Topic 7: visual processing

Question 1

where is the retina and what does it contain?

Answer 1

back of the eye, contains photoreceptors specialised to convert light energy into neural activity

Question 2

describe the properties of light

Answer 2

-electromagnetic radiation visible to our eyes
-wave of energy, has:
…wavelength –> distance between successive peaks and troughs,
…and has frequencies –> the number of waves per second
…and amplitude, the difference between wave trough and peak

Question 3

the energy content of electromagnetic radiation is proportional to its…

Answer 3

frequency

Question 4

radiation emitted at a high frequency (short wavelength) has the lowest energy content, true or false?

Answer 4

False, it has the highest energy content, examples are gamma radiation emitted by some radioactive materials, wavelengths less than 1nm

Question 5

radiation emitted at lower frequencies (longer wavelengths) has less energy, true or false?

Answer 5

True, examples are radar and radio waves, wavelengths greater than 1nm

Question 6

What is the part of the electromagnetic spectrum that is detectable by our visual system?

Answer 6

wavelengths of 400-700nm

Question 7

What is the pupil?

Answer 7

the opening that allows light to enter the eye and reach the retina, appears dark because of light-absorbing pigments in the retina

Question 8

What is the iris?

Answer 8

surrounds the pupil, pigmentation provides what we call the eye’s colour, the iris contains 2 muscles that can vary the size of the pupil, one makes it smaller when contracts the other larger

Question 9

What is the cornea?

Answer 9

covers pupil and iris, glassy transparent external surface of the eye, continuous with the sclera

Question 10

What is the sclera?

Answer 10

the “white of the eye”, which forms the tough wall of the eyeball

Question 11

where does the eye ball sit?

Answer 11

sits in a bony eye socket in the skull, also called the eye’s orbit

Question 12

What are the extraocular muscles?

Answer 12

-inserted into the sclera, move the eyeball in the orbit, not visible because they lie behind the conjunctiva

Question 13

What is the conjunctiva?

Answer 13

membrane that folds back from the inside of the eyelids and attaches to the sclera

Question 14

What is the optic nerve?

Answer 14

Carry axons from the retina, exits the back of the eye, passes through the orbit, and reaches the base of the brain near the pituitary gland

Question 15

What is the ophthalmoscope?

Answer 15

a device that enables one to peer into the eye through the pupil to the retina, can see blood vessels on its surface

Question 16

where do blood vessels in the eye originate?

Answer 16

from a pale circular region called the optic disc, which is also where the optic nerve fibres exit the retina

Question 17

what doesnt occur at the optic disk and why?

Answer 17

sensation of light, because there are no photoreceptors there

Question 18

What doesnt occur at the place where large blood vessel exit the eyes?

Answer 18

sensation of light, because vessels cast shadows on the retina

Question 19

What is the macula?

Answer 19

middle of each retina, dark-coloured region with a yellow-ish hue, part of the retina for central vision (as opposed to peripheral vision). distinguished also by the relative absence of large blood vessels

Question 20

What is the fovea?

Answer 20

a dark spot about 2mm in diameter, retina thinner in fovea than elsewhere, centre of retina

Question 21

What is aqueous humour?

Answer 21

nourishment by fluid for the cornea is provided by the aqueous humour (lies between cornea and lens)

Question 22

what is the lens?

Answer 22

located behind the iris, suspended by ligaments (called zonule fibres), attached to ciliary muscle, which forms rings inside the eye

Question 23

What is vitreous humour?

Answer 23

serves to keep eyeball spherical, lies between the lens and retina

Question 24

What light does the eye collect? and how does it focus images?

Answer 24

-The light rays emitted by or reflected off objects in the environment, and focuses them onto the retina to form images
-bringing objects into focus involves the combined refractive powers of the cornea and lens –> cornea is site where most refractive power of the eye is

Question 25

What does the eye use in order to see a single point?

Answer 25

refraction to focus the light to one point of the retina, light passes into a medium where its speed is slower and it will bend toward a line that is perpendicular to the border, or interface, between the media

Question 26

What is the focal distance?

Answer 26

The distance from the refractive surface to the point where parallel light rays converge

Question 27

What does the focal distance depend on in the eye?

Answer 27

curvature of the cornea, the tighter the curve, the shorter the focal distance

Question 28

What is the refractive power?

Answer 28

reciprocal of the focal point, measure in measurements called “diopter” (cornea has refractive power of roughly 42 diopters)

Question 29

What is the refractive power of the lens and cornea?

