RU2098059C1 - Device for correction of functional systems of man's organism - Google Patents

Abstract

FIELD: medicine. SUBSTANCE: device has spectacles with two light-insulated eyepieces which accommodate set of light-emitting diode radiators of different wave length of light radiation. Each of radiators is connected to respective switch. Device is provided with regulator of light radiation flickering frequency. Regulator forms two antiphase pulse sequences. Device has also modulating pulse former which modulates antiphase pulse sequences in modulator, light radiation brightness regulator, control unit, and power supply unit. EFFECT: improved design. 3 dwg, 1 tbl

Description

 The invention relates to medicine, and more specifically to a device for correcting the functional systems of the human body, in particular, to improve visual functions.

 The invention can be used to correct visual, central nervous, immune, endocrine, hematopoietic and other systems of the human body. In particular, the invention can be used for the treatment and prevention of various pathologies of the organ of vision, including congenital impaired vision, inability to correct with glasses and treatment, glaucoma, cataracts, pathology of the retina, optic nerve and others.

 A device is known for correcting visual functions, that is, one of the functional systems of the human body, containing glasses with two light-insulated eyepieces, each of which has a light-scattering reflector, inside of which a light radiation source and a light filter mounted opposite it are fixed. As sources of light radiation, incandescent bulbs are used. In addition, the device has a regulator of the frequency of flashing light radiation and a power supply.

 However, the constructive implementation of the specified device does not allow you to adjust the brightness of the light radiation, which negatively affects eye diseases with increased sensitivity to light. In addition, the design embodiment does not provide the possibility of amplitude modulation of the pulses of the acting light radiation necessary for the resonance correction of disturbed alpha rhythms of the brain, which limits the scope of its use. Moreover, the specified light source quickly fails, which causes inconvenience during operation of the device. Along with this, in the presence of a complex of diseases in the same patient, it is necessary to use filters of different wavelengths, the replacement of which also causes inconvenience in the operation of the device.

 The basis of the invention is the goal of creating a device with such a constructive implementation, which would expand the functional area of its use while reducing the treatment time for various pathologies of various functional systems of the human body.

 This goal was achieved by the creation of the Teterina device for correcting the functional systems of the human body, containing glasses with two light-insulated eyepieces, each of which has a light-scattering reflector, inside of which a light radiation source is rigidly fixed, while the device has a master oscillator, a controller for blinking light frequency and a power supply Moreover, according to the invention, the device comprises a brightness control of light radiation, connected in series to the control unit, form l modulating pulses and a modulator, the inputs of which are connected respectively to the outputs of the regulator of the blinking frequency of light radiation, and the outputs to the corresponding inputs of the regulator of brightness of light radiation, two switches, each of which is connected with its input to the regulator of brightness of light radiation, and the output to a light source, which is a set of LED emitters of different wavelengths of light radiation, and a control unit whose outputs are connected to the control inputs of the frequency controller ganiya of light radiation, a regulator of brightness of light radiation and switches.

 The proposed device has wide functionality and allows you to treat both diseases of the organs of vision, and diseases associated with impaired regulation of the brain by the brain of rhythmic processes in the human body.

 The presence of switches provides an extension of the possibilities of choosing the operating mode of the device, and depending on a particular pathology, one or another operating mode can be set.

 The brightness control of light radiation creates optimal conditions for influencing the visual system depending on light sensitivity, which increases the effectiveness of treatment by reducing eye fatigue during treatment and shortening the treatment time for diseases.

 During the treatment session, it is possible to regulate the pulse sequences and modulations of the blinking frequency of light radiation and to replace one color with another.

 The proposed device is simple both constructively and when using it, so it can be used for individual treatment at home.

 Thus, the use of the invention allows to expand the functional field of its application while reducing the treatment time for various pathologies.

 In FIG. 1 schematically shows a device for correcting the functional systems of the human body, made according to the invention, a top view; figure 2 is an electronic circuit of a device made according to the invention; figure 3 - panel control point of a device made according to the invention.

