2: Neurocognition

Question 1

What is dissociation?

Answer 1

A disruption in one component of mental functioning but no impairment of another (e.g., HM)

Question 2

What is long-term potentiation?

Answer 2

• • Changes in the ease at which two connected neurons will fire
• • Lasts a few hours, days, or weeks

Question 3

What is consolidation?

Answer 3

– Long-term change over days, weeks, months, or years
–> Small Scale
LTP between individual neurons
–> Large Scale:
LTP changes in assemblies of neurons over long periods of time

Question 4

What is the function of the thalamus?

Answer 4

– Gateway to the cortex: almost all sensory messages (except smell) pass through the thalamus.

Question 5

What is the function of the corpus callosum?

Answer 5

Primary bridge for messages to cross to the left and right hemispheres

Question 6

What is the myelin sheath?

Answer 6

– Insulator for the axon
– Gaps – called nodes of Ranvier
» Note: not all neuron have myelinated sheath
– Mainly on neurons that are long (e.g., periphery of nervous system)
» Myelinated neurons are white matter (myelin is fat)
– Most cortical neurons (cognition) are unmyelinated
»These form what we call “Gray Matter”

Question 7

What is the action potential?

Answer 7

• • The change in electrical charge of a neuron from negative to positive
• • This charge propagates from the dendrites and down the axon.
• • Either a neuron fires or it does not

Question 8

What is a synapse?

Answer 8

• • The region in which the axon terminals of one neuron and the dendrites of another come together
• • Convergence: many neurons may converge onto a single neuron

Question 9

What are neurotransmitters?

Answer 9

• • The chemical substance released into the synapse between two neurons
• • Responsible for activating or inhibiting the next post- synaptic neuron

Question 10

What is function of the hippocampus?

Answer 10

Implicated in storing new information in memory

Question 11

What is the function of the amygdala?

Answer 11

Important for processing emotional qualities of information

Question 12

What is the neocortex/cerebral cortex?

Answer 12

The top layer of the brain responsible for higher-level mental processes

• -Frontal lobe
• -Parietal lobe
• -Occipital lobe
• -Temporal lobe

Question 13

What is contralaterality?

Answer 13

– Control of one side of the body is localized in the opposite-side cerebral hemisphere.
» The left hand, for instance, is largely under the control of the right hemisphere.

Question 14

What are the hemispheric specialization?

Answer 14

Left hemisphere:
» language sounds, letters, words, speech, reading, writing, arithmetic, verbal memory, complex voluntary movement

Right Hemisphere:
» non-language sounds, geometric patterns, faces, nonverbal memory, prosody, narrative, inference, spatial processes, movements in spatial patterns.

Question 15

What is the sensory and motor cortex?

Answer 15

• • Sensory cortex: processing of sensory information from throughout the body
• • Motor cortex: control of voluntary muscle movements
• • further localization of function within the sensory and motor cortices

Question 16

What is the dorsal and ventral pathway?

Answer 16

• • Dorsal pathway: involved in “where” things are in space

- - Ventral pathway: Involved in “what” things are

Question 17

What is a CT scan?

Answer 17

– Computerized-Axial Tomography; a bunch of X-rays that captures every layer/slice

Question 18

What is an MRI scan?

Answer 18

– Gives clearer pictures of the structure of the brain

Question 19

What is a single-cell recording?

Answer 19

Electrodes record the firing rate of individual cells

Question 20

What are Electrocephalograms (EEG)?

Answer 20

– Electrodes are attached to the scalp to record the patterns of brain waves.
– Event-Related Potentials
» The momentary changes in electrical impulses when a particular stimulus is presented

Question 21

What is transcranial magnetic stimulation (TMS)?

Answer 21

• • An electrical field is targeted over specific brain areas to stimulate nerve cells
• • This is a disruptive technique

Question 22

What is Positron Emission Tomography (PET)?

Answer 22

• • Image shows regions of the brain with heightened neural activity based on levels of blood flow.
• • radioactive isotope injected and detected by scanner
• • Cortical area(s) involved in the cognitive activity “light up”

Question 23

What is a functional MRI (fMRI)?

Answer 23

• • Similar to PET, but a more detailed image and does not involve a radioactive isotope
• • Measures metabolic rates in specific brain area change
• • Compare across different cognitive tasks

Question 24

What are other measures of brain activity?

Answer 24

– Lesions
» Used by Sperry
» The site and extent of the brain lesion are important guides to the kind of disruption that is observed.
– Direct Stimulation
» Pioneered by Penfield
» The patient in brain surgery remained conscious and small electrical charges were administered to the exposed brain, thus triggering small regions
– Special Populations
Groups of people who have known differences in brain function

Question 25

What is sensation?

Answer 25

Reception of stimulation from the environment and the encoding of it into the nervous system
Initial encoding into the nervous system

Question 26

What is perception?

Answer 26

Process of interpreting sensory information

Question 27

How are visual signals perceived?

Answer 27

– Rods/cones: the back layer of neurons stimulated by light, beginning the process of vision. The periphery (20+ degrees) are composed of mainly rods (so no colour vision)
120 M rods, 7 M cones
– Bipolar cells: Patterns of neural firing from rods/cones are passed on to a second layer, the bipolar cells, which collect the messages and move them along to a third layer, the ganglion cells
– Ganglion cells: Receive messages from the bipolar cells- the axons of the ganglion cells converge at the rear of the eye, forming the bundle of fibers that makes up the optic nerve
– Optic Nerve: Projects neural messages to visual cortex in occipital lobe

Question 28

What is the Fovea?

Answer 28

– The highly sensitive area of the retina responsible for precise, focused vision
» Covers about 1 to 2 degrees of visual field
– Most cones are in the fovea

Question 29

How is visual information compressed from the retina to the brain?

