RU2109482C1 - Method and device for diagnosing average induced brain potential - Google Patents

Abstract

FIELD: medicine. SUBSTANCE: method involves acting upon an object with short duration signal of known magnitude. Its maximum value is less than signal magnitude corresponding to pain syndrome. It is recorded during 500 ms beginning from the moment the signal is emitted as averaged analog/digital signal. Search area of P2, N2 components of long-latent induced potential is set within the interval from the moment the signal is emitted to 340 ms. Two time intervals are selected, maximum and minimum signal values are determined and absolute value of difference between the maximum and minimum signal values is calculated. The obtained absolute value of difference is compared to K value, where K is coefficient determined in experimental way. The value is used for making conclusions concerning the presence of long-latent induced brain potential. EFFECT: enhanced effectiveness in diagnosing vision, hearing and tactile sensation threshold. 12 cl, 7 dwg

Description

 The invention relates to a method for determining, measuring and recording bioelectric signals of an organism, and more specifically to a method for diagnosing averaged evoked brain potential and a device for its implementation.

 The invention can be used to diagnose the threshold of vision, hearing threshold and threshold of tactile sensitivity in people of a wide age range from newborns to the elderly, including patients with mental retardation, as well as in veterinary medicine for the diagnosis of animals.

Automatic diagnosis of the level of sensory sensitivity, in particular the threshold of hearing, threshold of vision, threshold of tactile sensation, and in a broader sense, the diagnosis of the evoked potential of any modality is very important, as it allows:
it is more efficient to carry out the selection of specialists in the examination of professional suitability for persons whose profession requires increased sensitivity to visual, auditory and tactile stimuli: pilots, controllers, athletes, military personnel and others;
more effectively conduct a survey of the general population, in particular schoolchildren and the elderly, for early detection of perceptual impairment and lack of sensory sensitivity;
it is more effective to conduct clinical studies of patients with impaired sensory sensitivity of any modality - auditory, visual, tactile (somatosensory), including mentally retarded people.

Evoked potentials of various modality - auditory, visual, somatosensory, are recorded from the surface of the human head and are classified into three main groups:
stem latent evoked potentials arising during the first 10 ms after signaling;
mid-latent brain responses that occur between 7 and 50 ms after signaling:
long-latent evoked brain potentials arising with a delay of 50-500 ms after signaling.

 The evoked potentials of all these groups attract a lot of attention of researchers both as a neurological tool and as a tool for studying hearing, vision and tactile perception.

 A known method for diagnosing an averaged long-latent evoked potential of the brain, which consists in exposing the subject to a short-duration signal of a certain magnitude, the maximum value of which is less than the magnitude of the signal corresponding to pain syndrome, and recording the induced electrical activity of the subject's brain in the form of an electrical voltage signal, and then analyze the obtained long-latent evoked potentials of the brain.

 A device is also known for diagnosing an averaged long-latent evoked potential of the brain, comprising a means for delivering to the subject a short-duration external signal of a certain magnitude, the maximum value of which is less than the magnitude of the signal corresponding to pain syndrome, and a means for recording the electrical activity of the brain of the subject in the form of an electrical voltage signal connected to analysis unit of long-latency evoked brain potentials.

 In this method, an audio signal is used to feed it into the ear of a sleeping patient, while the carrier part is modulated in a special way by a signal with a frequency of more than 60 Hz. With such a signal, an increase in the signal-to-noise ratio in the electrical activity of the brain during sleep is observed and evoked potentials of a stable state with a locked phase arise. Recognition of these potentials in the analysis of the induced electrical activity of the brain allows you to measure the level of hearing in the studied subjects, in particular in newborns, young children and mentally retarded people.

 In this method, the time of exposure to the patient with the indicated signal is substantially long, which is due to the physiologically necessary time of the appearance in the brain of the evoked potentials of a stable state with a locked phase.

 When processing the obtained evoked potentials, the Fourier method is repeatedly applied at all stages of the analysis of the brain response.

