How Do We Detect Light?

Question 1

light

Answer 1

electromagnetic radiation
electromagnetic wave that we can detect (aka photons)

Question 2

what distinguishes the different colors of light

Answer 2

wavelength of light
red light= higher wavelength, lower frequency (moves slower)
purple/indigo light= lower wavelength, higher frequency

Question 3

frequency

Answer 3

cycles per second (Hertz)

Question 4

some electromagnetic radiation we cannot detect

Answer 4

UV rays, infrared, etc.

Question 5

radio waves

Answer 5

higher wavelength, lower frequency
travels through the air, radio takes the wavelengths-> transforms them into things we can hear-> how we have a radio

Question 6

human vision vs. dog vision

Answer 6

dogs don’t have the ability to see as many colors as we do
we only see colors based on the cones and number of cone receptor cells we have

Question 7

dogs

Answer 7

2 cone receptor cells

Question 8

humans

Answer 8

3 receptor cells

Question 9

human vision vs. snail vision

Answer 9

snails see in black and white, but don’t see in the same acuity as humans
snails see within our visual spectrum, but with less acuity (shockness, clearness)

Question 10

acuity

Answer 10

clearness

Question 11

human vision vs. gecko vision

Answer 11

gecko’s can receive and detect spectra that humans cannot see and protect
can see into the UV light spectrum (lower wavelength, higher frequency)

Question 12

pheromones

Answer 12

all mosquitos detect and if you get eaten, its cause you have sweet pheromones

Question 13

human vs. snake

Answer 13

snakes can detect heat
see wavelengths (longer) than we can see, on the infrared spectrum

Question 14

human vision vs. bird vision

Answer 14

can see shorter wavelengths (UV spectrum)
can see more bright things

Question 15

human vision vs. mantis shrimp vision

Answer 15

12 photoreceptors that detect color vs. 3 photoreceptors in humans (3 colors)

Question 16

physics of light

Answer 16

white light is made up of the spectrum of all the colors (ROYGBP).. put white light into a prism, (rain causes) light bends at different angles depending on wavelengths-> see a rainbow
see the separation of white light into all of those colors

Question 17

when we see colors

Answer 17

colors are being absorbed
black= absence of wavelength (0 photons coming into my eyes)

Question 18

packet of energy

Answer 18

photons, which are both particles and waves
energy from lights come into our eyes

Question 19

number of photons emitted by source

Answer 19

brightness
bright white light or dim white light (it will be white either way)

Question 20

frequency of photon waves

Answer 20

color
wavelengths determines the color

Question 21

light -> vision

Answer 21

white light bounces off the background of the slide… wavelengths bounce off and come into our eyes

Question 22

black and red

Answer 22

black- no wavelengths bounce off
red- only red wavelengths are being bounced off and entering eye
all other color wavelengths are being absorbed, no red wavelengths to bounce back… apple looks black

Question 23

shine only green light onto a red apple

Answer 23

green wavelengths get absorbed, no red wavelengths to bounce back… apple looks black

Question 24

Class Question: The frequency of light waves conveys information about ____, while the frequency of sound waves conveys information about ____
A. Color; loudness
B. Color; pitch
Wavelength or frequency of the light = color
C. Brightness; loudness
Brightness = number of photons
D. Brightness; pitch

Answer 24

B. color;pitch

Question 25

structural features of the eye

Answer 25

cornea
retina
lens
pupil
iris

Question 26

cornea refracts and is inverted

Answer 26

light entering the eye so that it is transferred to retina
inverted top-bottom and reversed left-right

Question 27

lens

Answer 27

focuses image on retina by changing shape

Question 28

pupil

Answer 28

opening in the iris

Question 29

pupil controls

Answer 29

how much light enters
brightness
optometrist dilates pupil by blocking acetylcholine transmission in iris muscles

Question 30

retina has

Answer 30

photoreceptors
visual processing begins in the retina

Question 31

photoreceptor cells

Answer 31

rods and cones

Question 32

rods

Answer 32

scotopic
1 photoreceptor, 100 million
more common in peripheral parts of retina
very high sensitivity-> respond in low light conditions, and saturated in bright light
wavelength insensitive (gray)

