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Cognitive

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Title: Component process model of memory Author: Baycrest User Last modified by: npark Created Date: 11/19/2001 12:03:42 AM Document presentation format – PowerPoint PPT presentation

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Title: Cognitive


1
Cognitive Neuroscience Intro
  • Themes
  • cognitive psychology has been guided by an
    information processing approach to theorizing
  • this approach attempts to characterize how
    information is processed from its initial input
    until its response
  • this approach continues to be used

2
Cognitive Neuroscience Intro
  • Primary measures
  • Reaction time (RT)
  • measure the elapsed time from the onset of a
    stimulus until there is a response to the
    stimulus
  • general goal of measuring RT is to make
    inferences about underlying cognitive processes
    (which are assumed to take time)

3
Cognitive Neuroscience Intro
  • Primary measures
  • Accuracy
  • this measure assesses the accuracy of an
    individuals performance
  • Note accuracy can be broadly (or narrowly)
    defined
  • e.g., verbatim versus gist recall

4
Cognitive Neuroscience Intro
  • Analogies
  • channel capacity
  • early uses attention/Broadbent
  • more recent uses controlled processing
  • computer analogy
  • serial sequential processing of information

5
Atkinson-Shiffrin Model
(Atkinson Shiffrin, 1968)
6
Cognitive Neuroscience Intro
  • General early assumptions
  • sequential stages of processing
  • stages are independent
  • stages are non-overlapping

7
Cognitive Neuroscience Intro
  • New conceptualizations
  • parallel processing
  • e.g., typing
  • hierarchical organization
  • e.g., typing a word
  • e.g., grasping an object (prepare index finger
    thumb apperture as you move arm toward object)
  • context effects
  • semantic priming

8
Cognitive Neuroscience Intro
  • Cognitive neuroscience intro
  • neuron is the basic building block of the brain
  • cell that is specialized for receiving and
    transmitting a neural impulse
  • Note there is enormous variability in the
    structure of neurons

9
Cognitive Neuroscience Intro
  • Development of neurons and glial cells
  • germinal (or stem) cells of an embryo give rise
    to two types of nervous system cells neuroblasts
    and spongioblasts (blast is an immature cell)
  • neuroblasts develop into neurons
  • spongioblasts develop into glial cells
  • glial cells provide support to neurons

10
Cognitive Neuroscience Intro
  • Cognitive neuroscience intro
  • Major structures of a neuron
  • input end dendrites, which accumulate neural
    stimulation into the neuron itself
  • cell body or soma regulates the biological
    activity of the neuron
  • axon a long tube-like structure used to transmit
    information
  • axon terminals or terminal arborizationsoutput
    end of the neuron, where neural impulses end

11
An illustration of the various structures of the
neuron. The lower diagram illustrates a
sensory-motor reflex arc
12
Cognitive Neuroscience Intro
  • Basic elements of nervous system
  • how a simple reflex works (e.g., jerking hand
    away from a hot stove)
  • receptor cells in hand react to physical stimulus
    and that triggers a pattern of firing down a
    sequence of sensory neurons
  • tracts of sensory neurons pass message along into
    the spinal cord where it is routed to brain and
    back into motor neurons
  • However, at the synapse the message can route
    directly to the motor neurons

13
Cognitive Neuroscience Intro
  • Basic elements of nervous system
  • motor neurons in spinal cord transmit message
    back to arm muscles
  • these terminate at effector cells, which connect
    directly to muscle fibres and cause the muscles
    to pull arm away from hot stove
  • brain route message is routed up spinal cord to
    brain (CNS)
  • note central nervous system spinal cord
    brain

14
Cognitive Neuroscience Intro
  • Basic elements of nervous system
  • synapse region where the axon terminals of one
    neuron and dendrites of another neuron come
    together
  • synapses are small gaps between neurons
  • any single neuron synapses on a large number of
    other neurons called divergence (a typical
    neuron synapses on from 100-15,000 other neurons)
  • also any single neuron is the destination of many
    neurons (called convergence)

