The Visual System Part 1

Question 1

Three Types of Eyes

Answer 1

1) Camera eyes (simple lens eye and corneal) 2) Compound eyes

Question 2

Difference between simple and compound eyes

Answer 2

Simple Eyes: A single lens collects and focuses light onto the retina of the eye.
Compound eyes: Multiple lenses are involved. Each of them focuses the light onto a small number of retinular cells

Question 3

Simple Eye Animals

Answer 3

Vertebrates, Cephalopod, jellyfish, gastropods, annelids and one type of copepod crustacean

Question 4

Simple Corneal Eye Animals

Answer 4

Arachnids, some vertebrates and some larval insects

Question 5

Compound eye Animals

Answer 5

Insects, crustaceans, some mollusks, and annelids

Question 6

Ciliary Muscle

Answer 6

Connects to the iris and changes the shape of the lens when your eyes focus on a near object

Question 7

Iris Function

Answer 7

Controls the opening of the pupil

Question 8

Lens Function

Answer 8

Connected to ciliary muscles transmit and focus the light onto the retina in order to create clear images of observed objects at various distances

Question 9

Cornear

Answer 9

Outer transparent layer at the front of the eye is specialized to allow incoming light rays to enter the eye

Question 10

Steps of Light Entering Eyes

Answer 10

1) Light enters the eye through the cornea
2) From the cornea, the light passes through the pupil. The iris, or the colored part of your eye, controls the amount of light passing through.
3) From there, it then hits the lens light is focused by the lens and passes through vitreous humor
4) It reaches the back of the eye where it is received by the photoreceptors of the retina, which are concentrated in the fovea.
5) Images are inverted in retina and the optic optic nerve is then responsible for carrying the signals to the visual cortex of the brain
6) he visual cortex turns the signals into images

Question 11

Branch of Ophthalmic Artery

Answer 11

Supplying blood to the retina and veins that are exiting out of the retina

Question 12

Optic Disck

Answer 12

1) Represents the beginning of the optic nerve and is the point where the axons of retinal ganglion cells come together

Question 13

Optic Nerve

Answer 13

Cranial nerve sends visual information from your retina to your brain

Question 14

Accommodation Def +Function

Answer 14

Describes the refractive power of the lens to ensure clarity of an image

Question 15

What is accommodation based on?

Answer 15

Contraction of ciliary muscles which releases tension of zonule fibres

Question 16

Zonule fibers

Answer 16

Allows for elasticity of lens to increase its curvature

Question 17

Myopia

Answer 17

an image of a distant object becomes focused in front of the retina, instead of the on the retina making distant objects appear out of focus.

Question 18

Hyperopia

Answer 18

An image of a distant object becomes focused behind the retina, making objects up close appear out of focus.

Question 19

Which layers do horizontal cells and amacrine cells mediate lateral interactions?

Answer 19

Outer and inner plexiform layers

Question 20

Horizontal Cells

Answer 20

Modulate information flow from photoreceptors to bipolar cells

Question 21

Where do bipolar cells exist?

Answer 21

Between photoreceptors (rod cells and cone cells) and ganglion cells.

Question 22

Which layer are amaricne, bipolar and horizontal cells and photorecpetors? located

Answer 22

Inner Nuclear Layer

Question 23

Bipolar Cells function

Answer 23

Bipolar cells receive input from photoreceptors (rods and cones) in the outer retina and transmit signals to amacrine and ganglion cells in the inner retina.

Question 24

Ganglion Cells

Answer 24

Carry information from photoreceptors received from interneurons into the brain via the optic nerve

Question 25

Inner Plexiform Layer

Answer 25

Consists of synaptic connections between the axons of bipolar cells and dendrites of ganglion cells.

Question 26

What does Outer Plexiform Layer contain?

Answer 26

Synapses between axons of photoreceptors and dendrites of bipolar and horizontal cells

Question 27

Outer Plexiform Layer Function

Answer 27

The splitting of the visual signal into two separate channels of information flow, one for detecting objects lighter than background and one for detecting objects darker that background

Question 28

What does outer nuclear layer contain

Answer 28

The cell bodies of the photoreceptor cells.