Question 33

cones

Answer 33

photopic
3 photoreceptors, 4 million
more common in fovea
low sensitivity-> only active under brighter conditions
wavelength sensitive (colors)

Question 34

fovea

Answer 34

center of the retina (more cones)

Question 35

transduction

Answer 35

photoreceptor cells transduce light to electrical signals to chemical signals

Question 36

transduction steps

Answer 36

light deforms rhodopsin in rods (photopsins for cones)-> releases transducin (like a G-protein)-> transducin activates PDE (phosphodiesterase)-> PDE reduces cGMP levels-> less cGMP causes Na+ channels to close-> hyperpolarization
*1 photon closes hundreds of Na+ channels and blocks 1 million Na+ ions

Question 37

light _____ the photoreceptor cell->

Answer 37

hyper polarizes-> leading to less glutamate release

Question 38

cones have the same general mechanisms as

Answer 38

rods
but, photopsins are deformed by specific ranges of wavelengths

Question 39

three separate opsin proteins

Answer 39

three type of cones

Question 40

color blindness

Answer 40

usually only can distinguish short wavelength from long wavelength

Question 41

retinal cells include

Answer 41

photoreceptor cells
bipolar cells
horizontal cells
amacrine cells

Question 42

photoreceptor cells

Answer 42

release glutamate onto bipolar cells

Question 43

bipolar cells

Answer 43

synapse onto ganglion cells, whose axons form the optic nerve fibers

Question 44

lateral interactions

Answer 44

horizontal cells
amacrine cells

Question 45

horizontal cells

Answer 45

contact photoreceptor and bipolar cells

Question 46

amacrine cells

Answer 46

contact bipolar and ganglion cells

Question 47

bipolar cells integrate

Answer 47

a bipolar cell receives info from multiple photoreceptors, so can monitor and integrate what they are all “seeing”

Question 48

two types of bipolar cells

Answer 48

photoreceptor cells steadily release glutamate onto bipolar cells
light causes less glutamate release
on-center vs off-center

Question 49

on-center bipolar cells

Answer 49

turning light on in the center of the field (less glutamate) excites them

Question 50

off-center bipolar cells

Answer 50

turning off light in the center of the field (more glutamate) excites them

Question 51

bipolar cells release glutamate, which always…

Answer 51

depolarizes ganglion cells

Question 52

What happens to an off-center bipolar cell when you turn off a light in the center of its field?
A. It is inhibited
B. It is excited
C. Nothing

Answer 52

B. It is excited

Question 53

ganglion cells integrate

Answer 53

a ganglion cell receives info from multiple photoreceptors (via bipolar cells), so can monitor and integrate what they are all “seeing”

Question 54

ganglion cells receptive fields

Answer 54

on/off center surround ganglion cell

Question 55

bipolar cell responses

Answer 55

changes in polarization

Question 56

ganglion cell responses

Answer 56

action potentials

Question 57

pathway to the brain

Answer 57

optic fibers pass through the retina

Question 58

blindspot or optic disc

Answer 58

where ganglion cell axons (optic nerves) cross retina to enter the brain

Question 59

ganglion cell axons-> optic chiasm

Answer 59

the optic nerves (ganglion cell axons) from each eye join at the optic chiasm

Question 60

side of chiasm

Answer 60

some axons with stay on same side (ipsilateral) and some cross (contralateral)

Question 61

visual fields

Answer 61

left and right visual fields

Question 62

binocular vision

Answer 62

in the center region of visual field

Question 63

depth perception

Answer 63

requires visual field overlap

Question 64

in the end

Answer 64

all axons carrying information about the left visual field end up on the right and vice versa

Question 65

which optic nerve fibers stay on the same side?

Answer 65

the temporal (lateral) retina views a shared part of the visual field, so those fibers stay on the same side

Question 66

which optic nerve fibers cross?

