30

Babelyuk Valeriy Ye., Popadynets’ Oleksandr O., Dubkova Galyna I., Zukow Walery, Muszkieta Radosław, Gozhenko Anatoliy I.,
Popovych Igor L. Entropy of gas-discharge image correlates with the entropies of EEG, immunocytogram and leukocytogram but not
HRV. Pedagogy and Psychology of Sport. 2020;6(2):30-39. elSSN 2450-6605. DOI http://dx.doi.org/10.12775/PPS.2020.06.02.003
https://apcz.umk.pl/czasopisma/index.php/PPS/article/view/PPS.2020.06.02.003
https://zenodo.org/record/3755035

The journal has had 5 points in Ministry of Science and Higher Education parametric evaluation. § 8. 2) and § 12. 1. 2) 22.02.2019.
© The Authors 2020;

This article is published with open access at Licensee Open Journal Systems of Nicolaus Copernicus University in Torun, Poland
Open Access. This article is distributed under the terms of the Creative Commons Attribution Noncommercial License which permits any noncommercial use, distribution, and reproduction in any medium, provided the

original author (s) and source are credited. This is an open access article licensed under the terms of the Creative Commons Attribution Non commercial license Share alike.
(http://creativecommons.org/licenses/by-nc-sa/4.0/) which permits unrestricted, non commercial use, distribution and reproduction in any medium, provided the work is properly cited.

The authors declare that there is no conflict of interests regarding the publication of this paper.

Received: 01.04.2020. Revised: 16.04.2020. Accepted: 16.04.2020.

ENTROPY OF GAS-DISCHARGE IMAGE CORRELATES WITH THE ENTROPIES
OF EEG, IMMUNOCYTOGRAM AND LEUKOCYTOGRAM BUT NOT HRV

Valeriy Ye. Babelyuk1,2, Oleksandr O. Popadynets’1, Galyna I. Dubkova2, Walery Zukow3,
Radosław Muszkieta3, Anatoliy I. Gozhenko1, Igor L. Popovych1,4

1Ukrainian Scientific Research Institute of Medicine for Transport MHU, Odesa, Ukraine
2Clinical Sanatorium „Моldоvа”, Truskavets’, Ukraine san.moldova.tr@ukr.net

3Nicolaus Copernicus University, Torun, Poland w.zukow@wp.pl
4OO Bohomolets’ Institute of Physiology NAS, Kyїv, Ukraine i.popovych@biph.kiev.ua

Abstract
Background. In implementing the project of verification gas discharge visualization
(kirlianography, biophotonics) method, we documented the significant correlation of the gas
discharge image parameters with the parameters of electroencephalogram, heart rate variability
(HRV), dexterity and spasticity of brush, blood pressure, as well as blood levels of adaptive
hormones. As part of a project to investigate the physiological nature of entropy, we have shown
that EEG entropy is related to a number of its amplitude-frequency and spectral parameters, as
well as to the parameters HRV, blood leukocytogram and immunocytogram and their entropies.
The purpose of this study is to analyze the relationships between the entropies of the listed
information systems. Material and research methods. The object of observation were 20
volunteers: 10 women and 10 men aged 33-76 years without clinical diagnose but with
dysfunction of neuro-endocrine-immune complex and metabolism. We registered twice
kirlianogram by the method of GDV by the device of “GDV Chamber” (“Biotechprogress”),
EEG (“NeuroCom Standard”, KhAI Medica), HRV ("CardioLab+HRV", "KhAI-Medica"),
Leukocytogram and Immunocytogram. Than we calculated the entropies of the listed information
systems. Results. By stepwise exclusion, 5 variables were included in the canonical GDV root
structure, and 6 variables were included in the root EEG structure. Overall, GDI entropy
determines the SPD EEG entropy by 33%. The additional inclusion in the dependent set the
parameters of HRV, LCG and ICG entropies gives a increase in determination to 48%. HRV
entropy was found outside the model. Conclusion. We have documented the relationship

http://dx.doi.org/10.12775/PPS.2020.06.02.003
https://apcz.umk.pl/czasopisma/index.php/PPS/article/view/PPS.2020.06.02.003
https://zenodo.org/record/3755035
mailto:san.moldova.tr@ukr.net
mailto:w.zukow@wp.pl
mailto:i.popovych@biph.kiev.ua


31

between the entropy parameters of electroencephalogram, blood leukocytogram and
immunocytogram but not HRV on the one hand, and gas-discharge images on the other. However,
the question of the causal nature of this relationship remains open. What is primary: electrical
activity of the brain, excretion of cytokines and hormones by immunocytes, or emission of
photons and free electrons by acupuncture points (circulation of vital energy)?

