RU2290061C2 - Method for detecting human capacity for extrasensory perception according to electroencephalogram data - Google Patents

Abstract

FIELD: medicine, psychophysiology.

SUBSTANCE: it is necessary to plot electroencephalogram (EEG) from the surface of standard points of patient's head. In the strip ranged 0.1-75 Hz it is necessary to isolate the range of cerebral potentials fluctuations that corresponds to combination of maximal values of spectral power and coherence for the above-mentioned points of the head. Then one should calculate the coordinates of spatial localization of equivalent dipolar sources of potentials in specified range of frequencies. At localization from 30 to 100% equivalent dipolar sources at dipolar coefficient being 0.90-1.00 in right-hand hemisphere between deep and frontal cerebral areas one should detect human capacity to extrasensory impact. The innovation enables to obtain objective data on human capacity for extrasensory perception.

EFFECT: higher accuracy and efficiency of detection.

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Description

The invention relates to medicine, traditional methods of diagnosis and treatment, neurophysiology and psychophysiology, in particular to methods for studying a person's ability to extrasensory perception according to electroencephalogram.

There is a method of determining a person’s ability to alternative vision, which is one of the types of extrasensory perception, including multi-channel recording of an electroencephalogram (EEG) by removing potentials of the brain from the surface of standard points of the head, with changes in the amplitude-frequency characteristics of biorhythms of the cerebral cortex, manifested in the form of an increase values of indicators of beta potentials and epileptiform activity, as well as the occurrence of evoked brain potentials in response to The use of visual stimuli bypassing the visual signal transmission channel to the brain is judged on the ability to alternative vision (N. Bekhtereva et al. “On the so-called alternative vision or direct vision phenomenon.” Human Physiology. 2002, v. 28, No. 1 , p.23-34).

However, this known method does not give a real picture of the integral volumetric activity of the brain, but provides only an assessment of the dynamics of the bioelectrical activity of the surface zones of the cerebral cortex with alternative vision. In this case, the conscious activity of a person is determined indirectly, through the neural activity that forms the EEG and evoked potentials on the surface of the head. Therefore, in a known manner it is impossible to conduct a differential assessment of this ability, not only with alternative vision, but also with another form of extrasensory perception.

According to the technical essence, the closest to the present invention is a method for determining (physiological analysis) of a person's ability to extrasensory perception according to the electroencephalogram, with which an increase in the value of the difference of electric potentials in the occipital and frontal areas of the right hemisphere of the brain during extrasensory perception and an increase in the value of the difference of electric potentials are evaluated in the occipital and frontal areas of the left hemisphere of the brain with non-contact movement of objects (log l «Life Information Science», vol.20, №2, Sept.2002, str.345, paper "Physiological Analysis for Consciousness Power" authors Yoshio MACHI, Chao LIU, Chang WANG et al.).

However, in the known method, the physical reality of the properties of extrasensory perception is not disclosed, since it is determined indirectly through changes in electric potentials on the surface of the head without calculating the coordinates of the spatial localization of equivalent dipole potential sources of the selected frequency range.

The technical result is to increase the reliability of determining a person’s ability to extrasensory perception, including persons with a potential, but not yet realized ability, as well as a differentiated definition of abilities for extrasensory perception.

This is achieved by the fact that the method of determining a person’s ability to extrasensory perception according to the electroencephalogram includes multichannel recording of the electroencephalogram while measuring potentials from the surface of standard points of the head and evaluating the possibilities of consciousness by the amplitude-frequency characteristics of the potentials of the cerebral cortex, while in the frequency band of 0.1 ... 75 Hz allocate the frequency range of oscillations of the potentials of the brain, corresponding to a combination of the maximum values of the spectral m the coherence and coherence for the above standard points of the head, the coordinates of the spatial localization of equivalent dipole sources of potentials of the selected frequency range are calculated, the nature of localization is estimated, and at a location of 30 to 100% of equivalent dipole sources with a dipole coefficient of 0.90 ... 1.00 , in the right hemisphere between the deep and frontal areas of the brain determine the ability of a person to extrasensory perception.

The essence of the claimed invention lies in the fact that a person’s ability to extrasensory perception is determined by the distribution (directed flow) of equivalent dipole sources calculated according to electroencephalograms based on spatial localization algorithms of equivalent sources of brain electrical activity using a current dipole model (V. Gnezditsky ., Koptelov Yu.M. “Three-dimensional localization of sources of EEG rhythms based on the equivalent dipole model”, material s of the 8th All-Union Conference on the Electrophysiology of the Central nervous system, Yerevan, Academy of Sciences of the Arm.SSR, 1980, p. 256-257).

