EA035247B1 - Stimulator using complex-structured optical signals and method for the use thereof - Google Patents

Abstract

The invention relates to the field of medical instruments and can be used in biomedical testing and technologies for stimulating the brain. A stimulator that uses complex-structured optical signals is intended for stimulating the visual system and the brain by means of fractal optical signals, the structure of which is close in terms of their dynamic to the activity of a healthy brain. The stimulator generates fractal optical signals having set parameters and is in the form of a portable device consisting of a light signal source, a signal generator consisting of a microcontroller, a signal programme memory, a power supply, wired and wireless interfaces, a programming device in the form of a computing device in the form of a personal computer comprising wireless interfaces for connection to the signal generator, and also a software unit for generating a signal programme, and a unit for loading a signal into the signal generator via the interfaces. Also proposed are best methods for using such a device. The technical result is the possibility of using the generator independently of the programming device, the versatile generation of a signal programme, control of the loading of signal programmes into the signal generator; and a device that is convenient to use owing to the absence of connecting cables.

Description

The invention relates to the field of medical instrumentation and can be used in biomedical research and brain stimulation technologies.

A stimulator device with complexly structured optical signals is designed to stimulate the visual system and the brain with fractal optical signals, the structure of which is close in dynamics to the activity of a healthy brain, in order to maintain, improve or restore its activity and related cognitive functions.

State of the art

Stationary devices and mobile applications for photostimulation are known that create achromatic or color flickers, which are generated, as a rule, with a constant frequency of alpha or beta rhythm, which are associated with relaxation and rest or, respectively, performance and concentration.

A common drawback of these devices is the generation of periodic signals with deterministic dynamics to stimulate the brain.

Given modern scientific ideas, brain stimulation with periodic rhythms or vice versa with signals that have completely random, stochastic dynamics is not able to restore the fractal complexity of the rhythms of healthy physiological functions, and in some cases there may be a risk of negative effects.

The basis for this conclusion is the results of scientific studies, which showed that the rhythm of healthy body functions, including cortical activity, has a highly correlated deterministic-chaotic (fractal) dynamics with a power spectral density close to 1 / f ¹ [1-4]. At the same time, human aging, exposure to stress factors and diseases lead to the loss of long-range correlations and the appearance of a completely uncorrelated stochastic dynamics (close to white noise, l / f ⁰ ) or a deterministic process (physiological rhythm close to periodic or quasiperiodic fluctuations) [5 -7]. Violation of the complexity of the EEG is documented in patients with schizophrenia and in depressive disorders [8].

In [9–13], it was postulated that fractal visual stimulation can increase the efficiency of restoration of brain activity and mental activity in healthy people in stressful situations, with psychoemotional disorders, and in people suffering from neurological and psychiatric disorders and neurodegenerative diseases. Including the use of generators of complex structured signals can be useful in the recovery period after injuries and strokes of the brain through reactivation of synaptic plasticity. On the other hand, the use of fractal optical or sound stimulation is also promising as a way to train cognitive functions [13].

To develop technologies and various ways of training, restoring and enhancing the activity of the brain, its sensory systems and enhancing cognitive functions, it is necessary to create stimulator devices that provide the generation of complex structured signals that are similar in structure to the dynamics of activity of a healthy brain. An analysis of the literature data allowed us to conclude that, to increase cognitive functions and improve brain activity, the use of complex structured signals with a fractal dimension from 1.1 to 1.5 is especially promising.

Optical stimulation devices are known, consisting of an optical terminal in the form of glasses with an opaque frame with light sources mounted on the inner (closest to the eyes) side of the frame, and a power and control unit connected to the optical terminal by a wired interface [14-18]. In these devices, the formation of signals of a periodic shape (rectangle, bell, sine, asymmetric sine [15]) is provided and complex-structured signals with a fractal dimension from 1.1 to 1.5 are not used. In addition, the optical terminal is connected to a wired interface control device, which can be a deterrent when used in hospitals.

