RU2157156C2 - Method and device for treating optic tract diseases - Google Patents

Abstract

FIELD: medicine; medical engineering. SUBSTANCE: device has implantable coil having current rectifier and light source, power supply unit, high frequency oscillator, external inductor having high frequency electromagnetic field emitter and pulse burst former with sweep generator which is started by means of pulse burst synchronizing trigger unit. Method involves implanting high inductance coil in the area of equator. Currents are invoked in the coil as a result of external inductor influence. The action is synchronized with pulsating wave system. Electric currents are additionally excited in the coil due to high frequency electromagnetic field to 200 kHz additionally applied. The currents are modulated as pulse bursts. Each burst pulse frequency is supported in sweeping mode from 20 to 50 Hz under voltage not exceeding 15 V. Light action is applied in visible and infrared wavelength range to 10 mW power in equatorial region or in the area of central fossa projection on the sclera. Session duration does not exceed 30 min. The total course is not longer than 15 sessions in daily mode. EFFECT: enhanced effectiveness of treatment. 7 cl, 4 dwg

Description

 The invention relates to medicine, namely to ophthalmology, and can also be used in traumatology, otolaryngology, nephrology, in the treatment of atrophy of the hearing aid.

 A known method of treating diseases of the optic tract and a device for its implementation by implantation of a high inductance coil and a magnetic pulse inductor. In this case, the coil is implanted and sutured to the sclera under the Tenn shell in the plane of the equator of the eyeball, one electrode being placed retrobulbarly near the optic nerve, and the other in the equatorial plane of the eyeball (A.S. N1799577).

 A pulsed inductor, due to an alternating magnetic field, induces a bipolar pulsed electric current in the implantable coil, which, together with the magnetic field, is therapeutic. Moreover, these effects are synchronized with the systole of the pulsating wave.

 However, these method and device have disadvantages. The duration of the pulse current in the implantable coil is small, which reduces the efficiency of the method. The amplitude of the electrical signal is also insufficient. Its increase is associated either with an increase in the number of turns in the implantable coil, or with a necessary increase in the magnetic field induction in the pulse. The first is associated with an increase in the dimensions of the implantable coil, which is unacceptable, and the second with the magnitude of the current in the inductor, which increases the heat release in it and reduces continuous operation time. In addition, when inducing currents in an implantable coil, it is not possible to increase the duration of an electric signal and modify it in the form of a "burst" of pulses; there is no possibility of simultaneous synchronized exposure to light flux along with exposure to a magnetic field and electric current.

 The technical result according to the invention is to increase the effectiveness of the treatment of diseases of the optic tract.

 The technical result of the method is achieved by the fact that in the method of treating diseases of the optic tract by implanting a highly inductive coil on the eyeball in the equator region with inducing acting currents from an external inductor in it and synchronizing the action with a pulsating wave systole, according to the invention, in an implantable coil due to> additionally acting high-frequency electromagnetic fields up to 200 kHz generate electric currents modulated in the form of "bursts" of pulses, within each and of which the pulse propagation frequency is maintained in the sweep mode from 20 Hz to 50 Hz at a voltage of not more than 15 V, and also provide light exposure in the visible or infrared wavelength range with a power of up to 10 mW, and the duration of the session of these actions is provided for no more than 30 minutes daily with no more than 15 sessions per treatment course.

 One option is one in which light exposure is provided in the equatorial region of the eye. Another option is to provide light exposure in the projection area of the central fossa on the sclera.

 The technical result of the device for treating diseases of the optic tract is achieved by the fact that in the device for treating diseases of the optic tract, containing an implantable coil with two or more electrodes and a magnetic field source in the form of an external inductor connected to a pulsed current source, according to the invention, the electric circuit of the implantable coil equipped with an additional current rectifier and a light source, and the external inductor is additionally equipped with a radiator of high-frequency electromagnetic field series connected power supply and a high frequency generator, comprising a generator packets and pulses with the sweep generator, the start input of which is connected to the synchronizer.

 One embodiment of the device is one in which light sources are placed in an implantable coil.

 In another embodiment, light sources are placed on one of the electrodes.

 The technical result is also achieved by the fact that the trigger synchronizer of the shaper comprises an external pulsation wave systole sensor, which is located on the patient.

 The authors carried out the necessary experimental work, which made it possible to determine the necessary parameters of the acting electrical signals by voltage due to the implantable coil, including light sources, and their repetition frequencies.

