Inhibitory Control PDF

Summary

This document provides an overview of inhibitory control, a crucial aspect of cognitive function. It details various aspects of the concept and explores the relationship with other cognitive processes. The paper goes through several studies to uncover the intricacies of this concept.

Full Transcript

11/15/2024

Inhibitory Control
Inhibitory control: Suppression of thoughts or
actions that are no longer required or that are
PSY 376
inappropriate in a situation
Attention and Cognitive Control Considered to be a hallmark of cognitive control,
supporting flexible and adaptive behavior
Inhibitory Control Example (thought): Trying
not to remember a bad day
Example (action): Stopping
your car when a traffic light
turns red
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Response Inhibition Stop Signal Procedure
Response inhibition: Deliberately stopping a Response inhibition can be studied in the lab
motor response with the stop signal procedure
Typically involves interrupting Subjects perform a primary task (“go task”) on
an ongoing action or activity most trials, responding to stimuli
Real-world example: Stopping – Example: Categorizing a shape as square or
yourself from stepping into a circle by pressing left or right keys
busy intersection A stop signal is presented during some trials,
Laboratory example: Stopping indicating the response should be withheld
yourself from pressing a – Example: A tone as an auditory stop signal
response key when instructed – Stop signal delay (SSD): Time from go stimulus
3 onset to stop signal onset 4

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Stop Signal Procedure Stop Signal Procedure
Stop signals randomly occur on a minority of
trials (e.g., 25%)
Therefore, subjects respond to the go stimulus
on most trials

Instructions to subjects:
Respond as quickly and accurately as possible to
the go stimulus when no stop signal occurs
Withhold the response on stop signal trials, but
do not wait for the stop signal to occur
5 – Trial ends automatically after a delay 6

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Stop Signal Procedure Stop Signal Procedure
Dependent measures: Probability of responding to a stop signal
Go reaction time (go RT) (failing to stop) is affected by SSD
– Time to respond to the go stimulus
– RT is variable, producing a go RT distribution Short SSD (stop signal soon after stimulus)
Probability of stopping, p(inhibit|signal) Easy to stop; go task processing has not finished
– Proportion of stop signal trials on which the p(respond|signal) is low
response was successfully inhibited
Probability of responding, p(respond|signal) Long SSD (stop signal long after stimulus)
– Proportion of stop signal trials on which there Hard to stop; go task processing has finished and
was a failure to inhibit the response response execution might be in progress
p(inhibit|signal) + p(respond|signal) = 1.0 7 p(respond|signal) is high 8

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Stop Signal Procedure Balancing Going and Stopping
By measuring p(respond|signal) at varying Success in the stop-signal procedure involves
SSDs, an inhibition function can be obtained balancing competing task demands
Going fast improves RT on most trials but makes
it harder to stop when needed
Long SSD:
Higher value Hard to stop
Short SSD:
means more
failures to stop Easy to stop Response strategies can be adjusted to yield a
tradeoff between going and stopping
Proactive adjustments are made before a trial
Reactive adjustments are made after a stop
(Inhibition functions for each of three subjects doing a letter categorization go signal trial
task with auditory stop signals; data from Logan & Cowan, 1984) 9 10

