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Psychophysiological Methods

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Title: Psychophysiological Methods


1
Psychophysiological Methods
2
Electrodermal Measurement
  • Galvanic skin response as indicative of the
    sympathetic branch of the autonomic nervous
    system
  • Sweat glands provide a shunt between skin and
    deeper tissues
  • Measures indicative of arousal, stress-strain,
    and emotion
  • Autonomic habituation provides a physiological
    measure of information processing capacity needed
    to complete a task
  • Used as measure of workload, mental strain, and
    emotional strain.

3
Procedure
  • Sampling across various locations of the body
  • Typically 3-4 cm distance between electrodes
    sampling dc current using a bioampifier
  • Sampling at 20hz sufficient to calculate Skin
    Conductive Response (SCR)
  • Amplitude, rise time and recovery time are
    measured
  • May be used to determine tonic Electrodermal
    Activity (EDA) to measure readiness for action

4
Three-Arousal Method of Measurement for the use
of Psychophysiology in Ergonomics
5
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6
Typical Epidermal Response
7
Advantages/Disadvantages
  • Easy to measure and interpret the physiological
    signal
  • Pure measure of the sympathetic branch of the ANS
  • Sensitivity to workload and emotional strain
  • Somewhat difficult to record
  • Prone to artifacts in non-laboratory settings
  • Indiscriminately sensitive to any ANS activity
  • Several months of lab training to be able to use
    plus training for use in an ambulatory setting

8
Reliability/Validity
  • Short term reliability (within days) is fairly
    good (.80 to .90)
  • Longer term reliability is more limited (.60)
  • Tonic EDA more reliable than SCL (test-retest
    correlations of .76 and .61 at one year)
  • Validity at or above .90 for EDA-Emotional
    strength in LAB setting
  • No similar data for applied settings
  • Validity based more on strength of emotion
    related to strain than physical relationship
  • Heart rate and BP are yield better validity than
    EDA (.68 to .86)

9
Electromyography
  • Studies muscle function using electrical analysis
    of signals emanating at muscle contraction
  • Motor activity
  • Anterior horn of the spinal cord, transmitted via
    alpha motor neurons to muscle
  • Each muscle fiber consists of multiple chains of
    contractile sarcomeres (actin-myosin-filaments)
  • These filaments create muscle contraction
  • Motor unit chemically activates the muscle fibers
    connected as myoneural junction is depolarized
    (amplitude of about 100mV with a 2-14msec
    duration
  • Muscle action potential causes sarcomeres to
    contract
  • Electrodes in tissue or skin can measure these
    action potentials (electrolytic response)

10
EMG (continued)
  • Muscle force defined by motor units activated
  • EMG forms a quasi-randomly shaped spikes of
    amplitude and duration but no identifiable
    sequence
  • Correlation between number and intensity of
    generation of amplitude spikes and muscle
    contraction force
  • Remember, doesnt measure force, joint position
    but rather voltage associated with local muscle
    recruitment

11
Use of EMG in the Workplace
  • Used for workplace and tool design
  • Muscle load (static and dynamic)
  • Local muscle fatigue due to overload
  • Muscle timing and coordination
  • Motor-unit recruitment
  • EMGs complemented by use of measures of external
    load, body posture, joint measurement
  • EMGs can be performed with needle electrodes
    inserted into muscle or surface electrodes

12
Procedure
  • Placement of electrodes or needles in muscles,
    signal passed to preamplifier, processed with
    band-pass filters for frequencies related to
    muscular activity
  • Select muscles related to action (may depend on
    how specific you want to be measuring potential
    between muscle and ground
  • Amplify, filter and store results
  • Signal Processing
  • Scaling

13
Surface EMG Signal Processing
14
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15
Correlation between feedback control and
execution speed during learning an assembly task
16
EMG Advantages/Disadvantages
  • Continuous and quantitative measured data
  • High temporal resolution with marginal
    interference with task execution
  • Allows detection of muscle fatigue at early
    stages providing objective measure
  • Multi-channel EMG can identify muscular
    bottle-necks
  • Surface EMG limited to muscles directly beneath
    area accessed by skin electrode
  • Only feasible for single muscles in individuals
    not too obese
  • Requires careful calibration, instrumentation,
    data manipulation, and interpretation
  • Setup is fairly time consuming
  • Interpretation requires data analysis and data
    integration
  • Calibration lacks reliability
  • Requires individual calibration, poor reliability
  • Needle method more specific but invasive and
    quite painful