 The use of light sources in the implantable coil, electrical signals in the mode of sweeping the frequencies of their repetition within each "packet" and repetition frequencies of the "packs" corresponding to the repetition rate of systolic broadening of blood vessels during the passage of pulse waves in them, are selected from the following considerations.

 Due to the fact that each of the effects (magnetic, electric and light) has a certain specificity; their combination gives an effect higher than when they are independently exposed.

 The magnetic field, as shown by our biophysical and clinical studies, increases the speed of blood flow (including microvessels), while conforming the hemoglobin of red blood cells and, accordingly, increasing the oxygenation of blood plasma and tissues. An increase in oxygen concentration increases the production of ATP in the mitochondria of cells and intensifies cellular metabolism.

 The impact of electric current due to the introduction of negative charges helps to narrow the threshold of sensitivity of neurons and axons, reduces the concentration of membrane-bound calcium blocker, reduces or eliminates inflammatory processes, accelerates metabolic processes in tissue structures.

 Light exposure in the range of visible or infrared wavelengths due to the internal photoelectric effect is ultimately identical to the electric effect. However, in contrast to the electrical effect, where it is necessary to use at least two electrodes, and the distribution of currents between the electrodes is not regulated in any way and the exposure area is indefinitely large, the light exposure does not require electrodes and is localized by the light absorption region, which is usually small, i.e. to. the mean free path of photons is small. However, the last two methods of exposure complement each other quite well. Due to the internal photoelectric effect, when the light is irradiated, the electrical conductivity of the irradiated region increases and the threshold voltage of the electrical effect can be reduced, because the current between the electrodes increases. In addition, the photons absorbed inside the cells contribute to a decrease in membrane potentials in the photoelectric effect due to electrons escaping outward through the membrane. At the same time, the positive potential inside the cells rises, areas of inflammation in which the potential is excessively positive are stopped, which reduces the rate of metabolic processes.

 Thus, a combination of exposure factors, complementing each other, create an overall higher clinical effect.

 Due to the fact that all actions are automatically synchronized with each other - the start of the magnetic field pulse is provided simultaneously with the start of the high-frequency generator, and the electric and light signals are induced by high-frequency electromagnetic radiation, almost all of the factors are affected simultaneously.

 In this case, the maximum induction of the external magnetic field will amount to 0.3-0.5 T, the frequency of high-frequency radiation from 2.0 to 2000 kHz, the magnitude of the electrical signal at a maximum of 15 V in the form of "packets" of sweep pulses with a repetition frequency of "packets" equal to the frequency of pulsations of the blood flow (heartbeats), when each "pack" is excited at the time of passage of the systole of the pulsating wave. Since each implantable coil is equipped with light sources - red, blue, green, infrared or one of them, when passing "bundles" of electrical pulses, they form a luminous flux of up to 10 mW when connected to electrodes of implanted coils in parallel.

 Clinical practice has shown that the duration of an action session should be 10-20 minutes, and the number of sessions per treatment course should not exceed 15 sessions. A session duration of less than 10 minutes in a pulsed mode is not effective. With a duration of more than 20 minutes, the braking phase begins, which disappears after 1.5-2 hours. However, at the same time, the patient may experience discomfort due to a headache that occurs after 0.5 hours - 1 hour.

 The invention is illustrated by drawings, where in FIG. 1 shows a General view of the device.

 In FIG. 2 shows a variant of an implantable coil with light sources in the center of the coil.

 In FIG. Figure 3 shows a variant of an implantable coil at the end of one of the electrodes.

 In FIG. 4 shows a block diagram of a power system and control the operation of a high-frequency emitter of an electromagnetic field. The device contains an implantable coil 1, a rectifying diode 2 or a bridge 3, and the rectifying diode 2 is connected in series with one of the electrodes 4, and the rectifying bridge 3 is connected in parallel to the current outputs 5 of the coil 1 and loaded on the electrodes 4. The light sources 6 are connected in parallel with the electrodes 4.

 The device also contains a pulsed magnetic field source in the form of an external inductor 7, an electromagnetic field emitter 8, a power supply 9, a high-frequency generator 10, a pulse burst generator 11 with an integrated sweep generator 12, a synchronizer 13 with a remote pulse wave sensor in the vessels 14, pulsed current source 15 to power an external inductor 7.