 A device for correcting the functional systems of the human body, made according to the invention, contains glasses 1 (Fig. 1) with two light-insulated eyepieces. Each of the eyepieces has a light-scattering reflector 2, inside of which LED emitters 3, 4 of different wavelengths are fixed: from 400 to 700 nm. The device includes a master oscillator 5 (Fig. 2), a regulator 6 of the blinking frequency of the light radiation, forming two antiphase pulse sequences in the frequency range from 0.06 to 1 Hz, a regulator 7 of the brightness of the light radiation, two switches 8, 9, each which provides a given light effect on the corresponding eye, and in series connected control unit 10, the shaper 11 of the modulating pulses with a frequency of 2 to 64 Hz and the modulator 12.

 The master oscillator 5 is connected to the input 13 of the controller 6 of the blinking frequency of the light radiation having two outputs connected to the corresponding inputs 14, 15 of the modulator 12, the two outputs of which are connected to the corresponding inputs 16, 17 of the controller 7 of the brightness of the light radiation, connected by its outputs to the input 18 , 19 of the corresponding switch 8, 9. The control unit 10 with its outputs is connected to the input 20 of the controller 6 of the blinking light frequency, input 21 of the controller 7 of the brightness of light radiation, inputs 22, 23 of each switch 8, 9 and ode 24 modulating pulse generator 11, whose output is connected to the input 25 of the modulator 12. The output of each switch 8, 9 is connected to the LED emitters 3, 4 of the corresponding eyepiece.

In this case, the device has a remote control 26 (Fig. 3) control and monitoring connected to its input to the power supply. Moreover, in the case of using industrial frequency voltage, a power supply unit is used, which is an adapter 27, which converts this voltage to a voltage of 9-12 V, safe for the user. The control and monitoring panel 26 has a transparent window 28 with indicator LEDs installed therein corresponding to LED emitters of 8, 9 colors, which allow controlling the wavelength of light radiation, pseudo-sensor switches 6 ¹ 7 ¹ , 8 ¹ , 9 ¹ , 11 ¹ , 12 ¹ for setting various modes of light emission and adjusting its brightness, a timer 29, which ensures that the entire device is turned off after a specified time of exposure minutes, and a connector 30 to which glasses 1 are connected.

 The device operates as follows.

The patient is wearing glasses 1, in the eyepieces of which inside the light-scattering reflectors 2 there is a set of LED emitters of different wavelengths from 400 to 700 nm. When voltage is applied to the input of the device, the light-emitting frequency control unit 6 generates two antiphase pulse sequences in the frequency range from 0.06 to 1 Hz, which are fed to the inputs 14, 15 of the modulator 12, the pulse train generator 11 generates a pulse sequence (meander) of purity 2 to 64 Hz, which modulates in the modulator 12 the amplitude of the signals of the controller 6 of the blinking frequency of the light radiation. The modulated signals are regulated in amplitude in the dimmer 7 and are fed through switches 8, 9 to LED emitters 3, 4 of the corresponding wavelength located in the eyepieces. Using the switches 8 and 9 set the desired color for each of the eyes. Using the controller 6 of the blinking frequency of the light radiation, the blinking frequency of the light radiation is set in the range from 0.06 to 1 Hz. Adjustment of the level of output radiation is carried out by means of the regulator 7 of the brightness of the light radiation stepwise through 1.5 dB (4 positions). The maximum brightness of the radiation is from 1.5 mW (for red) to 0.05 mW (for other colors). By means of a shaper 11 modulating pulses include pulse modulation of rhythms with a frequency of 8, 16 or 32 Hz. Set the operation mode of the device depending on the pathology. The electronic circuit allows the formation of the following radiation modes:
alternating effects on the eyes with a period of 4-8 s;
periodic exposure to one of the eyes and continuous exposure to the other;
any of the above modes with radiation modulation meander with a frequency of 8, 16 or 32 Hz.

In this case, you can affect both eyes with the same or different wavelengths:
660 nm (red color);
600 nm (orange color);
567 nm (green color);
470 nm (blue color).

 Timer 29 ensures that the device turns off after a certain time (for example, 8.5 minutes).

 The presence of radiation brightness control allows you to quickly set the brightness of the LED emitters individually for each of the patients.

 The device has small dimensions and consumption, which allows it to be used both in specialized clinics and at home. The power consumption is not more than 40 mW, and the mass (without glasses and a network adapter) does not exceed 200 g.

To set various modes of light emission and adjust its brightness, pseudo-sensor push buttons 6 ¹ , 7 ¹ , 8 ¹ , 9 ¹ , 11 ¹ , 12 ^{1 are used} . The radiation wavelength is controlled by indicator LEDs located in a transparent window 28 of the control and control panel 26 of the device.