Question 29

Nerve Fiber Layer

Answer 29

A layer that is formed by the expansion of optic nerve and includes the axons of the ganglion cells bodies also lie in this layer.

Question 30

Where are rods found in the retina?

Answer 30

Found concentrated in the outer edges of the retina and are much more abundant than the cone cells.

Question 31

Rod Function

Answer 31

Help in identifying the shape, size and brightness of images and cannot perceive light

Question 32

Cones Function

Answer 32

Less sensitive to light and are responsible for perceiving colour and fine details of a visual image.

Question 33

Where are cones found in retina?

Answer 33

concentrated in the fovea centralis which is a rods free area.

Question 34

List the photopigment(s) found in rods.

Answer 34

Rhodopsin

Question 35

List the photopigment(s) found in cones

Answer 35

opsin: short (blue), medium (green), long (red

Question 36

Retinal Pigment Epithelium

Answer 36

Function is to provide nourishment to the retinal visual cells.

Question 37

What type of vision occurs in levels of light at which only rods are activated?

Answer 37

Scotopic

Question 38

What type of vision occurs in levels of light at which both rods and cones contribute (at twilight, for example)?

Answer 38

Mesopic

Question 39

What type of vision occurs in levels of light at which only cones contribute—at twilight, for example?

Answer 39

Photopic

Question 40

Important Property of Opsin

Answer 40

They can change their conformation from a resting state to a signalling state upon light absorption, which activates the G protein, thereby resulting in a signalling cascade that produces physiological responses

Question 41

How does the phototranduction begin in a rod?

Answer 41

Begins with the absorption of a photon of light that causes the breaking of a double bond in 11-cis-retinal forming the isomer all-trans-retinal.

Question 42

Where does the recycling of all-trans-retinal needs to be recycled into 11-cis-retinal occur?

Answer 42

retinal pigment epithelium,

Question 43

Steps of Retinoid Cycle

Answer 43

1) All trans retinal is converted to all trans retinol (alchohol)
2) It is transported by the chaperone protein IRBP into the pigment epithelium
3) . There, in a series of steps, it is converted to 11-cis retinal and transported back to the outer segment (again via IRBP), where it recombines with opsin

Question 44

Why is the retinoid cycle important?

Answer 44

Allows for continuous phototransduction in the retina.

Question 45

What does light adaptation allow?

Answer 45

Allows the eye has to quickly adapt to the background illumination to be able to distinguish objects in this background.

Question 46

What is the role of Ca2+ in photo adaptation?

Answer 46

• By modulating the cGMP-gated channels as well as cGMP synthesis and breakdown.
  -Ca2+is involved in a negative feedback that is essential for photoreceptor adaptation to background illumination

Question 47

Steps of Phototransudction

Answer 47

1) In the dark positively charged sodium ions flow into rod cells through ion channels that are activated by cGMP

2) This influx of psoitively charged ions causes cells to remain in a depolarized state, leading to the continous release of glutamate

3) When retinal absorbs light, its configuration changes from 11cist retinal to all transretina, an event that prompts opsin to activate a protien called transducin

4) Transducin activates PDSE which begin to break down cGMP

5) As cGMP levels fall, ions channels begin to close, thus less sodium enters hte cell and the cell becomes hyperpolaized due to potassium ions leaving the cell

6) Glutamate decsrease which acts as a signal that a light stimlus is present, rod cell returns to its normal state when activatd rhodsoin is inactived and arrestin (protien) binds to rhodsipin and blocks the ability of rhodsopin to activate transducin which makes the cascade unable to continue

7) The retinoid cycle occurs to restore retinal to its original configuration, making it ready to absorb light once again

Question 48

Retinitis Pigmentosa

Answer 48

• Progressive vision loss results from degeneration of photoreceptors?
• A key feature of this disease is the formation of clumps throughout periphery from retinal pigments.

