Reactive inhibition is a phrase coined by Clark L. Hull in his 1943 book titled Principles of Behavior. He defined it as:

Whenever any reaction is evoked in an organism there is left a condition or state which acts as a primary negative motivation in that it has an innate capacity to produce a cessation of the activity which produced the state.

Reactive inhibition is typically studied in the context of drive reduction.  Hull likens it to fatigue through which humans become tired over time and thus less accurate and precise within a given task.[1] There is significant debate whether the process of reactive inhibition is due to fatigue or some other process.  Nevertheless, it is a factor researchers need to consider in analyses of sustained performance due to its possible role in the results and analysis of research.[2]

Hull goes on to further explain the decay of performance through the use of a decay formula which can estimate the rate of performance deterioration.

Hull explains:

I dissipates exponentially with time t:

With the passage of time since its formation IR spontaneously dissipates approximately as a simple decay function of the time t elapsed, i.e.,

(Hull, 1951, p. 74).

Hull's decay formula is somewhat awkward and might give rise to confusion. For example, I'R does not refer to the derivative of IR. A more convenient way of writing the formula would be as follows:

with . is the inhibition at the beginning the time interval [0,t]. Note that if one takes the natural logarithm of both sides one obtains:

where and . The last formula is used in inhibition theory.[3]

Reactive inhibition is distinct from proactive inhibition. Reactive inhibition occurs after an initial response has been activated and set to be carried out. In contrast, proactive inhibition determines whether or not the response process is activated in the future and occurs before initial activation.[4] Reactive inhibition is considered to be a bottom-up processing process and associated with “lower level mechanisms of inhibition”, whereas proactive inhibition is considered more top-down processing and dealing with “higher level mechanisms”.[5]

Applications

Reactive inhibition may be important in everyday life during a process in which a decline in performance can be detrimental such as driving a car during rush hour.[2] For example, Kathaus, Washcer, & Getzmann (2018) found that older adults who showed a tendency towards reactive inhibition, determined through electroencephalography measures, showed higher “driving lane variability” and more impairment. Although older adults matched younger adults in their lane keeping abilities, they were unable to change lanes as effectively when they relied on reactive inhibition.[6]

Another study also revolving around younger vs older adults in the realm of inhibition found that older adults had decreased reactive inhibition but sustain proactive inhibition overall.  By using a smart phone app, participants played a game in two apples were falling from either side of the tree. They were to tap either apple but not press one of the apples if that apple turned brown or “rotten”.  This is similar to a Stop Signal Task as described below.  Some of these trials were primed for a person to expect a change and others not. What was found was a decreased ability in older adults to inhibit an action when they were not primed thus indicating a deficit in reactive inhibition.[7]

Researchers have also studied reactive inhibition within the context of ADHD.[8] It is commonly accepted that decreased inhibition abilities are a prominent aspect of the symptoms associated with ADHD.[9] Within the context of the Stop Signal Task studies point to an inability to switch attention the signal switches from a go signal, to stop, which can be compared to environmental changes in the world.  Further, it is proven that reactive inhibition in particular is affected in individuals with ADHD and related ADHD symptoms, and may not even have an impact on proactive inhibition at all.[10] The ability to inhibit can impact children’s learning abilities and is a lack of reactive inhibition is present in many learning disorders.[11]

Relationship to learning

Reactive inhibition is also related to repetition performance, including learning. For example, Torok et al. (2017) recorded learning capabilities in 180 adults using the Alternating Serial Reaction Time Test.  Results showed reactive inhibition had a profound effect on performance.  Specifically, they showed that significantly more learning had occurred than was perceived at the end of the task, for reactive inhibition had effected the individual over time.  They concluded that reactive inhibition may affect one’s rate of learning due to how it causes progressive decline within a task.  It was stated to be a feature of performance within 90% of the participants, and thus playing a significant role in results.  These findings have caused some researchers to question existing psychological theories.[2] For example, Rickard, Pan, and Albarracín present evidence that even well accepted psychological findings such as memory consolidation during sleep may be incorrect.[12] The increase in “memory” that supposedly occurs after sleep may just be due to reactive inhibition.  It may have existed at the end of learning before sleeping occurred, and thus caused seemingly lower memory scores.