 The method and operation of the device are as follows. Implant a coil 1 on the eyeball in a known manner. In this case, the light sources 6 are placed either in the equatorial region of the eyeball or in the projection area, the central fossa on the sclera. A high-frequency emitter 8 is placed on the outer edge of the orbit of the eye when the distance between the implanted coil 1 and the emitter 8 is minimal and their planes are parallel. Connect the synchronizer sensor 13 to the patient. The power supply unit 9 is turned on, having previously set the minimum high-frequency radiation power, and the fact of the presence of synchronizer signals 13 is recorded. The high-frequency radiation power is selected at which the patient sees a flash of the light source 6. The power is increased to values corresponding to the appearance of patient discomfort. An exposure session is carried out for 10-20 minutes, depending on the complexity of the pathology and the occurrence of side effects.

 In the process of implementing the method in accordance with the systole of the pulse wave, a high-frequency generator 10 and a pulsed current source 15 are launched to power an external inductor 7.

 The modulating signals from the sweep generator 12 are fed to the input of the high-frequency generator 10 and form a "pack" of "sweep signals". The repetition frequency of the "packs" is determined by the signals of the synchronizer 13. The level of the sweep high-frequency signal varies before it is fed to the electromagnetic field emitter 8. Since the implantable coil 1 is a kind of antenna, modulated electromagnetic fields excite electromotive force in it in the current output circuit 5. In the presence of a rectifying diode 2, it will provide unipolar uni-half-wave current, and bridge 3 will provide biannual rectification. The output active electrodes 4 are placed after the diode 3 or at the output of the bridge 4. The light sources 6 are placed in an electric circuit parallel to the electrodes 4. Geometrically they are placed either in the center of the implantable coil 1, or on one of the electrodes 4.

 Example.

 Patient S., 32 g. In 1982, he underwent opto-chiasm arachnoiditis, as a result of which vision deteriorated.

On admission:
1. Right eye = 0.08 Left eye = 0.06
2. Computer perimetry - multiple central absolute and relative scotomas.

 3. The field of view of red is narrowed significantly, blue and green do not distinguish.

Electrophysiological parameters:
sensitivity threshold 114 μA (right eye); 118 μA (left eye).

 lability - 33 Hz (right eye); 32 Hz (left eye).

After implantation of the coils in both eyes and the course of treatment in accordance with the invention, changes occurred:
1. VIS Right eye = 0.08 Left eye = 0.06.

 2. The number of central cattle decreased significantly - single relative scotomas.

 3. The color perception was restored, the field of view of red, blue, green almost corresponds to the norm.

4. Significantly improved electrophysiological parameters:
sensitivity threshold 112 μA (right eye); 112 μA (left eye).

 lability 39 Hz (right eye); 32 Hz (left eye).

 The use of the method and device in the treatment of the optic tract has significantly improved the effectiveness of treatment. Within the patient observation time (1 year), there was no decrease in visual acuity, color sensitivity and electrophysiological parameters (lability, threshold of sensitivity, ERG) of the optic tract.

Claims (7)

 1. A method for treating the optic tract by implanting a highly inductive coil on the eyeball in the equator region with inducing acting currents from an external inducer in it and synchronizing the action with a pulsating wave systole, characterized in that in the implanted coil due to the additional acting high-frequency electromagnetic field up to 2000 kHz generate electric currents modulated in the form of "bursts" of pulses, within each of which the pulse propagation frequency is maintained in the drinking from 20 to 50 Hz at a voltage of not more than 15 V, and also provide light exposure in the visible or infrared range of wavelengths up to 10 mW, and the duration of the session of these effects is provided for no more than 30 minutes daily with the number of sessions not more than 15 per a course of treatment.  2. The method according to claim 1, characterized in that the light exposure is provided in the equatorial region of the eye.  3. The method according to claim 1, characterized in that the light exposure is provided in the projection area of the central pit on the sclera.  4. Device for treating diseases of the optic tract, containing an implantable coil with two or more electrodes and a magnetic field source in the form of an external inductor connected to a pulsed current source, characterized in that a power supply unit, a high-frequency generator, a pulse shaper are introduced into it with a sweep generator and a synchronizer, the electric target of the implantable coil is additionally equipped with a current rectifier and light sources, and the external inductor is equipped with an additional It is emitted by a high-frequency electromagnetic field connected through a power supply unit to a high-frequency generator.  5. The device according to claim 4, characterized in that the light sources are placed in an implantable coil.  6. The device according to claim 4, characterized in that the light sources are placed on one of the electrodes.  7. The device according to claim 4, characterized in that the driver trigger synchronizer comprises an external pulsation wave systole sensor, which is located on the patient.

Images