Question 49

What happens to epiteletial cells during retinas pigmentosa?

Answer 49

The epithetical cells do not regenerate photopigment molecules but rather they begin to phagocytes (engulf) the outer segments of rods and cones
1) First tip separates from the rod
2)Tip becomes engulfed by pigment epithelium

Question 50

The figure depicts an intracellular recording from a single cone. The amplitude increases with the intensity of the flash, proving that photoreceptors exhibit ______ potentials. Perhaps even more surprising, activation leads to ______, as evidenced by the change in membrane potential

Answer 50

graded; hyperpolarization

Question 51

Which type of photoreceptor exhibits a sustained, inward current that can be likened to voltage-gated K⁺ channels?

Answer 51

Rods stay hyperpolarized longer

Question 52

Which type of photoreceptor exhibits a transient, inward current that can be likened to voltage-gated Na⁺ channels?

Answer 52

Cones repolarize faster and regain sensitivity to light more quickly

Question 53

Describe the molecular activity of photoreceptors under dark conditions?

Answer 53

In the dark, cGMP levels in the outer segment membrane are high; cGMP binds to the Na+-permeable channels in the membrane, keeping them open and allowing sodium and calcium ions to enter, and K+ leaving thus depolarizing the cell

Question 54

Describe the molecular activity of photoreceptors under light conditions?

Answer 54

Absorption of photons leads to a decrease in cGMP levels, closing the cation channels and there is no influx of calcium and sodium but there is an efflux of potassium and resulting in receptor hyperpolarization

Question 55

Rods possess high ______ sensitivity. In contrast, cones possess high ______ sensitivity and ______ acuity.

Answer 55

light; colour; spatial

Question 56

Why do rods exhibit lesser spatial acuity than cones, based on structural features alone?

Answer 56

Because several rod cells share a connection to the optic nerve. But this also improves the eye’s ability to detect small amounts of light.

Question 57

Why do cones have higher visual acuity?

Answer 57

Cones have a high visual acuity because each cone is connected singly to bipolar cells so brain receives nerve impulses from small area

Question 58

What is sensitivity of light further amplified by?

Answer 58

By convergence of many rods onto a single bipolar cell

Question 59

Why is there a region in the forve that does not have vasculature?

Answer 59

Allows light to pass unblocked into the photoreceptor outer segment

Question 60

Macular Degeneration

Answer 60

Affects center of eye and causes blurred vision or blind spot in center of eye

Question 61

Cause of macular degeneration

Answer 61

Blood vessels that leak fluid or blood into the macula (responsible for our central vision)

Question 62

protanopia

Answer 62

Involves the loss of long (red)-wavelength-sensitive cones?

Question 63

deuteranopia

Answer 63

loss of medium (green)-wavelength-sensitive cones).

Question 64

Many deficiencies of color vision arise from alterations in the M- or L-cone pigment genes as a result of _______ _______ during meiosis.

Answer 64

Unequal crossing over

Question 65

Amacrine cells

Answer 65

mediate transmission from bipolar cells to gangalion cells

Question 66

How are on on-center bipolar cells activated and inhibited?

Answer 66

Activated when light falls in the center of their receptive fields and inhibited when light falls on the surrounding outer ring of their receptive fields.

Question 67

How are off-center ganglion cells activated and inhibited?

Answer 67

Inhibited upon light falling on the center, and activated upon light falling on the surrounding outer rings.

Question 68

What happens when light impacts the center of a recpetive field

Answer 68

In the forvea, each cone will contact and on and off center cell

Question 69

The effect of light on glumate release?

Answer 69

Absence of light = depolarizing dark current causes the release of the transmitter glutamate.
Light= the photoreceptors are hyperpolarized and they release less glutamate.

Question 70

What kind of receptors do on/off center bipolar cells express?

Answer 70

On center bipolar cells have metabotropic glutamate receptors

Off center bipolar cells have ionotropic glutamate receptors

Question 71

OFF CENTER BIPOLAR CELLS: DARK

Answer 71

In the dark, glutamate released by the photoreceptor activates the ionotropic receptors, and sodium can flow into the cell, depolarizing the membrane potential.