Known devices that provide optical stimulation in the form of glasses with an autonomous power source [14, 18]; as a result of reducing the number of wires, such devices less restrict the user. These devices contain a microcontroller with memory for signal programs and provide their reproduction using LEDs. The disadvantage of these devices is the limited (fixed) set of signals recorded in the controller memory, as well as the complex reprogramming of the signal in the microcontroller by pressing buttons on the optical terminal, which is small in size and strength. These devices also do not provide the formation of complex structured optical signals with a given fractal dynamics.

A known method of fractal stimulation based on the use of a device [19] - a fractal flicker generator for biomedical research, designed to generate a nonuniformly flickering background - a dynamic light fractal in which fluctuations of the intervals between flashes are time-invariant. A drawback [19] is the impossibility of creating complex structured signals of the desired fractal dimension in the range 1 <D <2 (not including 2), which does not allow us to approximate the complexity of the stimulating signal to the dynamics of activity of a healthy brain.

The device according to the invention Cheng W. The method and device of fractal stimulation (WO / 2015/131770 Fractal stimulation method and device PCT / CN2015 / 073241, Cheng, Weyland) [20] is the closest in essence to the claimed technical solution and is taken as a prototype.

The prototype stated that the stimulating device provides a fractal stimulation mode for optimal treatment of human diseases. The device contains a microprocessor that controls a series of pre-programmed stimuli, including electrical, magnetic stimulation, mechanical, auditory and photostimulation, with adjustable change in stimulation parameters (amplitude, intensity, wavelength, etc.). The parameters are adjusted so that they correspond to the fractal pattern and differ from periodic, random or random dynamics in typical stimulation devices. Thus, the formula and description of this invention according to Patent Scope do not regulate the requirements for the structure of stimulating signals, and there are no specific conditions that bring it closer to the dynamics of the activity of a healthy brain.

The goal of creating the device we offer is the formation of complex-structured optical signals with specified parameters for stimulating the brain, which are similar in dynamics to the activity of a healthy brain, increasing flexibility in the formation of signals and ease of use by increasing the mobility of devices. In this case, the stimulator with fractal optical signals is made with a given Hausdorff-Besikovich fractal dimension in the range from 1 to 2, not including 2, and the level of self-similarity is from 2 to 10.

The goals are achieved through a combination of emitters of optical signals;

generators, providing the formation of complex structured signals in accordance with a given program;

programmers that provide the formation of programs of complex structured signals that are close in dynamics to the activity of a healthy brain, which can be interconnected using both wired and wireless interfaces.

For the purposes of this application, the term interface refers to a channel or means of communication between parts of a device, including a wired channel (wired interface), a wireless channel (wireless interface).

The drawing shows the proposed scheme of the device stimulator complex structured optical signals.

The signal source IS1 provides the formation of a light signal that affects the visual system of a person. The signal source IS1 should provide the ability to reproduce an achromatic or color signal with a wavelength of 380 nm (790 THz) to 780 nm (385 THz), with a frequency of up to 10 KHz to provide the necessary fractal dimensions of the signal and the number of levels of self-similarity.

The GS2 signal generator consists of a microcontroller MKZ containing non-volatile EP4 memory for storing the signal program, power supply (stand-alone or network) IP5, wired (USB) IF6.1 and / or wireless (WiFi, Bluetooth) IF6.2 interfaces for connecting the PM7 programmer . The GS2 generator receives a signal program from the PM7 programmer via a wired IF6.1 or wireless IF6.2 interface, stores it in the EP4 non-volatile memory and ensures the signal is reproduced by the IP1 light source in accordance with the signal program recorded in the GS4 generator's EP4 memory, before overwriting the signal program .

The signal generator GS2 can provide the connection of an external light source IS1 via a wired interface or is combined in one housing with a light source.

