RU25280U1 - PHYSIOTHERAPY DEVICE - Google Patents

Abstract

Apparatus for physiotherapy, having: a housing with a receiving-emitting unit placed therein, containing a group of laser diodes and a group of photodetectors, and connected to a control panel with a microcontroller and a power supply, characterized in that it includes: IR radiometer, keyboard, lens Fresnel, a modulator matrix, a matrix for laser diodes and a matrix for photodetectors, the latter being connected to an infrared radiometer; the said matrices are installed in the receiving-emitting unit in such a way that the modulator matrix and the matrix for laser diodes are alternately inserted into the housing, repeating its shape and forming the configuration of the head from the outside, from the inside - of a spherical mirror; in the body of these matrices, lodges designed in the form of holes and spaced along concentric circles were arranged to accommodate modulators and laser diodes, respectively, with the orientation of each pair of modulator - laser diode along one axis radially, and the matrix for photodetectors has an annular shape and is placed on the end of a spherical mirror which, on the surface of its aperture, a Fresnel lens is installed.

Description

2002G1e562

: IHIMJ | pp1lpplin

Apparatus for phpiotherapy.

The utility model relates to medicine and medical equipment and can be used in physiotherapy in the treatment of diseases and injuries of the central and peripheral nervous systems, musculoskeletal system, internal organs, as well as for therapeutic treatment with electromagnetic radiation with the possibility of selecting radiation parameters and monitoring its use .

A known apparatus for light therapies (patent RU 2070077 IPC A 61 N 5/06), comprising an optical radiation head, a power supply, an emitter operation control unit with an additional microphone, a light phonendoscope and a microphone signal conversion unit connected to the microphone output and the input of the light phononoscope. The microphone is mounted on the output surface of the emitter head.

In this device, the diagnostic capabilities of the device are combined with therapeutic laser exposure, however, the nature of the laser exposure itself does not take into account the depth of the lesion and the deeper the latter is located, the less effective the therapeutic effect. In addition, the disadvantages include the lack of feedback elements in them that do not allow providing objective control over the response of the body to therapeutic effect. In the named device there are no modern means of controlling the treatment process, for example, they do not even have the means of computer program control, despite the high hardware saturation of the device.

Also known apparatus (patent RU 2072879, IPC A61 N 5/06 from 09.02.90) for laser therapy, containing an annular source of constant magnetic field, a semiconductor laser emitter, interconnected

IPC: A 61N 5/06

switch and synchronizer. To increase the accuracy of the individual dosage of light energy, LEDs and a photodetector installed in the nozzle are introduced into the device. In addition, the following indicators were introduced: an indicator connected with a photodetector, a current indicator connected with LEDs and a switch, a serially connected pulse master oscillator connected to the second output of the synchronizer, and a pulse shaper modulator connected to a semiconductor laser emitter.

This apparatus has the drawbacks of the analogue described above and, moreover, does not allow draining: the concentration of laser radiation in the affected area. The disadvantages of the device are the inability to automatically adjust the dose based on objective criteria. The doctor regulates the dose of radiation, guided by purely subjective estimates, in addition, it is impossible to achieve therapeutic doses of radiation on deep nerve structures, tissues and organs.

Closest to the claimed solution is an apparatus (patent RU 2143293 IPC A 61 N 5/06, 2/08, A 61 B 10/00) for diagnostics and magnetic laser therapy, consisting of a terminal containing N LEDs, a photodiode, a laser emitter, a source a constant magnetic field, one side of which represents the front of the terminal, and the control panel. The apparatus contains a digital indication unit, an audio indication unit, a LED power supply, a laser emitter power supply, and a synchronizer, consisting of a series-connected heart rate signal amplifier, the input of which is the signal input of the device, R-wave selector, pulse train shaper, switch, connected to the output of the pulse shaper, display, microprocessor, adaptation unit and mode switching unit. The terminal further comprises a photodetector, a second switch, at least one additional photodiode and a camera whose inner surface is capable of reflecting optical radiation. The camera is placed between the inner surfaces of the sources of constant magnetic field, one of the base of the camera is the front plane of the terminal, and on the other base of the camera are light-emitting diodes, a photodiode, a laser emitter, at least one photodiode installed in the source of the constant magnetic field through a switch connected to a photodetector, to which a photodiode mounted in the camera is also connected through a second switch. Exit

a /

the photodetector is connected to the indicator input of the microprocessor, a digital indication unit is connected to the indicator output of the microprocessor. The first and second triggering outputs of the microprocessor are connected respectively to the input of the power supply of the LEDs and the input of the power source of the laser emitter. The microprocessor trigger input through the first switch is connected to the apparatus trigger input, and the microprocessor output information input is connected via the adaptation block to the information input of the apparatus output.

The disadvantage of the apparatus is excessive overload by small autonomous units, which are not subordinate to a single important idea - to provide the necessary therapeutic doses of radiation in deeply located pathological zones.