 Fourier series are traditionally often used in the analysis of the electrical activity of the brain in general and evoked potentials in particular. This is due to the fact that the Fourier analysis allows you to formally describe and study the shape and calculate the parameters of the curves representing the electrical activity of the brain. The appearance of such curves is strongly individual for each subject and their analysis uses the procedure of multiple calculation of the expansion coefficients in the Fourier series so that the result describes the studied process in a particular subject quite well.

 Each procedure for calculating the coefficients contains the processing of each recording point of brain activity. Thus, the determination of the expansion coefficients in a Fourier series certainly includes the repeated exhaustive search of all recording points of brain activity.

 Therefore, the device for implementing this method has a complex structure and one of its features consists in the method of generating a modulated sound signal that affects the subject, because the specificity of this signal contains the prerequisites for the analysis and diagnosis of sound evoked potential.

 The high computational complexity of the task requires the use of specialized or standard powerful computer tools, while the calculation process is time-consuming and requires large amounts of memory.

 The basis of the invention is the task of creating a method for the diagnosis of averaged short-latency and long-latent evoked potential of the brain, in which the analysis of extremes at selected recording intervals of the investigated evoked potential allows to simplify the diagnosis of people and animals and increase its effectiveness in determining the hearing threshold, visual threshold and threshold of tactile sensation.

 The basis of the present invention is also the task of creating a device for the diagnosis of averaged short-latency and long-latent evoked potential of the brain, in which the presence of extrema analysis units and their connections with the decision-making unit allows us to simplify the device, increase the accuracy of processing the evoked potential, increase its speed, reliability, and reduce the cost of the procedure determination of the threshold of hearing, threshold of vision and threshold of tactile sensation in humans and animals.

 The problem is solved in that in a method for diagnosing a long-latent evoked potential of the brain, which consists in exposing a subject to a short-duration signal of a certain magnitude, the maximum value of which is less than the magnitude of the signal corresponding to pain syndrome, and recording the induced electrical activity of the brain of the subject in the form of an electric voltage signal, and then analyze the obtained long-latency evoked potentials of the brain, according to the invention, the evoked electrical act The brain function is recorded for 500 ms, starting from the moment of signal input in the form of an averaged analog / digital signal, the search area for the components P2, N2 of the long-latent evoked potential is set in the interval from the signal moment to 340 ms, two time intervals from T1 to T2 and from T2 to 340 ms for P2 and N2, respectively, where T1 and T2 are the boundaries of time intervals, depending on the type of receptor structure, determine the maximum signal value in the interval from T1 to T2 ms and the minimum value the signal in the interval from T2 to 340 ms, calculate the modulus between the maximum and minimum values of the signal defined above, compare the obtained value of the difference modulus with the value of K, where K is the experimentally determined coefficient, and judging by the positive number obtained as a result of the comparison, the presence of long-latent evoked potential brain, and by the negative number obtained as a result of the comparison, the absence of a long-latent evoked potential of the brain is judged.

 It is advisable that a tonal sound signal with a duration of 100 to 200 ms be used as the signal that affects the subject.

 It is useful that a flash of light or a flash of the picture tube screen is used as a signal that affects a subject.

 Advantageously, the signal selected from the group consisting of a mechanical deformation force, a temperature shift, or an electric signal in the form of a rectangular voltage pulse is used as the signal that affects the subject.

 It is advisable that, in order to determine the sensitivity threshold of the receptor structure, the subject is additionally exposed at least once by a signal whose value is less than the value of the signal of the previous exposure, if the long-latent potential was present as a result of the previous exposure, the induced electrical activity of the brain of the subject was recorded for 500 ms, starting from the moment of the signal, in the form of an averaged analog / digital signal, set the search area of the components P2, N2 long-latent of the evoked potential in the interval from the moment of signal input to 340 ms, two time intervals from T1 to T2 and from T2 to 340 ms for P2 and N2, respectively, were allocated in the established search area, where T1 and T2 are the boundaries of time intervals depending on the type of receptor structure , the maximum signal value in the range from T1 to T2 ms and the minimum signal value in the interval from T2 to 340 ms were determined, the modulus of the difference between the maximum signal value determined above was calculated, the obtained value of the difference modulus was compared with the value of K, where K is the mouth copulating experimental coefficient, and comparing the resulting positive number judged available long-latency evoked potential under provided additional exposure, and comparing the resulting negative number - the absence of long-latency evoked potential under provided additional exposure.

