Numerical Stroop effect

Last updated

In psychology, the numerical Stroop effect (related to the standard Stroop effect) demonstrates the relationship between numerical values and physical sizes. When digits are presented visually, they can be physically large or small, irrespective of their actual values. Congruent pairs occur when size and value correspond (e.g., large 5 small 3) while incongruent pairs occur when size and value are incompatible (e.g., large 3 small 5). It was found that when people are asked to compare digits, their reaction time tends to be slower in the case of incongruent pairs. This reaction time difference between congruent and incongruent pairs is termed the numerical Stroop effect (or the size incongruity effect; SICE)

Contents

Example of the different conditions: congruent, incongruent and neutral trials Examples of the numerical stroop effect trials.jpg
Example of the different conditions: congruent, incongruent and neutral trials

In a numerical Stroop experiment, participants carry out a physical or a numerical size judgement task in separate blocks. In the numerical task, participants respond to the values and ignore the physical sizes and in the physical task, participants respond to the sizes and ignore the values. It is also possible to add neutral pairs to the basic task. In neutral pairs the two digits vary in one dimension only (e.g., the pair 5 3 for the numerical task and large 3 small 3 for the physical task). Neutral pairs enable measuring facilitation (i.e., the difference in reaction time between neutral and congruent pairs) and interference (i.e., the difference in reaction time between incongruent and neutral pairs).

Original experiments

Besner and Coltheart (1979) asked participants to compare values and ignore the sizes of the digits (i.e., the numerical task). They reported that the irrelevant sizes slowed down responding when sizes were incongruent with the values of the digits. [1] Henik and Tzelgov (1982) examined not only the numerical task but also the physical task. The numerical Stroop effect was found in both tasks. Moreover, when the two dimensions were congruent, responding was facilitated (relative to neutral trials) and when the two dimensions were incongruent, responding was slower (relative to neutral trials). [2]

Experimental findings

The original Stroop effect is asymmetrical - color responses are slowed down by irrelevant words but word reading is commonly not affected by irrelevant colors. [3] [4] Unlike the Stroop effect, the numerical Stroop effect is symmetrical – irrelevant sizes affect the comparisons of values and irrelevant values affect comparisons of sizes. The latter gave rise to the suggestion that values are processed automatically because this occurs even when responding to values is much slower than responding to sizes. [2] Moreover, processing values depends on familiarity with the numerical symbolic system. Accordingly, young children may show the size effect in numerical comparisons but not the effect of values in physical size comparisons. [5] [6]

Neuroanatomy

Functional magnetic resonance imaging (fMRI) studies have pinpointed the brain regions that are involved in the numerical Stroop effect. [7] [8] [9] In these studies the most consistent finding was the involvement of the parietal cortex,

The intraparietal sulcus - a brain area that is active when the numerical stroop effect occurs Intraparietal sulcus (IPS).jpg
The intraparietal sulcus - a brain area that is active when the numerical stroop effect occurs

with increased activation for incongruent in comparison to congruent trials. When a neutral condition was included, it was observed that the bilateral parietal lobes were the only regions that were involved in both facilitation and interference. [10]

Electroencephalography (EEG) studies [11] [12] [13] have indicated that the amplitude or the latency of the P300 wave is modulated as a function of the congruity effect. This means that when looking at amplitude, the difference between the amplitude of the congruent and incongruent condition is observed 300 ms after the presentation of the digits. In addition, behavioral, physiological, and computational studies support the view, although not unanimously, [11] that the conflict between congruent and incongruent conditions is observed up to the response level, [12] [14] [15] [16] [17] and is dependent on the developmental stage of the participant. [13]

The above-mentioned studies allow inferring the neural correlate of the numerical Stroop effect. However, they do not allow concluding whether parietal lobe function is critical for this effect. Brain stimulation studies that use techniques such as transcranial magnetic stimulation or transcranial direct current stimulation allow modulating parietal lobe function and inferring its role. These studies have suggested that the right parietal lobe in particular is necessary for the numerical Stroop effect, [18] [19] albeit stimulation of the right parietal lobe might affect other connected brain regions. Moreover, work with acquired acalculia [20] suggested involvement of the left parietal lobe in the numerical Stroop effect. This effect is commonly reduced in cases of brain damage to the left intraparietal sulcus.

Related Research Articles

<span class="mw-page-title-main">Anterior cingulate cortex</span> Brain region

In the human brain, the anterior cingulate cortex (ACC) is the frontal part of the cingulate cortex that resembles a "collar" surrounding the frontal part of the corpus callosum. It consists of Brodmann areas 24, 32, and 33.