15
Cognitive Neuroscience Intro
  • Basic elements of nervous system
  • information is transmitted across a synapse
    chemically by means of a neurotransmitter
  • a neurotransmitter is released from small buttons
    or sacs in the axon terminals, which then fit
    into receptor sites on the dendrites of the next
    neuron
  • two types of neurons inhibitory and excitatory
  • inhibitory neurons decrease the likelihood of the
    next neuron from firing excitatory neurons have
    the opposite effect

16
Cognitive Neuroscience Intro
  • Structure of Nervous System
  • Nervous system consists of two major parts
    central nervous system (CNS) and peripheral
    nervous system (PNS)
  • PNS consists of skeletal nervous system and
    autonomic nervous system
  • Skeletal system controls striated (i.e., striped)
    muscles, which are under voluntary control, and
    play an important role in motor cognition and
    simulation

17
Cognitive Neuroscience Intro
  • Structure of Nervous System
  • autonomic nervous system governs smooth muscles
    and some glands
  • Smooth muscles, found in heart, blood vessels,
    stomach lining, and intestines, are not usually
    under voluntary control

18
Cognitive Neuroscience Intro
  • Structure of Nervous System
  • autonomic nervous system plays a key role in
    emotion and affects memory functioning
  • Autonomic nervous system is divided into
    sympathetic and parasympathetic nervous system

19
Cognitive Neuroscience Intro
  • Structure of Nervous System
  • sympathetic nervous system prepares animal to
    respond more vigorously in an emergency
    (flight-or-fight response). Some changes
  • Increasing heart rate (and delivering more oxygen
    and nutrients to organs)
  • Increasing breathing rate (and providing more
    oxygen)
  • Dilating pupils (increasing sensitivity to light)
  • Reducing digestive function

20
Cognitive Neuroscience Intro
  • Structure of Nervous System
  • parasympathetic nervous system counters
    sympathetic nervous system and dampens the
    organisms responses

21
Cognitive Neuroscience Intro
  • Cerebral cortex (Overview)
  • Brain should be thought of as a collection of
    components that work together
  • It consists of two halves, which are called the
    left and right cerebral hemispheres
  • Hemispheres are connected by a massive collection
    of nerve fibres called the corpus callosum, as
    well as several smaller connections

22
Cognitive Neuroscience Intro
  • Cerebral cortex (Overview)
  • Beneath the skull is a membrane covering the
    brain called the meninges
  • Beneath that is a network of blood vessels
    clinging to the surface of the brain
  • The surface of the brain contains most of the
    cell bodies of the neurons, which have a gray
    colour, hence the term gray matter

23
Cognitive Neuroscience Intro
  • Cerebral cortex
  • cortex consists of 4-6 layers of cells (or gray
    matter)
  • the term cortex (bark) refers to any outer layer
    of cells
  • conventionally the terms cortex and neocortex are
    used interchangeably
  • the cortex is wrinkled in order to increase its
    area (think of crumpled paper)

24
Cognitive Neuroscience Intro
  • Cerebral cortex
  • Clefts (indentations) in the brain are called
    fissures if they extend deeply into brain or
    sulci if they are shallower
  • A ridge in the cortex is called a gyrus

25
Gyri and sulci. Lateral (A) and medial (B) views
of the gyri. Lateral (C) and medial (D) views of
the sulci
26
Cognitive Neuroscience Intro
  • Subcortical structures
  • Beneath the cortex are found subcortical
    structures and at the centre of the brain are a
    series of cavities, called ventricles
  • Ventricles are filled with the same fluid that is
    found in the spinal cord

27
Cognitive Neuroscience Intro
  • hemispheres and lobes
  • cortex consists of two hemispheres separated by
    the medial longitudinal fissure
  • each hemisphere is divided into four lobes
  • frontal lobe (behind forehead)
  • temporal lobe (underneath temples)
  • occipital lobe
  • parietal lobe

