RU2268761C2 - Magnetic light therapeutic device - Google Patents

Abstract

FIELD: medical equipment; physiotherapy.

SUBSTANCE: magnetic light therapeutic device can be used for influencing onto nidus of pathology and reflexogenic areas by optical radiation from semiconductor laser and light-emitting diodes together with magnetic field influence. Area of medicinal application of the device is widened due to application of green, red and IR-radiation laser. Combined, synchronized and co-phased influence of five factors, i. e. four optical and magnetic field, allows reducing of procedure due to synergetic effect without loss in therapeutic efficiency. Dissipating element in form of cut of optic fiber is mounted at output of semiconductor laser to protect internal organs of patient from damage at targeted action of laser beam. Light-emitting diodes are placed inside plastic cases to generate dissipated radiation which results in generation of spatial-uniform light field in opening of radiating head. Permanent magnetic field is replaced by pulse one induced by introducing electromagnet into pumping circuit of laser.

EFFECT: improved efficiency of operation.

5 cl, 2 dwg

Description

The invention relates to medical equipment, and in particular to apparatus for physiotherapeutic exposure to the focus of pathology and reflexogenic zones by optical radiation of a semiconductor laser and LEDs in combination with a magnetic field. Known works confirming the fact that the combined effect of laser radiation and a magnetic field has higher therapeutic efficacy compared to their separate use, because their complex use leads to a synergistic effect [1].

The invention can be used in the treatment of surgical, internal, nervous, skin and other diseases in clinical and outpatient practice, as well as at home and in the field.

Known apparatuses for physiotherapeutic treatment using a semiconductor laser and emitting diodes in the infrared range. These include domestic therapeutic devices MILTA, ISEL, MLADA, VITYAZ, etc. [1] Analysis of the physical, technical and operational characteristics of these devices shows that all of them have the following disadvantages:

- the small divergence of the laser beam at a distance of 1-2 cm from the irradiated surface practically creates a point on this surface with a diameter of about 0.5 mm, which is equivalent to a flux density of 7-10 W / cm ² . This is unacceptable, since it can lead to non-linear phenomena and damage to deeply located tissues (1, p. 46);

- LEDs with directional radiation create spots on the irradiated surface with a diameter of 5-6 mm with a bright dot in the middle, which means that 4-6 lamps will illuminate no more than 10% of the opening area of the radiating head;

- in all known devices a permanent magnet is installed. It has been shown that the greatest therapeutic effect is exerted by a pulsed magnetic field - UTI (2 p., 475);

- a large penetrating ability of infrared radiation in the depth of biological tissues from 6 to 8 cm, and red from 1 to 1.5 cm allows for exposure only to internal organs and surface tissues;

- the devices lack the protection of the eyes of the patient and medical personnel from laser radiation.

Closest to the claimed technical essence and selected for the prototype is the "Device for magnetic therapy" according to patent RU No. 2033825, class. A 61 N 5/06, comprising a housing, infrared light emitting diodes, red LEDs, a timer, a power amplifier, a ring magnet, a battery and a stabilized power source.

The main disadvantages of this device are:

- limited scope, due to the use of a limited radiation spectrum. In this case, the green radiation, penetrating to the depth of biological tissue from 1 to 2 mm, is not involved, which makes it impossible to use the device in dermatology and cosmetology;

- a constant radiation regimen in therapeutic effect is inferior to a pulsed radiation regime (1, p. 44);

- insufficiently high efficiency of exposure to a constant magnetic field;

- lack of eye protection for the patient and medical personnel.

At the same time, it is known that an increase in the parameters affecting the biological object at the same time allows to obtain the maximum treatment efficiency.

The objective of the invention is to create an apparatus for magnetic light therapy that meets the requirements for mass use apparatuses: minimizing weight, dimensions and cost, ease of control and selection of exposure modes in accordance with established guidelines. At the same time, the apparatus should have expanded functionality with respect to a set of biotropic parameters, ensure a reduction in the duration of the procedure without losing the therapeutic effectiveness of the combined and synergistic effects on the pathology pathway by heterogeneous physical factors: synchronous and common-mode green, red, infrared and laser radiation and pulsed magnetic field. In this case, the opening of the radiation of the head is completely filled with the radiation of LEDs, and the laser beam is scattered over an area of about 1 cm2, which reduced the power flux density by about 500 times while maintaining the healing properties of the laser radiation. The device provides laser safety for the eyes of the patient and medical personnel.