17
Heart Rate/Variability
  • Various Measures
  • Electrocardiogram (ECG)
  • Duration between heartbeats (HR)
  • Mean heart period or Interbeat Interval (IBI)
  • Heart Rate Variability (HRV)
  • Normal Rhythm
  • Cardiac Sinusoidal Mode
  • Modulated by innervations from the sympathetic
    and parasympathetic branches of the ANS
  • Heart Rate
  • Controlled by nuclei in the brain stem and guided
    by the hypothalamus and prefrontal cortical
    structures
  • Two control modes
  • Parasympathetic (Vagal) and Sypathetic output
    (Pores (1995))
  • Mediation of bororeflex activity

18
Use of ECG
  • HRV related to changes in autonomic control
  • Vagal Gating
  • NSR is vagally determined
  • HRV and other cardiovascular variables modulated
    by baroreflex gain.
  • General cardiac response found in mental-effort
    studies characterized by increased HR and BP and
    decreased HRV and BP variability at all
    frequencies
  • Compatible with fight-flight reaction (lab
    studies, short-lasting tasks, challenging mental
    operations in working memory.
  • Mid freq. band most sensitive to variation in
    mental effort due to decreased vagal activation
    and increased sympathetic activation.

19
Procedure
  • Three or 7 lead methods
  • Sampling and R-peak detection
  • Artifact detection and Correction
  • Spectral procedures
  • HR, IBI or Normalized Values?
  • Logarithmic Transformation

20
Disadvantages
  • HR and HRV used as indicators of mental effort
  • Higher invested effort, higher HR and lower HRV
  • Complex relationship between HR with baroreflex
    BP control and autonomous nervous activity
  • Most stable results only really found in lab
    settings
  • Restrictions in sensitivity for artifacts in
    obtained IBI series and sensitivity for changes
    in respiration
  • Artifact correction time consuming
  • Newer technologies are mitigating some of these
    limitations

21
Reliability and Validity
  • R and V of HR and HRV in short duration mental
    loading lab results usually high
  • Doesnt hold for practical settings
  • Diagnostic validity and reliability debated
  • Sensitivity of the measure not very high
  • Difficult to distinguish levels of task load and
    related invested effort
  • Requires multiple data collection sessions on
    single subject
  • Validity affected by fight-flight mechanism
    versus compensatory mechanisms

22
Ambulatory EEG Methods
  • Sleepiness linked with accidents (Comair 5191)
  • Sleep loss, long time awake, work at circadian
    trough of physiological activation and alertness,
    monotony
  • Effects of drugs, alcohol, sedative, hypnotics,
    antihistamines all can have an effect.
  • Concept of sleepiness (various components)
  • Subjective
  • Behavioral
  • Physiological

23
Methods
  • EEG sum of electrical brain activity
  • Recorded at scalp or needle electrodes
  • When alertness falls, frequency of EEG falls and
    amplitude increases as more neurons synchronized
    to fire by the thalamus (rational behind EEG
    indicator of sleepiness)
  • Progression from Alpha (8-12Hz) to Theta (4-8Hz)
    to Delta (0-2Hz)

24
Procedure/Example
  • See text for in depth discussion of procedure for
    setup and use of EEG and EOG.
  • Example 12.1 shows EEG/EOG pattern in severe
    sleepiness performing a task and demonstrates
    beta activity, increased alpha activity, eye
    closure, slow eye rolling movements, and dozing
    off, reappearing beta activity, return of eye
    blinks

25
EEG/EOG Recording
26
Application/Training
  • Application takes 15-30 minutes minimum for
    electrode placement
  • Learning to setup takes 10-20 hours for reliable
    recording
  • Scorring takes several months to learn
  • Requires repeated quality checks

