visual fields in neuro ophthalmology-part 1

VISUAL FIELDS IN NEURO
OPHTHALMOLOGY

VISUAL PATHWAY
Visual Pathway is the nervous pathway that transmits
impulses from retina to visual centre in cerebral cortex.
Components:
1. Optic Nerve
2. Optic Chiasma
3. Optic Tract
4. Lateral Geniculate Bodies
5. Optic Radiations
6. Visual cortex

VISUAL PATHWAYANATOMY
Visual sensations
rods and cones
visual cortex
1st order neurons –BIPOLAR CELLS
2nd order neurons –RETINAL
GANGLION CELLS TO LGN IN
THALAMUS
3rd order neurons- LGN TO VISUAL
CORTEX

•Extends from optic disc to optic chiasma.
• It is about 45 to 50mm in length.
•It is backward continuation of NFL of retina
consists of 1 million myelinated axons originating from
ganglion cells & contains
• Afferent fibres of pupillary light reflex.
•It is covered by meningeal sheath of the brain, does not
regenerate when cut.
PARTS OF OPTIC NERVE
1. Intraocular part - 1mm
2. Intraorbital part - 25mm
3. Intracanalicular part - 9mm
4. Intracranial part -10mm
OPTIC NERVE

INTRAOCULAR PART
•Starts from optic disc, pierces
the choroid and sclera
converting into sieve like
structure the lamina cribrosa &
•At back of eyeball it becomes
continuous as intraorbital part.
•4 layers

INTRAORBITAL PART
•Extends from the back of the eyeball to optic
foramina, covered dura, arachnoid & pia.
•Anteriorly - separated from the ocular muscles by
orbital fat.
•Posteriorly near optic foramina, closely surrounded
by annulus of zinn & origin of rectus muscle.
•Some fibres of SR muscle are adherent to its sheath
here & accounts for painful ocular movements in
retrobulbar neuritis.
RELATIONS:
•B/w optic nerve & LR –ciliary ganglion, nasociliary
nerve, branch of 3,6 CN, & sympathetic nerve.
•Central retinal artery with accompanying vein enter
the nerve on inferomedial aspect 10mm from
eyeball.

INTRACANALICULAR
PART
•Lies within the optic canal
•Inferolateral - ophthalmic
artery & crosses obliquely over
it as it enters the orbit to lie on
medial side
• Medial - posterior ethmoid
sinus & sphenoid sinus
separated by thin bony lamina.
•This accounts for retrobulbar
neuritis following infection of
sinuses.

INTRACRANIAL PART
RELATIONS
•Inferior- cavernous sinus, diaphragma sellae,
pituitary gland.
•Superiorly- anterior perforated substance,
medial root of olfactory tract & anterior
cerebral artery.
•Laterally – internal carotid artery.
•Ophthalmic artery originates from internal
carotid artery under the optic nerve.
•AA- carotid artery aneurysms compress nerve.

OPTIC CHIASMA
•It is flattened structure. Fibres
originating from the nasal halves
of the retina , divides at the
chiasma.
Relations:
•Anterior- anterior cerebral artery,
anterior communicating artery.
•Posteriorly- infundibulum,
hypothalamus, mamillary body &
pituitary.
•Superior- 3rd ventricle.
•Inferior- pituitary gland.
•Lateral – extracavernous internal
carotid artery.
A- sagittal section, B - superior view

OPTIC TRACT
•These are cylindrical bundle
of nerve fibres.
•Lies b/w tuber cinereum &
anterior perforated substance
& joins the cerebral peduncle.
•Each optic tract consists of
fibres from the temporal half
of the retina of the same eye
and the nasal half of the
opposite eye.
•Pupillary reflex fibres pass on
to superior colliculus through
superior brachium from here.

LATERAL GENICULATE BODY
•It is a mushroom-shaped structure in the
posterior thalamus .
•It receives approximately 70% of the optic
tract fibers within its 6 alternating layers of
grey and white matter (the other 30% of the
fibers go to the pupillary nucleus).
•Layers 1, 4, and 6 of the LGN contain axons
from the contralateral optic nerve.
•Layers 2, 3, and 5 arise from the ipsilateral
optic nerve.
• The 6 layers, numbered consecutively from
inferior to superior, give rise to the optic
radiations.
•2nd order neurons from optic tract relay here.

OPTIC RADIATIONS
•Fibres spread out fanwise to form
medullary optic lamina, first vertical later
becomes horizontal.
•Superior fibres which subserve inferior
visual fields proceed directly posteriorly
through parietal lobe to visual cortex.
•Inferior fibres which subserves superior
visual fields,1st sweep anteroinferiorly in
meyer loop around anterior tip of temporal
horn of lateral ventricle then into temporal
lobe.

VISUAL CORTEX
•Located on the medial aspect of
the occipital lobe, above and
below calcarine fissure.
•Visuosensory area V1
(Brodmann area 17) receives
fibres of optic radiations.
•Surrounding it is visuopsychic
area 18(peristriate) V2,V3 and
19(parastriate)V4,superior
temporal gyrus V5.