Answer 29

lens = roughly 6 diopters
cornea = roughly 42 diopters

Question 30

what is the lens more involved with?

Answer 30

-in forming crisp mages of objects located closer than 9m from the eye
-With near objects, the light rays originating at a point are no longer parallel. Rather, these rays diverge from a light source or a point on an object, and greater refractive power is required to bring them into focus on the retina.
-This additional focusing power is provided by changing the shape of the lens, a process known as accommodation

Question 31

What happens during accommodation?

Answer 31

-During accommodation, the ciliary muscle contracts and swells in size, thereby making the area inside the ring smaller and decreasing the tension in the suspensory ligaments.
-Consequently, the lens becomes rounder and thicker because of its natural elasticity. This rounding increases the curvature of the lens surfaces, thereby increasing their refractive power.
-Conversely, relaxation of the ciliary muscle increases the tension in the suspensory ligaments, and the lens is stretched into a flatter shape.

Question 32

what is the pupillary light reflex?

Answer 32

-involves connections between the retina and neurons in the brainstem that control the muscles that constrict the pupils –> when lights increases
-this is consensual, shining light on one eye causes constriction of both pupils

Question 33

What is the benefits of the pupillary light reflex?

Answer 33

increase in depth of focus

Question 34

Describe the visual field

Answer 34

-The left visual field is images on the right side of the retina and the right visual field on the left side of the retina
-similarly upper visual field is image on bottom of retina and vice versa

Question 35

What is visual acuity?

Answer 35

The ability of the eye to distinguish two points near each other

Question 36

What does visual acuity depend on?

Answer 36

several factors but especially on spacing of photoreceptors in retina and precision of eye’s refraction

Question 37

What is the viusal angle?

Answer 37

Distance across the retina, ability of eye to revolve points that are separated by a certain number of degree

Question 38

What is the pathway of visual information before exiting the eye?

Answer 38

photoreceptors to bipolar cells to ganglion cells

Question 39

what do photoreceptors do?

Answer 39

respond to light, they influence membrane potential of the bipolar cells connected to them

Question 40

What do the ganglion cells do?

Answer 40

fire action potential in response to light, and these impulses propagate along the optic nerve to the rest of the brain

Question 41

what are the horizontal cells?

Answer 41

assists in further retina processing, receives input from photoreceptors and projects neurites laterally to influence surround bipolar cells and photoreceptors

Question 42

What are amacrine cells?

Answer 42

assists in further retina processing, generally receive input from bipolar cells and project laterally to influence surrounding ganglion cells, bipolar cells and other amacrine cells

Question 43

what are the cells that are light-sensitive and the cells that are influence by light only via direct and indirect synaptic interactions?

Answer 43

only rod and cone photoreceptors are light sensitive, all the other cells are influenced

Question 44

What is the source of output from the retina?

Answer 44

only the ganglion cells

Question 45

what fires action potential in the retinal?

Answer 45

with exception of certain amacrine cells, only ganglion cells fire action potentials, other cells depolarise or hyperpolarize but do not fire AP

Question 46

What organization does the retina have?

Answer 46

laminar organization, in an “inside-out” arrangement, i.e., light must pass from the vitreous humour through the ganglion cells and bipolar cells before reaches photoreceptors

Question 47

what is the order of cell layers of the retina? and what does each layer consist of?

Answer 47

direction of nose to back of head, ganglions cell layer –>inner plexiform layer –> inner nuclear layer –>outer plexiform layer –>outer nuclear layer –> layer of photoreceptors –> pigmented epithelium

-ganglion cell layer contains ganglion cells
-inner plexiform layer contains synaptic contacts between bipolar, amacrine and ganglion cells
-inner nuclear layer contains cell bodies of bipolar cells
-outer plexiform layer where photoreceptors make synaptic contact with bipolar and horizontal cells
-outer nuclear layer contain cell bodies of photoreceptors
-layer of photoreceptors, photoreceptors

Question 48

What are the regions of photoreceptor?

Answer 48

outer segment, inner segment, cell body and synaptic terminal

Question 49

Describe the outer segment of photoreceptors

Answer 49

-contains a stack of membranous disks, light sensitive photopigments in the disk membranes absorb light, thereby triggering changes in the photoreceptor membrane potential
-rod and cones distinguished by shapes of outer segment –> rods have long cylindrical outer segment containing many discs –> cones have shorter, tapering outer segments with few membranous disks
-rods 1000 times more sensitive to light because more disk (about 5 million cones and 92 million rods)

Question 50

What is duplex retina?