The PM7 programmer is implemented in the form of software operating on the platform of a computing device in the form of a personal computer, tablet, or smartphone containing wired (USB) and / or wireless (WiFi, Bluetooth) interfaces used to connect to a signal generator. The PM7 programmer consists of a signal program forming unit (BF8) and a signal loader unit (ZS9) using wire-based IF10.1 interfaces or wireless IF10.2 interfaces of the platform used. The signal program is generated by the BF8 block based on the specified signal parameters, including the waveform (mathematical function), fractal dimension, the number of signal self-similarity levels, and the signal pattern repetition rate. The BF8 block provides the formation of both signals with regular or stochastic dynamics for biomedical research, and signals with fractal dynamics. The generated signal program by the signal loader ЗС9 is transmitted to the signal generator ГС2 via a wired (IF10.1 -> IF6.1) or wireless (IF10.2 -> IF6.2) interface.

The programmer provides the formation of fractal signal programs with dimensions in the range 1 <D <2 (not including 2) and the number of self-similarity levels from 2 to 10.

The programmer provides signal generation based on the use of software implementation of fractal functions, such as the Bolzano, Weierstrass, Riemann, Hankel, Darbu functions,

- 2 035247 fractal splines, fractal wavelets and others.

The programmer provides the formation of a signal program of a given duration.

The device can be implemented in the following versions.

1. As a signal source, an LED emitter is used in a stationary or mobile design, combined in one housing with a signal generator. The programmer is made in the form of a personal computer, tablet or mobile phone (smartphone) containing software for generating a signal program with specified parameters and downloading the signal program via a wireless or wired interface to a signal generator.

2. An optical terminal in the form of glasses containing an LED emitter and a signal generator is used as a signal source. The programmer is made in the form of a personal computer, tablet or mobile phone (smartphone) containing software for generating a signal program with specified parameters and downloading the signal program via a wireless or wired interface to a signal generator.

3. An optical terminal containing an LED emitter, a diffuser, a signal generator is used as a signal source and a signal generator. The specified device is installed in virtual reality glasses for signal perception. The programmer is made in the form of a personal computer, tablet or mobile phone (smartphone) containing software for generating a signal program with specified parameters and downloading the signal program via a wireless or wired interface to a signal generator; in this case, in the particular case, the estimated size of the optical terminal can have such parameters (dimensions) as 80x160x10 mm (height x length x depth), a rectangular shape and weight up to 200 g are preferable.

4. An optical terminal in the form of a mobile phone (smartphone) containing the signal generator software is used as a signal source and a signal generator. The programmer is made in the form of a personal computer, a tablet containing software for generating a signal program with specified parameters and downloading the signal program via a wireless or wired interface to a signal generator.

5. The programmer may be located in a separate electronic computer connected to the signal source via the Internet.

With this design of the programmer, it is possible to use a device in which the user gives commands to the programmer via the Internet, and the programmer transmits the signal program to the signal generator upon request via the Internet.

The proposed device operates as follows.

Using the programmer’s software, a set of signal programs with specified parameters is generated. The parameters used are the type of fractal function (Bolzano, Weierstrass, Riemann, Hankel, Darboux, fractal splines, fractal wavelets and others), fractal dimension (in the range from 1 to 2, not including 2), the number of self-similarity levels (from 2 to 10 ), the duration of the playback signal (from 1 to 60 minutes). The signal program may contain background areas, providing, for example, preparation of the recipient for signal perception. As a result, a set of generated signal programs is stored in the programmer's memory.

Based on the characteristics of the recipient, the purpose of the impact (brain training, treatment, biomedical research), a signal is selected for loading into the signal generator. The signal generator is turned on, connected via a wired or wireless interface to the programmer, after which the signal program is loaded into the non-volatile memory of the signal generator.

In the case of using the stimulator with complex structured optical signals in version 5, the Internet is connected to the electronic computer on which the programmer is located, and the selected signal program is loaded into the signal generator.

After loading the signal program into the non-volatile memory of the signal generator, the specified signal can be reproduced repeatedly. To play another signal, it is necessary to load its program into the signal generator using the programmer.

