Features of the condition of the neuroendocrine-immune complex in different constellations of entropies of morpho-functional immune subsystems in rats
DOI:
https://doi.org/10.12775/JEHS.2020.10.08.025Keywords
Entropy of thymocytogram, splenocytogram, immunocytogram and leukocytogram, autonomic nervous, endocrine and immune parameters, female and male rats.Abstract
Background. We have previously shown that the Entropy (E) of the Thymocytogram (T), Splenocytogram (S) as well as Leukocytogram (L) and Immunocytogram (I) of the blood in rats are virtually independent of each other. The purpose of this study was to clarify the characteristics of the condition of the neuroendocrine-immune complex in different constellations of E(s) of these four morpho-functional immune subsystems. Materials and methods. Experiment was performed on 108 healthy Wistar rats (48 male and 60 female) weighing 240-290 g divided into 8 groups. Animals of the first group remained intact. Instead, the other rats received various balneofactors for 6 days. The day after the completion of the drinking/application course the parameters of neuroendocrine-immune complex were registered. Results. The method of cluster analysis created four homogeneous groups of rats, significantly different from each other in the constellation of E of four morpho-functional immune subsystems. The members of the first cluster (n=31) are characterized by elevated levels of E (Z±SE) of I (1,12±0,16), T (1,00±0,14) and L (0,88±0,12) at the normal E level of S (0,14±0,16). The members of the second cluster (n=21) are characterized by reduced E level of L (-1,59±0,16) in combination with increased levels of I (0,80±0,17) and T (0,81±0,15) at the normal E level of S (0,13±0,16). A characteristic feature of the members of the third cluster (n=28) is reduced E of T (-1,01±0,17) at normal E levels of S (-0,33±0,23), I (-0,19± 0,14 ) and L (0,35±0,20). The last cluster (n=28) is characterized by reduced E of I (-1,36± 0,14), while the E of other immune subsystems are at the borderline levels: L (-0,52±0,16), S (0,49±0,15), T (0,60±0,15). The method of discriminant analysis revealed 15 parameters of the neuroendocrine-immune complex, the set of which four clusters of Entropies differ from each other with an accuracy of 95%. Conclusion. Each constellation of independent Entropies of the thymocytogram, splenocytogram, immunocytogram and leukocytogram is accompanied by a specific constellation of parameters of the neuroendocrine-immune complex which indicates their natural functional relationships.
References
Aldenderfer MS, Blashfield RK. Cluster analysis (Second printing, 1985) [trans. from English in Russian]. In: Factor, Discriminant and Cluster Analysis. Moskva: Finansy i Statistika. 1989: 139-214.
Baevskiy RM, Ivanov GG. Heart Rate Variability: theoretical aspects and possibilities of clinical application [in Russian]. Ultrazvukovaya i funktsionalnaya diagnostika. 2001; 3: 106-127.
Balanovs’kyi VP, Popovych IL, Karpynets’ SV. About ambivalence-equilibratory character of influence of curative water Naftussya on organism of human [in Ukrainian]. Dopovidi ANU. Mat. pryr. tekhn. Nauky. 1993; 3: 154-158.
Belousova OI, Fedotova MI. Comparative data on changes in spleen, thymus and bone marrow lymphocyte counts in the early post-irradiation period over a wide range of doses [in Russian]. Radiobiology-Radiotherapy. 1968; 9(3): 309-313.
Bilas VR, Popadynets’ OO, Flyunt I-S.S, Sydoruk NO, Badiuk NS, Gushcha SG, Zukow W, Gozhenko AI, Popovych IL. Entropies of thymocytogram, splenocytogram, immunocytogram and leukocytogram in rats are regulated by sex and the neuroendocrine parameters while regulates immune parameters. Journal of Education, Health and Sport. 2020; 10(7): 266-288.
Bilas VR, Popovych IL. Role of microflora and organic substances of water Naftussya in its modulating influence on neuroendocrine-immune complex and metabolism [in Ukrainian]. Medical Hydrology and Rehabilitation. 2009; 7(1): 68-102.
Chebanenko OI, Popovych IL, Chebanenko LO. Introduction to Information Balneology. Influence of Bioactive Water Naftussya of Truskavets’ Spa on Information Components of Neuroendocrine-immune Complex and Metabolism [in Ukrainian]. Kyiv: UNESCO-SOCIO; 2011: 373 с.
Goryachkovskiy AM. Clinical biochemi [in Russian]. Odesa: Astroprint; 1998: 608 p.
Gozhenko AI, Zukow W, Polovynko IS, Zajats LM, Yanchij RI, Portnichenko VI, Popovych IL. Individual Immune Responses to Chronic Stress and their Neuro-Endocrine Accompaniment. RSW. UMK. Radom. Torun; 2019: 200 p.
Instructions for the use of a set of reagents for the enzyme-linked immunosorbent assay in human serum. St. Petersburg: Alkor Bio CJSC; 2000: 50 p.
