Anatomy OF VISUAL PATHWAY

SIVATEJA CHALLA
SSSIHMS
ANATOMY OF VISUAL PATHWAY

Refers to neuronal networks
that extend from the retina to
visual cortex
comprises of
1.organisation in retina
2.optic nerve
3.optic chiasma
4.optic tract
5.lateral geniculate body
6.optic radiations
7.visual cortex

OPTIC NERVE
• Comprises axons of ganglion cells
• 47-50 mm length
• Extends from optic disc to chiasma
• Contains the afferent fibres of light reflex
• Has 4 parts : 1)intraocular (1mm)
2)intraorbital (30mm)
3)intra canalicular (6-9mm)
4)intracranial (10mm)

• Optic nerve is an outgrowth of brain.
• Not covered by neurilemma so does
not regenerate when cut.
• Fibres of optic nerve are very thin(2-
10 um in diameter)& are million in
number.
• surrounded by meninges unlike
other peripheral nerves.

INTRA OCULAR PART
• Part passes through sclera and choroid
and appears as optic disc
• Short introcular course of optic nerve is
k/a optic nerve head and portion that
can be seen by ophthalmoscope is
called optic disc
• Divided in to 1.surface nerve fibre layer
2.prelaminar region
3.lamina cribrosa
4.retro laminar region

INTRA ORBITAL PART
• 25 mm in length
• Extends from globe to orbital apex
• Takes curved path,extra length allows
gentle movement of globe
RELATIONS
• Surrounded by all 3 layers of meninges &
subarachnoid space.
• Some fibres of superior & medial rectus are
adherent to its sheath & account for painful
occular movements in retrobulbar neuritis.
• The central retinal artery along with vein
crosses the subarachnoid space to enter the
nerve on its inferomedial aspect.

INTRA CANALICULAR PART
• 10MM LONG
• Begins where optic nerve leaves optic
foramen and ends at a point where optic
nerve enters optic canal
• Limited space for expansion
• Most traumatic optic neuropathies
frquently afected
RELATIONS
• ophthamic artery crosses frm medial to
lat side
• Sphenoid & posterior ethmoidal
sinuses lie medial to it & seperated by
thin bony lamina, coz retrobulbar neuritis
following infection of sinuses.

INTRA CRANIAL PART
• 10mm
• Extension
• Lies above cavernous sinus and Internal carotid artery runs
below then lateral to it.
• Aneurysms of ICA may coz compression on intracranial optic
nerve

ARRANGEMENT OF AXONS IN OPTIC NERVE

OPTIC CHIASMA
• Results from cross over of two
optic nerves
• Dorso ventrally flattened
• Lies over sella,so visual field
defects seen in patients with
supra sellar extension
• Surrounded by meninges and CSF
• Size-8mm length,15 mm width
and 4 mm thickness

• RELATIONS-
• Anterior - anterior cerebral
arteries & its communicating
arteries.
• Posterior- tuber cinereum,
infundibulum ,pitutary body
,posterior perforated
substance.
• Superior- third ventricle.
• Inferior- hypophysis
• Lateral- extra cavernous part
of internal carotid artery&
anterior perforated
substance.

• ORGANISATION OF OPTIC
CHIASMA-
• In general nasal fibres from
optic nerve cross in chiasma and
temporal fibres remains
uncrossed
• Fibres from ext macular inf
nasal retina cross and loop
anteriorly in C/L optic nerve
before they head in to optic tract
forming VON WILLEBRANDS
KNEE

ANATOMICAL VARIATION IN POSITION OF
NORMAL OPTIC CHIASMA
• a)central : lies directly over sella,
expanding pituitary tumor involves
chiasma first.
•
b)pre-fixed : lies more anteriorly
over tuberculum sellae,pituitary
tumor involves optic tract first.
•
c) post-fixed : lies more posterior
over dorsum sellae,pituitary tumor
damage optic nerve first.

