Session 4: The Retina and Central Visual Pathways

Question 1

Three layers of the eye.

Answer 1

Sclera

Uvea

Retina

Question 2

What is the sclera continous with?

Answer 2

The dural sheath of the optic nerve

Question 3

Contents of the uvea.

Answer 3

Choroid

Ciliary body

Iris

Question 4

Neural layer of the retina - superficial to deep:

Answer 4

Retinal pigment epithelium

Photoreceptor cells

Bipolar cells

Ganglion cell layer

Nerve fibre layer

Question 5

Function of the retinal pigment epithelium.

Answer 5

Prevents light from bouncing around in the eyeball causing a glare.

Question 6

What are the bipolar cells?

Answer 6

First order neurones receiving input from photoreceptors.

These bipolar cells are connect by horizontal cells which assist with enhancing edges through a process called lateral inhibition.

Question 7

Purpose of the ganglion cell layer.

Answer 7

Receives input from bipolar cells and axons of ganglion cells form the nerve fibre layer.

Question 8

Give example of conditions fundoscopy can pick up.

Answer 8

Hypertensie retinopathy

Diabetic retinopathy

Macular degeneration

Question 9

What is amaurosis fugax?

Answer 9

Sudden visual loss due to occlusion of the cenral retinal artery.

Question 10

What is the medial retina called?

Answer 10

The nasal retina

Question 11

What is the lateral retina called?

Answer 11

Temporal retina.

Question 12

Light coming from the temporal field is detected by:

Answer 12

The nasal retina

Question 13

Light coming from the nasal field is detected by:

Answer 13

The temporal retina

Question 14

Explain the route of the light stimulus once it has become the optic nerve.

Answer 14

Optic nerve will run to the optic chiasm and will then form optic tracts.

Ganglion cell axons project to a part of the tahalmus called the lateral geniculate nucleus. This is via the optic tract.

The lateral geniculate nucleus projects to the visual cortex through the optic radiations.

Question 15

What are the superior optic radiations?

Answer 15

Ganglion cells from the superior retina - inferior field.

Question 16

What do the superior optic radiations run through?

Answer 16

The parietal lobe

Question 17

What are the inferior optic radiations?

Answer 17

Ganglion cells from the inferior retina - superior field.

Question 18

What do the inferior optic radiations run through?

Answer 18

Temporal lobe

Question 19

What is monocular blindness?

Answer 19

Complete visual field loss of one eye

Question 20

What is scotoma?

Answer 20

A localised defect in the retina that can cause a small patch of visual loss.

Question 21

Explain the route of the temporal fibres through the optic chiasm.

Answer 21

They will travel from the optic nerve to the optic tract on their ipsilateral side.

Question 22

Explain the route of the nasal fibres through the optic chiasm.

Answer 22

They will decussate and then travel to the optic tract contralaterally.

Question 23

What is monocular blindness?

Answer 23

Complete visual field loss in one eye.

Question 24

What is bitemporal hemianopia?

Answer 24

Visual loss of the temporal fields.

Question 25

What is contralateral homonymous hemianopia?

Answer 25

Visual loss of one temporal field and one nasal field.

Question 26

What is contralateral superior quadrantopia?

Answer 26

Visual field loss of one of the superior temporal field quadrants and one of the superior nasal field quadrants.

Question 27

What is contralateral inferior quadrantopia?

Answer 27

Visual field loss of one of the inferior temporal field quadrants and one of the inferior nasal field quadrants.

Question 28

What is contralateral homonymous hemianopia with macula sparing?

Answer 28

Similar to contralateral homonymous hemianopia but macula is spared.

One nasal field and one temporal field is lost but the whole field of the macula remains intact.

Question 29

What will a lesion here cause?

Answer 29

Optic nerve leading to monocular vision loss of the ipsilateral eye (left)

Question 30

What will a lesion here cause?

Answer 30

Optic chiasm

Bitemporal hemianopia

Question 31

What will a lesion here cause?

Answer 31

Optic tract

Contralateral homonymous hemianopia meaning visual loss of the temporal field on the right eye and the nasal field on the left eye.

Question 32

What will a lesion here cause?

Answer 32

Inferior (temporal) optical radiations

Contralateral homonomous superior quadrantopia meaning visual field loss of upper temporal quadrant of right eye and upper nasal quadrant of left eye.

Question 33

What will a lesion here cause?

Answer 33

Superior optical radiation

Contralateral homonomous inferior quadrantopia meaning visual field loss of lower temporal quadrant of the right eye and the lower nasal quadrant of the left eye.

Question 34

What will a lesion here cause?

Answer 34

Contralateral homonymous hemianopia

Visual field loss of temporal field of right eye and nasal field of left eye.

Question 35

How might contralateral homonymous hemianopia with macula sparing occur?

Answer 35

The primary visual cortex is supplied by the posterior cerebral artery.

However the macula is supplied by a branch of the middle cerebral artery.

This means that in the case of an occlusion of the posterior cerebral artery there will still be macula sparing.

Question 36

How might both superior and inferior optic radiations be affected?

Answer 36

Stroke

Question 37

What does optical coherence tomography do?

Answer 37

A specialist technique that can be used to visualise the layers of the retina.

Question 38

Afferent and efferent of light reflex.

Answer 38

Afferent = optic nerve

Efferent = oculomotor nerve

Question 39

Explain the light reflex.

Answer 39

Light shone in one eye and afferent signal goes via optic nerve into the pretectal nucleus. Then goes bilateral to both Edinger westphal nuclei and carried on oculomotor nerve to ciliary body and constrictor sphincter pupillae.

This causes constriction of both pupils.

Question 40

Explain the accommodation reflex.

Answer 40

When the eye is unable to refract the light effectively anymore because the object is too close.

This causes convergence of the eyes via medial rectus.

Pupillary constriction via constrictor pupillae.

Fattens the lens via the contraction of ciliary muscle causing laxity of the suspensory ligaments.

The cerebral cortex must be involved.

The reflex follows the visual pathway via the lateral geniculate nucleus.

Question 41

Action of horizontal cells.

Answer 41

Help narrow down the light signal that is being sent by lateral inhibition.

This means that it detects the signal from the area of light impulse. The horizontal cells will inhibit any adjacent (lateral) photoreceptors that are not under the stimulus of the light.

Question 42

Why is the primary visual cortex involved in the accommodation reflex?

Answer 42

Because it is relating to image analysis

Question 43

Explain the accommodation reflex.

Answer 43

An object close by where refraction isn’t possible anymore there will be convergence, constriction and fattening of the lens.

Information is sent via optic nerve -> optic chiasm -> optic tract and then ultimately to primary visual cortex.

It will then communicate with the Edinger-Westphal nuclei (similarly to the light reflex) and cause impulse of the parasympathetic fibres of the CN III to cause constriction of pupils as well as contraction of the ciliary muscles which cause the suspensory ligaments to go lax -> fattening of the lens.

Question 44

Answer 44

Question 45

Where do the inferior optic radiations travel in the brain?

Answer 45

In the temporal lobe or specifically in Meyer’s loop.