Key words: gas-discharge visualization; electroencephalogram; HRV; blood leukocytogram and
immunocytogram; entropy, relationships.

INTRODUCTION

In implementing the project of verification gas discharge visualization (kirlianography,
biophotonics) method proposed by KG Korotkov [17,18], we documented the significant
correlation of the gas discharge image (GDI) parameters with the parameters of
electroencephalogram [4,8,9,16,19,20,30,31], HRV [4,8-10,19,20,28,29,31], dexterity and
spasticity of brush [4,9,19,20,31], blood pressure [28,29], as well as blood levels of adaptive
hormones [1-3,5-7,10,11]. As part of a project to investigate the physiological nature of entropy,
we have shown that EEG entropy is related to a number of its amplitude-frequency and spectral
parameters, as well as to the parameters HRV, blood leukocytogram and immunocytogram and
their entropies [13,22-27,33].

The purpose of this study is to analyze the relationships between the entropies of the listed
information systems.

MATERIAL AND RESEARCH METHODS

The object of observation were 20 volunteers: ten women and ten men aged 33-76 years
without clinical diagnose but with dysfunction of neuro-endocrine-immune complex and
metabolism, characteristic for premorbid (intermediate between health and illness) state.

In the morning on an empty stomach we registered kirlianogram by the method of GDV by
the device of “GDV Chamber” (“Biotechprogress”, SPb, RF). The first base parameter of GDV is
Area of gas discharge image (GDI) in Right, Frontal and Left projections registered both with
and without polyethylene filter. The second base parameter is the Shape coefficient (ratio of
square of length of external contour of GDI toward his area), which characterizes the measure of
serration/fractality of external contour. The third base parameter of GDI is the Entropy [17,18].
The most recent set of parameters was selected for further analysis in this article.

Than we recorded EEG (hardware-software complex “NeuroCom Standard”, KhAI Medica)
monopolar in 16 loci (Fp1, Fp2, F3, F4, F7, F8, C3, C4, T3, T4, P3, P4, T5, T6, O1, O2) by 10-
20 international system, with the reference electrodes A and Ref on the tassels of ears. Among
the options considered the normalized (%) spectral power density (SPD) in the standard
frequency bands: β (35÷13 Hz), α (13÷8 Hz), θ (8÷4 Hz) and δ (4÷0,5 Hz) in all loci, according
to the instructions of the device.

Simultaneosly we recorded electrocardiogram in II lead (hardware-software complex
"CardioLab+HRV", "KhAI-Medica") to assess the parameters of HRV. For further analysis



32

(Frequency Domain Methods) were selected normalized (%) spectral power (SP) bands of HRV:
high-frequency (HF, range 0,4÷0,15 Hz), low-frequency (LF, range 0,15÷0,04 Hz), very low-
frequency (VLF, range 0,04÷0,015 Hz) and ultra low-frequency (ULF, range 0,015÷0,003 Hz)
[15].

We calculated for HRV and each locus EEG the Entropy (h) of normalized SPD using
formulas [22] based on classic CE Shannon’s formula:
hHRV = - [SPHF•log2SPHF+SPLF•log2SPLF+SPVLF•log2SPVLF+SPULF•log2SPULF]/log24;
hEEG = - [SPDα•log2SPDα+SPDβ•log2SPDβ+SPDθ•log2SPDθ+SPDδ•log2SPDδ]/log24

In portion of capillary blood we counted up Leukocytogram (LCG) (Eosinophils, Stub and
Segmentonucleary Neutrophils, Lymphocytes and Monocytes) and calculated its Entropy (h)
using formula:
hLCG = - [Lym•log2Lym+Mon•log2Mon+Eos•log2Eos+SNN•log2SNN+StubN•log2StubN]/log25