The objective of the utility model is to increase the effectiveness of the influence of electromagnetic radiation therapy on deeply lying pathologically altered body tissues with the control of changes in the pathological focus and with the ability to adjust the parameters of the influencing factors and, therefore, change the treatment procedure scheme.

The essence of the utility model is that in an apparatus for electromagnetic therapy, which has: a housing with a receiving-emitting unit placed in it and containing a group of laser diodes and a group of photodetectors, and connected to a control panel with a microcontroller and a power supply, the following are introduced: IR radiometer , keyboard, Fresnel lens, modulator matrix, matrix for laser diodes and a matrix for photodetectors, the latter being connected to an IR radiometer; these matrices are installed in the receiving-emitting unit in such a way that the modulator matrix and the matrix for laser diodes are sequentially inserted into the housing, repeating its shape and forming the configuration of the head from the outside, from the inside - of a spherical mirror; in the body of these matrices, lodges designed in the form of holes and spaced along concentric circles were arranged to accommodate modulators and laser diodes respectively with the orientation of each pair of modulator-laser diode along one axis radially, and the matrix for photodetectors has an annular shape and is placed on the end of a spherical mirror, inside which, on the surface of its aperture, a Fresnel lens is installed.

1.- receiving and emitting unit;

2.- housing of the receiving-emitting unit;

3.- matrix of laser diodes;

4.- lodgement;

5.- laser diode;

6.- modulator matrix with lodgements;

7.- optical modulator of the MM-range;

8.- buffer ring;

9.- matrix of photodetectors;

10.- photodetector;

11.- optical lens;

12.- lens alignment element;

13.- control unit with keyboard;

14.- block of current stabilizers (laser diodes);

15.- IR radiometer;

16.- electrical power connector for laser diodes;

17.- electrical power connector of optical modulators;

18.- electrical connector for connecting photodetectors;

19.- power supply;

The connection of the elements in the apparatus is as follows.

The unit in contact with the patient’s body performs the functions of the receiving-emitting unit 1, since it carries out the concentration of laser radiation in the pathology region to a predetermined depth and perceives the scattered part of the radiation for subsequent processing. The receiving and emitting unit 1 is a universal receiving and emitting head. It is placed in the housing 2, having the shape of a glass, which is the holder of all the parts making up the head. The composition of the elements of the receiving-emitting unit 1 includes: a matrix of laser diodes 3, in the body of which are made lodges 4 formed as holes, inside of each of which one laser diode 5 is placed. Similarly, the structure of the modulator matrix 6 is embedded in the matrix of laser diodes 3, in the lodges of which are placed one optical modulator 7 of the MM range. Thus, the bodies of matrices 3 and 6 have lodgements 4, arranged in the form of coaxial identical holes, the number of which is from 10 to 150. Their axes converge at the focal point of the spherical mirror formed by the working surface of the modulator

matrices 6. The matrix of laser diodes 3 and the modulator matrix 6 embedded in it are concave spherical mirrors combined along the axes of the lodgments, made of a multilayer composite material. The surfaces of the mirrors are covered with metal foil about OD mm thick. Laser diodes 5 and optical modulators 7 are rigidly fixed in the respective lodges 4 in a concentric orientation so that the rays coming out of the optical modulators 7 converge at one point located in the same place as the focus of the spherical mirror of the modulator matrix 6. Matrices 3 and 6 are rigidly connected to the buffer ring 8 along the end surfaces. The radius of curvature of the working inner surface of the modulator matrix 6 is 0.7 from the external diameter of the end part of the universal receiving-emitting head.

The radius of curvature of the outer surface of the modulator matrix 6 is 0.9 of the diameter. The radius of curvature of the working surface of the matrix of laser diodes 3 is 0.92 of the diameter. The radius of curvature of the outer surface of the matrix of laser diodes 3 is 1.1 diameter. The radius of curvature of the inner surface of the spherical part of the housing 2 is 1.12 diameter. The radius of curvature of the external surface of the spherical part of the housing 2 is 1.2 diameters.

To receive backscattering radiation, a photodetector array 9 is included in the receiving-emitting unit 1, which is made of photodetectors 10 connected to a series circuit so that the voltages add up to the total output voltage of the photodetector matrix 9, which contains 4 or more photodetectors 10. One of The main elements of the receiving-emitting unit 1 is a Fresnel lens 11, as a rule, with the number of layers of 10 or more, performing the function of matching with the patient’s body, which allows changing the depth of radiation concentration. Each layer of the Fresnel lens 12 is made of a transparent material that is transparent to optical radiation. The Fresnel lens 11 is placed inside the matrix of photodetectors 9, fixed in it and fixed on the annular part of the alignment element 12, which has a mushroom-like appearance, and its leg has the shape of a thin glass, passing into the annular disk at the external end. The outer diameter of the cup is equal to the inner diameter of the buffer ring 8. The patient receiving-emitting unit 1 is connected to the control unit 13, the block of current stabilizers 14 of the laser diodes 5, the block of the infrared radiometer 15 through the electrical connectors 16.17, 18, respectively. At the input of the infrared radiometer 15, the total output voltage from the matrix of photodetectors 9 is supplied. Through the electrical connector 16, the matrix of laser diodes 3