To influence the recipient, it is necessary to turn on the signal generator;

to ensure the relative position of the recipient, the signal source and the signal generator in accordance with the design of the device;

wait for the completion of the stimulation program;

turn off the signal generator, complete the procedure.

The room should be provided with comfortable lighting in the range from 50 to 500 Lux.

In the case of using execution 1, it is necessary to place the recipient near the device in a sitting or lying position so that the device is at a distance of no more than 1 m.

In case of use of performance 2, the optical terminal in the form of glasses should be fixed on the recipient's head.

In the case of using version 3, the signal source should be installed in the holder, for example 3 035247 example of a case of virtual reality glasses. Glasses-holder with an installed signal source are fixed on the recipient's head to exert impact.

In the case of using performance 4, the smartphone is installed in the holder and is located at a distance of no more than 30 cm from the recipient.

The presence of a power source in the generator allows the generator to be used separately from the programmer. The presence of the programmer allows you to flexibly generate signal programs and control the loading of signal programs into the signal generator. The presence of wireless interfaces allows you to increase the comfort of using the device due to the absence of connecting cables that limit the freedom of movement of the recipient.

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Claims (10)

1. A stimulator of fractal optical signals, designed to stimulate the visual system and brain, characterized in that it forms fractal optical signals with specified parameters, the structure of which is close in dynamics to the activity of a healthy brain, while the stimulator provides the formation and reproduction of fractal optical signals with the specified Hausdorff-Besikovich fractal dimension in the range from 1 to 2, not including 2, the level of self-similarity from 2 to 10 and is a portable device consisting of: a) a signal source that reproduces an achromatic or color signal with a wavelength of 380 to 780 nm, a frequency of up to 10 KHz, connected via a wired interface to a signal generator; b) a signal generator, consisting of a microcontroller, a signal program memory, a power source, USB interfaces for connecting a programmer that reproduces the signal in accordance with the signal program recorded in the generator memory in the form of a separate device; c) a programmer in the form of a computing device such as a personal computer, containing wired and wireless interfaces for connecting to a signal generator, as well as a program block for generating a signal program, as well as a signal loader that provides loading of the signal program through the interfaces to the signal generator, while the signal source and the signal generator is structurally integrated into an optical terminal containing an LED emitter, a diffuser mounted in glasses or a smartphone-type mobile phone containing signal generator software. 2. The stimulator of fractal optical signals according to claim 1, characterized in that the signal source is an LED emitter. 3. The stimulator of fractal optical signals according to claim 1 or 2, characterized in that it has wireless WiFi and / or Bluetooth interfaces. 4. The stimulator of fractal optical signals according to claim 1 or 2, characterized in that the programmer is a mobile device that is installed in a holder. 5. The stimulator of fractal optical signals according to claim 1, characterized in that the optical terminal is a pair of glasses. 6. The stimulator of fractal optical signals according to claim 1, characterized in that the optical terminal is a virtual reality glasses. 7. Stimulator of fractal optical signals according to claims 5, 6, characterized in that the glasses are fixed on the recipient's head. 8. The stimulator of fractal optical signals according to claim 1 or 2, characterized in that the programmer is located in a separately located computing device connected to the signal generator via the Internet. 9. The method of using the device according to claims 1 to 8, characterized in that by means of a block forming - 5 035247 programming of the signal of the programmer provides the formation of signal programs having periodic, stochastic and deterministic chaotic dynamics, and signal programs of fractal dynamics, while the signal loader of the programmer ensures the loading of the signal program generated by the program signal generator of the programmer into the memory of the signal generator by wired or wireless interfaces, and the signal generator provides the preservation and multiple reproduction of the signal in accordance with the signal program loaded into the memory of the signal generator, while the programmer, signal generator and signal source provide the formation and reproduction of signals with specified characteristics: type of fractal function, fractal dimension Hausdorff-Besikovich in the range from 1 to 2, not including 2, the level of self-similarity from 2 to 10. 10. The method of using the device according to claim 8, characterized in that the user gives commands to the programmer via the Internet, and the programmer transmits the signal program to the signal generator upon request via the Internet.