Work in offline mode makes it possible to use the device both in clinical conditions and at home at the patient’s bed.

The indicated result is achieved in an apparatus for magnetic light therapy, which contains a radiating head, in which infrared and red light-emitting diodes are placed, a ring magnet is fixed on the outside of the radiating head, a control panel including a battery, to which a timer, a power amplifier is connected, and indicators of the device. The device is equipped with a stabilized power supply connected to the battery, and differs in that a semiconductor pulsed laser with an integrated feedback photodiode and a scattering element at the output of the laser beam is introduced into it, the ring magnet is replaced by an electromagnet, the winding of which is connected in series to the laser pump circuit, the north pole of which is connected to a washer of soft magnetic material mounted on the end of the radiating head.

In addition, according to claim 2, the scattering element at the input of a semiconductor laser is made in the form of a segment of a multimode stepped optical fiber.

According to claim 3 of the claims, green, red, and IR radiation with scattered radiation are installed in the emitted head.

According to claim 4, a feedback photodiode is connected to a photocurrent amplifier, the output of which includes a laser radiation indicator.

According to claim 5 of the invention, a microswitch is introduced into the laser pump circuit.

From the analysis of the current level of technology, not a single apparatus was found with approximate features identical to all the essential features of the proposed apparatus for magnetic light therapy.

Therefore, the claimed invention meets the criterion of "novelty" under existing law.

To verify the claimed invention to the requirement of an inventive step, the applicant conducted an additional search, the results of which showed that the claimed invention does not follow for experts explicitly from the prior art.

The technical result is a reduction in the duration of the procedure due to synchronous and in-phase pulsed exposure to the pathology pathway with green, red and infrared light, laser radiation with λ = 0.95 μm and pulsed magnetic field.

The invention is illustrated in figure 1, which presents a structural diagram of a device for magnetic light therapy.

The device contains a control panel 1, a radiating head 2. The control panel contains a battery 3, a meander generator 4 with a variable frequency, an amplifier 5, a photocurrent amplifier 6, a timer 7 with a sound emitter at the output.

The control unit housing 1 has a front panel with organs for selecting the operating mode of the apparatus and indicators (not shown in FIG. 1).

The housing of the radiating head 2 is made in the form of a cylinder mated to a truncated cone of non-magnetic metal or plastic. Inside the housing there is a block 8 with three groups of green LEDs 9, red 10 and IR radiation 11 mounted on it, as well as a semiconductor laser 12 with feedback photodiode 13 and a scattering element (not numbered in FIG. 1).

Two sockets are placed on the front flange of the radiating head, in one of which an electromagnet 14 is installed, the north pole of the electromagnet is connected to a thin washer 15 of soft magnetic material. In the other slot, a microswitch 16 is fixed, the movable rod of which passes through the hole in the washer and protrudes on it by the amount of free play of the microswitch. The outer side of the washer has a protective coating.

The inner surface of the radiating head has the form of a truncated cone with an angle of 90 ° at the apex and is equipped with a reflective coating.

Figure 1, view "A" shows a variant of the arrangement of emitters, which provides a close to uniform distribution of radiation over the aperture of the radiating head.

Figure 2 shows the electrical circuit of the pumping circuit of the laser 12. From the first output of the power amplifier 5, the current passes through the winding of the electromagnet 14, the laser 12, the closed contacts of the microswitch 16, the second output of the power amplifier 5.

To prevent breakdown of the laser 12 by the transient voltage possible in the pump circuit, a semiconductor diode 17 in reverse polarity is connected in parallel with the laser.

The control unit is connected to the radiating head with an electric cable with connectors.