<span class="mw-page-title-main">Parietal lobe</span> Part of the brain responsible for sensory input and some language processing

The parietal lobe is one of the four major lobes of the cerebral cortex in the brain of mammals. The parietal lobe is positioned above the temporal lobe and behind the frontal lobe and central sulcus.

Dyscalculia is a disability resulting in difficulty learning or comprehending arithmetic, such as difficulty in understanding numbers, learning how to manipulate numbers, performing mathematical calculations, and learning facts in mathematics. It is sometimes colloquially referred to as "math dyslexia", though this analogy is misleading as they are distinct syndromes.

<span class="mw-page-title-main">Baddeley's model of working memory</span> Model of human memory

Baddeley's model of working memory is a model of human memory proposed by Alan Baddeley and Graham Hitch in 1974, in an attempt to present a more accurate model of primary memory. Working memory splits primary memory into multiple components, rather than considering it to be a single, unified construct.

<span class="mw-page-title-main">Stroop effect</span> Effect of psychological interference on reaction time

In psychology, the Stroop effect is the delay in reaction time between congruent and incongruent stimuli.

Affective neuroscience is the study of how the brain processes emotions. This field combines neuroscience with the psychological study of personality, emotion, and mood. The basis of emotions and what emotions are remains an issue of debate within the field of affective neuroscience.

In psychology, the emotional Stroop task is used as an information-processing approach to assessing emotions. Like the standard Stroop effect, the emotional Stroop test works by examining the response time of the participant to name colors of words presented to them. Unlike the traditional Stroop effect, the words presented either relate to specific emotional states or disorders, or they are neutral. For example, depressed participants will be slower to say the color of depressing words rather than non-depressing words. Non-clinical subjects have also been shown to name the color of an emotional word slower than naming the color of a neutral word. Negative words selected for the emotional Stroop task can be either preselected by researchers or taken from the lived experiences of participants completing the task. Typically, when asked to identify the color of the words presented to them, participants reaction times for negative emotional words is slower than the identification of the color of neutral words. While it has been shown that those in negative moods tend to take longer to respond when presented with negative word stimuli, this is not always the case when participants are presented with words that are positive or more neutral in tone.

<span class="mw-page-title-main">Parieto-occipital sulcus</span> Fold which separates the parietal and occipital lobes of the brain

In neuroanatomy, the parieto-occipital sulcus is a deep sulcus in the cerebral cortex that marks the boundary between the cuneus and precuneus, and also between the parietal and occipital lobes. Only a small part can be seen on the lateral surface of the hemisphere, its chief part being on the medial surface.

Numerical cognition is a subdiscipline of cognitive science that studies the cognitive, developmental and neural bases of numbers and mathematics. As with many cognitive science endeavors, this is a highly interdisciplinary topic, and includes researchers in cognitive psychology, developmental psychology, neuroscience and cognitive linguistics. This discipline, although it may interact with questions in the philosophy of mathematics, is primarily concerned with empirical questions.

<span class="mw-page-title-main">Stanislas Dehaene</span> French cognitive neuroscientist

Stanislas Dehaene is a French author and cognitive neuroscientist whose research centers on a number of topics, including numerical cognition, the neural basis of reading and the neural correlates of consciousness. As of 2017, he is a professor at the Collège de France and, since 1989, the director of INSERM Unit 562, "Cognitive Neuroimaging".

<span class="mw-page-title-main">Posterior parietal cortex</span>

The posterior parietal cortex plays an important role in planned movements, spatial reasoning, and attention.

In cognitive psychology, the Eriksen flanker task is a set of response inhibition tests used to assess the ability to suppress responses that are inappropriate in a particular context. The target is flanked by non-target stimuli which correspond either to the same directional response as the target, to the opposite response, or to neither. The task is named for American psychologists Barbara. A. Eriksen & Charles W. Eriksen, who first published the task in 1974, and for the flanker stimuli that surround the target. In the tests, a directional response is assigned to a central target stimulus. Various forms of the task are used to measure information processing and selective attention.

The concept of motor cognition grasps the notion that cognition is embodied in action, and that the motor system participates in what is usually considered as mental processing, including those involved in social interaction. The fundamental unit of the motor cognition paradigm is action, defined as the movements produced to satisfy an intention towards a specific motor goal, or in reaction to a meaningful event in the physical and social environments. Motor cognition takes into account the preparation and production of actions, as well as the processes involved in recognizing, predicting, mimicking, and understanding the behavior of other people. This paradigm has received a great deal of attention and empirical support in recent years from a variety of research domains including embodied cognition, developmental psychology, cognitive neuroscience, and social psychology.