27
Reliability/Validity
  • No formal reliability established for ambulatory
    EEG methods
  • Hard to define due to the definitions of the
    measures and the changing nature of the measure
  • Several studies have defined validity between
    subjective sleepiness and sleepiness-impaired
    performance
  • Purposeful interaction with the environment not
    possible when EEG dominated by alpha/theta and
    slow eye movements

28
Event Related Potentials (ERPs)
  • ERP Transient series of voltage oscillations
  • Recorded from the scalp
  • Response to direct stimuli and responses
  • Often defined in terms of polarity and minimum
    latency with respect to discrete
    stimulus/response
  • Found to reflect perceptual, cognitive, motor
    processes
  • Useful to decompose processing requirements of
    complex tasks (Fabiani et al., 2000)

29
Procedure
  • Experimental paradigm design
  • Subject preparation
  • Preparation of ERP data for analysis
  • Component definition and pattern recognition
  • Data analysis

30
Advantages/Disadvantages
  • We possess understanding concerning functional
    significance of different ERP components
  • Brain regions from which component generated are
    known
  • ERPs can be obtained in absence of operator
    action/performance
  • Motion artifacts
  • Require discrete stimulus or response
  • Substantial training required for recording,
    analysis, interpretation

31
Sample ERP Outputs
32
Training/Application Times
  • Depends on whether you want to learn the basics
    (2 months) or become knowledgeable about the
    basis of ERP signals (advanced degree)
  • Application times from 15min for a few electrodes
    to 45min for large electrode array

33
Reliability/Validity
  • Validity of ERP components to specific cognitive
    constructs convincingly demonstrated
  • Reliability established through extensive
    replications
  • Split-half reliability high for P300 amplitude
    (.92) and latency (.83)
  • Test-retest reliability over several days for
    P300 amplitude .83 and P300 latency .63

34
EEG/MEG/fMRI
  • Neural activity generates currents outside the
    skull which can be monitored by their electrical
    and magnetic fields
  • Electroencephalogram (EEG)
  • Magnetoencephalogram (MEG)
  • Magnetic Resonance Imaging (MRI)
  • Functional MRI (fMRI)
  • Provide a basis for examining the neural
    substrate of specific cognitive processes

35
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36
Research Areas amenable to MEG fMRI
  • Movement-related brain activation
  • Memory processes (encoding retrieval)
  • Visual perception, attention, selection
  • Auditory perception, attention selection
  • Language production and processing
  • Perception of music
  • Learning and brain plasticity with respect to
    cognitive functions
  • Uses
  • Neurosurgery
  • Localization of epileptic foci based on specific
    brain areas spiking
  • Estimation of the impact of certain lesions on
    higher neural functioning
  • MEG preferred for temporal resolution fMRI for
    spatial resolution and maximum information
    when/where the two methods can be combined.
  • Limited to patients without ferromagnetic inserts

37
MEG/fMRI Mechanisms
  • Requires use of superconducting quantum
    interference devices (SQUIDs)
  • Exploit quantum mechanical Josephson-effect
  • Modern MEG systems monitor signals from 150-300
    SQUIDs spread equally over the head surface
  • Variants of MEG sensors known as Gradiometers
  • Spin tilt of protons aligned with strong magnetic
    field is pertubated by a brief electromagnetic
    pulse
  • Protons emit burst of RF energy as they return to
    their initial aligned state
  • Strength of signal with particular RF signature
    allows determination of proton density
  • Helps define tissue characteristics at that
    location

38
Procedure (MEG)
  • Helmet like gantry placed over subjects head
  • Coils fixed on head provide weak magnetic sources
    known as anatomical sites.