Answer 29

• • Only fraction of light waves reach retina
• • One cone synapses with one bipolar cell. In contrast, in peripheral vision, tens to hundreds of rods converge on a single bipolar cell (120M rods reduced down to about only 1M ganglion cells)
• • Such convergence results in a loss of information because a bipolar cell cannot “know” which of its many rods triggered it

Question 30

How do the eyes transmit visual information to the brain?

Answer 30

• • contralaterality principle: each eye transmits to both hemispheres, however each half of the retina gathers information from the contralateral visual field
• • The left half of the retina in each eye receives images from the right visual field and the right half of each retina receives images from the left visual field
• • Thus, the right visual field projects to the left half of the retina in both eyes, and this is then transmitted to the left hemisphere. Similarly, stimuli in the left visual field project to the right half of both retinas, and are then sent to the right hemisphere.

Question 31

What are saccades?

Answer 31

• • Movement of the eyes from one fixation point to another
• • Jerky & variable: 25ms – 175 ms
• • Nothing “seen” during a saccade

Question 32

What are fixations?

Answer 32

• • Eyes pause to foveate and gather visual information
• • For the most part we take in visual information only during a fixation. It is almost as if we are blind during the actual saccade (if the eye did encode information during the saccade, we’d see a smear)

Question 33

What is sensory memory?

Answer 33

• • allows the sensation of a visual pattern, sound, or touch to linger for a brief moment after the sensory stimulation is over
• • the information that is being held within ourSensory Memory appears to be unprocessed (not making any sense of it. It has to be processed for it to move to short term memory)

Question 34

How does information accumulate in sensory memory?

Answer 34

• • Information accumulates over time (50ms)

- - Not “all-or-none”

Question 35

What is visual persistence?

Answer 35

– The apparent persistence of a visual stimulus beyond its physical duration

Question 36

How did Eriksen & Collins study the duration of visual persistence (iconic SM)?

Answer 36

– superimposed dot patterns
– delay varied: 0 to 500 ms
@ 0 ms delay > 1 pattern, see letters (VOH)
@ ~ 75 ms > 2 patterns, but perceive letters
@ > 250 ms > 2 patterns, no letters
– Visual SM lasts for a short period of time: about between 250ms – 500ms

Question 37

What was Sperling’s Whole Report Procedure and what was the problem?

Answer 37

• • participants had to report all items in the display
• • Only able to report ~ 3 of 9 items
• • Problem with whole report technique; working short-term memory rather than sensory-memory because maybe all the items got into sensory memory but because it fades away so quickly you don’t get the chance to report them all

Question 38

What was Sperling’s Partial-Report Technique

Answer 38

• -Subjects saw three rows of letters flashed on a screen for just 1/20 of a second. A tone following the exposure signalled which row of letters the subject should report to the experimenter.
• • If interval short between the tone and presentation, then close to 100% accurate however their accuracy steadily declined as the delay of the tone increased to one second. Why? Because the memory trace in the visual sensory store decays in about 1/4 (250ms) of a second
• • Conclude: capacity of visual SM is very large

Question 39

How is information coded in sensory memory?

Answer 39

– Can select items from display based on:
> Location
> Colour
> Even angles/line versus circles
– However, cannot select based on higher-level features
> e.g., not able to select based on letters vs. digits (meaning sensory memory deals with primitive features so cannot categorize based on letters or numbers)
– Conclude: Information in SM is pre-categorical, not semantic

Question 40

How can information in SM be erased?

Answer 40

• • Originally thought that information in SM simply decayed over time
• • But, turns out that information can be erased from SM through interference; forgetting caused by the effects of intervening stimulation or mental processing
• • this is called masking; the partial or complete obscuring of one stimulus (the target) by another (the masker)
• • Masking occurs because we can’t keep different sensory information to integrate cause all this sensory information will overlap and blur out everything

Question 41

How did Averbach and Coriell study interference?

Answer 41

• • presented a display of two rows of letters, eight letters per row, for 50 ms. A blank white postexposure field, varying in duration, followed the display and was itself followed by a partial report cue
• • The bar marker was just above (or below) the position of the to-be-reported letter, and the circle marker surrounded the position where the to-be-reported letter had just been
• • With the bar marker, the results that were similar to those obtained by Sperling, such as higher performance with short delays of the cues
• • With the circle marker, accuracy was lower than with the bar marker, especially when the target letter resembled the circle marker (for instance, when the letter c had been shown at that position).
• • These results suggest that the circle had in some way disrupted the memory trace for the letter in that position
• • Thus, a later visual stimulus interfered with the memory for the prior stimulus at that location (called backwards masking)

Question 42

What are the different types of masking?

Answer 42

• • Backward Masking: when Target followed by Mask
• • Forward Masking: when Mask before the Target
• • Energy; such as a flash of light; affect peripheral (early)
• • Pattern ; has features (information) and is central & interrupts processing of features
• • Masking is strongest with energy masks when it happens at the same time as the stimulus

Question 43

What are the different visual fields you can use with masking?

Answer 43

Monocular: target & mask to one eye Binocular: target & mask to both eyes Dichoptic: target to one eye, mask to other eye

Question 44

What type of visual field can you use with energy masking?

Answer 44

– Occurs with mono & binocular, not with dichoptic

Question 45

What type of visual field can you use with pattern masking?

Answer 45

Is effective with all, even dichoptic

Question 46

What does masking suggest and why does it happen?

Answer 46

• • Shows that features coded in SM (not just energy)
• • Processing in SM is NOT passive, but dynamic
• • Masking arases information to allow for next event to be cleanly encoded into SM