28
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29
The location of the frontal, parietal, occipital,
and temporal lobes of the brain
30
Cognitive Neuroscience Intro
  • Lobes
  • The cognitive activities are not assigned
    specifically to one of the lobes and the lobes
    are involved in several cognitive activities
  • A rough guide
  • occipital lobes
  • processes visual input from eyes and from
    memory (visual imagery, some)
  • Within the occipital lobe specific different
    regions process different aspects of vision
    (e.g., motion, color, shape)
  • if occipital lobes are damaged blindness results

31
Cognitive Neuroscience Intro
  • Lobes
  • temporal lobes
  • Involved in several functions
  • Retention of visual memory
  • Matching visual input to visual memory
  • Process input from the ears
  • Posterior region of the left temporal lobe
    (Wernickes area is crucial for comprehending
    language
  • Anterior regions of temporal lobes are crucial
    for processing new memories, deriving meaning,
    and processing emotion

32
Cognitive Neuroscience Intro
  • Lobes
  • Parietal lobes
  • Involved in several functions
  • Its most anterior gyrus, the somatosensory cortex
    (area S1), represents sensations on different
    parts of your body with left S1 representing
    right side of body and vice versa for right S1
  • Parietal lobes are also involved in representing
    space and your relationship to it, and in
    representing tool knowledge

33
Cognitive Neuroscience Intro
  • Lobes
  • Frontal lobes
  • Involved in several functions
  • Managing sequences of behaviors or mental
    activities
  • Major role in producing speechBrocas area of
    left hemisphere
  • Controlling movements area M1 (most posterior
    gyrus of frontal lobes (also called motor strip)
    this area is immediately adjacent to S1
  • Left M1 controls movements by right part of body
    and vice versa
  • Frontal lobes also involved in memory retrieval,
    in planning and reasoning, and in some emotions

34
Cognitive Neuroscience Intro
  • Projection maps
  • constructed by tracing axons from sensory systems
    into the brain, and by tracing axons from the
    neocortex into the motor systems of the brain
    stem and spinal cord

35
Cognitive Neuroscience Intro
  • Projection maps
  • dark areas in figure are primary projection
    areas. These areas receive input from the sensory
    systems or project to the spinal motor systems
  • lightly shaded areas receive projections (input)
    from the primary projection areas and are called
    secondary projection areas
  • unshaded areas are called higher-order
    association or tertiary areas

36
Cognitive Neuroscience Intro
  • Topography of the neocortex
  • primary projection areas
  • visual system--occipital lobes
  • auditory system -- temporal lobes
  • somatosensory system -- parietal lobes
  • motor system -- frontal lobes

37
A projection map
38
Subcortical structures
39
Cognitive Neuroscience Intro
  • Subcortical areas
  • thalamus consists of several nuclei all sensory
    systems except for smell have relays here on
    their way to cortex also different cortical
    regions communicate with each other via thalamus

40
Cognitive Neuroscience Intro
  • Thalamus
  • consists of two symmetric nuclei at base of
    cerebral hemispheres superior to hypothalamus
  • each hemisphere contains half of the thalamus
  • thalamus receives ascending input (sensory
    information) and descending input from cerebral
    hemispheres, particularly from those cortical
    regions to which it projects
  • all sensory systems except for smell have relays
    here on their way to cortex

41
Cognitive Neuroscience Intro
  • Thalamus
  • can be thought of as a complex relay station for
    sensory and motor systems except for olfaction
    (smell)
  • thalamus is thought to play an important role in
    the classification, integration of information,
    before sending it to the cortex for further
    processing

42
Cognitive Neuroscience Intro
  • Thalamus
  • Thalamus also plays an important role in
    selective attention
  • Pulvinar nucleus (a nucleus refers to a cluster
    of cells) is involved in focusing attention

43
Cognitive Neuroscience Intro
  • hypothalamus composed of small nuclei involved
    in feeding, sexual behaviour, sleeping,
    temperature regulation, blood pressure, heart
    rate, etc.
  • Some of these functions are accomplished by
    hormones (chemicals that affect various organs)
  • Hippocampus located at the anterior end of the
    temporal lobes it plays a central role in
    entering new information into memory although it
    is not where memories are stored it governs
    processes that allow memories to be stored