VISUAL PATHWAY
The macular fibres typically receive vascular supply at the occipital cortex from the
middle cerebral artery& posterior cerebral artery.

visual fields in neuro ophthalmology-part 1

Visual fields & Retina have INVERTED & REVERSED
relationship.
TERMINOLOGIES
• CONGRUOUS –Alike in both eyes, size, shape.
eg-Post optic radiation lesions
• INCONGROUS– Different in both eyes.
eg-Optic tract & LGB lesions
• HOMONYMOUS- Both eyes with same laterality.
• HETERONYMOUS- Both eyes with different
laterality.

ANOPIA
Loss of vision in one visual field
(Right anopia)

HEMIANOPIA
Loss of vision in one half of visual field.
Heteronymous hemianopia

QUADRANTANOPIA
Loss of vision in a quadrant of visual field.
HOMONYMOUS TYPE

ARRANGEMENT OF NERVE
FIBRES IN RETINA

FIELD DEFECTS IN RETINAL
LESIONS
– Central scotoma.
– Ring scotoma.
– Nonspecific focal
depression.
– Generalised constriction.

CENTRAL SCOTOMA
Involves fixation only
CAUSES
• Papillitis
• Leber’s hereditary optic
atrophy
• Drug toxicity – ethambutol, ethyl
alcohol, chloroquine
• Compressive lesions of optic
nerve

PARACENTRAL
SCOTOMA
– Involves a region next to
but not including fixation
CAUSES
• Myelinated nerve fibres
• Congenital optic nerve
head hypoplasia.

CENTROCECAL
SCOTOMA
– Extends from fixation to
blind spot
• Papilloedema –
centrocecal scotoma
with sloping edges

ENLARGED
BLIND SPOT
• Papilloedema
• Optic disc drusen
• Optic nerve pit

VISUAL PATHWAY – NFL
ARRANGEMENT

OPTIC NERVE FIBRE ARRANGEMENT
Arrangement of distal optic nerve fibre
just behind eyeball.
Arrangement of proximal nerve
fibre near chiasma.

FIELD DEFECTS IN LESIONS OF OPTIC
NERVE
Cause
•Traumatic avulsion of optic nerve
• Optic atrophy
•Head injury
•Optic neuritis.
Clinical features
Ipsilateral anopia
(loss of vision)
Loss of direct pupillary reaction
(same side)
loss of consensual pupillary reaction
(other side)
Near or accommodation reflex is
present

LESION OF PROXIMAL PART OF OPTIC NERVE OR
ANTERIOR CHIASMAL SYNDROME
•Involves ipsilateral optic nerve fibers and contralateral inferonasal fibres.
•Type- junctional scotoma (combination of central scotoma/complete
scotoma in one eye and temporal hemianopia in the other)
.

OPTIC CHIASMA- NFL
TEMPORAL FIBRES
• Uncrossed temporal fibres, run
backwards in lateral part.
NASAL PERIPHERAL FIBRES
• 3/4th of fibres cross over to enter
medial part of opposite tract in
following manner-
1.Lower nasal fibres in optic tract
traverse chiasma low & anteriorly.
2.Upper nasal fibres in optic tract
traverse chiasma high & posteriorly.

MACULAR FIBRES
• Some fibres crossed &
run backwards in
opposite optic tract.
• Some fibres uncrossed
and run on same side
in optic tract.

CENTER CHIASMA
•Produced by lesions involving the decussating fibres in the body of
chiasma.
• Bitemporal hemianopia.
•Bitemporal hemianopic paralysis of pupillary reflexes.
•Optic atrophy
CAUSES
Pituitary adenoma or
malignancy
Craniopharyngioma
Chronic chiasmal
arachnoiditis
Fracture of the base
of skull
Suprasellar
aneurysms &
meningioma.

LESION LATERAL TO OPTIC CHIASMA
• Binasal hemianopia
• Binasal hemianopic paralysis of pupillary
reflex
• Optic atrophy.
CAUSES
• IIIrd ventricle enlargement causing pressure
on each side of chiasma.
• Atheroma of carotids or posterior
communicating arteries on both sides.

TSM— tuberculum sellae
meningioma

OPTIC TRACT
• Macular fibres crossed &
uncrossed- dorsolateral
aspect of tract.
• Upper retinal fibres ( upper
uncrossed temporal retina+
upper crossed nasal retina) –
medial aspect of optic tract.
• Lower reinal fibres ( lower
uncrossed temporal + lower
crossed nasal) – lateral aspect
of optic tract.

FIELD DEFECTS IN LESIONS OF OPTIC
TRACT- 5
Right incongruous homonymous
hemianopia
Afferent pupillary conduction
defect present.
C/L hemianopic pupillary
response
Optic atrophy
Association with right hemiplegia
and left 3rd nerve paralysis indicates
a left optic tract lesion involving
left cerebral peduncle and left 3rd
nerve.

CAUSES OF OPTIC TRACT LESION
Syphilitic meningitis
Tuberculous meningitis
 Tumors of thalamus
Temporal lobe glioma
 Aneurysm of superior cerebellar or posterior
cerebral arteries.