For phenotyping subpopulations of lymphocytes used the methods of rosette formation with
sheep erythrocytes on which adsorbed monoclonal antibodies against receptors CD3, CD4, CD8,
CD22 and CD16 from company "Granum" (Kharkiv) with visualization under light microscope
with immersion system [21]. Next we calculated also the Entropy of Immunocytogram (ICG)
using formula:
hICG = - [CD4•log2CD4+CD8•log2CD8+CD22•log2CD22+CD16•log2CD16]/log24

Every day four people were tested. A week later, all the tests were repeated. Results
processed using the software package "Statistica 5.5".

RESULTS AND DISCUSSION

According to the formula:
|r|≥{exp[2t/(n-1,5)0,5] - 1}/{exp[2t/(n-1,5)0,5] + 1},

for a sample of 40 observations critical value of correlation coefficient module at p<0,05 (t>2,02)
is 0,31, at p<0,01 (t>2,70) is 0,41, at p<0,001 (t>3,55) is 0,52.

In the first stage of the analysis a correlation matrix is created (Table 1).



33

Table 1. Correlation matrix for Entropies of gas-discharge image, spectral power
density EEG loci, HRV, Leukocytogram and Immunocytogram

Entropy Right
GDI

Right
GDI (f)

Frontal
GDI

Frontal
GDI (f)

Left
GDI

Left
GDI (f)

Right GDI 1,00 ,46 ,71 ,42 ,58 ,31
Right GDI (f) ,46 1,00 ,50 ,69 ,49 ,64
Frontal GDI ,71 ,50 1,00 ,58 ,77 ,36
Frontal GDI (f) ,42 ,69 ,58 1,00 ,50 ,64
Left GDI ,58 ,49 ,77 ,50 1,00 ,44
Left GDI (f) ,31 ,64 ,36 ,64 ,44 1,00
Fp2 ,09 ,10 ,18 ,16 ,08 ,06
F4 ,08 -,07 ,16 -,04 ,07 -,14
F8 -,01 -,19 -,02 -,24 -,07 -,46
T4 -,22 -,08 -,06 -,27 -,02 -,16
C4 ,03 -,07 -,06 -,04 -,17 -,19
T6 ,17 -,01 ,03 -,12 -,05 -,08
P4 ,24 ,20 ,19 ,27 ,13 ,02
O2 ,21 ,21 -,02 ,06 ,04 ,11
Fp1 -,00 -,07 -,06 ,11 -,15 ,05
F3 ,19 ,14 ,28 ,19 ,25 -,02
F7 -,03 -,03 ,08 ,10 -,19 -,11
T3 -,22 -,05 -,07 -,08 -,24 -,22
C3 ,01 -,14 -,17 -,11 -,24 -,19
T5 ,10 -,17 -,07 -,10 -,07 -,14
P3 ,20 ,12 ,09 ,20 ,04 ,05
O1 ,16 ,24 ,13 ,31 ,17 ,19
HRV -,10 -,05 -,08 -,24 -,21 -,10
LCG ,30 -,08 ,30 ,18 ,18 ,14
ICG -,25 -,18 -,26 -,21 -,27 -,30

To visualize correlations we should decide concerning factor (argument) and effective
(function) parameters. As stated in the previous article, in terms of mathematics it does not matter,
while in terms of physiology there is the perennial problem of cause and effect. We have chosen
as a factor GDV parameters [10].

As a result of the screening, the most significant relationship was found between the GDI
entropy (filtered) in the left projection and the SPD EEG entropy in the right lateral frontal locus
(Fig. 1). Unfortunately, intrigue about cross-linking such as the corticospinal pyramid tract has
been dispelled by other facts.

The inclusion in the multiple regression model of the second, by the power of the link,
variable brought about the aesthetic pleasure of the three-dimensional image (Fig. 2), but no more,
judging by R.