The coordinates of the equivalent dipole sources are calculated on the basis of an algorithm in which the values of the parameters recorded from the surface of the head of the oscillations of potentials integrally reflecting the activity of the brain are entered. The calculation results reflect this activity in the next step of integrating the activity of the brain as a whole. The direction of the flow of equivalent dipole sources is influenced by the systemic activity of the brain with alternating predominance of activity of individual regions of the right or left hemisphere, which is manifested in the temporal dynamics of the extrasensory abilities of the human operator (i.e., the ability to spatiotemporally structure the active medium, for example, the brain or other organ of an individual )

Figure 1 presents the results of multi-channel recording of potentials from the surface of standard points of the head during a calm state of wakefulness (background), Figure 2 shows an example of recording EEG (electroencephalograms) of an operator during extrasensory perception, Figure 3 shows diagrams of the distribution of the spectral power of oscillations EEG potentials, Fig. 4 is a diagram showing the number of coherent bonds.

The determination of the ability to extrasensory perception begins with the procedure of multichannel registration of EEG in the frequency range 0.1 ... 75 Hz by simultaneously diverting brain biopotentials for 80 ... 100 seconds from the surface of 8 ... 256 standard points of the head adopted by the international location system electrodes on the head (Homan RW, Herman J., Purdy P. Cerebral location of international 10-20 system electrod placement. EEG a. Clin. NeurophysioL, 1987, v.66, pp.376-382).

The number of standard points of the head for recording the biopotentials of the brain affects the accuracy of calculating the coordinates of the spatial localization of equivalent dipoles. The minimum number of 8 points is determined by the algorithm for the numerical solution of the inverse problem of electroencephalography (Koptelov Yu.M. Research and numerical solution of some inverse problems of electroencephalography. Diss. For the degree program. Ph.D. M., M., 1988), the maximum number of 256 points is a limitation associated with the technical capabilities of creating a multi-channel amplifier-encephalograph in modern production.

The frequency band of 0.1 ... 75 Hz and the time of registration of brain biopotentials depend on the individual characteristics of the human condition and the corresponding organization of the rhythmic activity of the brain (Human Physiology. 2003, v.29, No. 2, p. 18-27), with extrasensory perception - additionally in the range of beta and gamma oscillations (13 ... 75 Hz) (Bekhtereva N.P., Lozhnikova L.Yu., Danko S.G., Melyucheva L.A., Medvedev S.V., Davitaia S.Zh. On the so-called alternative vision or the phenomenon of direct vision (Human Physiology, 2002, v. 28, No. 1, pp. 23-34). At a minimum frequency of 0.1 Hz, the period of one oscillation is 10 seconds, however, to evaluate the reproducibility of the results of calculations of spectral and coherent types of analysis, the recording time is increased to 80 ... 100 seconds, which allows a subsequent assessment of up to 8 ... 10 oscillations. This registration period meets the same requirements for reproducibility when activating the rhythmic activity of the brain at higher frequencies.

It is known that the values of the spectral power of the EEG in a certain frequency range correspond, according to neurophysiological studies (Zenkov L.R., Ronkin M.A. Functional diagnosis of nervous diseases. M., "Medicine", 1991, p.640), involvement of neurons in the activity with refractory periods corresponding to this frequency range. An increase in the value of spectral power can be associated both with an increase in the number of active neurons and with an increase in the level of synchronization of neural pulses. On the other hand, an increase in the level of coherence between fluctuations in the potential of any two brain regions indicates an increase in the functional relationship between these two regions (Livanov MN, Rusinov BC, Simonov PV, etc. Diagnosis and prediction of the functional state of the human brain Academy of Sciences of the USSR, Moscow, "SCIENCE", 1988, p.206). It has been established that potential fluctuations between two brain structures can be considered highly coherent if the value of the coherence coefficient is in the range of 0.8 ... 1. Thus, a simultaneous increase in the values of spectral power and coherence in a single frequency range indicates a certain nature of brain activity.

Then, frequency clusters are distinguished according to indicators of alternating maxima and minima of the spectral power values and compared with indicators of coherence. In order to isolate the frequency cluster, the values of the previous and subsequent minima are taken with respect to the maximum of the spectral power indices. The criterion of novelty is the sign of the allocation of a frequency cluster with a maximum spectral power, the frequency of which simultaneously corresponds to the maximum number of coherent links between regions of the cerebral cortex with a coherence coefficient of 0.8 ... 1.

Filter the EEG data, highlighting the rhythmic fluctuations of the potential in the frequency range of the found cluster and the selected oscillations using a special approximation algorithm (Gnezditsky V.V., Koptelov Yu.M. “Three-dimensional localization of EEG rhythm sources based on the equivalent dipole model.” Materials 8- of the All-Union Conference on the Electrophysiology of the Central nervous system, Yerevan, Academy of Sciences of the Armenian SSR, 1980, p. 256-257) the coordinates of the three-dimensional localization of the centers of electrical activity are calculated, presented for each time point of a digital readout in the form equivalent dipole current sources inside the brain. Sources with a dipole coefficient of 0.90 ... 1 are distinguished, then the nature of the distribution of sources in the deep structures of the brain is evaluated. With a concentration of sources mainly in the interhemispheric region in the front of the brain, the potential for extrasensory perception is determined.

