Cognitive Psychology PDF

Summary

This document contains questions and answers about cognitive psychology, focusing on selective attention, memory, and brain functions involved in movement. It covers topics like voluntary and reflexive attention, and explores the roles of different brain regions in these processes. The content is likely intended for higher education.

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Question Answer

Selective attention The ability to prioritize and attend to some things while ignoring others
Overt vs. covert Overt: moving eyes to the location/object/feature
Same or di erent neurons? Covert: attention without moving the eyes
Same parietal neuron res for both

Voluntary vs. re exive attention Voluntary: choosing what to attend to based on current goals (top-down), ventral parietal
Bottom-up vs. top-down Re exive: automatically orienting to new information (bottom-up), dorsal parietal
Ventral vs. dorsal parietal

Posner Cuing Task (measures attention to space) Arrows indicate which side the target will appear on
Valid, invalid, and neutral Valid: arrow is correct
Invalid: arrow is wrong
Neutral: either side is equally likely

Valid vs. invalid condition and voluntary vs. involuntary attention Valid condition uses voluntary attention, and response time is faster
Invalid condition uses re exive attention, response time is slower

Re exive attention and response to features, eg. gray letter, horizontal number Re exive attention responds to pop-out features
When is search slowest? Response time is much slowest for voluntary, controlled search

What lobe of the brain is responsible for control of attention? Parietal lobe (active primarily for switching attention)
What lobes are responsible for voluntary vs. re exive attention? Voluntary: Superior Parietal Lobe/IPs and Frontal Eye Field (FEF)
SPL, FEF, TPJ, VFC Re exive: Temporal Parietal Junction (TPJ), Ventral Frontal Cortex (VFC)

fMRI activity in TPJ and IPS during Posner Cuing Task TPJ is more active for invalid trials and for target, NOT cue (arrow)
IPs (voluntary) is active for valid and invalid, and for cue (arrow)

Attention and sensory processing Attention allows us to select what stimuli we are paying attention to by "priming" areas of the brain to attend to speci c objects, features, or spaces

ERP study and Posner Cuing Task Enhanced responses when target is on the attended side

Stroop Task and attention to color Greater activity in the color area, less in word area vs. control task
Parietal lobes and sensory areas Suggests that parietal lobes direct (control) sensory/perception regions to be enhanced/inhibited

Disorders of spatial attention Unilateral neglect: de cit in attending to information on contralesional side of space
3 Extinction: inability to perceive stimuli on contralesional side when there are stimuli on healthy side
Unilateral, extinction, Balint's Balit's syndrome: only can see one object at a time

Unilateral neglect and extinction Re exive attention de cits
Re exive or voluntary Often in the right parietal lobe, usually IPC (Inferior Parietal Cortex)
What part of the brain?

Examples of unilateral neglect Visual search: patients fail to search the left side of space for the target
Posner cuing task Posner: neglect patients are slower to detect leftwards target than right
Visual search task Stronger alpha waves for right hemisphere = greater suppression
Alpha waves

Memory and unilateral neglect When asked to describe village, patient could describe neglected eld information if asked to face the other direction, towards intact side
Village imagery Memory is still intact

Unilateral neglect and environmental vs object attention Neglect is object AND spatial
Horizontal line drawing Patient will neglect left side of the space and the left side of the object

Extinction Attention is biased away from contralesional side (towards intact eld) when competing stimuli are present
What happens when competing stimuli are present?

Attentional disorders are domain general Span all the senses, including touch

Object knowledge and extinction Patients are less likely to ignore left (impaired) object if the two objects are di erent

Action knowledge and extinction Action knowledge increased likelihood that ignored eld information will be reported
Object orientation Objects at correction orientation are more likely to be reported

Is unattended information represented in the brain Yes! Recognizing object, action, and feature information means that we are somehow processing those details even if we aren't consciously aware

Balint's syndrome Severe loss of spatial representation-di culty binding details
Impaired dorsal pathway (which lobes?) A) Optic ataxia: impaired vision guided reaching
3 features: B) Ocular apraxia: inability to voluntarily control gaze
Optic ataxia, ocular apraxia, simultanagnosia C) Simultanagnosia: inability to recognize more than one object at once
Posterior parietal/lateral occipital lesions

Illusory conjunctions Combining features of two separate objects into one object
Attention is required to correctly bind features together

What unattended information is represented in the brain? 1. Feature information (colors, shapes)
2. Object information (eg. a key and a fork, two di erent objects)
3. Action information (eg. object orientation)
4. Memory remains intact