44
Cognitive Neuroscience Intro
  • Amygdala (named, from Greek, because of its
    almond shape) plays an important role in the
    appreciation of emotion in others and in the
    expression of our own emotion (esp. fear)
  • The amygdala can modulate the functioning of the
    hippocampus this helps you store vivid memories
    of highly emotional information
  • The amygdala and hippocampus along with other
    structures are part of the limbic system, which
    used to be thought to regulate emotion

45
Model of the human limbic system and its major
structures
46
Cognitive Neuroscience Intro
  • Basal ganglia
  • collection of nuclei lying beneath the anterior
    regions of the neocortex
  • include the putamen (shell), the globus pallidus
    (pale globe), the caudate nucleus (tailed
    nucleus), and the amygdala (almond). Note
    striatum putamen caudate globus pallidus
    pallidum
  • caudate nucleus receives projections from all
    parts of the neocortex and then projects through
    the putamen and globus pallidus to the thalamus,
    and then to the motor areas of the cortex

47
Cognitive Neuroscience Intro
  • Basal ganglia
  • basal ganglia also has reciprocal connections to
    the substantia nigra (black area)
  • this projection provides dopamine to the basal
    ganglia when dopamine is lost a motor disorder
    called Parkinsons disease results

48
Cognitive Neuroscience Intro
  • Basal ganglia
  • functions of basal ganglia
  • involved in motor function--including postural
    changes, sequencing of movements into a smoothly
    executed response, and habit learning
  • Habit learning (e.g., development of routinized
    activities such as coming to this lecture hall)

49
Relation between the basal ganglia and the
cortex. Arrows indicate theoretical projections
of the various areas into basal ganglia structures
50
Cognitive Neuroscience Intro
  • Brainstem
  • Includes the pons and medulla and reticular
    formation
  • regulates many movements of animals
  • responds to sensory features of the environment
  • regulates eating, sleeping, drinking, body
    temperature

51
The three divisions of the brain
52
Cognitive Neuroscience Intro
  • Topography of the neocortex
  • The remaining functional neuroanatomy slides,
    about 6, contain additional useful, reference
    information
  • You will not be tested on this material

53
Medial view through the center of the brain
showing structures of the brainstem
54
Cognitive Neuroscience Intro
  • Topography of the neocortex
  • cytoarchitectonic maps
  • constructed by examining the neurons in the
    neocortex to identify regions that have unique
    organization
  • the best known of these is called Brodmanns map
    shown in Figure 3.9

55
Brodmanns areas of the cortex
56
Cognitive Neuroscience Intro
57
Cognitive Neuroscience Intro
58
The First Brain Imaging Experiment
and probably the cheapest one too!
Angelo Mosso Italian physiologist (1846-1910)
In Mossos experiments the subject to be
observed lay on a delicately balanced table which
could tip downward either at the head or at the
foot if the weight of either end were increased.
The moment emotional or intellectual activity
began in the subject, down went the balance at
the head-end, in consequence of the
redistribution of blood in his system. --
William James, Principles of Psychology (1890)
Courtesy J. Culham, Robarts Research Institute
59
Brain imaging and cognition
  • Brain imaging techniques
  • early 1970s x-ray computed tomagraphy or x-ray CT
    technique developed
  • when highly focused x-rays are passed through the
    body, the beam is affected in predictable ways by
    the relative density of the tissue
  • by passing a beam through the body at many
    different angles it becomes possible (using
    sophisticated math techniques) to re-construct an
    image of the body

60
Brain imaging and cognition
  • Brain imaging techniques
  • this technique led to the development of Positron
    Emission Tomography (PET)
  • PET also built on a technique known as
    autoradiography

61
Brain imaging and cognition
  • autoradiography
  • radioactive labeled compound is injected into
    organism
  • experiment is performed
  • organ is removed and sectioned
  • individual slices are placed on film which is
    sensitive to radioactivity

62
Brain imaging and cognition
  • PET
  • PET also uses radioisotopes but does not require
    organs to be removed
  • PET uses radioisotopes that have positrons that
    emit gamma radiation that can be detected by
    sensors outside of the head