Reactive inhibition is often not recognized as a factor of performance in learning based experiments and thus can lead to incorrect results.[13] The presence of reactive inhibition can result in decreased performance over time and thus decrease the level of supposed learning.  If tested at a later time, however, when reactive inhibition is not present one may see true measures of learning.

Stop-signal task (SST)

Reactive inhibition within experimental settings is most commonly measured through the stop-signal task (SST).  In the SST, a “go-signal” is presented to the participant to indicate that he or she should complete an action.  Then, in some instances, a “stop-signal” is also presented to the participant indicate he or she should abandon the previously initiated action.  This stop signal is presented within hundreds of milliseconds of receiving the go signal.[14] What is important within this task is the stop signal reaction time, which indicates how long it takes reactive inhibition to be triggered and thus for the action to be ceased.[4] Shorter times indicate a person has better reactive inhibition skills, and thus able to more quickly switch from the activation of some response to the abandoning of that goal through reactive inhibition.[15]

Due to the simplicity of the SST some modern researchers are against its use to make broader assumptions about inhibition. The SST’s demands on attention and inhibition are relatively low and simple in nature, unlike many real life situations, which makes them distrusting of its results.[16] However, the SST is thought to be more indicative by many of reactive inhibition as opposed to proactive.[17] In addition, reactive inhibition is thought to involve mechanisms that are not context dependent but generally the same amongst many conditions in which contexts are changing and the original “go-signal” explicitly or implicitly stated.[18]

Relationship with Parkinson's Disease

Reactive inhibition is negatively affected by Parkinson's disease.[19] People with Parkinson’s disease have difficulty inhibiting their behaviors.  It is proposed that levels of Dopamine are directly associated with one’s ability to inhibit. Proper inhibition is believed to be successful at some desired level of dopamine. Using the simon task, researchers showed that inhibitory processes were significantly depleted in Parkinson’s patients who were withdrawing from their medications, and thus experiencing low levels of dopamine. Performance has been also depleted among high levels of dopamine, indicating that there is an ideal middle ground level of dopamine in which reactive inhibition is most successful. These results suggest an association between dopamine levels and reactive inhibition.[20]

Brain involvement

Reactive inhibition appears to be related to the subthalamic nucleus (STN), particularly within the active inhibition of “overriding the behavior”.[21] The STN is in charge of sending a signal to “inhibit thalamo-cortical activation”.  Thus reaction then causes GABA driven inhibitory signals to be sent to the thalamus which inhibits the behavior.[22] Although reactive inhibition is supported by early STN activity relative to the time of responses, proactive inhibition is defined by more continuous STN activity.[21]

One study has also shown that significant damage to the prefrontal cortex, particularly the right superior medial frontal region, can result in a lack of inhibitory control.  When this particular region was damaged patients relied more on last second reactive inhibition to avoid performing inappropriate behaviors.[23]