39
fMRI
  • Subject reclined on movable gantry, shifted into
    the bore of a magnet.
  • Structural scan
  • Repeated functional scans

40
Experimental Setup
  • During session, sequence of visual or auditory or
    other sensory stimuli is presented to the subject
    who has to process them according to a predefined
    task.
  • Often the same or similar stimuli are presented
    with slightly different task requirements
  • Differences between the BOLD responses in the
    different experimental conditions are evaluated
    to determine what brain regions are specifically
    activated by a particular task or sensory input

41
MEGData Analysis
  • Event-locked epochs initially averaged separately
    for each subject, channel (sensor), task, or
    condition
  • Epochs containing artifacts are rejected or
    correlated
  • Grand average waveforms are scanned for
    components (peaks/troughs)(50-100msec)
  • Time/amplitude measurements determined for each
    component, task, subject.
  • Statistical analysis to ascertain significant
    differences which are localized to a region of
    the brain
  • Various co registration techniques possible using
    nonlinear parameters, algorithms from chaos
    theory
  • Analyzing continuous MEG data is based on chaos
    theory and beyond the scope of this class

42
fMRI Data Analysis
  • Continuously recorded fMRI/BOLD data sorted
    according to different stimulus/task condition
  • Any distortions are corrected by a processing
    algorithm.
  • Those functional images showing significant
    differences in activation levels at the level of
    the individual voxels
  • fMRI permits single subject statistical analysis
    due to better signal to noise ratios
  • Comprehensive evaluation packages are available
  • Statistical parametric mapping (SPM) package
  • Also advanced applications that deconvolve
    temporally overlapping BOLD responses

43
Sample MEG Data
44
Sample fMRI Data
45
Training
  • Predefined protocols performed by techs after two
    week training period
  • For more advanced/sophisticated applications, at
    least one full time engineer or physicist should
    be available (6 month training).
  • In clinical setting, support of a dedicated
    physician is required for data interpretation
  • Neuroscientists should have a sound background in
    experimental design as well as neurophysiological
    education. Specific training per investigations
    being conducted
  • Joint program between Emory and Georgia Tech
    provides degree and background in medical physics

46
Test Times
  • Experimental run may require about 1.5 hours with
    15 minutes additional subject preparation

47
MEG Reliability/Validity
  • MEG
  • Artifacts can be minimized but not eliminated
  • Raw signals, an experienced rater can recognize
    these distortions
  • Potential artifacts depend on s/n
  • Avoid misinterpretation of waveform
  • Reasonable solutions possible but not foolproof.
  • Reliability and validity rely on users experience

48
fMRI Reliability/Validity
  • fMRI
  • Continuous maintenance should result in
    acceptable raw images
  • Artifacts due to discontinuities in magnetic
    susceptibility can lead to low structural
    distortions and signal loss
  • Easily detected but not readily corrected
  • Errors can be introduced to statistical analysis
  • Even with formal fMRI handling correct, erroneous
    conclusions may be drown from data obtained using
    inappropriate experimental designs
  • Reliability and validity of fMRI method also
    relies on user experience

49
Blood Pressure Measures
  • Strain affects mood and behavior
  • Performance and physiological effort have used
    strain analyses that are only psychological
  • Progress in ambulatory measurement has allowed
    assessment of behavioral, emotional and
    activational interaction with workload under real
    work conditions.
  • Low strain load has been used to investigate long
    term work (fatigue, boredom, vigilance) on health

50
Ambulatory BP
  • Developed clinically to measure physical work
    effects
  • Increased use for psychosocial work
    characteristics
  • Use of portable recorders for non-invasive
    recording

51
Procedure
  • Procure ABPM Device
  • Select work analysis objective methods
  • Develop prequestionnaire about normal activities
  • Maintain diary
  • Prepare BP monitor
  • Fit monitor to subject
  • Instruct subject
  • Subject resumes daily routine
  • Remove BP monitor, collect diaries
  • Transfer data

52
Requirements
  • Must have information about body position and
    motor activity at time of measurement
  • Also should combine measurement with
    psychological data
  • Must assess the nature of strain
  • Include measures of perceived mental load,
    perceived control, mood, motivation

53
Advantages/Disadvantages
  • Can simultaneously record workload and subjects
    strain experience behavior
  • Work-strain-related effects on BP recovery can be
    investigated and assessed
  • ABPM can have an artifact effect on daily
    activity (Hawthorn type effect)
  • May have an effect on subjects sleep

54
Example of Recorded Data
55
Training/Application
  • Investigator experienced in principles of BP
    measurement and interpretation of readings
  • Main and artifact variables on BP
  • Fitting takes 15-20 minutes
  • Subject instruction about inflation/deflation of
    cuff
  • Instruct subject on need for written diary
  • Removal done by investigator with follow up