63
Brain imaging and cognition
  • PET (how it works)
  • a PET camera is a set of radiation detectors that
    circle the subjects head
  • subject is injected with positron-emitting
    radioactive isotope oxygen-15 (half-life about 2
    minutes)
  • radioactive water accumulates in brain in
    proportion to the local blood flow
  • the greater the blood flow the more radiation
    counts recorded by PET

64
Brain imaging and cognition
  • PET (experimental strategy)
  • Paired image subtraction
  • record image of subject while she is performing
    an experimental task
  • record image of subject while she is performing a
    control task
  • (e.g., dots in motion - stationary dots)
  • difference tells us what brain regions are
    associated with representation of motion

65
Brain imaging and cognition
  • PET (experimental strategy)
  • to eliminate noise or random variation, the
    differenced images are averaged across subjects
  • the slide on the following page illustrates the
    strategy
  • row 1-- experimental - control difference
  • row 2 -- individualized difference images
  • row 3 -- mean difference image

66
(No Transcript)
67
Brain imaging and cognition
  • Disadvantages of PET
  • Invasive
  • Poor temporal resolution
  • Expensive

68
Brain imaging and cognition
  • What is MRI and fMRI
  • MRI uses strong magnetic fields to create images
    of biological tissue
  • The strength of the magnetic field created by an
    MRI scanner is measured in Tesla
  • MRI scanners are typically 1.5 3.0 Tesla
    (earths magnetic field is 0.00005 Tesla
  • Refs Smith and Kosslyn (2007) Huettal, Song,
    McCarthy (2008) functional magnetic resonance
    imaging

69
Brain imaging and cognition
  • What is MRI and fMRI
  • To create images the scanner uses a series of
    changing magnetic gradients and oscillating
    electromagnetic fields known as pulse sequences
  • These electromagnetic fields result in energy
    being absorbed and then emitted by atomic nuclei
    in the tissue being examined
  • The amount of emitted energy depends upon the
    number and type of nuclei present, thus creating
    an image of the tissue being examined

70
Brain imaging and cognition
  • What is MRI and fMRI
  • MRI structures brain structure
  • Important to study brain structure when it is
    suspected there is neurological change to brain
    (e.g., stroke, dementia)
  • fMRI is designed to reveal short-term
    physiological changes associated with the active
    functioning of the brain it can also reveal
    patterns of brain activation associated with
    these changes

71
MRI vs. fMRI
Functional MRI (fMRI) studies brain function.
MRI studies brain anatomy.
Courtesy J. Culham, Robarts Research Institute
72
fMRI Setup
Courtesy J. Culham, Robarts Research Institute
73
Brain imaging and cognition
  • MRI (overview)
  • many atoms in the presence of a magnetic field
    behave like little bar magnets or compasses
  • that is, they line up in a particular orientation
  • when a radio wave is applied to this aligned
    sample, the sample emits detectable radio signals
    characteristic of the chemical environment

74
Brain imaging and cognition
  • fMRI
  • functional magnetic resonance imaging
  • nuclear magnetic resonance (NMR) image intensity
    reflects the concentration of water in the sample

75
Brain imaging and cognition
  • fMRI
  • To map brain function it is necessary to create
    images that distinguish between active and
    inactive brain regions
  • Called functional contrast
  • This is done by measuring the metabolic
    consequences of neuronal activity

76
Brain imaging and cognition
  • fMRI
  • (BOLD) contrast is a sensitive MRI marker of
    neuronal activity
  • How BOLD works
  • Red blood cells contain hemoglobin
  • the iron ion in hemoglobin can have oxygen bound
    to it or stripped off

77
Brain imaging and cognition
  • fMRI
  • How BOLD works
  • When brain functions it draws in more red blood
    cells than it needs by detecting extra
    oxygenated blood cells BOLD signal detects brain
    activity

78
Brain imaging and cognition
  • fMRI
  • fMRI contrast is tailored to optimize the signal
    dependence on deoxyhemoglobin concentration
  • deoxyhemoglobin is used as a contrast agent
  • this so called, blood oxygenation level dependent
    (BOLD) contrast is a sensitive MRI marker of
    neuronal activity
  • MRI signal arises from the stimulation of
    transitions of hydrogen atoms in water, placed in
    a large field