34

F8H      = 2,3630 - ,4318  * ELF
Correlation: r = -,4553

3,3 3,4 3,5 3,6 3,7 3,8 3,9 4,0 4,1

ELF

0,3

0,4

0,5

0,6

0,7

0,8

0,9

1,0

F8H

95% confidence

Fig. 1. Scatterplot of correlation between the entropy GDI (filtered) on the Left
projection (X-axis) and the entropy in F8 locus EEG (Y-axis)

Quadratic Surface
Z = Distance Weighted Least Squares

 0,8 
 0,6 
 0,4 
 0,2 
 0 

F8h=2,22-0,472•ELf+0,081•EFf; R=0,458; R2=0,210; F(2,4)=4,9; p=0,013

Fig. 2. Scatterplot of dependence of entropy in F8 locus EEG (Z-axis) on entropies GDI
(filtered) on the Left (X-axis) and Frontal (Y-axis) projections



35

In the next step, the canonical correlation between the entropy indices of the gas-discharge
image taken without a filter and with a filter in three projections, on the one hand, and SPD 16
EEG loci, on the other, was analyzed.

By stepwise exclusion, 5 variables were included in the canonical GDV root structure, and 6
variables were included in the root EEG structure (Table 2). Judging by the factor loadings, the
causal root represents directly, mainly, the entropy of GDI (with filter) in the left projection,
while the entropy of GDI (without filter) in the right projection reflects inversely.

On the other hand, the EEG root reflects the SPD entropy at five loci inversely and only one
directly. Overall, GDI entropy determines the SPD EEG entropy by 33% (Fig. 3).

Table 2. Factor structure of canonical correlation between Entropy of GDI (right set) and
EEG (left set)

Right set R
Left GDI (f) ,536
Left GDI ,158
Right GDI -,420
Frontal GDI (f) -,084
Frontal GDI -,055
Left set R
F8H -,514
P4H -,478
C3H -,454
F3H -,237
O1H -,141
T4H ,360

hGDV

E
ntropy E

E
G

-2

-1

0

1

2

-2 -1 0 1 2

R=0,575; R2=0,330; χ2(30)=38; p=0,158; Λ Prime=0,341
Fig. 3. Scatterplot of canonical correlation between Entropy of GDI (X-line) and EEG (Y-
line)



36

The additional inclusion in the left set parameters of HRV, LCG and ICG entropies gives a
significant increase in the canonical relationship between the roots. This changes the factor
structure of the roots. Contrary to expectations, HRV entropy was found outside the model (Table
6 and Figure 4).

Table 6. Factor structure of canonical correlation between Entropy of GDI (right set) and
EEG,LCG&ICG (left set)

Right set R
Right GDI ,50
Frontal GDI ,24
Frontal GDI (f) ,24
Left GDI (f) -,33
Right GDI (f) -,28
Left GDI -,03
Left set R
LCGH ,477
P4H ,335
C3H ,287
F8H ,229
F3H ,183
O1H ,121
T4H -,440
ICGH -,006

hGDV

E
ntropy E

E
G

,IC
G

,LC
G

-2

-1

0

1

2

-2 -1 0 1 2

R=0,699; R2=0,489; χ2(48)=54; p=0,262; Λ Prime=0,181
Fig. 4. Scatterplot of canonical correlation between Entropy of GDI (X-line) and EEG as
well as LCG&ICG (Y-line)



37

CONCLUSION

We have documented the relationship between the entropy parameters of
electroencephalogram, blood leukocytogram and immunocytograms on the one hand, and gas-
discharge images on the other. However, the question of the causal nature of this relationship
remains open. What is primary: electrical activity of the brain, excretion of cytokines and
hormones by immunocytes, or emission of photons and free electrons by acupuncture points
[17,18] (circulation of vital energy [32])?

ACKNOWLEDGMENT

We express sincere gratitude to administration of JSC “Truskavets’kurort” and “Truskavets’
SPA” for help in conducting this investigation.

ACCORDANCE TO ETHICS STANDARDS

Tests in patients are conducted in accordance with positions of Helsinki Declaration 1975, revised and
complemented in 2002, and directive of National Committee on ethics of scientific researches. During
realization of tests from all participants the informed consent is got and used all measures for providing of
anonymity of participants.

For all authors any conflict of interests is absent.

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