is formed by thinning of ganglion and inner
nucleated layer by 24 weeks
68. Retina by 5th
week Retinal pigment epithelium
developed from outer layer
of an optic cup
Outer segment-
photoreceptors
Outer nucleated layers
retina
Outer plexiform layers
Inner nucleated layers
Inner plexifor layers
Ganglion layer
Nerve fiber layer
Derived
from outer
neuroblastic
layer
Derived from
inner
neuroblastic
layer
69. Optic nerve
Develops from optic
stalk(connection between
optic vesicle and forebrain)
Initially optic stalk has two
layers
1. Inner neuroectodermal cells
layer
2. Outer undifferentiated
neural crest cells layer
70. Optic nerve formation
Late in 6th
week, cells of inner layer of optic
nerve degenerates and become vacuolated
Nerve fibers (axons) from the ganglion cells
migrates through the vacuolated space of
optic stalk
By 33 weeks it establishes an adult type optic
nerve of 1.1 million of axons
Few cells of inner layer differentiated into
glial cell which forms lamina cribosa by 8th
week.
Outer neural crest cells differentiates into (1)pia, (2)arachnoid
and (3)dura matter which form optic nerve sheath by 4th
month
72. Optic anomalies
1.Morning glory disc anomaly
Appears as funnel shaped excavation of the
posterior fundus that incorporates the disc.
Occurs due to abnormal closure of embryonic
fissure
2.Coloboma of optic nerve.
May occurs as a part of chorioretinal
coloboma or solitary abnormality
Due to failure of embryonic fissure to close
Can be associated with systemic
abnormalities-CHARGE association
3.
73. Formation of vitreous
Develops between lens and optic cup
Mostly derived from mesoderm with minimal
contribution from ectoderm
Formation of vitreous occurs in three stages ;
❶ Primary vitreous
❷Secondary vitreous
❸Tertiary vitreous
74. Primary vitreous-1st
month of gestation
Network of delicate cytoplasmic
process which occupy the space
between lens vesicle and inner
layer of optic cup
It is composed of fibrils
(ectoderm) and mesenchymal
cells(mesoderm) which
constitutes primary vitreous
Supplied by hyaloid vessels and
its branches
75. Secondary vitreous- 2nd
month of gestation
By 2nd
month the hyaloid system
regresses and primary vitreous cell
differentiates into hyalocytes which
synthesis type 11 collagen and
hyaluronic acid which constitutes
secondary vitreous
2nd
vitreous is avascular gel like
substances occupying the space
between primary vitreous and retina
By 5th
-6th
month primary vitreous and
Hyaloid vessels undergoes atrophy.
Atrophied hyaloid vessels become
hyaloid cannal which remain
throughout the life as Cloquet canal
Primary vitreous
76. Tertiary vitreous-3rd
month
It is Formation of zonular fiber between the ciliary
body and lens capsule
Collagen fibrils synthesized by
ciliary epithelium becomes more
condensed and extends to the
lens equator and become zonular
fiber of lens which constitutes
the tertiary vitreous
77. Persistent hyperplastic primary
vitreous(PHPV)
Presents as leukocoria-white pupillary reflex
Its occurs due to failure of
primary vitreous and hyaloid
vessels to regress
None hereditary and not
associated with systemic defects.
78. Choroid
Vascular endothelium and the haemopoietic cells of
choroid are derived from endoderm
Choroidal stroma ( vascular pericytes, smooth muscles,
melanocytes and collagenous components) of choroid
are derived from ectoderm.