79
Brain imaging and cognition
  • Parameters of neuroimaging data
  • Spatial resolution
  • Refers to the ability to distinguish between
    different locations within an image
  • In 2-dimensional pictures, a pixel refers to the
    smallest picture element that can be resolved.
  • In a satellite photo of a large region a picture
    element might represent hundreds of metres,
    whereas a zoom picture of a region might
    represent 1 metre

80
Brain imaging and cognition
  • Parameters of neuroimaging data
  • Spatial resolution
  • In MR images, 3-dimensional samples of the brain
    are obtained and the smallest resolvable 3-D
    element is called a voxel in MRI, voxels are
    often 1 to 2 mm, in each dimension, whereas in
    fMRI, voxels are 3 to 5 mm on each side

81
Brain imaging and cognition
  • Parameters of neuroimaging data
  • Temporal resolution
  • Factors affecting temporal resolution include
  • 1. the rate at which an imaging technique obtains
    its images (sampling rate)
  • 2. the sluggishness of the physiological process
    being measured in fMRI BOLD measures blood
    oxygenation, a relatively slow process

82
Brain imaging and cognition
  • fMRI (Experimental strategy)
  • acquire MR images while subjects are presented
    with blocks of stimulation (experimental) for
    about 30 seconds
  • have control or baseline activity
  • subtract one from the other

83
Brain imaging and cognition
  • fMRI
  • echo-planar imaging (EPI)
  • this technique commonly used to obtain images
  • multi-slice EPI is acquired by first exciting an
    nuclear magnetic resonance (NMR) signal from a
    thin-slice of the head, using a shaped RF pulse
    in the presence of a rapidly switched magnetic
    field gradient
  • this generates a series of echoes of the NMR
    signal that can then be used to construct a
    2-dimensional image of the slice

84
Brain imaging and cognition
  • fMRI
  • echo-planar imaging
  • volume data are built up by repeating the process
    of image acquisition at different slice positions
    (40 slices commonly used to cover the brain)
  • TR refers to the time between repeated
    acquisitions of the same slice
  • a common set of parameters is 100 ms per slice x
    50 slices 5 seconds (TR 5 seconds)
  • a parameter, TE, is defined as the time needed to
    generate half of the echoes for a single slice

85
Brain Imaging Anatomy
CAT
Photography
PET
MRI
Source modified from Posner Raichle, Images of
Mind
Courtesy J. Culham, Robarts Research Institute
86
Brain imaging and cognition
  • Disadvantages of fMRI
  • Poor temporal resolution
  • Machines are
  • Expensive
  • Noisy
  • Tube narrow, which some people find upsetting

87
Brain imaging and cognition
  • PET and fMRI are correlational methods
  • That is, they correlate areas of brain activation
    that accompany information processing when
    performing a task
  • Correlation does not necessarily imply causation
  • Brain regions that are activated may not
    necessarily play a functional role in performing
    the task
  • Hence these methods only suggest which brain
    regions may process information when performing a
    task

88
Brain imaging and cognition
  • PET and fMRI are correlational methods
  • Data from PET and fMRI can be used to compare 2
    (or more) tasks to determine whether the same or
    different brain regions are activated
  • If different brain regions are activated, this
    suggests that these tasks are carried out by
    different processes
  • If the same brain regions are activated, this
    provides evidence to support the claim that
    similar processes are involved in performing the
    2 tasks

89
Brain imaging and cognition
  • Limitations of neuroimaging methods
  • Excitatory and inhibitory activity cannot be
    distinguished
  • More activation does not necessarily mean more
    processing
  • Same functional areas may be located in slightly
    different brain areas making averaging across
    participants difficult
  • Brain is always active making it difficult to
    know what processing is going on during
    baseline condition (note neuroimaging methods
    usually involve comparison of a treatment to a
    control condition
  • Finding of no activity is difficult to
    interpretcould mean process is active in both
    conditions, inactive in both conditions or
    activation is subtle
  • Different processes appear to be implemented in
    the same area (e.g., different neurons in area 17
    process colour and shape)