 It is useful that, in order to determine the threshold of sensitivity of the receptor structure, the subject is additionally exposed at least once by a signal whose value is greater than the value of the signal of the previous exposure, if the long-latent cortical potential was absent as a result of the previous exposure, the induced electrical activity of the brain of the subject was recorded for 500 ms, starting from the moment of the signal, in the form of an averaged analog / digital signal, the search area of the components P2, N2 of the long-latency of the potential in the interval from the moment the signal was delivered to 340 ms, two time intervals from T1 to T2 and from T2 to 340 ms P2 and N2, respectively, were allocated in the established search area, where T1 and T2 are the boundaries of time intervals depending on the type of receptor structure, the maximum signal value in the range from T1 to T2 ms and the minimum signal value in the interval from T2 to 340 ms were determined, the modulus of the difference between the maximum signal value determined above and the minimum signal value was calculated, the obtained value of the difference module with K value, where K is the experimentally determined coefficient, and the positive number obtained as a result of the comparison was used to judge the presence of a short-latent cortical evoked potential of the brain with an additional effect, and the negative number obtained as a result of the comparison was judged as the absence of a long-latent evoked potential when the additional effect was exerted.

 It is advisable that the accuracy of measuring the sensitivity threshold of the receptor structure is set and the subject is exposed at least once more to a signal whose value differs from the previous value of the signal by a multiple of a given measurement accuracy.

The problem is also solved by the fact that in the method for diagnosing an averaged short-latency evoked brain potential, which consists in exposing a subject to a short-duration signal of a certain magnitude, the maximum value of which is less than the magnitude of the signal corresponding to pain syndrome, and recording the induced electrical activity of the brain of the subject in in the form of an electrical voltage signal, and then analyze the resulting latent evoked potentials of the brain, according to the invention is called the electrical activity of the brain is recorded for 10 ms, starting from the moment of signal input, in the form of an averaged analog / digital signal, the search area for the main peaks of the short-lattice evoked potential is set in the interval from the moment of signal input to 10 ms, a number of time intervals are selected in the set search area by the number of extrema, determine the extreme value of the signal at each selected interval, calculate the absolute value of the difference between adjacent extreme values, compare the sequence no each obtained difference value with the corresponding value K _i of the module, where K _i - established experimentally factor for each time slot, i - is an integer corresponding to the number of the interval, and the resulting each comparison positive number judged on the presence on each interval of the peak brainstem evoked potential of the brain, and the negative number obtained as a result of each comparison judges the absence of a peak of short-latency evoked potential in each interval.

 It is advisable that for the diagnosis of passing levels of the auditory system, the number of successive peaks of the short-latent evoked potential, starting from the moment of the signal, according to which passable levels of the auditory system are judged, is determined.

 The problem is also solved by the fact that in a device for diagnosing an averaged long-latent evoked brain potential containing a means for supplying a subject with a short-duration external signal of a certain magnitude, the maximum value of which is less than the magnitude of the signal corresponding to pain syndrome, and a means for recording the electrical activity of the brain of the subject in the form an electrical voltage signal connected to a long-latency evoked brain potential analysis unit according to the invention of them a unit for averaging evoked potentials is input, the input of which is connected to the output of the means for recording the electrical activity of the brain of the subject, and the output is connected to the input of the analysis unit of long-latency evoked potentials of the brain, while the analysis unit of long-latency evoked potentials of the brain contains a time interval formation block, the input of which is the input of the block analysis, a unit for determining the maximum value of the signals in the first selected time interval and a unit for determining the minimum value of the signal in the second m selected interval, the inputs of which are connected to the outputs of the time interval generation unit, the difference module calculation unit, the outputs of which are connected to the outputs of the blocks for determining the maximum and minimum signal values in the selected interval, the comparison unit connected to the input to the output of the difference module calculation unit, long-latency identification unit evoked potential with a display, an input connected to the output of the comparison unit, and the output of which serves as the output of the analysis unit.

 It is advisable that the device contains a control unit for supplying the subject with an exposure signal, the output of which would be connected to the means for supplying the subject with a short-duration external signal of a certain magnitude, and the input connected to the output of the analysis unit.