BOW-TIE” OPTIC ATROPHY
• Cause – involvement of fibres entering
optic disc nasally & temporally.
• it occurs lesions of chiasma & c/l optic
tract involving crossed retinal fibres
nasal to fovea.

• Macular fibres
wedge shaped area
broadeningtowards
caudalplate.
• Upper retinal –
Medial ½ of anterior
LGB.
• Lower retinal –
Lateral ½ of
anterior LGB.

FIELD DEFECTS IN LESIONS OF
•6- Incongruous
homonymous hemianopia
•Sparing of pupillary
reflexes.
•Optic disc pallor may
occur due to partial
descending atrophy.

CAUSES
• AV malformations
• Arterial inflammations
• Injuries
• Vascular occlusions

OPTIC RADIATION
Upper retinal fibres
Upper part of optic radiations
Lower retinal fibres
Lower part of optic radiations
Macular fibres
Central part of optic radiations

OPTIC RADIATIONS OF THE TEMPORAL
LOBE
• From the LGN, inferior visual fibers first
course anteriorly and then laterally and
posteriorly to the meyer loop of the temporal
lobe.
• Superior fibers course more directly
posteriorly in the parietal lobe.
• Lesions affecting the meyer loop thus
produce superior incongruous homonymous
visual field defects- pie in the sky.
• Damage to the temporal lobe anterior to the
meyer loop does not cause visual field loss.
• Lesions affecting the radiations posterior to
the loop produce homonymous hemianopic
defects that extend inferiorly.

OPTIC RADIATIONS OF THE PARIETAL LOBE
Lesions of the parietal lobe, which often result from stroke or neoplasms,
tend to involve superior fibers first, causing contralateral inferior
homonymous hemianopic defects.
More extensive lesions affect the superior visual fields but remain denser
inferiorly.
Other neurologic effects
Agnosia- unable to recognise objects (inability to interpret sensations).
Apraxia- unable to make movements.
Acalculia- loss of ability to perform simple calculations.
Agraphia – inability to write letters,symbols.
Left–right confusion.
Optokinetic nystagmus

OPTIC RADIATIONS OF THE OCCIPITAL LOBE
•As the visual fibers approach the occipital lobes, the visual field becomes
congrous.
•The central fibers become separate from the peripheral fibers and course to the
occipital tip, whereas the peripheral fibers travel to the anteromedial cortex.
•The anteromedial region of the occipital lobe subserves a monocular “temporal
crescent” of visual field in the far periphery(60°–90° from fixation).
• Visual field defects resulting from occipital lobe lesions may have the following
characteristics in the hemifields contralateral to the lesion:
• congruous homonymous hemianopia, possibly sparing the fixation region
• monocular defect of the temporal crescent involving only the most anterior
portion of the occipital lobe.

VISUAL FIELD DEFECT OF OPTIC
RADIATIONS
7. Anterior temporal lobe, inferior fibres
are involved - Superior quadrantanopia
Pie in the sky.
8. Parietal lobe, superior fibres are
involved- Inferior quadrantanopia- Pie
on the floor.
9. Total fibres of optic radiations are
involved- Complete homonymous
hemianopia.
10. Posterior part of Internal capsule
(Ant occipital cortex)-homonymous
hemianopia with macular sparing.

COMMON CAUSES OF LESIONS OF OPTIC
RADIATIONS
 Vascular occlusions
 Cerebral tumours
 Injury by fall on the back of head
Temporal lobectomy for epilepsy

VISUAL
CORTEX
• Called cortical retina, since true
copy of retinal image is formed
here.
• Right & left visual fields are
represented within left & right
occipital lobe respectively.
• Fibres from macular area relay
posteriorly in visual cortex.
• Fibres from superior & inferior
peripheral retina end upper &
lower part of calcarine sulcus.

FIELD DEFECTS IN LESIONS OF VISUAL
CORTEX
LESIONS IN VISUAL CORTEX
TIP OF OCCIPITAL ANTERIOR VISUAL ANTERIOR MOST PART
CORTEX CORTEX OF VISUAL CORTEX
CONGRUOUS
HOMONYMOUS
HEMIANOPIA with
macular sparing.
Ex : pca occlusion.

Bilateral homonymous macular defects, presenting like bilateral central scotoma occur
in bilateral lesions of occipital cortex.

COMMON CAUSES OF LESIONS OF VISUAL
CORTEX
Vascular lesions in territory of PCA
Trauma- fall on the back of head or
gunshot injury
Cerebral tumours- primary or metastatic.

CHECKERBOARD QUADRANTANOPIA
Bilateral occipital lobe
infarcts

HALF-MOON SYNDROME / TEMPORAL CRESCENT
SYNDROME
– Only example of a monocular field defect from a
retrochiasmal lesion
– Most likely infarction of the anterior 10% of the occipital
cortex
– Measured by kinetic perimetry from 60-90°

REFERENCE
• AK KHURANNA ANATOMY & PHYSIOLOGY
• WOLFF’S ANATOMY OF EYE AND ORBIT( 8TH EDITION)

visual fields in neuro ophthalmology-part 1

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