90
Brain imaging and cognition
  • Other correlational methods
  • Other correlational methods are called
    electroencephalography (EEG) event-related
    potentials (ERP)
  • In both of these methods electrodes are placed
    on the scalp
  • EEG records fluctuations in electrical activity
    over time, at different bands or sets of
    frequencies (e.g., 8 12 cycles per second)
  • ERP uses electrodes to observe fluctuations in
    activity relative to presentation of a stimulus
    (e.g., P300 is a positive fluctuation that is
    observed 300 milliseconds after a stimulus
  • Both ERP and EEG have disadvantages 1. Both are
    sensitive to muscle twitches because muscles
    produce electrical activity when they twitch 2.
    spatial resolution poor because electrical
    activity detected comes from spatially
    distributed regions

91
Method Spatial Res Temporal Res Invasive-ness
EEG Poor (1 inch) Excellent (ms) Low
ERP Poor (1 inch) Excellent (ms) Low
PET Good (about 1cm) Poor High
fMRI Good (about .5 cm) Poor Low
92
Brain imaging and cognition
  • Causal neural methods
  • It is also possible to use other methods to
    establish causal connections between brain
    activation and behavioral performance
  • Classic method is the neuropsychological patient
    study
  • Logic is straightforwardif a brain region plays
    a key role in carrying out a task, a patient with
    damage to that region should be impaired in
    carrying out that task

93
Brain imaging and cognition
  • Causal neural methods
  • Brain damage can occur for a variety of reasons
    including
  • Stroke or other medical conditions that result in
    disruption of blood flow to the brain (e.g.,
    heart attack)
  • Brain surgery (e.g., to remove a tumor)
  • Traumatic brain injury (e.g., MVA, assault)
  • Brain-damaging toxins (e.g., certain drugs
    including alcohol)
  • Brain-damaging diseases (e.g., Alzheimers,
    Parkinsons)

94
Brain imaging and cognition
  • Causal neural methods
  • Limitations of neuropsychological studies
  • Brain damage usually affects a large area of
    neural tissue
  • It is possible that brain damage results in a
    change in the functioning of the brain as a whole

95
Brain imaging and cognition
  • Causal neural methods
  • Lesions indicate necessity of region, but not
    sufficiency i.e., other brain regions may also
    be necessary for function
  • E.g., think of a radio that wont play music
    examination of the radio revealed that its
    speakers were broken conclusion that speakers
    are necessary for music to play is correct
    however, it does not mean that a radio with
    undamaged speakers will necessarily play (e.g.,
    think of a radio with a broken switch)

96
Brain imaging and cognition
  • Causal neural methods
  • Note a given brain region may have more than one
    function

97
Brain imaging and cognition
  • Causal neural methods
  • Another causal neural method is Transcranial
    magnetic stimulation (TMS)
  • In this method brain processes of a small,
    circumscribed area of the brain are disrupted (1
    cubic cm)
  • A coil is placed on the participants head and a
    current is run through the coil, which disrupts
    the neural areas of the brain beneath the coil
  • 2 versions of TMS
  • Single pulse TMS delivers a single pulse to
    specific brain area repetitive TMS (rTMS)
    delivers a series of pulses to specific brain
    area before a task is performed
  • If enough pulses are delivered, this has the
    effect of temporarily disrupting neural
    processing of specific brain area (like inducing
    a specific lesion)

98
Brain imaging and cognition
  • Causal neural methods
  • Limitations of rTMS
  • Stimulating 1 brain area can affect other areas
    making it difficult to infer which area is
    responsible for effects
  • rTMS can induce seizures if it is not used
    according to safety guidelines
  • rTMS can be used to investigate only those
    regions directly below the skull

99
Brain imaging and cognition
  • Limitations of neuroscience methods
  • As this overview shows, each neuroscience method
    has strengths and weaknesses
  • This is why neuroscientists rely on evidence from
    a variety of different methods (converging
    evidence) to understand which cognitive processes
    and brain regions perform specific tasks
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