 The problem is also solved by the fact that in a device for diagnosing an averaged evoked short-latency potential of the brain, containing a means for delivering to the subject a short-duration external signal of a certain magnitude, the maximum value of which is less than the magnitude of the signal corresponding to pain syndrome, and a means for recording the electrical activity of the brain of the subject in the form of electric voltage signal connected to the block analysis of latent evoked potentials of the brain according to the invention has a unit for averaging evoked potentials is inserted, the input of which is connected to the output of the means for recording the electrical activity of the brain of the subject, and the output is connected to the input of the analysis module for short-latency evoked potentials of the brain, while the analysis module for short-latency evoked potentials of the brain contains a time interval formation block, the input of which is the input of the analysis block connected in parallel a number of blocks for determining the extreme value of the signal at the corresponding selected time intervals, the inputs of which are connected to the output of the time interval formation block, a number of difference module calculation blocks by the number of selected time intervals, the input of each of which is connected to the output of two blocks that determine the signal extreme values at two adjacent selected time intervals, a number of comparison blocks by the number of difference module calculation blocks, each of which is connected by an input to the output of the corresponding unit of the calculation of the difference module, the identification block of the short-latched evoked potential with a display, input p CONNECTIONS to the outputs of the comparator, and whose output serves as output of the analysis unit.

 In FIG. 1 shows a block diagram of a device for diagnosing averaged long-latent brain potential; in FIG. 2 is a block diagram of a unit for analysis of evoked electrical activity of the brain to determine the presence or absence of long-latency evoked potential; in FIG. 3 is a block diagram of an embodiment of a device for diagnosing averaged short-latency evoked brain potential; in FIG. 4 is a block diagram of the analysis of the induced electrical activity of the brain to determine the presence of peaks of short-latency evoked potential; in FIG. 5 - curves of averaged long-latent evoked potentials with components P2, N2 marked on it; in FIG. 6 - curves of averaged long-latent evoked potentials when determining the sensitivity threshold of the receptor structure; in FIG. 7 - curve of the averaged short-latency auditory evoked potential of the brain, having a number of peaks.

 A device for diagnosing an averaged evoked long-latent brain potential comprises a means 1 (Fig. 1) for supplying a subject 2 with a short duration external signal of a certain magnitude. The maximum value of the signal supplied to subject 2 is less than the value of the signal corresponding to the pain syndrome. The induced electrical activity of the brain of the subject 2 is removed from the scalp in the form of an electrical voltage signal through a sensor 3, which is connected to the input 4 of the means 5 for recording the electrical activity of the brain of the subject in the form of an electrical voltage signal. The output 6 of the means 5 is connected to the input 7 of the block 8 averaging evoked potentials, the output 9 of which is connected to the input 10 of the block 11 analysis of long-latency evoked potentials of the brain. Averaging is necessary to filter noise.

 When this block 11 (Fig. 2) analysis of long-latency evoked potentials of the brain contains a block 12 of the formation of time intervals, the input of which is the input 10 of block 11 of the analysis. Block 11 also contains a block 13 for determining the maximum signal value in the first selected time interval and a block 14 for determining the minimum signal value in the second selected time interval, inputs 15, 16 of which are connected to the outputs of block 12 for generating time intervals, respectively.

 The outputs of blocks 13, 14 for determining the maximum and minimum signal values for the selected first and second time interval are connected to the inputs 17, 18, respectively, of the difference module calculation unit 19, the output of which is connected to the input 20 of the comparison unit 21. The input 22 of the long-latency evoked potential identification unit 23 is connected to the output of the comparison unit 21, and its output 21 serves as the output of the analysis unit 11.

 In this case, the block 23 has a display 25, on which the medical staff has the opportunity to observe the curve of the averaged long-latent evoked potential.

 The device also contains a block 26 (Fig. 1) for controlling the means for supplying the subject with an exposure signal, the output of which is connected to the input 27 of the means 1 for supplying the subject with a short duration external signal of a certain magnitude, and the input 28 is connected to the output of the analysis unit 11.