OPTIC TRACTS
• Extends from optic chiasma to LGB
• 3.5 mm height and 5mm long
• Consists fibres from temporal half of
same eye and nasal half of other eye
• Run outwards & backwards from
posterolateral aspect of optic chiasma
,between tuber cinereum & anterior
perforated substance to unite with LGB

LATERAL GENICULATE BODY
• Thalamic relay nucleus,is
positioned b/l along lateral aspects
of mid brain
• Serves as a relay station which is
very accurate that there is exact
piont to point transmission of
impulse from the retina to visual
cortex.
• 2nd order neurons arising from
ganglion cells relay here
• Each consist of 6 layers of
neurons(grey matter) alternating
with white matter (optic fibres)

• The crossed fibres end in lamina 1, 4and 6while uncrossed fibres
end in the lamina 2,3and 5.
• The layers1and 2 of the LGB have large cells and are called
magnocelluar , whereas layred 3-6 have small cells and are called
parvocellular.
• Magnocellular layers receive their visual input from the large Y
ganglion cells of retina.It provides rapidly conducting pathway to
the visual cortex, i.e carry signals for detection of movement and
flicker.
• Parvocelluar layers receive their input almost entirely from the
X-ganglion cells and thus transmit colour vision and also convey
accurate point-to-point spatial information, for texture, shape
and fine depth vision

OPTIC RADIATIONS (GENICULO-CALCARINE
PATHWAY)
• From LGB to the occipital cortex.
• Pass forwards then laterally through the
area of wernicke as optic peduncles.
• Then fibres spread out fan wise to form
medullary optic lamina
• There occurs temporal rotation of fibres

• The inferior fibres of the optic
radiations, which subserve the
upper visual fields, first sweep
antero inferiorly in Meyers loop
around the anterior tip of the
temporal horn of the lateral
ventricle,and into the temporal
lobe.
• The superior fibres of the
radiations,which subserve the
inferior visual fields,proceed
directly posteriorly through the
parietal lobe to the visual cortex

VISUAL CORTEX
• It is located on the medial aspect of the occipital lobe in the
calcarine fissure.
• It is subdivided into the visuosensory area(striate area17) and
visuopsychic area(peristriate area 18 and parastriate area 19)
• Since visual cortex recieves much larger input from macular area
the macula vf may less affected in lesions of occipital cortex

Modified nomenclature:
• V1 in area 17
• V2 occupying the greater part of of
area18,but not the whole of it
• V3 occupying a narrow strip over the
anterior part of area18
• V4 with in area 19
• V5 at the posterior end of superior
temporal gyrus.

BLOOD SUPPLY OF VISUAL PATHWAY
Arterial
Circle of
Willis
Carotid
arterial
system
Vertebral
arterial
system

BLOOD SUPPLY OF OPTIC NERVE:
• A. Intraocular part
• Surface NFL-capillaries derived from retinal
arterioles
• Peripapillary choroidal vesselsPrelaminar
• ciliary vessels derived from short post
ciliary arteries
• arterial circle of zinn haller
Lamina
cribrosa
region
• Centrifugal branches from central
retinal artery
• Centripetal branches from pial vessels
Retrolaminar

B . Intraorbital part :
• Derived from 6 branches of internal carotid
artery:
• ophthalmic
• long & short posterior ciliary artery.
• Lacrimal artery.
• Central artery of retina.
Periaxial
system of
vessels
• Intraneural b/o central retinal artery.
• Central collateral b/o central retinal artery.
• Central artery of optic nerve.Axial system
of vessels

C .Intracanalicular part :
Periaxial system of vessels.
Since pial vessels supply intra orbital and intracanalicular parts of
ON during sx if pia gets removed,blood supply is lost to nerve

D . Intracranial part :
Pial system of vessels
B/o internal
carotid artery
B/o anterior
cerebral artery
B/o
ophthalmic
artery
Twigs from
anterior
communicating
artery

VENOUS DRAINAGE :
Optic nerve
head
• Central
retinal vein
Orbital part
• Peripheral
pial plexus
• Central
retinal vein
Intracranial
part
• Pial plexus
which ends
in anterior
cerebral &
basal vein

OPTIC CHIASMA
• Arterial supply
1.ant cerebral
2.Ant communicating
3.Sup hypophyseal
4.Post communicating
• Venous drianage
1.Sup chiasmal in to
ant cerebral vein
2.Inferior pre
infundibular in to
basal veins

BLOOD SUPPLY OF OPTIC TRACT:
• Arterial: Pial plexus
receiving contribution
from posterior
communicating artery,
anterior choroidal artery &
middle cerebral artery.
• Venous drainage: anterior
cerebral vein & basal vein.