Question 72

OFF CENTER BIPOLAR CELLS: LIGHT

Answer 72

In the light, the absence of glutamate causes the ionotropic receptors (AMPA and Kinate) to close, preventing sodium influx, hyperpolarizing the membrane potential.

Question 73

In OFF bipolar cells, the glutamate released by the photoreceptor is _______`

Answer 73

excitatory

Question 74

In ON In ON bipolar cells, the glutamate released by the photoreceptor is __________

Answer 74

inhibitory

Question 75

ON CENTER BIPOLAR CELLS: DARK

Answer 75

In the dark, glutamate released by the photoreceptor activates the metabotropic receptors, and the G-proteins close cation channels in the membrane, stopping the influx of sodium and calcium, hyperpolarizing the membrane potential.

Question 76

ON CENTER BIPOLAR CELLS: LIGHT (express metabotropic receptors)

Answer 76

In the light, the absence of glutamate results in the ion channels being open and allowing cation influx, depolarizing the membrane potential.

Question 77

Difference in response of ON/OFFbipolar and ON/OFF ganglion cells respond?

Answer 77

ON-centre ganglion cells and OFF-centre ganglion cells do not respond by depolarizing or hyperpolarizing, but rather by increasing or decreasing the frequency with which they discharge action potentials.

Question 78

Relationship between OFF Bipolar Cells and OFF Center Ganglion Cells

Answer 78

OFF bipolar cells will also hyperpolarize in light, which will lead to a decreased firing rate in OFF-center ganglion cells.

Question 79

Relationship between ON Bipolar Cells and ON Center Ganglion Cells

Answer 79

ON bipolar cells will depolarize in light, which will lead to an increased firing rate in ON-center ganglion cells.

Question 80

What is the primary neurotransmitter used in the visual system for generating receptive field center responses of retinal ganglion cells?

Answer 80

Glutmate

Question 81

Are photoreceptor synapses with off-center bipolar cells sign-conserving or sign-inverting?

Answer 81

sign-conserving (since the sign of the change in membrane potential of the bipolar cell (depolarization or hyperpolarization) is
the same as that in the photoreceptor.

Question 82

Are photoreceptor synapses with on-center bipolar cells sign-conserving or sign-inverting?

Answer 82

sign inverting (because the change in the membrane potential of the bipolar cell is the opposite of that in the photoreceptor)

Question 83

Are on-center synapses with on-center ganglion cells sign-conserving or sign-inverting?

Answer 83

sign-conserving (Both on- and off-center ganglion cells are connected to their respective bipolar cells via sign-conserving, ionotropic receptors. This is not to be confused with photoreceptor synapses with on-center bipolar cells, which are sign-inverting due to metabotropic receptors.)

Question 84

Match Bands

Answer 84

Optical phenomenon from edge enhancement due to lateral inhibition of the retina
- This is an inbuilt edge enhancement mechanism of the retina, where the edges of darker objects next to lighter objects will appear darker and vice versa, creating a false shadow.

Question 85

Light stimulation of the surround leads to (DEPOLARIZATION / HYPERPOLARIZATION) of horizontal cells and a(n) (DECREASE / INCREASE) in the release of GABA onto the photoreceptor terminals.

Answer 85

hyperpolarization, decrease

Question 86

Fill in the structures of the visual pathway, from where ganglion cell axons exit the retina at the optic disk to the visual projection areas in the brain.

Answer 86

1) Optic Nerve
2) Optic Chaism
3) Optic tract
3) LGN (lateral geniculate nucleus
4) Optic Radiation
5) Visual (straied) Cortex

Question 87

Optic Chiasm

Answer 87

The place in the brain where some of the optic nerve fibers coming from one eye cross optic nerve fibers from the other eye.

Question 88

Lateral geniculate nucleus (thalamus)

Answer 88

From here, visual information is organized from the retina and sent off to the primary cortex.