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Proactive Adjustments Proactive Adjustments
One strategy to increase stopping success is Lappin and Eriksen (1966) results
to prolong go RT when SSD increases Go RT became longer as SSD
increased, suggesting a proactive
Lappin and Eriksen (1966) study response strategy adjustment
Two lights in front of subject
Go task (simple reaction): Press a (Respond) Even with the adjustment, stopping
key when one light is turned on failures [p(respond|signal)] still
Stop signal: Both lights turned on increased with SSD, despite
SSD: Time between lights turning instructions to maintain a constant
on (0, 12, 33, or 63 ms) (Do not respond) rate of successful inhibition
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Proactive Adjustments Proactive Adjustments
Do people adjust go task responding based Verbruggen et al. (2006) results
on the expectation of stop signals?
Go RT longer when stop
signals were expected than
Verbruggen et al. (2006) study when they were not
Go task: Categorize the letters Indicates subjects slowed
making up a large block letter go task responding as a
– Stimulus was congruent/incongruent proactive adjustment to
One half of experiment: No stop signals improve stopping
Other half of experiment: Stop signals (tones) on
30% of trials, SSD adjusted with tracking method
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Reactive Adjustments Reactive Adjustments
Do people adjust go task responding based Rieger and Gauggel (1999) results
on stopping performance?
Go RT longer after stop
signal trial, regardless
Rieger and Gauggel (1999) study of stopping outcome
Go task: Classify a shape as circle or square by Indicates subjects
pressing different keys adjusted go task
Stop signal (tone) occurred on 25% of trials; SSD responding in reaction
to stop signal
adjusted using an alternative tracking method
Examined go RT on current trial based on
previous trial type
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Reactive Adjustments Reactive Adjustments
Verbruggen et al. (2008) study Verbruggen et al. (2008) results
Go task: Classify a shape as circle or square by
pressing different keys Longer go RTs after
failures to stop suggest
Stop signal (tone) occurred on 25% of trials; SSD reactive adjustments
adjusted using the tracking method following errors
Trials presented in pairs in which the stimulus Longer go RT after
repeated or switched across trials in a pair successful stop only for
Examined go RT on current trial based on stimulus repetitions
previous trial type and stimulus transition suggests inhibition can
be stimulus-specific

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Stop Signal Reaction Time Independent Race Model
Stopping is not instantaneous: It takes time to SSRT can be estimated using the independent
encode stop signal and inhibit response race model of Logan and Cowan (1984)

Stop signal reaction time (SSRT): Time from Performance involves a race between a go
stop signal onset to response inhibition process and a stop process
Go process initiated by the go stimulus
Problem: Stopping is a covert process Stop process initiated by the stop signal
Unlike go RT, you cannot directly measure SSRT They “race” against each other and
because there is no overt response when behavior is determined by the
stopping is successful process that finishes first
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Independent Race Model Independent Race Model
Stop process finishes before go process: Model assumes go RTs are variable (resulting
Successfully inhibit the response in a distribution), but SSRT has fixed duration
More likely when SSD is short
Go process finishes Stop process finishes
before stop process before go process
Go process finishes before stop process: (shaded area) (unshaded area)

Fail to inhibit the response
More likely when SSD is long

Explains the inhibition function: As SSD gets
The model correctly predicts the effects of
longer, p(respond|signal) gets higher
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prolonging SSD, SSRT, and go RT 22

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Race Model: Prolonging SSD Race Model: Prolonging SSRT
Short SSD Short SSRT

Long SSD Long SSRT

Longer SSD results in more inhibitory failure; Longer SSRT results in more inhibitory failure;
p(respond|signal) is higher 23 p(respond|signal) is higher 24

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Race Model: Prolonging Go RT Race Model: Summary of Effects
Short go RTs
Prolonging SSD (stop signal comes later) or
prolonging SSRT (stopping takes longer)
Go process more likely to finish first, resulting in
failure to inhibit the response
Increase in p(respond|signal)
Long go RTs

Prolonging go RT (go task takes longer)
Stop process more likely to finish first, resulting
in successful response inhibition
Longer go RTs result in more inhibitory success; Decrease in p(respond|signal)
p(respond|signal) is lower 25 26

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Race Model: Estimating SSRT Race Model: Estimating SSRT
SSRT can be estimated with the integration Integration method: (You will not be tested on these details)