BLOOD SUPPLY OF LATERAL GENICULATE BODY:
Posterior
cerebral artery
• Supply fibres coming from
superior homonymous quadrant
of retina.
Anterior
choroidal artery
• Supply fibres coming from
inferior homonymous quadrant
of retina.
Macular fibres
over region of
hilum
• Supplied by anastomosis from
posterior cerebral & anterior
choroidal artery.

BLOOD SUPPLY OF OPTIC RADIATIONS
• Anterior choroidal
artery
Anterior
part
• Deep optic artery
b/o middle cerebral
artery.
Middle
part
• Calcarine branches
from posterior
cerebral artery.
Posterior
part

BLOOD SUPPLY OF VISUAL CORTEX
Visual cortex
Calcarine artery b/o
Posterior cerebral
artery
Terminal b/o middle
cerebral artery &
anastomosis between
middle& posterior
cerebral artery.

1) LESIONS OF OPTIC NERVE :
Causes:
optic atrophy
 indirect optic neuropathy
acute optic neuritis
traumatic avulsion of optic nerve.
Characterised by: complete blindness in affected eye with loss of both
direct on ipsilateral & concensual light reflex on contralateral side. Near
reflex is preserved.
Eg. Right optic nerve involvement

2)Lesions through proximal part of optic chiasma :
 ipsilateral blindness.
 contralateral quadrantic hemianopia
 abolition of direct light reflex on affected side &
concensual light reflex on contralateral side.
 near reflex intact.
Eg. Rt optic nerve Involvement in Proximal part
d/t von willebrands knee-traquairs junctional scotoma

3)Central lesions of chiasma (sagittal)
causes:
 suprasellar aneurysm
 tumors of pituitary gland
 craniopharyngioma
 suprasellar meningioma & glioma of 3rd ventricle.
 third ventricular dilatation due to obstructive hydrocephalus.
 chronic chiasmal arachnoiditis.
 Characterised by:
 Bitemporal hemianopia
 Bitemporal hemianopic
paralysis of pupillary reflex. (usually lead to partial descending optic atrophy)
Bowtie atrophy or band atrophy

4)Lateral chiasmal lesions :
causes:
• Distension of 3rd ventricle causing pressure on each side of optic
chiasma
• Atheroma of carotids & posterior communicating artery.
Characterised by
• Binasal hemianopia
• Binasal hemianopic parallysis of pupillary reflex (usually lead to
partial descending optic atrophy)

5)Lesions of optic tract :
Causes:
Syphilitic meningitis/ gumma.
Tuberculosis
 Tumors of optic thalamus
Aneurysm of superior cerebellar or posterior cerebral
arteries.
Characterised by :
• Incongruous homonymous hemianopia with C/L hemianopic
pupillary reaction( wernicke’s reaction)

6)Lesions of lateral geniculate body :
 leads to homonymous hemianopia with sparing of pupillary
reflexes & may end in partial optic atrophy.

7)Lesions of optic radiations :
Causes:
Vascular occlusion
Primary & secondary tumors
Trauma
Characterised by :
TOTAL OPTIC RADIATION
INVOLVEMENT
COMPLETE
HOMONYMOUS
HEMIANOPIA( sometimes
sparing macula)

LESIONS OF PARIETAL
LOBE (involving superior
fibres of optic radiations)
INFERIOR
QUADRANTIC
HEMIANOPIA( PIE
ON THE FLOOR)
LESIONS OF
TEMPORAL LOBE
(involving inferior
fibres of optic
radiations)
SUPERIOR
QUADRANTIC
HEMIANOPIA( PIE
ON THE ROOF)

In lesions of optic radiations
• Pupillary reactions are normal as fibres of light reflex leave the
optic tracts to synapse in the superior colliculi.
• Lesions of optic radiations do not produce optic atrophy as the
2nd order neurons (optic nerve fibres) synapse in LGB.

8)Lesions of visual cortex :
• blood supply by MCA(ant 1/3rd) and PCA(post 2/3rd)
Congruous
homonymous
hemianopia(sparing
macula)
IF MCA IS
AFFECTED
Congruous
homonymous
macular defect
IF ONLY
PCA
AFFECTED

Anatomy OF VISUAL PATHWAY

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Anatomy OF VISUAL PATHWAY