electrical connector 16, the matrix of laser diodes 3 of the receiving-emitting unit 1 is connected to the current stabilizer block of the laser diodes 14. Through the electrical connector 17, the modulator matrix of the unit 1 is connected to the control unit 13. Through the electrical connector 18, the matrix of photodetectors 9 is connected to the input of the IR radiometer 15. IR output -radiometer 15 is connected to the control unit 13 through the input of an analog-to-digital Converter, which is part of it. The inputs of the power supply 19 are connected to the inputs for connecting the necessary supply voltages of the blocks 13,14, 15. On the buffer ring 8 there are electrical connectors 16,17,18.

The operation of the apparatus. The doctor places the receiving-emitting unit 1, directing it with a radiating surface in the projection of the pathological focus near the patient's body. Then connects the device to AC power. Next, the switch "network includes the device. After that, all the blocks of the device are supplied with the necessary voltage from the power supply 19.

Using the keyboard of the control unit 13, the patient's personal data, medical history, clinical and local status data, and laboratory tests are entered into the microprocessor. Then the work program is launched, which analyzes the entered patient data and makes recommendations on choosing the appropriate subprogram for the treatment procedure using the map of modes stored in the memory of the microprocessor of the control unit 13. Then, taking into account the recommendations received, the doctor selects and starts the optimal treatment regimen.

The control unit 13 forms the time intervals of the matrix of laser diodes 3, sets and changes, lying in the range of extremely high frequencies, the operating frequencies of the modulator matrix 6, and generates control signals for the current stabilizer block 14 of the laser diodes 5. The stabilized values change according to these control signals currents of laser diodes 14 and, therefore, the levels of power emitted by them. If necessary, part of the laser diodes 5 can be turned off.

Part of the laser radiation passing into the patient’s body, generated by the receiving-emitting unit 1, is scattered by the body tissues and enters the ring matrix 9 of the photodetectors 10. From them, the total response signal is fed to the input of the IR radiometer 15, where it is amplified and converted to voltage levels.

proportional to the averaged coefficient of backscattering of irradiated tissues, sensitive to all types of physiotherapeutic influence.

The output signal of the infrared radiometer 15 is fed to the input of the control unit 13, where it is converted to digital form and compared with the reference values from the interval, typical for this area of the body and the nature of the pathology.

The weakening of the scattered radiation, and therefore the response, means increasing the efficiency of the effect of radiation on biological tissues. And the increase in response indicates a decrease in the effectiveness of the impact. This is due to the fact that the transparency of biological tissues in the IR range increases during structuring and decreases with the growth of destructive changes.

Therefore, when a positive difference signal is obtained as a result of comparison, the control unit 13 starts automatically sorting the operating parameters of the receiving-emitting unit stored in the memory until a minimum response value is obtained. Next, the irradiation process is automatically adjusted by the control unit 13 according to the found values of the operating parameters of the receiving-emitting unit 1.

The medical and social effect of the claimed utility model lies in the fact that the resulting therapeutic effect with such an effect significantly exceeds the simple combined use cases of laser and EHF irradiation of pathologically altered tissues. The increased effect of the therapeutic effect of laser radiation on pathologically altered body tissues is associated with two factors that are absent in the above analogues. The first of these is the summation of the radiated power from individual sources in deeply located areas of the patient’s body, the second significant factor is the use of modulation of laser beams with frequencies close to the natural frequencies of the oscillation of cellular structures. The frequencies of molecular vibrations of cellular structures lie in the range of extremely high frequencies used in electromagnetic EHF therapy. The modulation frequency of laser beams is allocated in the form of electrical vibrations in the interaction of the optical with biological tissues. The appearance of such an additional stimulating factor on cellular structures significantly increases the effectiveness of physiotherapy treatments.

Claims (1)

Apparatus for physiotherapy, having: a housing with a receiving-emitting unit placed therein, containing a group of laser diodes and a group of photodetectors, and connected to a control panel with a microcontroller and a power supply, characterized in that it includes: IR radiometer, keyboard, lens Fresnel, a modulator matrix, a matrix for laser diodes and a matrix for photodetectors, the latter being connected to an infrared radiometer; the said matrices are installed in the receiving-emitting unit in such a way that the modulator matrix and the matrix for laser diodes are alternately inserted into the housing, repeating its shape and forming the configuration of the head from the outside, from the inside - of a spherical mirror; in the body of these matrices there are made lodges arranged in the form of holes and spaced along concentric circles to accommodate modulators and laser diodes respectively with the orientation of each pair of modulator - laser diode along one axis radially, and the matrix for photodetectors has an annular shape and is placed on the end of a spherical mirror, inside which, on the surface of its aperture, a Fresnel lens is installed.