Since the coordinates of the equivalent dipole sources are calculated on the basis of an algorithm into which the values of the parameters of potential oscillations recorded from the surface of the head are entered that integrally reflect brain activity, the calculation results reflect this activity in the next step of integrating the brain activity as a whole. The systemic activity of the brain with a predominance of activity of certain regions of the right hemisphere is manifested in the dynamics of the extrasensory properties of an individual human operator.

This is a combination of essential features, providing a result in all cases to which the subject of the invention applies.

Thus, when distributing equivalent dipole sources of potentials of the selected frequency range in the form of a stream directed from the depth of the brain to the surface of the head towards the forehead in the right hemisphere, the person’s ability to extrasensory perception is determined.

Figure 1 presents the results of multi-channel recording of potentials from the surface of 16 standard points of the head during a calm state of wakefulness (background). The numbers on the left side indicate the areas of the cerebral cortex corresponding to the following designations of the standard points of the head: 1 - Fz (central frontal); 2 - F4 (right frontal); 3 - C4 (right central); 4 - P4 (right parietal); 5 - O2 (right occipital); 6 - Cz (central sagittal); 7 - F3 (left frontal); 8 - C3 (left central); 9 - P3 (left parietal); 10-01 (left occipital); 11 - F8 (right frontotemporal); 12 - T4 (lower right central); 13 - T6 (right lower shadow); 14 - F7 (left frontotemporal); 15 - T3 (lower left central); 16 - T5 (left lower shadow). At the bottom, a time scale of 1 second is indicated; on the right, the potential difference is 50 μV. The rhythmic activity of the brain is observed, which is characteristic of a state of calm wakefulness with closed eyes, which is accompanied by the spread of the alpha rhythm with a frequency of 8-10 vibrations per second over the surface of the cerebral cortex with pronounced zonal differences and maximum values of the potential difference in the occipital and parietal regions.

Figure 2 gives an example of recording an EEG of the operator during extrasensory perception. Designations are the same as in Figure 1. There is a decrease in the amplitude of fluctuations of the alpha rhythm and an increase in the amplitude of oscillations of the theta rhythm with a frequency of 5-6 vibrations per second, most pronounced in the frontal and central regions of the cerebral cortex.

Figure 3 presents a diagram of the distribution of the spectral power of the oscillations of the potentials of the EEG. To the left of the diagram, the numbers indicate the corresponding standard points on the surface of the head, as in Figure 1. Below is given the scale of the considered frequency range (Hz). On the right are the maximum values of the spectral power indices (μV ² ) of the EEG at a frequency of 5.875 Hz at the corresponding standard points of the head (1 ... 16).

Figure 4 presents diagrams showing the number of connections between 16 regions of the cerebral cortex corresponding to 16 standard points on the surface of the head, determined by the coherence coefficient of 0.8 ... 1 (scale on the right) at each frequency with a step of 1 Hz in the range 0 ... 7 Hz (scale below). The maximum number of bonds is observed in the range of 80 ... 100 at a frequency of 5 ... 6 Hz.

Figure 5-1 gives an example of the distribution of equivalent dipole sources in the right hemisphere of an operator with extrasensory abilities. The coordinates of the equivalent dipole current sources, highlighted in white, are given in accordance with the coordinate axes of the schematic image of the brain. The X axis passes between the central points of the nasolabial deepening (nasion) and the occipital protuberance (inion); Y axis - between the central points of the ear holes; the Z axis is the line perpendicular to the intersection of the X and Y axes. Brain diagrams are given: A - projection from the side from left to right, B - projection from top to bottom, C - projection from front to back. In the lower left corner is given the scale of the length of the axes (cm).

The implementation of the method is as follows.

During the procedure for determining the capacity for extrasensory perception, the human operator is located in a room equipped for electroencephalography with sensors of brain bio-potentials attached to the head. Operator sensors are switched with an electroencephalograph. In this case, a standard international scheme of biopotential leads from the surface of the head is used (Homan RW, Herman J., Purdy P. Cerebral location of international 10-20 system electrod placement. EEG a. Clin. Newophysiol., 1987, v. 66, pp.376 -382). In the process of recording the EEG, a monopolar lead system is used, where an integrated pair of ear sensors is connected as an indifferent one.

Brain biopotentials from electroencephalograph amplifiers are introduced into a computer using an analog-to-digital converter and files are generated in the operator’s database. After viewing the files, checking and eliminating artifacts, the EEG is processed in the frequency band of 0.1 ... 75 Hz using computer programs for spectral and coherent analysis.