 Possibility is an embodiment of a device for diagnosing an averaged evoked short-latency potential of the brain containing means 1 (Fig. 3) of supplying subject 2 with a short-duration external signal of a certain magnitude, the maximum value of which is less than the magnitude of the signal corresponding to pain syndrome.

 The induced electrical activity of the brain of the subject 2 is removed from the scalp in the form of an electrical voltage signal through a sensor 3, which is connected to the input 4 of the means 5 for recording the electrical activity of the brain of the subject in the form of an electrical voltage signal. The output 6 of the means 5 is connected to the input 7 of the unit 8 of averaging evoked potentials, the output 9 of which is connected to the input 29 of the block 30 of analysis of short-latency evoked potentials of the brain.

 In this case, the block 30 (Fig. 4) of the analysis of short-latency evoked potentials of the brain contains a block 31 for forming time intervals, the input 32 of which is the input of the analysis block 30. Block 30 also contains a parallel series of blocks 33 determining the extreme value of the signal at the corresponding selected time intervals, the inputs 34 of which are connected to the output 35 of the block 31 of the formation of time intervals.

 The outputs of two neighboring blocks 33, which determine the extreme values of the signal at two adjacent selected time intervals, are connected to the inputs 36, 37, respectively, of the difference module calculation blocks 38. The number of blocks 38 is determined by the number of selected time slots.

 Block 30 also contains a number of comparison blocks 39 according to the number of difference module calculation blocks 38, each of which is connected by input 40 to the output of the corresponding difference module calculation block 38.

 The outputs of the comparison units 39 are connected to the input 41 of the short-latency evoked potential identification unit 42, the output of which serves as the output of the analysis unit 30. Block 42 also has an output to the display 43. The output 44 of the block 30 is connected to the input 45 of the means 1.

 A method for the diagnosis of averaged long-latent evoked brain potential is as follows.

 Affect subject 2 (Fig. 1) with a short duration signal of a certain magnitude, the maximum value of which is less than the magnitude of the signal corresponding to pain syndrome.

 The induced electrical activity of the brain of the subject is recorded in the form of an electrical voltage signal (Fig. 5, a, b). Recording is performed within 500 ms, starting from the moment the signal is supplied, in the form of an averaged analog / digital signal. The averaged records of the induced electrical activity are received in block 12 of the formation of time intervals.

 In this block 12, the search area for the components P2, N2 (Fig. 5, a, b) of the long-latent evoked potential is set in the interval from the moment of signal input to 340 ms, since the analysis of the obtained curves shows that the components P2, N2 appear during the first 340 ms from the start of the signal.

 Two time intervals from T1 to T2 and from T2 to 340 ms for P2 and N2, respectively, are distinguished in the established search area, where T1, T2 are the boundaries of time intervals depending on the type of receptor structure.

 So, in the study of hearing T1 = 100 ms, T2 = 220 ms, the analyzed record in the first time interval goes to block 13 (Fig. 2) for determining the maximum signal value in the time interval. The analyzed record in the second time interval enters the block 14 for determining the minimum signal value in the time interval.

 It should be noted that the allocated intervals make up slightly more than half the duration of a standard recording of evoked brain activity of 500 ms. Thus, about half of the recording is processed, which significantly reduces the analysis time.

 The maximum signal value in the interval from T1 to T2 ms and the minimum signal value in the interval from T2 to 340 ms are determined. The execution of blocks 13, 14 determining the maximum or minimum value of a signal of a certain type allows you to avoid a complete search of the signal values and to further reduce the analysis time.

 The calculated maximum signal value in the interval from T1 to T2 ms and the minimum signal value in the interval from T2 to 340 ms are sent to the difference module calculation unit 19. The calculation result enters the comparison unit 21, where the obtained value of the difference modulus is compared with the value of K, where K is the experimentally established coefficient. In particular, for hearing K = 65.

 The positive number obtained as a result of the comparison is judged on the presence of a long-latent evoked potential of the brain, and the negative number obtained as a result of the comparison is judged on the absence of a long-latent evoked potential.

 As a signal that affects the subject, use a tonal sound signal lasting 100 to 200 ms, which is used to determine the threshold of hearing, and when determining the threshold of vision as a signal that affects the subject, use a flash of light or a flash of the picture tube screen.