 The use of LEDs 3, 4 as emitters with a relatively narrow spectral emission line (of the order of 30–40 nm) makes it possible to influence the visual analyzer with almost monochrome colors, which makes it possible to more differentially treat various specific diseases. The emitters used so far based on incandescent lamps with relatively broadband filters did not allow selective exposure of the eyes.

Example 1. Patient C. 67 years. Complaints of a progressive decrease in vision in both eyes. Suffers from myopia from 12 years. Three years ago, glaucoma of both eyes was established, about which a year ago an antiglaucomatous operation was performed on the left eye. Over the past six months, the general well-being of the patient has worsened. Headaches, insomnia, depression, memory loss appeared, it became difficult to engage in scientific and pedagogical activities, suffering from impotence. During the examination, the following was established. Visual acuity of the right eye of 0.02, with corr.spheres. 10.0 D 0.5; left eye -0.01, with corr. spheres. 7.0 D 0.08. The field of view in both eyes is concentrically narrowed by 20 ^o . The intraocular pressure of both eyes is 21 mmHg. Fundus: optic nerve discs pale with a grayish tint, severe glaucomatous excavation. Diagnosis Myopia is high, progressive, open-angle glaucoma with a developed stage in the right eye and a distant stage of the (operated) left eye. The treatment was carried out using the proposed device with the mode of pulse sequences and modulation of rhythms by a meander with a frequency of 8, 16, 32 Hz and alternating colors. The treatment was carried out at home. When examining after the proposed treatment, the following was established. Visual acuity of the right chapter with corr. spheres. -8.0 D 0.7 (0.8 incomplete); left eye with corr. spheres. 8.0 D 0.1. The boundaries of the field of view of both eyes expanded to normal. Significantly improved near vision with correction. The general condition of the patient has improved significantly. Headaches, depression disappeared, memory improved, creativity increased, potency recovered, sleep returned to normal.

 Example 2. Patient K., 70 years old. Diagnosis: artifact of the right eye (three years ago there was cataract extraction with implantation of an artificial lens), initial cataract of the left eye. During the examination, the following was established. Visual acuity of the right eye of 0.7, not corrected, of the left eye of 0.5, spheres. +1.0 D 0.6. The treatment was carried out using the proposed device with light radiation of 500, 567, 590, 600 and 660 nm with a rhythm modulation mode either alternately in two eyes, or in combination with filling with a meander. The treatment was carried out at home. When examining after the proposed treatment, the following was established. Visual acuity of the right eye of 0.8 spheres. 0.5 D 0.9; left eye 0.7, spheres. + 1.0 D = 0.9. General condition has improved significantly. The function of the gastrointestinal tract improved, blood pressure returned to normal (the patient suffered from hypertension, drug-resistant therapy), the symptoms of neurasthenia disappeared.

 Example 3. The effect of ophthalmic color therapy (on the proposed device) was studied on the visual functions and general condition of the body of 45 patients with initial cataract, who had concomitant diseases: hypertension, neurasthenic syndrome, osteochondrosis, diabetes mellitus, gall bladder and gastrointestinal tract dysfunction, syndrome chronic fatigue, immunodeficiency, mastopathy, impotence, etc. The age of patients is from 35 to 79 years. Most patients had a combination of several diseases, about which they were under medical supervision and treatment at interns for many years. However, drug treatment was ineffective. Visual acuity with correction averaged 0.73, and after one course of treatment 0.86. In 45% of patients, vision was normalized (visual acuity 0.9-1.0). Before treatment, the minimum visual acuity was 0.1, and after treatment 0.3. Along with the improvement of visual function in patients, the symptoms of the neurological syndrome and chronic fatigue syndrome disappeared, the immune system improved in patients with immunodeficiency, blood pressure in hypertensive patients, and overall well-being in patients with diabetes. At the same time, thirst, dry mouth and polyuria disappeared. In patients with cardiovascular disease, symptoms such as shortness of breath, swelling on the legs, and malaise disappeared. In patients with osteochondrosis, pain symptoms disappeared. Clinical data obtained confirm that ophthalmoflower stimulation, acting on the visual analyzer, also affects all functional systems through the regulatory centers of the brain: the pituitary, hypothalamus, pineal gland, reticular pharmacy, stem structures and cerebral cortex, thus provides energy homeostasis through energy centers . This is evidenced by indicators of the bioelectric activity of the brain and immune status when exposed to ophthalmic color stimulation on the visual analyzer.