Khaitov RM. Physiology of the Immune System [in Russian]. Мoskwa: VINITI RAS; 2005: 428 p.
Klecka WR. Discriminant Analysis [trans. from English in Russian] (Seventh Printing, 1986). In: Factor, Discriminant and Cluster Analysis. Moskva: Finansy i Statistika. 1989: 78-138.
Kozyavkina OV, Kozyavkina NV, Gozhenko OA, Gozhenko AI, Barylyak LG, Popovych IL. Bioactive Water Naftussya and Neuroendocrine-Immune Complex [in Ukrainian]. Kyiv: UNESCO-SOCIO; 2015: 349 p.
Perederiy VG, Zemskov AM, Bychkova NG, Zemskov VM. Immune status, principles of its evaluation and correction of immune disorders [in Russian]. Kyiv: Zdorovya; 1995: 211 p.
Polovynko IS, Zayats LM, Zukow W, Popovych IL. Neuro-endocrine-immune relationships by chronic stress at male rats. Journal of Health Sciences. 2013; 3(12): 365-374.
Popadynets’ OO, Gozhenko AI, Zukow W, Popovych IL. Relationships between the entropies of EEG, HRV, immunocytogram and leukocytogram. Journal of Education, Health and Sport. 2019; 9(5): 651-666.
Popovych AI. Features of the immunotropic effects of partial components of the balneotherapeutic complex of spa Truskavets’. Journal of Education, Health and Sport. 2018; 8(12): 919-935.
Popovych AI. Features of the neurotropic effects of partial components of the balneotherapeutic complex of spa Truskavets’. Journal of Education, Health and Sport. 2019; 9(1): 396-409.
Popоvych IL. Information effects of bioactive water Naftyssya in rats: modulation entropic, prevention desynchronizing and limitation of disharmonizing actions water immersion stress for information components of neuro-endocrine-immune system and metabolism, which correlates with gastroprotective effect [in Ukrainian]. Medical Hydrology and Rehabilitation. 2007; 5(3): 50-70.
Popovych IL. Stresslimiting Adaptogene Mechanism of Biological and Curative Activity of Water Naftussya [in Ukrainian]. Kyiv: Computerpress; 2011: 300 p.
Popovych IL, Gozhenko AI, Zukow W, Polovynko IS. Variety of Immune Responses to Chronic Stress and their Neuro-Endocrine Accompaniment. Scholars' Press. Riga; 2020: 172 p.
Popovych IL, Kul’chyns’kyi AB, Korolyshyn TA, Zukow W. Interrelations between changes in parameters of HRV, EEG and cellular immunity at patients with chronic pyelonephritis and cholecystitis. Journal of Education, Health and Sport. 2017; 7(10): 11-23.
Popovych IL, Kul’chyns’kyi AB, Gozhenko AI, Zukow W, Kovbasnyuk MM, Korolyshyn TA. Interrelations between changes in parameters of HRV, EEG and phagocytosis at patients with chronic pyelonephritis and cholecystitis. Journal of Education, Health and Sport. 2018; 8(2): 135-156.
Shannon CE. Works on the theory of informatics and cybernetics. Moskwa: Inostrannaya literatura; 1963: 329 p.
Struk ZD, Mel’nyk OI, Zukow W, Popovych IL. The diversity of immune reactions to balneotherapy and their accompaniments. Journal of Education, Health and Sport. 2019; 9(11): 349-373.
Uchakin PN, Uchakina ON, Tobin BV, Yershov FI. Neuroendocrine Immunomodulation [in Russian]. Vestnik Ross. AMN. 2007; 9: 26-32.
Zajats LM, Polovynko IS, Zukow W. Features neuro-endocrine support diversity of immune responses to chronic stress in male rats. Journal of Education, Health and Sport. 2017; 7(3): 97-105.
Zajats LM, Polovynko IS, Zukow W, Yanchij RI,. Mysakovets’ OG, Mel’nyk OI, Hrytsak YaL. Neuroendocrine-immune relatioships in rats females. Journal of Education, Health and Sport. 2017; 7(10): 59-78.
Gozhenko, A., Biryukov, V., Gozhenko, O., & Zukow, W. (2018). Health as a space-time continuum. Journal of Education, Health and Sport, 8(11), 763-777. DOI: http://dx.doi.org/10.5281/zenodo.2657000.
Gozhenko, A., Biryukov, V., Muszkieta, R., & Zukow, W. (2018). Physiological basis of human longevity: the concept of a cascade of human aging mechanism. Collegium antropologicum, 42(2), 139-146.
Downloads
Published
How to Cite
Issue
Section
License
The periodical offers access to content in the Open Access system under the Creative Commons Attribution-NonCommercial-ShareAlike 4.0
Stats
Number of views and downloads: 644
Number of citations: 0