Hierarchy of action control 1. Conceptual level "do you want to dance?"
2. Response system level- selecting a response
3. Motor implementation

Motor pathway Premotor and supplementary systems->primary motor cortex->brainstem->spinal cord

Corticospinal/pyramidal tract Responsible for voluntary control
Longest neurons in the brain Primary motor cortex->midbrain->medulla->spinal cord
90% crossed Synapse at alpha motor neurons (control muscle contraction)

Electromyography Measures electrical activity caused by alpha motor neurons ring

Agonist/antagonist muscles Agonist contracts while antagonist relaxes to allow movement
Ex. biceps and triceps

Re exive movement Sensory neuron (dorsal root)->motor neuron (ventral root) in spinal cord
No motor cortex processing Dorsal=to CNS, vental=away from CNS

Primary motor cortex (M1) Responsible for the execution of movement
How is it organized? Organized by body part
How are neurons specialized? Neurons are specialized for direction of movement

Population vector The sum of the preferred directions of a population of neurons
Movement is a function of summed activity of all neurons

Disorders of movement Hemiplegia: loss of voluntary movement in contralateral limbs
Hemiplegia Hemiporesis: weakness/impaired control of contralateral limbs
Hemiporesis

Motor planning action plans Not tied to a speci c body part
Ex. you can write with multiple body parts

TMS of SMA-planning vs M1 (primary motor cortex)-execution SMA (supplementary motor area):
Timing of errors, complex vs. simple tasks Delay in errors, only for complex sequences-partial action plan already in m1 ex. forgetting which step
M1:
Immediate errors, in complex and simple tasks ex. hand is stuck

Parietal lobe vs. M1 activation during learned task for di erent body parts Parietal lobe is activated in the same area for both arm and hand-encodes action plan regardless of body part
M1 had di erent regions activated for arm vs. hand

Apraxia Loss of ability to generate coordinated purposeful actions NOT due to loss of muscle control
Di culty with action planning Particularly with miming movements ex. whistling, blowing out a match

Video games and cognitive skill improved ability to focus on visual details
heightened sensitivity to visual contrast
mentally rotate objects more accurately
quicker reaction times to sudden events
better decision making under pressure

Brain regions with activity changes due to video games dorsolateral prefrontal cortex: helps sustain attention
Dorsolateral prefrontal, parietal, and cingulate cortex parietal cortex: switches focus among di erent targets
cingulate cortex: monitoring one's own behavior

Action vs. nonaction video games Action video games that emphasize attention, exibility, and speed show cognitive gains, where nonaction games do not

Populations not bene tted by traditional action games ADHD, older players, lazy-eye patients

Cumulative cultural evolution (CCE) the process by which incremental accumulations of changes to a cultural trait lead to functional improvement in performance
Requires social learning

Two parts of chimpanzee experiment (1) whether naive chimpanzees who were exposed to all relevant materials could master the required skill by themselves within a prolonged period
(2) whether naive chimpanzees could acquire the skill by observing a pro cient (trained) conspeci c model

Results of chimpanzee study 1: not a single chimpanzee out of the 66 residents was successful in operating the apparatus through the drawer mechanism once
2: 14 naive chimpanzees who at some point during the experimental sessions mastered the skill (watching trained chimp)

Results of chimpanzees observing task being solved the more times chimpanzees observed the task being solved, the faster they were to start interacting with it, and the faster they were to solve the task once they had started interacting with it

Mirror neurons Neurons in premotor cortex (frontal) that re for both observing and performing

Monkeys, dogs, and human motor neurons for familiar action vs "speaking" action Familiar (biting): activation in mirror circuit
Speaking (silent speech, barking, lip smacking): activation only in humans

Fine motor coordination brain regions Basal ganglia and cerebellum

What is the cerebellum involved in? Motor timing, feedback, execution, planning, balance, and eye movements

What is the basal ganglia involved in? Initiation, switching between motor tasks
Not just motor Also cognition

Agonist/antagonist muscles in cerebellar lesions Poorly timed=poor coordination

Rabbit and air pu feedback and cerebellar lesions Rabbits with cerebellar lesions could not learn from stimulus to close their eyes in time for the pu

Prism glasses and cerebellar lesions Cerebellar patients could not correct for distorted vision from glasses-they never hit the target
Typical patients adapted to distorted vision, and had to adjust back after glasses were removed

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 Ataxia Impaired coordination despite knowledge of correct action
Cerebellar lesions

5 nuclei of basal ganglia Caudate and putamen (striatum)
Globus pallidus
Sub-thalamic nucleus
Substantia nigra