See also

References

Citations

  1. Hull, Clark (1943). Principles of Behavior: an introduction to behavior theory. Oxford, England: Appleton-Century. pp. 1–20.
  2. 1 2 3 Török, Balázs; Janacsek, Karolina; Nagy, Dávid G.; Orbán, Gergő; Nemeth, Dezso (2017). "Measuring and filtering reactive inhibition is essential for assessing serial decision making and learning" (PDF). Journal of Experimental Psychology: General. American Psychological Association (APA). 146 (4): 529–542. doi:10.1037/xge0000288. ISSN 1939-2222. PMID 28383991. S2CID 31080758.
  3. Howarth, E. (1965). "A test of Hull's reactive inhibition concept: persistence of curvilinear response pattern in button-pressing". Perceptual and Motor Skills. 21 (2): 453–454. doi:10.2466/pms.1965.21.2.453. ISSN 0031-5125. PMID 5848918.
  4. 1 2 Meyer, Heidi C.; Bucci, David J. (2016-09-15). "Neural and behavioral mechanisms of proactive and reactive inhibition". Learning & Memory. Cold Spring Harbor Laboratory. 23 (10): 504–514. doi:10.1101/lm.040501.115. ISSN 1549-5485. PMC 5026209. PMID 27634142.
  5. Kenemans, J. (2015). "Specific proactive and generic reactive inhibition". Neuroscience & Biobehavioral Reviews. 56: 115–126. doi:10.1016/j.neubiorev.2015.06.011. PMID 26116545. S2CID 2254502.
  6. Karthaus, Melanie; Wascher, Edmund; Getzmann, Stephan (2018-01-19). Yao, Dezhong (ed.). "Proactive vs. reactive car driving: EEG evidence for different driving strategies of older drivers". PLOS ONE. Public Library of Science (PLoS). 13 (1): e0191500. Bibcode:2018PLoSO..1391500K. doi:10.1371/journal.pone.0191500. ISSN 1932-6203. PMC 5774811. PMID 29352314.
  7. Smittenaar, Peter; Rutledge, Robb B.; Zeidman, Peter; Adams, Rick A.; Brown, Harriet; Lewis, Glyn; Dolan, Raymond J. (2015-10-21). Luo, Xi (ed.). "Proactive and Reactive Response Inhibition across the Lifespan". PLOS ONE. Public Library of Science (PLoS). 10 (10): e0140383. Bibcode:2015PLoSO..1040383S. doi:10.1371/journal.pone.0140383. ISSN 1932-6203. PMC 4619547. PMID 26488166.
  8. Oosterlaan, Jaap; Sergeant, Joseph A. (1998). "Inhibition in AD/HD, Disruptive, Anxious, and Normal Children". Journal of Abnormal Child Psychology. Springer Science and Business Media LLC. 26 (3): 161–174. doi:10.1023/a:1022650216978. ISSN 0091-0627. PMID 9650623. S2CID 11945235.
  9. LIPSZYC, JONATHAN; SCHACHAR, RUSSELL (2010-08-19). "Inhibitory control and psychopathology: A meta-analysis of studies using the stop signal task". Journal of the International Neuropsychological Society. Cambridge University Press (CUP). 16 (6): 1064–1076. doi:10.1017/s1355617710000895. ISSN 1355-6177. PMID 20719043. S2CID 206315698.
  10. van Hulst, Branko M.; de Zeeuw, Patrick; Rijks, Yvonne; Neggers, Sebastiaan F. W.; Durston, Sarah (2016-12-01). "What to expect and when to expect it: an fMRI study of expectancy in children with ADHD symptoms". European Child & Adolescent Psychiatry. Springer Science and Business Media LLC. 26 (5): 583–590. doi:10.1007/s00787-016-0921-7. ISSN 1018-8827. PMC 5394180. PMID 27904952.
  11. De Weerdt, Frauke; Desoete, Annemie; Roeyers, Herbert (2013). "Behavioral inhibition in children with learning disabilities". Research in Developmental Disabilities. Elsevier BV. 34 (6): 1998–2007. doi:10.1016/j.ridd.2013.02.020. hdl:1854/LU-3213911. ISSN 0891-4222. PMID 23584180.
  12. Rickard, Timothy C.; Pan, Steven C. (2017). "Time for considering the possibility that sleep plays no unique role in motor memory consolidation: Reply to Adi-Japha and Karni (2016)". Psychological Bulletin. American Psychological Association (APA). 143 (4): 454–458. doi:10.1037/bul0000094. ISSN 1939-1455. PMID 28301203.