Answer 50

two complementary systems in one eye

Question 51

besides the outer segments how do rods and cones differ and relate?

Answer 51

-all rods have same pigment but 3 types of cones containing different pigment –>variations among pigments make the different cones sensitive to different wavelengths of light
- only cones responsible for seeing colour
-most of 5 million cones in fovea and proportion diminishes substantially in retinal periphery
-no rods in central fovea
-many more rods than cones in peripheral retina

Question 52

in a cross section, the fovea appears as a pit in retina, what’s the reason for this pit?

Answer 52

-due to a lateral displacement of cells above the photoreceptors, allowing light to strike the photoreceptors without passing through the other retinal cell layers. maximises visual acuity at the fovea by pushing aside other cells that might scatter the light ad blur the image.

Question 53

describe transduction in Rods

Answer 53

-in photoreceptors, light stimulation of photopigment activated G-proteins, which in turn activates an effector enzyme that changes the cytoplasmic concentration of a second messenger molecule. This change causes a membrane ion channel to close, and the membrane potential is thereby altered
-in darkness rod outer segment is about -30mV –> depolarisation cause by influx of Na+ through special channels in outer segment of membrane

Question 54

describe movement of charge across membrane in the dark of rod

Answer 54

-movement of positive charge across membrane, occurs in dark, is called dark current –> sodium channels stimulate to open by intracellular second messenger called cyclic guanosine monophosphate (cGMP) (produced in photoreceptor by enzyme guanylyl cyclase), keeping the Na + channels open. Light reduces cGMP, causing the Na + channels to close, and the membrane potential becomes more negative. Thus, photoreceptors hyperpolarize in response to light

Question 55

what is the pigment responsible for absorption of electromagnetic radiation in hyperpolarising response in rods? and receptor protein for it

Answer 55

in the stacked disks of rod outer segment, pigment called rhodopsin, receptor protein called opsin, opsin has seven transmembrane alpha helices typical of G-protein-coupled receptors

Question 56

What happens when absorption of light occurs?

Answer 56

change in conformation of retinal so that activates the opsin –> process known as bleaching because changes the wavelengths absorbed by the rhodopsin (photopigment literally changes colour from purple to yellow).

Question 57

What does bleaching of rhodopsin do?

Answer 57

stimulates a G-protein called transducin in disk membrane, which in turn activates the effector enzyme phosphodiesterase (PDE), which breaks down cGMP that is normally present in cytoplasm of the rod (in the dark). The reduction in cGMP causes the Na+ channels to close and the membrane to hyperpolarize

Question 58

summarise steps in transduction of light by rods

Answer 58

1. light activates (bleaches) rhodopsin
2. transducin, the G-protein, is stimulated
3. phosphodiesterase (PDE), the effector enzyme, is activated
4. PDE activity reduced the cGMP level
5. Na+ channels close, and the cell membrane hyperpolarizes

Question 59

In bright light, cGMP levels in rods fall to the point where the response to light becomes saturated ; increasing the light level causes no additional hyperpolarization. Thus, vision during the day depends entirely on the cones, whose photopigments require more energy to become bleached. True or false?

Answer 59

True

Question 60

what is the differences and similarities of transduction in cones and rods

Answer 60

-virtually the same, only major difference is in the type of opsin in the membranous disks of the cone of the outer segment
-the different opsin related to different spectral sensitiveies
–>short wavelength or “blue” cones, about 430nm
–>medium wavelength or “green” cones, about 530nm
–>long wavelength or “red” cones, about 560nm

there is overlap with these opsin not just activated at these wavelengths

Question 61

what determines colour?

Answer 61

relative contributions of short- (blue), medium- (green) and long- (red) wavelength cones to the retinal signal –> theory of all colours made up of blue, green and red (of the colours not wavelengths of cones) called Yong-helmholtz trichromacy theory –> not to be confused to red wavelengths only perceiving red colour and etc.

Question 62

what is dark adaption?

Answer 62

-The transition from all-cone daytime vision to all-rod nighttime vision is not instantaneous; depending on how high the initial light level is, it can take minutes to nearly an hour to reach the greatest light sensitivity in the dark. (aka getting used to the dark),
-sensitivity to light increases a millionfold or more during this period

Question 63

how is dark adaption explained?