Two pathways of the basal ganglia Direct: excitatory (inhibits inhibitory neurons)
Indirect: inhibitory

Basal ganglia as a dam Basal ganglia is inhibitory by default
The most active motor response overcomes the dam

Two key aspects of Parkinsons Akinesia: problems in shifting motor state eg. from one key pattern to another
Akinesia and bradyphrenia Bradyphrenia: problems in shi ting cognitive state, eg. from naming color to naming shape

Parkinsons and loss of dopaminergic projections from substantia nigra to striatum Reduced excitation of cortex
More inhibition of thalamus

Hippocampus and memory during sleep The hippocampus replays memories during REM sleep
David Marr Key to memory consolidation

Targeted memory reactivation (TMR) researchers played unique sounds while people memorized the locations of 50 objects on a computer screen eg. meow and cat

Roles of motor cortex, secondary/association, cerebellum, and basal ganglia in movement/action Motor cortex: motor execution
Secondary/association: motor planning, action perception
Cerebellum: motor coordination, feedback learning
Basal ganglia: state changes

Action plans during memory/delay period Action plans for both possible tasks are active during memory/delay period, at cue, one is enhanced while other is suppressed

Brain-machine interface Computer decodes patterns of neuronal ring to move a robotic limb or the person's own limb based on intention of movement

Types of long term memory Explicit/declarative: episodic (events) and semantic (facts, world knowledge)
2 main branches, 2 sub branches Implicit/non-declarative (performance): skills, conditioned responses, perceptual priming, sensitization, habituation

Disorders of declarative/explicit memory Anterograde amnesia:
Anterograde and retrograde amnesia problem with "learning", forming new memories
Loss of memory for events after disturbance
Retrograde amnesia: problem with "memory", recalling
Loss of memory for events before disturbance

Clive Wearing Bilateral hippocampal lesions, and some prefrontal damage
What kind of amnesia did he have? Anterograde amnesia
What kind of damage did he have?

What brain region is associated with anterograde amnesia? Medial temporal lobe (hippocampus, amygdala, mammillary bodies, thalamus)

Korsako 's Disease Due to a lack of thiamine, often caused by alcoholism
What brain region is a ected? Leads to degradation of mammillary bodies->anterograde amnesia
What do patients display? Patients often confabulate, and are unaware that they have memory issues

Is alzheimers disease a retrieval problem or a storage problem? When neurons associated with the fear response were tagged and light-activated, the long-term memory was restored
Mice with fear reactions AD is a retrieval problem, not a storage problem

Amnesiacs and procedural memory Amnesiac patients show intact procedural learning on performance tasks
ex. HM improved on mirror gure drawing
ex. patients learned to weave

Threshold reading task Hippocampal patients had normal priming but impaired recall (if word was in study set)
Double dissociation between declarative and non-declarative memory Occipital patients had impaired priming but normal recall (if word was in study set)
Hippocampal vs. occipital patients

Weather task double dissociation Parkinson's patients show intact declarative memory (recalling details) but impaired non-declarative memory (learning patterns)
Parkinson's vs. hippocampal patients Hippocampal patients show the opposite

Morris Water Maze Hippocampal lesion rats could not learn where the platform was, and could not locate the platform in cloudy water
Cortical lesion vs. hippocampal lesion rats

London taxi drivers Taxi drivers show increased volume, and increase is linked to time on the job
Posterior hippocampal volume

Hippocampus and parietal lobe and spatial memory Hippocampus creates a spatial map, parietal lobe reads map

Hippocampus during sleep Neurons re quick replays of learning episodes-encode memories

Hippocampal activity during recalled vs. forgotten tasks Hippocampal activity is greater during encoding for correctly recalled words, scenes, etc., especially for events
Ex. while watching scene, or while making size/animacy judgements

Long term potentiation (LTP) and long term depression (LTD) and consolidation LTP strengthens synaptic connections, LTD weakens
Hippocampus consolidates multiple representations of an event into one memory

Hebbian learning Neurons that re together become wired together
3 rules 1. Cooperativity: there must be more than 1 input active
2. Associative: weak and strong must co-occur
3. Speci city: only active neurons potentiate

Ataxia vs. apraxia Ataxia: loss of muscle control/coordination, a ects all actions
Apraxia: inability to carry out familiar movements (eg. whistling, blowing). Spontaneous movements possible

Relational memory the ability to remember the connections between people, places, objects, and events
Implicit Hippocampus lesions: intact shape discrimination, but no relational memory
How does it relate to hippocampal patients?

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