  13. Howard, James H.; Howard, Darlene V. (1997). "Age differences in implicit learning of higher order dependencies in serial patterns". Psychology and Aging. American Psychological Association (APA). 12 (4): 634–656. doi:10.1037/0882-7974.12.4.634. ISSN 1939-1498. PMID 9416632.
  14. Logan, Gordon D.; Cowan, William B. (1984). "On the ability to inhibit thought and action: A theory of an act of control". Psychological Review. American Psychological Association (APA). 91 (3): 295–327. doi:10.1037/0033-295x.91.3.295. ISSN 0033-295X.
  15. Aron, Adam R.; Robbins, Trevor W.; Poldrack, Russell A. (2004). "Inhibition and the right inferior frontal cortex". Trends in Cognitive Sciences. Elsevier BV. 8 (4): 170–177. doi:10.1016/j.tics.2004.02.010. ISSN 1364-6613. PMID 15050513. S2CID 19332756.
  16. Swann, N.; Poizner, H.; Houser, M.; Gould, S.; Greenhouse, I.; Cai, W.; Strunk, J.; George, J.; Aron, A. R. (2011-04-13). "Deep Brain Stimulation of the Subthalamic Nucleus Alters the Cortical Profile of Response Inhibition in the Beta Frequency Band: A Scalp EEG Study in Parkinson's Disease". Journal of Neuroscience. Society for Neuroscience. 31 (15): 5721–5729. doi:10.1523/jneurosci.6135-10.2011. ISSN 0270-6474. PMC 3086079. PMID 21490213.
  17. Zandbelt, Bram B.; Vink, Matthijs (2010-11-04). Rodriguez-Fornells, Antoni (ed.). "On the Role of the Striatum in Response Inhibition". PLOS ONE. Public Library of Science (PLoS). 5 (11): e13848. Bibcode:2010PLoSO...513848Z. doi:10.1371/journal.pone.0013848. ISSN 1932-6203. PMC 2973972. PMID 21079814.
  18. Kenemans, J. Leon (2015). "Specific proactive and generic reactive inhibition". Neuroscience & Biobehavioral Reviews. Elsevier BV. 56: 115–126. doi:10.1016/j.neubiorev.2015.06.011. ISSN 0149-7634. PMID 26116545. S2CID 2254502.
  19. Mirabella, Giovanni (2017). "O173 Unilateral deep brain stimulation of subthalamic nucleus does not affect reactive inhibition". Clinical Neurophysiology. Elsevier BV. 128 (9): e234. doi:10.1016/j.clinph.2017.07.183. ISSN 1388-2457. S2CID 53201123.
  20. van Wouwe, Nelleke C.; Kanoff, Kristen E.; Claassen, Daniel O.; Spears, Charis A.; Neimat, Joseph; van den Wildenberg, Wery P. M.; Wylie, Scott A. (2016). "Dissociable Effects of Dopamine on the Initial Capture and the Reactive Inhibition of Impulsive Actions in Parkinson's Disease". Journal of Cognitive Neuroscience. MIT Press - Journals. 28 (5): 710–723. doi:10.1162/jocn_a_00930. ISSN 0898-929X. PMC 4896305. PMID 26836515.
  21. 1 2 Benis, Damien; David, Olivier; Lachaux, Jean-Philippe; Seigneuret, Eric; Krack, Paul; Fraix, Valérie; Chabardès, Stéphan; Bastin, Julien (2014). "Subthalamic nucleus activity dissociates proactive and reactive inhibition in patients with Parkinson's disease". NeuroImage. Elsevier BV. 91: 273–281. doi:10.1016/j.neuroimage.2013.10.070. ISSN 1053-8119. PMID 24368260. S2CID 7252342.
  22. Aron, Adam R.; Gluck, Mark A.; Poldrack, Russell A. (2006). "Long-term test–retest reliability of functional MRI in a classification learning task". NeuroImage. Elsevier BV. 29 (3): 1000–1006. doi:10.1016/j.neuroimage.2005.08.010. ISSN 1053-8119. PMC 1630684. PMID 16139527.
  23. Floden, Darlene; Stuss, Donald T. (2006). "Inhibitory Control is Slowed in Patients with Right Superior Medial Frontal Damage". Journal of Cognitive Neuroscience. MIT Press - Journals. 18 (11): 1843–1849. doi:10.1162/jocn.2006.18.11.1843. ISSN 0898-929X. PMID 17069475. S2CID 9597178.

Sources

  • Hull, C.L.: Essentials of behavior. Westport (Connecticut): Greenwood Press, 1951.
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