Answer 66

the nasal (medial) retina views the non-overlapping part visual field, so axons cross over

Question 67

Which retina (A or B) will detect the
orange circle?
Which side of the brain will information
about this orange circle be received?
A B

Answer 67

both retinas- orange circle is close to the middle
B- left visual field is transferred to the right

Question 68

optic fibers -> lateral geniculate nucleus

Answer 68

optic fibers (ganglion cell axons) pass through optic chiasm and synapse in lateral geniculate nucleus (LGN: part of thalamus)

Question 69

lateral geniculate nucleus layers

Answer 69

the LGN has six layers
each layer receives input from only one eye
magnocellular & parvocellular

Question 70

magnocellular layers

Answer 70

(1 and 2) receive information from rod cells
depth and motion
large receptive fields
1 from one eye, 2 from the other eye

Question 71

parvocellular layers

Answer 71

(3 to 6) receive information from cone cells
fine detail and color
small receptive fields
3 and 5- one eye, 4 and 6- other eye

Question 72

LGN-> primary visual cortex (V1)

Answer 72

LGN axons send information to the primary visual cortex (V1)

Question 73

retinotopic (location) map in V1- topographic organization

Answer 73

V1 is retinotopically organized-> neighboring cells tend to receive information from multiple nearby ganglion cells
V1 cells receptive fields are bigger than LGN fields

Question 74

V1 “simple neuron” receptive fields

Answer 74

each “simple cell” monitors a small stripe of the visual field
responds to bars and edges present in that location
orientation matters- horizontal, vertical, slanted

Question 75

V1 “complex neuron” receptive fields

Answer 75

each “complex cell” monitors a larger stripe of the visual field
responds to movement
orientation matters

Question 76

complex V1 neurons receive from

Answer 76

simple V1 cells<- LGN cells<- V1

Question 77

retinotopic maps in V1 allows for

Answer 77

detection of bars/edges and movement in spatial representation

Question 78

a second level of topographic organization

Answer 78

ocular dominance column/slab

Question 79

ocular dominance column/slab

Answer 79

vertical column of neurons in V1 that respond to one eye
adjacent column of neurons respond to other eye
same receptive field

Question 80

third level of organization

Answer 80

orientation column

Question 81

orientation column

Answer 81

vertical column of neurons that respond to rod-shaped stimuli of a particular orientation

Question 82

two pathways of higher order visual processing

Answer 82

dorsal (where) pathway & ventral (what) pathway
starts at the occipital lobe

Question 83

ventral “what” pathway

Answer 83

V1-> V2
V2-> V4
V4-> IT

Question 84

V1->V2

Answer 84

V2 combines information from multiple V1 neurons to build complex representations
textures
multiple actual features and some illusionary features
filling in gaps of shapes

Question 85

V2-> V4

Answer 85

V4 neurons respond to complex radial and concentric stimuli
wavelength (color) specific receptive fields

Question 86

V4-> IT

Answer 86

inferior temporal cortex responds to complex shapes, sensitivity to color and texture
facial recognition (fusiform face area)
prospagnosia or “face-blindness”

Question 87

IT

Answer 87

inferior temporal cortex

Question 88

What will a patient with damage to V4 be likely unable to perceive?
A. the brightness of the lights on the roller coaster
B. the color of the roller coaster
C. the motion of the roller coaster

Answer 88

B. the color of the roller coaster

Question 89

dorsal “where” pathway

Answer 89

V1-> V5
V5-> posterior parietal cortex

Question 90

V1-> V5

Answer 90

V5 neurons perceive speed and direction of moving stimulus
motion blindness

Question 91

V5

Answer 91

medial temporal lobe

Question 92

V5-> posterior parietal cortex

Answer 92

neurons tuned to spatial location of objects
planned movements, visuomotor transformation

Question 93

lesions in the posterior parietal cortex

Answer 93

hemi-spatial neglect
visual->motor is biasing one side over the other (able to engage both sides when prompted)

Question 94

What will a patient with damage to the medial temporal area (area
V5) be likely unable to perceive ?
A. the brightness of the lights on the roller coaster
B. the motion of the roller coaster
C. the color of the roller coaster

Answer 94

B. motion of the roller coaster