ENTROPY OF BEHAVIORAL REACTIONS AND FUNCTIONAL ORGANIZATION OF THE CENTRAL NERVOUS SYSTEM
Main Article Content
Abstract
The purpose of the study was to investigate the possibility of using entropy analysis of simple sensorimotor reaction time to study the functional state of the central nervous system
Methods. The study was conducted at Bohdan Khmelnytsky National University of Cherkasy with 80 participants aged 17 to 75. Simple visual-motor reaction time was determined using the Makarenko method. Data preprocessing included removing reactions outside the 100–700 ms range and applying the Median Absolute Deviation (MAD) method to eliminate statistical outliers. Entropy was calculated based on discrete Shannon entropy applied to reaction time distribution histograms, with RT values grouped into intervals using Sturges' rule.
Results. It was found that as age increases, the average reaction time grows, but changes in variability are more significant. The coefficient of variation and interpercentile range (P90–P10) demonstrate an expansion of the value range and increased instability, especially in the 61–75 age group. Entropy values also increased with age, from 2.285 bits in the 17–18 group to 2.543 bits in the 61–75 group. Analysis revealed no functional dependence between entropy and mean reaction time or coefficient of variation, confirming that entropy reflects unique characteristics of distribution related to structural uncertainty. Generalized age dynamics show that while all metrics (Mean RT, CV, P90-P10, Entropy) increase with age, entropy demonstrates the most consistent and monotonic growth.
Originality. For the first time, an integral approach combining classical statistical metrics with Shannon entropy was applied to sensorimotor reaction time series across a wide age range to quantify the degree of organization of the central nervous system. The study demonstrates that entropy serves as an independent indicator of the "organized complexity" of behavioral responses that classical statistics cannot fully capture.
Conclusion. The introduction of entropy analysis allows for a deeper assessment of the functional state of the CNS beyond simple speed metrics. Age-related changes in sensorimotor reactions manifest not only as slowing but as a decrease in the stability and organization of the reaction process. Increased entropy in older age groups indicates higher uncertainty and reduced order in the functioning of the sensorimotor system, reflecting a decline in functional organization.
Article Details
Authors retain copyright and grant the journal right of first publication with the work simultaneously licensed under a Creative Commons Attribution License that allows others to share the work with an acknowledgement of the work's authorship and initial publication in this journal.
AGREEMENT ABOUT TRANSMISSION OF COPYRIGHT
I, the author of the article / We, the authors of the manuscript _______________________________________________________________________
in case of its acceptance for publication, we transfer the following rights to the founders and editorial boards of the scientific publication "Cherkasy University Bulletin: Biological Sciences Series":
1. Publication of this article in Ukrainian (English) and distribution of its printed version.
2. Dissemination of the electronic version of the article through any electronic means (placing on the official journal web site, in electronic databases, repositories, etc.). At the same time we reserve the right without consent of the editorial board and the founders:
1. Use the materials of the article in whole or in part for educational purposes.
2. To use the materials of the article in whole or in part for writing your own theses.
3. Use article materials to prepare Summarys, conference reports, and oral presentations.
4. Post electronic copies of the article (including the final electronic version downloaded from the journal's official website) to:
a. personal web-pecypcax of all authors (web sites, web pages, blogs, etc.);
b. web-pecypcax of the institutions where the authors work (including electronic institutional repositories);
with. non-profit, open-source web-pecypcax (such as arXiv.org).
With this agreement, we also certify that the submitted manuscript meets the following criteria:
1. Does not contain calls for violence, incitement of racial or ethnic enmity, which are disturbing, threatening, shameful, libelous, cruel, indecent, vulgar, etc.
2. Does not infringe the copyrights and intellectual property rights of others or organizations; contains all the references to the cited authors and / or publications envisaged by applicable copyright law, as well as the results and facts used in the article by other authors or organizations.
3. It has not been previously published in other publishers and has not been published in other publications.
4. Does not include materials that are not subject to publication in the open press, in accordance with applicable law.
____________________ ___________________
First name, Last name, signature of the author
"___" __________ 20__
References
Іванець О. Б., Буриченко М. Ю., Архирей М. В., Братко В. Ю. Особливості використання методів нелінійної динаміки для обробки біомедичних даних // Наукоємні технології. – 2022. – № 4(56). DOI: https://doi.org/10.18372/2310-5461.56.17131
Попадинець О.О., Гоженко А.І., Бадюк Н.С., Попович І.Л. Індивідуальні особливості ентропії параметрів нервових регуляторних структур (ЕЕГ/ВРС). VIII Національний конгрес патофізіологів України “Патологічна фізіологія - охороні здоров’я України” (Одеса, 13-15 травня 2020 р). Одеса; 2020: 312-314.
Brown J. W., Mendes N., Heathcote A., McKinnon R., Seli P. (2017). Hick–Hyman law is mediated by the cognitive control network in the brain. Scientific Reports. Vol. 7. Article 16104. DOI: https://doi.org/10.1038/s41598-017-16104-3
Fitousi D. (2023). Quantifying entropy in response times (RT) distributions using the cumulative residual entropy (CRE) function. Entropy. Vol. 25, No 8. Article 1239. DOI: https://doi.org/10.3390/e25081239
Goldberger A. L. (1996). Non-linear dynamics for clinicians: chaos theory, fractals, and complexity at the bedside. The Lancet. Vol. 347, No 9011. Pp. 1312–1314. DOI: https://doi.org/10.1016/S0140-6736(96)90948-4
Iglesias-Martínez M. E., Candela-Riera G., Hernández-Wilches C. (2020). Machinery failure approach and spectral analysis to study the reaction time dynamics over consecutive visual stimuli: an entropy-based model. Mathematics. Vol. 8, No 11. Article 1979. DOI: https://doi.org/10.3390/math8111979
Ilya Prigogine – Facts. Nobel Prize in Chemistry 1977: “for his contributions to non-equilibrium thermodynamics, particularly the theory of dissipative structures”. [Електронний ресурс]. – NobelPrize.org. – Режим доступу: https://www.nobelprize.org/prizes/chemistry/1977/prigogine/facts/ (Accessed: 23.02.2026).
Keshmiri S. (2020). Entropy and the Brain: An Overview. Entropy. Vol. 22, No 9. Art. 917. DOI: https://doi.org/10.3390/e22090917
Lipsitz L. A., Goldberger A. L. (1992). Loss of complexity and aging. JAMA. Vol. 267, No 13. Pp. 1806–1809. DOI: https://doi.org/10.1001/jama.1992.03480130122036
Pincus S. M. (1991). Approximate entropy as a measure of system complexity. Proceedings of the National Academy of Sciences of the USA. Vol. 88. Pp. 2297–2301
Richman J. S., Moorman J. R. (2000). Physiological time-series analysis using approximate entropy and sample entropy. American Journal of Physiology – Heart and Circulatory Physiology. Vol. 278. Pp. H2039–H2049
Shannon C. E. (1948). A Mathematical Theory of Communication. Bell System Technical Journal. Vol. 27. Pp. 379–423, 623–656. DOI: https://doi.org/10.1002/j.1538-7305.1948.tb01338.x