56
Eye Blink Measures
  • Issues related to alertness/drowsiness
  • Neurobiological products of interaction between
    endogenous circadian pacemaker and homeostatic
    need for sleep
  • Objective biobehavioral signs often require
    intrusive physiological monitoring
  • Growing use of these measures as humans subjected
    to 24 hour workdays
  • Technological improvements are making measurement
    more affordable and less obtrusive
  • PERCLOS

57
Procedure
  • Use infrared, retinal reflectance monitor
  • Uses CCD camera to record eye closure
    measurements in real time
  • General use of two cameras situated at 90 degree
    angle
  • 850-nm filtered bright eye camera and a 950-nm
    filtered dark-eye (dark pupil) image
  • Calculate the changes in brightness of pupil
    based on average brightness

58
Sample Pupil Imaging
59
Advantages/Disadvantages
  • Availability of on-line, near-real-time,
    automated slow eyelid PERCLOS system unobtrusive
    to user
  • Ideal if used with preset thresholds versus
    self-report
  • Can be used as an investigative and applied tool.
  • May not work in all situations (requires
    restricted FOV)
  • May create artifacts in completion of task
  • Equipment may be too obtrusive in mobile
    real-world applied environment
  • Not ideal in low humidity environments (not able
    to differentiate moistening of eyes and fatigue
    based closure
  • Misuse in safety sensitive environment may
    generate risk.

60
Training/Application
  • No training required other than to teach operator
    to interpret feedback indicating drowsiness
  • Small, fairly easily applied and useful in many
    but not all environments

61
Reliability/Validity
  • Loss of alertness, drowsiness, and hypovigilance
    must be theoretically linked to performance
    deficits
  • Two levels of validation
  • Biobehavioral parameters
  • Specificity of biobehavioral measure used
  • Both reliability and validity must be established
    across dynamic range of performance

62
Human Respiration
  • Respiration linked to a variety of functional
    psychological dimensions
  • Response requirements
  • Appraisal patterns
  • Mental effort investment
  • Various dimensions of emotion
  • Affect
  • Mood

63
Respiratory Measures
  • Assessment of how depth and frequency of
    breathing contributes to ventilation
  • Expressed as tidal volume
  • Frequency is respiration rate (BPM)
  • Measurement of parameters associated with gas
    exchange
  • Breathing cycle

64
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65
Applications
  • Can be used with verbal self report related to
    work
  • Task demands
  • System demands
  • Operator workload
  • Stressful/hazardous aspects of environment
  • Must remain cautious of respiratory changes not
    related to work environment
  • May be secondary or compensatory to respiratory
    volume changes

66
Measurement/Procedure
  • Measure non-obtrusively motions of the rib cage
    and abdomen using an inductive respiratory
    plethysmography device
  • Calibration techniques
  • Often combined with other measures
    (accelerometry, ECG, oximetry, PetCO2
  • Research Design
  • Prepare Subject
  • Physiological Monitoring
  • Data Acquisition/Analysis

67
Equipment
68
Advantages/Disadvantages
  • Valuable in applied studies of complex
    tasks/systems demands/effort investment
  • Combines easily performance-based and subjective
    methods
  • Demonstrates metabolic activity associated with
    task but may be affected by extraneous variables
  • Respiration is intricate interplay between
    brainstem, metabolic, volitional influences
  • Difficult to unravel
  • May not be a convenient measure when interested
    in monitoring oxygen consumption
  • Will the quantification of respiration answer the
    questions which researcher is interested in?

69
Training/Application
  • Considerable investment in time, effort,
    resources to familiarize oneself with the
    underlying physiology, measurement, analysis
    required
  • Basics in a few weeks, expert knowledge much more
    time
  • Application of sensors, calibration, signal
    quality verification varies from 10-30min.

70
Reliability/Validity
  • Problems with reliability related to posture
    changes, movement and respiration related
    movement
  • Possible to filter some of these out but probably
    too complex for automatic filtering
  • Measurement of PetCO2 may pose serious validity
    problems that need to be considered
  • Breathing can vary widely and it may be difficult
    to correlate these changes to changes in work
    requirements
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