Choroidal development is
associated with the
condensation of neural
crest cells around the optic
cup
79. Choroid..cntn
Differentiation of neural crest
cells form choroidal stroma by
the end of 3rd
month gestation
Endothelium line blood vessels appears in
the choroid stroma and forms
choriocapillary
By 4the week Choriocapillary begins to
differentiate and by 2nd
month it anastomosis
with short ciliary artery
By 8th
month final arterial circulation of
choroid is established after anastomosis with
vessels of ciliary body and iris
80. Sclera
Sclera is mostly ectodermal (neural crest) in origin,
however posterior region are mesoderm in origin
Sclera begins to develop by
condensation of mesenchymal cells
around the anterior rim of optic cup
Mesenchymal cells proliferates and
deposits glycosaminoglycans, collagen
and elastin fibrils and forms stroma of
sclera
By 5th
month sclera is relatively well
formed
81. Vascular system of eye- overview
Arterial wall has three layers;
1. Tunica adventitia(connective tissue)
2. Tunica media(smooth muscle layer)
3. Tunica intima( endothelium)
Tunica adventitia and tunica media of ocular vessels are
derived from neural crest cells(ectoderm)
Tunica intima is derived from endoderm
82. Primitive orbital vessels
During early embryonic life
untill 8th
month, the
developing ocular structure is
nourished by three transient
vessels originating from
internal carotid artery;
A.Ventral ophthalmic artery
B. Dorsal ophthalmic artery
F. Stapedial artery
Ventral artery later atrophy and only a portion remain as long
posterior nasal ciliary artery
Dorsal ophthalmic artery become definitive ophthalmic artery
Stapedial artery becomes Middle meningeal artery
Internal carotid artery
83. Primitive ocular vessels
Embryonic intraocular vasculature system has
two components;
1.Anterior system- supplies anterior segment
formed in iris and pupillary membrane
formed by the branches of ophthalmil artery- anterior
ciliary artery and posterior long ciliary artery
2.Posterior system- supplies posterior segment
formed within the vitreous
formed by hyaloid vascular system
84. Anterior artery system
Anterior artery system is formed by
posterior long,short ciliary artery and
anterior ciliary artery which are the
branches of dorsal opthalmic artery
Anastomosis of ciliary arteries forms
major arterial circle at the root of iris
Vascular twigs from major arterial cicle
and annular vessels forms the pupialiary
arcade
With the disappearance of pupillary
membrane pupilliary arcade remain
peripherally as minor artery circle which
supply iris
Posterior
ciliary artery
Anterior
ciliary artery
85. Posterior arterial system
Hyaloid artery nourishes the
developing eye globe until
the 8th
month of gestation
Hyaloid artery is the branch
of primitive dorsal
ophthalmic artery
Later the Hyaloid artery
regresses and become
central retinal artery
Atrophied
ventral artery
Dorsal artery
86. Hyaloid system….
As the optic vesicle develops there
is incomplete folds in its inferior
portion of cup and stalk called
embryonic fissure
Embryonic fissure allows hyaloid
system to be incorporated within
the eye.
In 3rd
week Hyaloid artery enters
the embryonic fissure of optic
stalk.
With the fusion of fissure the
hyaloid system are enclosed
within the eye
87. Clinical application
Failure to close embryonic fissure causes
colobomatous deformaties of an iris, choroid,
retina and optic nerve
88. Hyaloid system
Branches of the hyaloid artery supplies developing lens,
vitreous, optic nerve
Anastomosis of branches of hyaloid artery forms 3
arterial arcades calledTunica vasculosa Lentis
1.Anterior vascular capsule
2.Capsulopupialary portion
3.Posterior vascular capsule
Valsa hyaloida propria(small
capillary branches)
Hyaloid artery
89. Retinal circulation
By 4th
month the hyaloid artery bud of to from
central retinal artery
Hyaloid artery system atrophy and regresses in
3rd
trimester
Retinal artery vascularizes the retinal
Nasal retina completes vascularization prior to
temporal retina
By 8th
month all retinal part are vascularized
except for portion of peripherals temporal retina
which completes 3 months after birth
90. Retinal circulation
Atrophied hyaloid system
Retinal vessels buds from
hyaloid artery and
vascularizes retina
Vascularization reaches
nasal ora serrata by 8th
month and temporal ora
serrata by 2 month after
birth
91. Retinopathy of prematurity
Ischemia triggers abnormal vessel formation called
neovascularization-retinopathy of prematurity
Premature baby has incomplete
vascularization of retina
Hyperoxia(supplementary
oxygenation) causes
vasoconstriction
Vasoconstriction causes
ischemia in the incompletely
developed retinal periphery
93. Human eye at birth and after
birth Eye grows rapidly during first 2 years of life
until puberty
Most young children are hyperopic of 3.0 D
because of less axial length of eye( at birth
17mm, adult 24mm)
Corneal diameter is 9.5-10.5 at birth and 12
mm in adults
Radius of corneal curvature is 6.6-7.4 mm at
birth and 7.4-8.4 in adults
94. …………continue
Newborn has miotic pupil because dilator pipillae
muscle is not well form at birth
Visual development
Pupillary light reflux-present after 31 week of gestation
Blink reflex to light- several days after birth
6 weeks-maintain eye contact and react with facial
expression
2-3months –preferential to bright objects
95.
96. References
1. American Academy of Ophthalmology
(BCSC-section 2-fundamentas and principles
of ophthalmology
BCSC-section6-pediatric ophthalmology)
2.Langmans medical embryology
3.Oxford Text Book of ophthalmology
4.Internet resources