method, which uses the go RT distribution, 1. Rank order the go RTs (shortest to longest) for
SSD, and p(respond|signal) trials on which no stop signal occurs
2. Find the Nth go RT, where N is the proportion of
go RTs corresponding to p(respond|signal)
– Nth go RT cuts off the shaded area equal to
p(respond|signal) in the previous figure
– Example: For 100 go RTs and p(respond|signal) =.25,
find the 25th fastest go trial
3. SSRT = Nth go RT – SSD
4. Repeat for each SSD and average across SSDs
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Race Model: Estimating SSRT Race Model: Estimating SSRT
SSRT can also be estimated with a tracking 3. Over time, the mean SSD will yield stopping
method involving a dynamic SSD failures on about half of the stop signal trials:
1. Start with an initial SSD value (e.g., 300 ms) p(respond|signal) ≈.50
2. Adjust SSD (e.g., by 50-ms increments) after 4. SSRT = mean go RT – mean SSD
every stop signal trial
Estimates of SSRT are useful because they
serve as indices of inhibitory control
Longer SSRTs indicate slower stopping and result
in higher probabilities of failing to stop, which
might reflect changes or deficits in inhibitory
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Inhibitory Control Development Inhibitory Control Development
How does inhibitory control Williams et al. (1999) results
change across the life span? SSRT improves across
childhood but changes
Williams et al. (1999) study little in adulthood
Subjects were 275 visitors to a science center Go RT improves across
childhood but worsens
(age range: 6–81 years)
in adulthood
Stop signal procedure with tracking method Suggests going and
Go task: Press a key to classify a letter as X or O stopping develop and
Stop signal (25% of trials): Brief auditory tone decline independently

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Inhibitory Control Deficits Inhibitory Control Deficits
Is deficient inhibitory control associated with ADHD characteristics:
clinical and neurological disorders? Inattention: Difficulty maintaining attentional
focus; mind wandering; lacking persistence
Attention-deficit/hyperactivity – Not due to defiance or lack of comprehension
Hyperactivity: Moving about constantly (even
disorder (ADHD): A disorder
when inappropriate); excessive fidgeting;
marked by inattention and/or extreme restlessness
hyperactivity/impulsivity that Impulsivity: Making hasty actions without
interferes with functioning or thinking; difficulty delaying gratification;
development intrusive or interruptive
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Inhibitory Control Deficits Inhibitory Control Deficits
ADHD diagnosis: Are people with ADHD impaired at stopping?
Requires a comprehensive examination by a
licensed clinician with expertise in ADHD Lijffijt et al. (2005) review of 29 studies
Symptoms must be chronic, impair the person’s Each study involved a variant of the stop signal
functioning, and cause the person to fall behind task, often with the tracking method and stop
normal development for their age signals on 25% of trials
– Symptoms not due to other medical conditions Each study compared subjects with ADHD vs.
Symptoms can appear as early as 3 years of age normal subjects
Typically diagnosed when a child is in elementary Also analyzed data by age, comparing children vs.
school, but can be diagnosed in adulthood adults
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Inhibitory Control Deficits Inhibitory Control Deficits
Lijffijt et al. (2005) results Schachar et al. (2005) study
Children with ADHD had longer go RT and SSRT Stop signal procedure with tracking method
compared with normal children Go task: Press a key to classify a letter as X or O
– Slower going and stopping suggests a general Stop signal (25% of trials): Brief auditory tone
attention deficit (not necessarily inhibitory) Compared three groups of subjects:
Adults with ADHD had longer SSRT but – ADHD-concordant sibling pairs: Siblings both
equivalent go RT compared with normal adults diagnosed with ADHD
– Impaired stopping but no difference in going – ADHD-discordant sibling pairs: One sibling
indicates a selective deficit in inhibitory diagnosed with ADHD; the other not
control – Healthy controls: Neither they nor any siblings
37 diagnosed with ADHD 38

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Inhibitory Control Deficits Inhibitory Control Deficits
Schachar et al. (2005) results Other disorders that yield prolonged SSRT,
SSRT elevated for all
suggesting inhibitory control deficits:
children with ADHD Obsessive-compulsive disorder (OCD)
(first 3 bars) vs. Trichotillomania (repetitive hair pulling)
healthy controls Tourette’s syndrome
Unaffected siblings
had intermediate
Substance abuse linked to prolonged SSRT in:
SSRT, suggesting a
genetic component Chronic cocaine users
to inhibitory deficits Chronic methamphetamine users
Alcoholics
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Summary of Inhibitory Control
Stop signal procedure is an effective method
for studying inhibitory control
Proactive and reactive adjustments may occur to
balance going and stopping

Independent race model allows estimation of
SSRT for the covert stopping process

SSRT is a useful index for assessing inhibitory
control, especially in clinical disorders 41

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