The algorithm for obtaining the EEG spectral characteristics is based on the fast Fourier transform method (Cooley J.W., Tukey J.W. An Algorithm for the Machine Calculation of Complex Fourier Series. Mathematics of Computation, 1965, v.19, No. 90, p. 297).

According to the Parseval theorem, in the Fourier transform, the energy in the time domain is equal to the energy in the frequency domain, i.e. the mean square of the signal amplitude is equal to the total power of the spectrum. If we filter the initial EEG signal in any range, the dispersion (i.e., the average squared amplitude) of this signal will be equal to the spectral power in this range (A. Mitrofanov, “Brainsys computer system for analysis and topographic mapping of brain electrical activity” ". Statokin, 1999, p.65).

The indicators of the coherence of potential fluctuations between separate regions of the cerebral cortex at the frequency of each selected cluster are calculated and the number of coherent relationships is determined by the indices of the coherence function Λ ² _xy , which have values of 0.8 ... 1 between all regions of the cerebral cortex. The basis of coherent analysis using the function of coherence (Bendat D., Pirsol A. Application of correlation and spectral analysis. M., 1983, p. 312).

Based on the obtained values of the spectral power and EEG coherence, the frequency range of the potential oscillations of the brain corresponding to the combination of the maximum values of the spectral power and coherence is selected, then the potential fluctuations are filtered within the selected frequency range and three-dimensional localization coordinates of the equivalent dipole sources of potentials are calculated, and then the nature of the localization of the sources is determined , and when 30 ... 100% of sources are located with a dipole coefficient of 0.90 ... 1.00, in the right hemispheres determine the ability to extrasensory perception, including the potentially available, but not yet conscious ability.

Example 1. During the conduct of extrasensory diagnosis of the state, the EEG of the healer P. was recorded - psychic. The results of multichannel recording of potentials from the surface of 16 standard points of his head during a state of calm wakefulness (background) are presented in Fig. 1, and the results in the process of extrasensory perception are presented in Fig. 2. Compared with the recording data during a state of calm wakefulness, the features of the EEG during extrasensory perception are expressed in periodic changes in the EEG rhythm - a decrease in the amplitude of the main alpha rhythm with a frequency of 8 ... 13 vibrations per second and an increase in the amplitude of the theta rhythm with a frequency of 5 ... 6 oscillations per second during time intervals of 3 ... 12 seconds. On the graph of the distribution of the spectral power of the EEG (Figure 3), its maximum value equal to 36.3 μV ² in the Fz region is determined at a frequency of 5.875 Hz and the frequency range between the minimum values corresponding to the band of 5 ... 6 Hz is distinguished. Compare with the indicators of coherence in individual frequency ranges with a discrete step of 1 Hz and find that the maximum coherence indicator coincides with the frequency of the maximum power indicator in frequency of 5 ... 6 Hz (Figure 4). Filter the EEG in the frequency band of 5 ... 6 Hz and calculate the distribution of equivalent dipole sources of the origin of the EEG rhythm of 5 ... 6 Hz. Equivalent dipole current sources are distributed in the form of a directed flow coming from the depth of the brain and entering the frontal region of the right hemisphere (Figure 5-1). The observed phenomenon reflects the ability of the healer P. to extrasensory perception.

The above type of testing was also carried out with other psychic healers. The results of these tests were identical to the above example.

Thus, the use of standard devices (sensors, electroencephalographs), generally accepted mathematical methods of spectral and coherent analysis, subject to the required test conditions, gives reason to judge that this method is reproducible, reliable and can be used to determine the ability to extrasensory perception.

The absence in the closest analogue of the totality of the essential features of the invention allows to judge the compliance with the criterion of "novelty", and the absence of distinctive features in the analogues allows us to confirm compliance with the criterion of "inventive step".

The stated advantages of the proposed method provide the possibility of its use to determine the person’s ability to extrasensory perception, as well as for testing individuals with potentially existing, but not yet conscious ability to extrasensory perception.

Claims (1)

A method for determining a person’s ability to extrasensory perception according to an electroencephalogram, characterized in that it includes multi-channel recording of an electroencephalogram while measuring potentials from the surface of standard points of the head and evaluating the possibilities of consciousness by the amplitude-frequency characteristics of the potentials of the cerebral cortex, while in the frequency band of 0.1 ... 75 Hz allocate the frequency range of oscillations of the potentials of the brain, corresponding to a combination of the maximum values of the indicators spectrally power and coherence for the above standard points of the head, the coordinates of the spatial localization of equivalent dipole sources of potentials of the selected frequency range are calculated, the nature of localization is estimated, and from 30 to 100% of equivalent dipole sources with a dipole coefficient of 0.90 ... 1.00 in the right hemisphere between the deep and frontal areas of the brain determine the ability of a person to extrasensory perception.

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