The claimed device operates as follows: using the appropriate toggle switches and buttons on the front panel of the control unit 1 include the groups of emitters 9, 10, 11, necessary for the given treatment, set the time of the dispensed procedure with a timer from 1 to 5 minutes, the pulse frequency of the meander generator 4 and set radiating head to the area of pathology. In this case, the microswitch 16 closes the pump circuit of the laser 12 and the timer starts counting the timer 7. A part of the laser radiation is incident on the feedback photodiode 13. The photocurrent of this photodiode is amplified by the amplifier 6, at the output of which an LED installed on the front panel of the control panel indicates the presence of radiation laser 12. The pulse pump current of the laser 12 passes through the winding of the electromagnet 14, which causes a pulsed magnetic field of the electromagnet 14 and a thin washer 15 of soft magnetic material.

Thus, all emitting diodes, a semiconductor laser, and a magnetic field act on the pathology region synchronously and in phase; therefore, we obtain the maximum possible synergistic effect, which means reducing the time of the procedure without reducing the therapeutic effect.

The correct operation of the emitters of green, red and infrared radiation is recorded on the front panel of the control unit.

When the radiating head 2 is removed from the patient’s body, a microswitch is activated, the laser pump circuit is broken, which ensures safety for the eyes of the patient and medical personnel.

The device uses a stabilized power source 19, which provides recharging the battery from a network of 220 V.

The ILPN-232 type semiconductor laser installed in the apparatus has a built-in feedback photodiode; By the order of the Research Institute Polyus, this laser is manufactured with a segment of a multimode optical fiber at the output.

When using an optical fiber with a numerical aperture NA = 0.27 = Sinα, where α is the angle between the optical axis of the fiber and the extreme angle of the incoming or outgoing radiation beam, the laser beam will be scattered over an area of about 1 cm2.

Light emitting diodes with scattered radiation are installed in the apparatus: green AL307NM with a maximum radiation at a wavelength of 0.567 microns, red AL307KM with a wavelength of 0.665 microns and an IR laser ILPN-232 with a radiation wavelength of 0.95 microns [3]. The presence of an electromagnet winding inductance in the laser pump circuit provides a “soft” inclusion of the laser, which, by reducing degradation, increases its working life. The master square wave generator and timer are built on microchips of the KR1006VI1 type. The meander generator operates at frequencies from 1 to 100 Hz. This interval includes the known resonance frequencies of Schumann biostructures (7 and 17 Hz) and frequencies corresponding to the Fibonacci series (1, 2, 3, 4, 5, 8, 13, 21 ...) (1, p. 47).

The output of the meander generator is connected to a two-stage amplifier on transistors KT-361 and KT-817, assembled according to the scheme with a common emitter.

The photocurrent amplifier is assembled on a KR-544UD1A chip.

Literature

1. Illarionov V.E. The basics of laser therapy. - M.: Publishing house "Respect" association INOTECH - progress, 1992.

2. Balneology and physiotherapy. Edited by V.M. Bogolyubov. T.1. - M .: Medicine, 1985.

3. Ivanov V.I. and other semiconductor electronic devices. Directory. - M .: Energoatomizdat, 1988.

Claims (5)

1. Apparatus for magnetic light therapy, comprising a radiating head, in which red and infrared light emitting diodes are placed, an annular magnet is fixed on the outside of the radiating head, a control panel including a battery, to which a timer, a power amplifier is connected, the device is equipped with a stabilized block power supply connected to the battery, characterized in that a pulsed semiconductor laser with a radiation wavelength of 0.95 μm with an integrated feedback photodiode is introduced into it and a scattering element and green LEDs, the ring magnet is made in the form of an electromagnet, the winding of which is included in the laser pump circuit, and the north pole of which is connected to a washer of soft magnetic material mounted on the front side of the radiating head. 2. The apparatus according to claim 1, characterized in that the scattering element at the output of the beam of a semiconductor laser is made in the form of a segment of a multimode optical fiber. 3. The apparatus according to claim 1, characterized in that the LEDs with scattered radiation are installed in the emitting head. 4. The apparatus according to claim 1, characterized in that the feedback photodiode is connected to a photocurrent amplifier, the output of which includes a laser radiation indicator. 5. The apparatus according to claim 1, characterized in that a microswitch is introduced into the laser pump circuit.

Images