Recognition memory, a subcategory of explicit memory, is the ability to recognize previously encountered events, objects, or people. When the previously experienced event is reexperienced, this environmental content is matched to stored memory representations, eliciting matching signals. As first established by psychology experiments in the 1970s, recognition memory for pictures is quite remarkable: humans can remember thousands of images at high accuracy after seeing each only once and only for a few seconds.

It has been estimated that over 20% of adults suffer from some form of sleep deprivation. Insomnia and sleep deprivation are common symptoms of depression, and can be an indication of other mental disorders. The consequences of not getting enough sleep could have dire results, not only to the health, cognition, energy level and the mood of the person, but also to those around them. Sleep deprivation increases the risk of human-error related accidents, especially with vigilance-based tasks involving technology.

The approximate number system (ANS) is a cognitive system that supports the estimation of the magnitude of a group without relying on language or symbols. The ANS is credited with the non-symbolic representation of all numbers greater than four, with lesser values being carried out by the parallel individuation system, or object tracking system. Beginning in early infancy, the ANS allows an individual to detect differences in magnitude between groups. The precision of the ANS improves throughout childhood development and reaches a final adult level of approximately 15% accuracy, meaning an adult could distinguish 100 items versus 115 items without counting. The ANS plays a crucial role in development of other numerical abilities, such as the concept of exact number and simple arithmetic. The precision level of a child's ANS has been shown to predict subsequent mathematical achievement in school. The ANS has been linked to the intraparietal sulcus of the brain.

Dichotic listening is a psychological test commonly used to investigate selective attention and the lateralization of brain function within the auditory system. It is used within the fields of cognitive psychology and neuroscience.

<span class="mw-page-title-main">Neuroscience of sex differences</span> Characteristics of the brain that differentiate the male brain and the female brain

The neuroscience of sex differences is the study of characteristics that separate the male and female brains. Psychological sex differences are thought by some to reflect the interaction of genes, hormones, and social learning on brain development throughout the lifespan.

<span class="mw-page-title-main">Avishai Henik</span> Israeli neurocognitive psychologist (born 1945)

Avishai Henik is an Israeli neurocognitive psychologist who works at Ben-Gurion University of the Negev (BGU). Henik studies voluntary and automatic (non-voluntary/reflexive) processes involved in cognitive operations. He characterizes automatic processes, and clarifies their importance, the relationship between automatic and voluntary processes, and their neural underpinnings. Most of his work involves research with human participants and in recent years, he has been working with Archer fish in order to examine evolutionary aspects of various cognitive functions.

<span class="mw-page-title-main">Roi Cohen Kadosh</span> Israeli-British cognitive neuroscientist

Roi Cohen Kadosh is an Israeli-British cognitive neuroscientist notable for his work on numerical and mathematical cognition and learning and cognitive enhancement. He is a professor of Cognitive Neuroscience and the head of the School of Psychology at the University of Surrey.