 Example 4. Patient N. 38 years old, a disabled person of group II as a result of arachnoencephalomyelitis transferred in 1990. She suffered from almost constant headache, photophobia, photophobia (green), visual fatigue, decreased light perception, hypotension (80/50 mmHg), drug and food allergies. A decrease in visual acuity of the right eye from 1.0 to 0.8, left 1.0 to 0.6. The field of view of both eyes is narrowed to 30-45 degrees. there were many spot cattle. On the encephalogram, diffuse changes in the biorhythm of the brain. The patient repeatedly underwent treatment in neurological departments with a temporary improvement in visual function. Three courses of ophthalmic color therapy were carried out on the proposed device for 15-20 sessions once a day, mainly in red (partially alternated with green), daily, without concomitant drug therapy. Repeated courses of treatment with an interval of 1.5 months. As a result of treatment, the visual acuity of both eyes increased to 1.0; the visual fields expanded by 15-30 degrees. most spotted cattle disappeared, headache and photophobia decreased, blood pressure increased and stabilized (100/60 mmHg), allergies, visual fatigue, photophobia disappeared.

 Example 5. Patient M., 60 years old, having for 10 years occupational hazards in the workplace (exposure to ultrashort waves). Since 1991, suffers from iron deficiency anemia. The visual acuity of both eyes is 1.0. Repeatedly underwent treatment with iron-containing drugs with a temporary improvement in performance. A course of ophthalmic color therapy was carried out on the proposed device (in red, 10 sessions of 15 minutes once a day, daily). As a result of treatment, the iron content increased from 6.7 to 13.3 μm mol / L (norm 9-29). Hemoglobin increased from 8.9 to 9.2 lg / dl (normal 12-18). The patient is recommended a second course of color therapy after 2 months.

 Example 6. A study was carried out of the effect of ophthalmic color therapy on the proposed device on the human immune system in five patients. The following parameters were studied: the number of Leu leukocytes, Neu netrophils, Eos eosinophils, Mon monocytes, Lym lymphocytes, CD3, CD4, CD8, CD16, Lym subpopulations CD72, T4 / T8 ratio, IgG immunoglobulins, IgA, IgM, rheumatic factor RF index, ph FI and number F4, hemolytic activity of the complement of US, sedimentation rate of erythrocytes ESR. The data are presented in the table, significant changes at Pi 0.1 are marked *. RF changes are given as the average of the log difference logs **.

 A clear positive effect of ophthalmic color therapy on the state of the immune system is noted. A significant (in a very small sample) increase in the level of CD4 helpers was revealed, a pronounced trend towards an increase in CD3 of mature T-lymphocytes and CD72-B lymphocytes. This increase cannot be attributed to the overall increase in Lym. A significant increase in logM (by 58%) and PS (by 52%) was observed, which reflects an increase in the anti-infective and detoxification activity of the macrophage-phagocytic system. A decrease in lgA accompanies remission in the foci of chronic inflammation. Changes in immunity indicators correlate well with clinical improvement in patients. The data obtained indicate that ophthalmic color therapy on the proposed device is a powerful non-pharmacological method of immunocorrection.

Claims (1)

 A device for correcting the functional systems of the human body, containing glasses with two light-insulated eyepieces, each of which has a light-scattering reflector, inside of which a light radiation source is rigidly fixed, while the device has a master oscillator, a regulator of the frequency of flashing light radiation and a power supply unit, characterized in that it contains a regulator of brightness of light radiation, a control unit connected in series, a modulating pulse shaper and a modulator, the inputs of which are respectively, are connected to the outputs of the regulator of the blinking frequency of light radiation, and the outputs to the corresponding inputs of the regulator of brightness of light radiation, two switches, each of which is connected by its input to the regulator of brightness of light radiation, and by an output to a source of light radiation, which is a set of LED emitters of different wavelengths light radiation, the control unit, the outputs of which are connected to the control inputs of the controller for the blinking frequency of the light radiation, the brightness control of the light cheniya and switches.

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