Question 89

Optic Radiation

Answer 89

Contains axons from the neurons in the lateral geniculate nucleus to the primary visual cortex.

Question 90

Visual Cortex

Answer 90

This is where images received from your retina begin to get processed and then sent out to other brain regions

Question 91

Pretectum

Answer 91

Responsible for reflex control of the pupil and lens

Question 92

superior colliculus

Answer 92

receives input from the retina and the visual cortex and participates in a variety of visual reflexes (head and eye movements)

Question 93

Pupillary light reflex

Answer 93

Automimic reflex that constricts the pupil in response to light, thereby adjusting the amount of light that reaches the retina.

Question 94

Course of Optic Radiation to Striate Cortex

Answer 94

• Axons carrying information about the superior portion of the visual field sweep around the lateral horn of the ventricle in the temporal lobe (Meyer’s loop) before reaching the occipital lobe.

Question 95

Calcrine Suclus Location and Function

Answer 95

Located at the caudal end of medial occipital lobe separates the upper and lower visual fields in the striate cortex

Question 96

Fovea

Answer 96

an area in the middle of the retina that gives the sharpest vision of any part of the retina and contains only cones

Question 97

Where is the upper and lower visual vield in relation to the calcarine suclus?

Answer 97

The upper visual field = below the calcarine sulcus
The lower field =above the calcarine sulcus

Question 98

How many layers does the LGN have?

Answer 98

Six cell body layers in the LGN
- The inner two layers, (1 and 2) are magnocellular layers
- outer four layers, (3,4,5 and 6), are parvocellular layers.

Question 99

Where do layers 1,4 and 6 recieve input from? LGN

Answer 99

Contralateral (the eye located on the opposite side of the body) nasal hemiretina,

Question 100

Where do layers 2, 3 and 5: receive input from LGN?

Answer 100

From the ipsilateral (the eye located on the same side of the body as another structure) temporal hemiretina.

Question 101

What happens at the LGN?

Answer 101

There is a mix and blend of info coming from the left and right eye and this info is mixed and blended/distributed across these six layers at the visual cortedx

Question 102

Occular Dominance

Answer 102

tendency to prefer visual input from one eye over the other

Question 103

M cells supply which layer of LGN

Answer 103

M cells have large-diameter cell bodies and large dendritic fields. =supply the magnocellular layers

Question 104

P cells characteristic and supply which layer of LGN

Answer 104

P cells have smaller cell bodies and dendritic fields = supply the parvocellular layers

Question 105

K cells charactersitic and supply which layer of LGN?

Answer 105

K cells have small cell bodies and intermediate-sized dendritic fields =supply the koniocellular layers (present between the layers)

Question 106

Bitemporal (heteronomous) hemianopsia

Answer 106

Results in blindness of the temporal visual field of each eye, the loss of half of the visual field on different sides in both eyes.)

Question 107

Left homonymous hemianopsia.

Answer 107

loss of sight in the left visual field

Question 108

Left superior quadrantanopsia

Answer 108

loss of vision) affecting a left quater of the visual field

Question 109

Left homonymous hemianopsia with macular sparing

Answer 109

A partial loss of vision in the left half of both eyes with the center, the macula, spared.

Question 110

How many principal cellular layers is the primary visual (striate) cortex divided into?

Answer 110

6 (nissil staining, dendritic morphology, LGN inputs, interlaminar, outputs (ascending red and descneidng (green, blue)

Question 111

Ocular dominance columns:

Answer 111

Respond preferentially to input from one eye or the other

Question 112

Orientation columns

Answer 112

Preferentially respond to orientation

Question 113

Neurons in the primary visual cortex response

Answer 113

Neurons in the primary visual cortex typically respond vigorously to a bar of light oriented at a particular angle (vertical edges) and less strongly—or not at all—to other orientations.

Question 114

Scelera

Answer 114

The supporting wall of the eyeball. It helps maintain your eyeball’s shape, and protects it from injury.