Answer 63

-one way is dilation of the pupils, allows more light to enter eye (diameter of pupil ranges from 2-8mm) –>changes to sizes increase sensitivity to light by only a factor of 10.
-another way is regeneration of unbleached rhodopsin and adjustment of the functional circuitry of the retina so that information from more rods is available to each ganglion cell

Question 64

What is light adaption and how does it occur?

Answer 64

-adaption of light, reversing the changes in the retina that accompanied dark adaption

Question 65

What does the light-dark adaption gives us?

Answer 65

-the light-dark adaption in the duplex of retina gives our visual system the ability to operate in light intensities ranging from moonless to midnight to bright high noon

Question 66

describe calcium’s role in light adaption

Answer 66

-ability of eye to adapt to changes in light level relies on changes in calcium concentration within cones
-constriction of the pupil helps a bit in reducing the light, however, most important change is the gradual depolarisation of membrane back to about -35mV
- reason this happens stems from cGMP-gate sodium channels also admit calcium
-Ca 2+ enters the cones and has an inhibitory effect on the enzyme (guanylyl cyclase) that synthesizes cGMP. When the cGMP-gated channels close, the flow of Ca 2+ into the photoreceptor is curtailed along with the flow of Na + ; as a result, more cGMP is synthesized (because the synthetic enzyme is less inhibited), thereby allowing the cGMP-gated channels to open again. Stated more simply, when the channels close, a process is initiated that gradually reopens them even if the light level does not change. Calcium also appears to affect photopigments and phosphodiesterase in ways that decrease their response to light. These calcium-based mechanisms ensure that the photoreceptors are always able to register relative changes in light level, though information about the absolute level is lost.

Question 67

at each synaptic relay what are the responses modified by in retina?

Answer 67

by lateral connections of horizontal cells and amacrine cells

Question 68

What is the neurotransmitter released by photoreceptor when depolarised? when does this occur and when does hyperpolarization occur

Answer 68

amino acid glutamate when depolarised, depolarisation in the dark, hyperpolarization by light –> less transmitters release in light

Question 69

what do the horizontal cells feed information to?

Answer 69

laterally in the outer plexiform layer to influence activity of neighbouring bipolar cells and photoreceptors

Question 70

What is the receptive field in retina?

Answer 70

-light that is applied to small portion of retina that changes firing rate of neuron

Question 71

What can bipolar and receptive fields be categorised into?

Answer 71

-two classes ON and OFF –> based on the response to the glutamate release by photoreceptors

Question 72

What is the circuitry the gives rise to bipolar receptive fields?

Answer 72

-consists of direct input from photoreceptors and indirect photoreceptor input relayed by horizontal cells

Question 73

What are OFF bipolar cells?

Answer 73

light shined onto a cone will hyperpolarize some bipolar cell –> because light will effectively turn them off

Question 74

what are ON bipolar cells?

Answer 74

light shined onto a cone will depolarise other bipolar cells –> these cells are “turned on” by light

Question 75

The cone-to-bipolar synapse inverts the signal from the cone. The cone hyperpolarises to light, but the ON bipolar cell depolarises. True or False?

Answer 75

true

Question 76

How can different bipolar cells give opposites responses to direct cone input?

Answer 76

-there are 2 kind of receptors that receive glutamate release by the photoreceptors

Question 77

Describe the OFF bipolar cells

Answer 77

-have ionotropic glutamate receptors, and these glutamate-gated channels mediate a classical depolarising excitatory postsynaptic potential from the influx of Na+. hyperpolarised of cone causes less transmitter to be release, resulting in a more hyperpolarised bipolar cell

Question 78

Describe ON bipolar cells

Answer 78

have G-protein-couples (metabotropic) receptors and respond to glutamate by hyperpolarising

Question 79

Each bipolar cell receives direct synaptic input from a cluster of photoreceptors. The number of photoreceptors in this cluster ranges from one at the centre of the fovea to thousands in the peripheral retina. true or false?

Answer 79

true

Question 80

describe the synaptic interactions of photoreceptors, horizontal cells and bipolar cells

Answer 80

-First, when a photoreceptor hyperpolarizes in response to light, output is sent to horizontal cells that also hyperpolarize.
-Second, the effect of horizontal cell hyperpolarization is to counteract the effect of light on neighbouring photoreceptors.
-light is shined onto two photoreceptors connected through horizontal cells to a central photoreceptor and bipolar cell. The effect of this indirect path input is to depolarize the central photoreceptor, counteracting the hyperpolarizing effect of light shined directly on it.

Question 81

what are the 2 parts of the receptive field of bipolar cell? and what does this means?