 Studies show that similar curves can be obtained when determining tactile sensitivity, then a mechanical deformation force, a temperature shift, or an electrical signal in the form of a rectangular voltage pulse is used as a signal that affects a subject.

 To determine the sensitivity threshold of the receptor structure, the subject is additionally exposed at least once by a signal (Fig. 6b), the value of which is less than the signal value (Fig. 6a) of the previous exposure, if the long-latent potential is present as a result of the previous exposure.

 The induced electrical activity of the brain of the subject is recorded for 500 ms, starting from the moment the signal is supplied, in the form of an averaged analog / digital signal. Then set the search area of the components P2, N2 long-latency evoked potential in the interval from the moment of signal to 340 ms. Similarly to the previous method, two time intervals from T1 to T2 and from T2 to 340 ms for P2 and N2, respectively, are selected in the established search area, where T1, T2 are the boundaries of time intervals depending on the type of receptor structure, and the maximum signal value in the interval from T1 to T2 ms and the minimum signal value in the interval from T2 to 340 ms. After that, the difference modulus between the maximum signal value determined above and the minimum signal value is calculated, and the obtained value of the difference modulus is compared with the value K, where K is the experimentally established coefficient.

 The positive number obtained as a result of the comparison is used to judge the presence of a long-latent evoked potential of the brain when the additional effect is exerted, and the negative number obtained as a result of the comparison is judged as the absence of a long-latent evoked potential when the additional effect is exerted.

 In some cases, to determine the sensitivity threshold of the receptor structure, the subject is additionally exposed at least once by a signal whose value is greater than the value of the signal of the previous exposure if the long-latent cortical potential is absent as a result of the previous exposure. Next, the signal processing is carried out similarly as described above.

 It is more expedient to implement such a method when the accuracy of measuring the sensitivity threshold of the receptor structure is set and the subject is additionally exposed at least once by a signal whose value differs from the previous value by a multiple of a predetermined measurement accuracy.

 To determine the sensitivity threshold of the receptor structure, the subject is additionally exposed to the signal as many times as necessary so that the modulus of the difference in signal values of two successive actions is less than the value Q, where Q is the specified accuracy of determining the sensitivity threshold.

 A method for diagnosing an averaged short-latency evoked potential of the brain consists in exposing the subject to a short-duration signal of a certain magnitude, the maximum value of which is less than the magnitude of the signal corresponding to pain syndrome.

 The induced electrical activity of the brain of the subject is recorded in the form of an electrical voltage signal for 10 ms, starting from the moment the signal is supplied, in the form of an averaged analog / digital signal.

 The search area of the main peaks of the short-lattice evoked potential is set in the interval from the moment of signal input to 10 ms and a number of time intervals are selected in the established search area by the number of extrema in block 30 (Fig. 4).

 In the described embodiment of the method, in the case of a hearing analysis, twelve time intervals, ms: 0-1.5; 1.5-2.0; 2.0-2.5; 2.5-2.9; 2.9-3.4; 3.4-4.0; 4.0-4.6; 4.6-5.3; 5.3-6.5; 6.5-7.4; 7.4-8.2; 8.2-10.0.

 In blocks 32, the extreme value of the signal is determined at each selected interval, and in blocks 37, the modules of the difference between adjacent extreme values are calculated.

In series 38, each obtained value of the difference modulus is compared with the corresponding value K _i , where K _i is the experimentally determined coefficient for each time interval; i is an integer corresponding to the number of the interval, in the described embodiment i = 1, 2, 3 ... 12.

 A positive comparison result diagnoses the peak of the short-latency stem evoked potential of the brain at the corresponding interval, and a negative - the absence of a peak.

 For the diagnosis of passable levels of the auditory system, the number of peaks of successively evoked short-latency evoked potentials is determined, starting from the moment the signal is supplied, according to which passable levels of the auditory system are judged.

 The proposed method is universal for various receptor structures: auditory, visual, tactile. So, he uses common procedures for analyzing the induced electrical activity of the brain for all of them, a single sequence of processing steps, and uniform procedures for identifying the long-term and short-latency induced potential.