References

  1. Besner, Derek; Coltheart, Max (1979). "Ideographic and alphabetic processing in skilled reading of English". Neuropsychologia. 17 (5): 467–472. doi:10.1016/0028-3932(79)90053-8. PMID   514483. S2CID   33877667.
  2. 1 2 Henik, Avishai; Tzelgov, Joseph (July 1982). "Is three greater than five: The relation between physical and semantic size in comparison tasks". Memory & Cognition. 10 (4): 389–395. doi: 10.3758/BF03202431 . PMID   7132716.
  3. MacLeod, C. M. (1991). "Half a century of research on the Stroop effect: An integrative review". Psychological Bulletin. 109 (2): 163–203. CiteSeerX   10.1.1.475.2563 . doi:10.1037/0033-2909.109.2.163. PMID   2034749.
  4. Stroop, J. R. (1935). "Studies of interference in serial verbal reactions". Journal of Experimental Psychology. 18 (6): 643–662. doi:10.1037/h0054651. hdl: 11858/00-001M-0000-002C-5ADB-7 .
  5. Girelli, Luisa; Lucangeli, Daniela; Butterworth, Brian (June 2000). "The Development of Automaticity in Accessing Number Magnitude". Journal of Experimental Child Psychology. 76 (2): 104–122. doi:10.1006/jecp.2000.2564. PMID   10788305.
  6. Rubinsten, Orly; Henik, Avishai; Berger, Andrea; Shahar-Shalev, Sharon (2002). "The development of internal representations of magnitude and their association with Arabic numerals". Journal of Experimental Child Psychology. 81 (1): 74–92. doi:10.1006/jecp.2001.2645. PMID   11741375.
  7. Pinel, P; Piazza, M; Le Bihan, D; Dehaene, S (2004). "Distributed and overlapping cerebral representations of number, size, and luminance during comparative judgments". Neuron. 41 (6): 983–993. doi: 10.1016/S0896-6273(04)00107-2 . PMID   15046729. S2CID   9372570.
  8. Kaufmann, L; Koppelstaetter, F; Delazer, M; Siedentopf, C; Rhomberg, P; Golaszewski, S; Felber, S; Ischebeck, A (2005). "Neural correlates of distance and congruity effects in a numerical Stroop task: An event-related fMRI study". NeuroImage. 25 (3): 888–898. doi:10.1016/j.neuroimage.2004.12.041. PMID   15808989. S2CID   26403107.
  9. Cohen Kadosh, R; Cohen Kadosh, K; Henik, A (2008). "When brightness counts: The neuronal correlate of numerical-luminance interference". Cerebral Cortex. 18 (2): 337–343. doi: 10.1093/cercor/bhm058 . PMID   17556772.
  10. Cohen Kadosh, R; Cohen Kadosh, K; Henik, A; Linden, D.E.J (2008). "Processing conflicting information: Facilitation, interference, and functional connectivity". Neuropsychologia. 46 (12): 2872–2879. doi:10.1016/j.neuropsychologia.2008.05.025. PMID   18632120. S2CID   42536335.
  11. 1 2 Gebuis, T; Leon Kenemans, J; de Haan, E.H.F; van der Smagt, M.J (2010). "Conflict processing of symbolic and non-symbolic numerosity". Neuropsychologia. 48 (2): 394–401. doi:10.1016/j.neuropsychologia.2009.09.027. hdl: 1874/379927 . PMID   19804788. S2CID   20108831.
  12. 1 2 Cohen Kadosh, R; Cohen Kadosh, K; Linden, D.E.J; Gevers, W; Berger, A; Henik, A (2007). "The brain locus of interaction between number and size: A combined functional magnetic resonance imaging and event-related potential study". Journal of Cognitive Neuroscience. 19 (6): 957–970. CiteSeerX   10.1.1.459.2779 . doi:10.1162/jocn.2007.19.6.957. PMID   17536966. S2CID   17251825.
  13. 1 2 Szucs, D; Soltesz, F; Jarmi, E; Csepe, V (2007). "The speed of magnitude processing and executive functions in controlled and automatic number comparison in children: An electro-encephalography study". Behavioral and Brain Functions. 3: 23. doi: 10.1186/1744-9081-3-23 . PMC   1872027 . PMID   17470279.
  14. Szucs, D; Soltesz, F; White, S (2009). "Motor conflict in Stroop tasks: Direct evidence from single-trial electro-myography and electro-encephalography" (PDF). NeuroImage. 47 (4): 1960–1973. doi:10.1016/j.neuroimage.2009.05.048. PMID   19481157. S2CID   18396230.
  15. Cohen Kadosh, R; Gevers, W; Notebaert, W (2011). "Sequential analysis of the numerical Stroop effect reveals response suppression". Journal of Experimental Psychology: Learning, Memory, and Cognition. 37 (5): 1243–1249. doi:10.1037/a0023550. PMC   3167478 . PMID   21500951.
  16. Santens, S; Verguts, T (2011). "The size congruity effect: is bigger always more?". Cognition. 118 (1): 94–110. doi:10.1016/j.cognition.2010.10.014. PMID   21074146. S2CID   206864161.
  17. Szucs, D; Soltesz, F (2007). "Event-related potentials dissociate facilitation and interference effects in the numerical Stroop paradigm". Neuropsychologia. 45 (14): 3190–3202. doi:10.1016/j.neuropsychologia.2007.06.013. PMID   17675108. S2CID   15708961.
  18. Cohen Kadosh, R; Cohen Kadosh, K; Schuhmann, T; Kaas, A; Goebel, R; Henik, A; Sack, A.T (2007). "Virtual dyscalculia induced by parietal-lobe TMS impairs automatic magnitude processing". Current Biology. 17 (8): 689–693. doi: 10.1016/j.cub.2007.02.056 . PMID   17379521. S2CID   18084538.
  19. Cohen Kadosh, R; Soskic, S; Iuculano, T; Kanai, R; Walsh, V (2010). "Modulating neuronal activity produces specific and long lasting changes in numerical competence". Current Biology. 20 (22): 2016–2020. doi:10.1016/j.cub.2010.10.007. PMC   2990865 . PMID   21055945.
  20. Ashkenazi, S; Henik, A; Ifergane, G; Shelef, I (2008). "Basic numerical processing in left intraparietal sulcus (IPS) acalculia". Cortex. 44 (4): 439–448. doi:10.1016/j.cortex.2007.08.008. PMID   18387576. S2CID   11505775.
This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.