Answer 81

-a circular area of retina providing direct photoreceptor input, the receptive field centre;
and a surrounding area of retina providing input via horizontal cells, the receptive field surround
-the response of bipolar cell’s membrane potential to light in the receptive field centre is opposite to that of light in the surround –> thus these calls are said to have antagonistic centre-surround receptive fields

Question 82

the centre-surround receptive field organisation is passed on from what to what?

Answer 82

from bipolar cells to ganglion cells via synapses in the inner plexiform layer

Question 83

What do ON-centre and OFF centre ganglion receive inputs from?

Answer 83

from corresponding type of bipolar cell

Question 84

what is an important difference in centre-surround receptive field organisation in bipolar and ganglion cells

Answer 84

-ganglion cells fire action potentials –> they fire whether or not they are exposed to light, and increases or decreases in relations to the receptive field centre or surround

Question 85

describe the OFF ganglion cell action

Answer 85

-will fire fewer AP when small spot of light is projected to the centre of its receptive field, it will fire more AP if small dark spot covers receptive field centre

Question 86

in both ON and OFF types of cell the response to stimulation of centre is cancelled by what?

Answer 86

response to stimulation of the surround

Question 87

What are the 2 major types of ganglion cells in retina?

Answer 87

large M-type ganglion cells (about 5% of population) and smaller P-type ganglion cells (about 90% of population)

Question 88

what happens when there is a generation of centre response of ganglion cells receptive fields?

Answer 88

-When on-centre bipolar cell is
depolarized it increases
transmitter release onto on-centre ganglion cell dendrites

-On centre ganglion cell is
depolarized and fires faster
Off-centre bipolar cell is
hyperpolarized causing
decreased transmitter
release.

-Off centre ganglion cell
hyperpolarizes and fires more
slowly

Question 89

describe the generation of antagonistic surround of ganglion cell RFs by horizontal cells

Answer 89

-Photoreceptors in surround
hyperpolarize and release less
glutamate onto horizontal cells

-Horizontal cells hyperpolarize and so release less neurotransmitter

-Horizontal cell neurotransmitter
(GABA) hyperpolarizes photoreceptor terminals (like light in centre of RF)

-Thus less transmitter causes
depolarization of photoreceptor
terminals in RF centre increasing
glutamate release onto bipolar cells in RF centre

Question 90

Describe colour opponency in P-type ganglion cells

Answer 90

P type ganglion cells have colour opponent RFs Red ON centre, green OFF surround shown Blue – yellow opponency also found

Question 91

describe the pathway of visual perception

Answer 91

-originates in retina –> lateral geniculate nucleus (thalamus) –> primary visual cortex –> higher order visual areas in occipital, temporal, and parietal lobes

Question 92

describe receptive fields of LGN neurons

Answer 92

almost identical to the ganglion cells that feed them

Question 93

Describe magnocellular LGN neurons receptive fields

Answer 93

large centre-surround receptive field with transient response

Question 94

describe parvocellular LGN cells receptive field

Answer 94

Small centre-surround receptive fields with sustained response

Question 95

Describe the retinotopy

Answer 95

-Map of the visual field onto a target structure (retina, LGN, superior colliculus, striate cortex)
-Central visual field (fovea) overrepresented in map
-Discrete point of light can activate many cells in the target structure due to overlapping receptive fields.
-Perception is based on the brain’s interpretation of distributed patterns of activity—not literal map

Question 96

describe the monocular receptive fields

Answer 96

–Layer IVC: similar to LGN cells

–Layer IVCalpha: insensitive to the wavelength
–Layer IVCbeta: centre-surround colour opponency

Question 97

decribe the binocular receptive fields

Answer 97

–Most neurons in layers superficial to IVC are binocular.
–Two receptive fields—one for each eye

Question 98

describe parallel processing

Answer 98

-Simultaneous input from two eye
–> Input from eyes compared in cortex –> Determines depth and distance of object
-Information about light and dark: ON-center and OFF-centre ganglion cells
-Different receptive fields and response properties of retinal ganglion cells: M and P cells, and nonM–nonP cells

Question 99

describe parallel processing and perception

Answer 99

Hierarchy of complex receptive fields:
-In retinal ganglion cells: center-surround structure, sensitive to contrast and wavelength of light
–In striate cortex (v1): orientation selectivity, direction selectivity, and binocularity
–Extrastriate cortical areas: selective responsive to complex shapes (faces) and motion

Question 100

Rods and cones both hyperpolarize in light, true or false

Answer 100

True