Claims (12)

 1. A method for diagnosing an averaged long-latent evoked potential of the brain, which consists in exposing the subject to a short-duration signal of a certain magnitude, the maximum value of which is less than the magnitude of the signal corresponding to pain syndrome, and recording the induced electrical activity of the brain of the subject in the form of an electrical voltage signal, and then analyze the obtained long-latent evoked potentials of the brain, characterized in that the evoked electrical activity of the brain is recorded within 500 ms, starting from the moment of signal input, in the form of an averaged analog-digital signal, the search area for components P2, N2 of the long-latent evoked potential is set in the interval from the moment of signal input to 340 ms, two time intervals from T1 to T2 and from T2 to 340 ms for P2 and N2, respectively, where T1 and T2 are the boundaries of the time intervals, depending on the type of receptor structure, determine the maximum signal value in the interval from T1 and T2 ms and the minimum signal value in the interval from T2 d 340 ms, the modulus between the maximum and minimum values of the signal determined above is calculated, the obtained value of the difference modulus is compared with the value K, where K is the experimentally determined coefficient, and the positive number obtained as a result of the comparison is judged with the presence of a long-latent evoked brain potential, and with the result obtained in as a result of a comparison, a negative number is judged on the absence of a long-latent evoked brain potential.  2. The method according to claim 1, characterized in that as a signal that affects the subject, use a tonal sound signal with a duration of 100 to 200 ms.  3. The method according to claim 1, characterized in that as a signal that is applied to the subject, a flash of light or a flash of the picture tube screen is used.  4. The method according to claim 1, characterized in that as a signal that affects the subject, use a signal selected from the group consisting of mechanical deformation stress, temperature shift or an electrical signal in the form of a rectangular voltage pulse.  5. The method according to PP. 1 to 4, characterized in that to determine the sensitivity threshold of the receptor structure, the subject is additionally exposed at least once by a signal whose value is less than the value of the signal of the previous exposure, if the long-latent potential was present as a result of the previous exposure, the induced electrical activity of the brain of the subject is recorded during 500 ms, starting from the moment of signal input, in the form of an averaged analog-to-digital signal, set the search area for the components P2, N2 of the long-latent of the potential in the interval from the moment of signal input to 340 ms, two time intervals from T1 to T2 and from T2 to 340 ms for P2 and N2, respectively, are distinguished in the established search area, where T1 and T2 are the boundaries of time intervals depending on the type of receptor structure determine the maximum signal value in the range from T1 to T2 ms and the minimum signal value in the interval from T2 to 340 ms, calculate the modulus of the difference between the maximum signal value determined above and the minimum signal value, compare the obtained value of the modulus of values with a value of K, where K is the experimentally determined coefficient, and by the positive number obtained as a result of the comparison, the presence of a long-latent evoked potential of the brain is judged with the additional effect, and by the negative number obtained as a result of the comparison, the absence of the long-latency evoked potential by the additional effect is judged .  6. The method according to claims 1 to 4, characterized in that to determine the sensitivity threshold of the receptor structure, the subject is additionally exposed at least once by a signal whose value is greater than the value of the signal of the previous exposure if the long-latent cortical potential was absent as a result of the previous exposure caused by the electrical activity of the brain of the subject is recorded for 500 ms, starting from the moment the signal is supplied, in the form of an averaged analog-to-digital signal, the search area for the components is set P2, N2 of the long-latent evoked potential in the interval from the moment of signal input to 340 ms, select two time intervals from T1 to T2 and from T2 to 340 ms for P2 and N2, respectively, where T1 and T2 are the boundaries of time intervals depending on the set search area from the type of receptor structure, determine the maximum signal value in the range from T1 to T2 and the minimum signal value in the interval from T2 to 340 ms, calculate the modulus of the difference between the maximum signal value determined above and the minimum signal value, compare the received e is the value of the difference modulus with the value K, where K is the experimentally determined coefficient, and the positive number obtained as a result of the comparison is used to judge the presence of a long-latent cortical evoked potential of the brain with an additional effect, and the negative number obtained as a result of the comparison is used to judge the absence of a long-latent evoked potential with additional exposure.  7. The method according to claims 5 and 6, characterized in that the accuracy of measuring the sensitivity threshold of the receptor structure is set and the subject is additionally affected at least once by a signal, the value of which differs from the previous signal value by a multiple of a given measurement accuracy. 8. A method for diagnosing an averaged short-latency evoked brain potential, which consists in exposing a subject to a short-duration signal of a certain magnitude, the maximum value of which is less than the magnitude of the signal corresponding to pain syndrome, and recording the induced electrical activity of the subject's brain in the form of an electrical voltage signal, and then analyze the obtained latent evoked potentials of the brain, characterized in that the evoked electrical activity of the brain is recorded within 10 ms, starting from the moment of signal input, in the form of an averaged analog-to-digital signal, the search area of the main peaks of the short-latency evoked potential is set in the interval from the signal moment to 10 ms, a number of time intervals are selected in the established search area by the number of extrema, and the extreme the signal value at each selected interval, the difference modules between adjacent extreme values are calculated, each obtained value of the difference module is compared sequentially with the corresponding value of K _i , where K _i is the experimentally determined coefficient for each time interval, i is the number corresponding to the number of the interval, and by the positive number obtained as a result of each comparison, the presence of a short-latent evoked brain potential in each interval is judged, and by As a result of each comparison, a negative number is judged that there is no peak in the short-latency evoked potential at each interval.  9. The method according to p. 7, characterized in that for the diagnosis of passable levels of the auditory system, determine the number of peaks of successive evoked potential located in series, starting from the moment the signal is supplied, according to which passable levels of the auditory system are judged.  10. A device for diagnosing an averaged long-latent evoked potential of the brain, comprising a means for delivering to the subject a short-duration external signal of a certain magnitude, the maximum value of which is less than the magnitude of the signal corresponding to pain syndrome, and a means for recording the electrical activity of the brain of the subject in the form of an electrical voltage signal connected to block analysis of long-latency evoked potentials of the brain, characterized in that it contains an averaging block evoked potentials c, the input of which is connected to the output of the means for recording the electrical activity of the brain of the subject, and the output is connected to the input of the analysis unit of long-latency evoked potentials of the brain, while the analysis unit of long-latency evoked potentials of the brain contains a time interval formation block, the input of which is the input of the analysis unit, the determination unit the maximum signal value in the first selected time interval and the unit for determining the minimum signal value in the second selected interval, the inputs of which are connected are the outputs of the unit for generating time intervals, the unit for calculating the difference module, the inputs of which are connected to the outputs of the units for determining the maximum and minimum values of the signal in the selected interval, the comparison unit connected by the input to the output of the unit for calculating the difference module, the identification unit of the long-latched evoked potential with a display, an input connected to the output of the comparison unit, and the output of which serves as the output of the analysis unit.  11. The device according to claim 10, characterized in that it contains a control unit for supplying the subject with an exposure signal, the output of which is connected to the means for supplying the subject with a short-duration external signal of a certain magnitude, and the input is connected to the output of the analysis unit.  12. A device for diagnosing an averaged short-latency evoked brain potential, comprising a means for supplying a subject with a short-duration external signal of a certain magnitude, the maximum value of which is less than the magnitude of the signal corresponding to pain syndrome, and a means for recording the electrical activity of the brain of the subject in the form of an electrical voltage signal connected to the unit analysis of long-latency evoked potentials of the brain, characterized in that it contains a block of averaging evoked potentials, the input of which is connected to the output of the recording instrument of the electrical activity of the brain of the subject, and the output is connected to the input of the analysis block of the short-latency evoked potentials of the brain, while the analysis block of the short-latency evoked potentials of the brain contains a time interval formation block whose input is the input of the analysis block the extreme value of the signal at the corresponding selected time intervals, the inputs of which are connected to the output of the block forming the time intervals, a number of blocks for calculating the difference module in the number of selected time intervals, the inputs of each of which are connected to the outputs of two blocks that determine the extreme values of the signal in two adjacent selected time intervals, a number of comparison blocks in the number of blocks of calculation of the difference module, each of which is connected to an input to the output of the corresponding unit for calculating the difference module, the identification block of the short-latched evoked potential with a display connected to the outputs of the comparison unit, and in the output of which serves as the output of the analysis unit.

Images