RU2143293C1 - Apparatus for diagnostics and magnetolaser therapy - Google Patents

Abstract

FIELD: medical engineering. SUBSTANCE: apparatus is used for diagnostics and physiotherapeutic effect of infrared laser and light-emitting diode radiations in combination with magnetic field on internal and external tissues of biological object. Apparatus has terminal containing of N light-emitting diodes, photodiode, laser radiator, source of permanent magnetic field, photoreceiver, second switch, at least one auxiliary photodiode, chamber, and control panel. The latter includes digital indication unit, sound indication unit, power source of light- emitting diodes, laser radiator power unit, microprocessor, adaptation unit, mode-of-operation change-over unit, and synchronizer consisting of series- connected cardiac-rhythm signal amplifier, R-tooth selector, former of pulse, burst, switch, and display. Functional capabilities of apparatus are enlarged due to diagnostics of biological object subsurface layer and due to apparatus operation in automated system in combination with external computer. Light-emitting diodes and lasers used in apparatus are sources of low-energy light radiation at wavelength of 0.84-0.89 mcm. They provide for exposure of biological object tissues to this radiation to depth of 7-8 cm. Use of adaptation unit with external computer in apparatus makes it possible to automate performance of physiotherapy process, to take account of information on carried-out procedure, and to process results obtained. EFFECT: enhanced efficiency of therapy. 6 cl, 2 dwg

Description

 The invention relates to medical equipment, namely to devices for the diagnosis and physiotherapeutic effect of infrared laser and LED radiation in combination with a magnetic field on the internal and external tissues of a biological object, including the diagnosis and treatment of cardiac disorders.

 A known apparatus for magnetic laser therapy (patent RU N2072879, A 61 N 5/06, 1997), containing a functionally interconnected irradiating terminal with LEDs and a photodetector installed in the nozzle, a semiconductor laser emitter, a constant magnetic field source, and a control panel containing connected between each other a switch and a synchronizer, a current control unit connected to the LEDs and a switch, a pulse master oscillator connected to the synchronizer output, and a module of the forms rovatel pulse connected to a semiconductor laser transmitter, and indicator coupled to the photodetector.

 The disadvantage of this apparatus is the lack of functionality: it is not applicable, for example, in the diagnosis and treatment of cardiac abnormalities, as well as for the diagnosis of subsurface layers of a biological object, as well as the impossibility of its operation in an automated system in conjunction with an external computer.

 Known cardiological magnetic laser therapeutic apparatus (patent RU N 2022574, A 61 N 5/06, 1997), consisting of a terminal with a semiconductor laser emitter, a constant magnetic field source, LEDs located on the nozzle, and a photodiode, as well as a control panel, comprising a light indication unit, a timer and an autonomous laser start generator, a laser power supply and protection connected to the laser emitter, a LED power source and a reflected radiation indicator connected to the photodiode, synchronize p, consisting of series-connected sensors of a heart rate signal and an R-wave selector, a pulse shaper and a display, the pulse shaper through a switch connected to the R-wave selector and an autonomous laser start generator and connected by outputs to a laser power supply and protection and to a display, the second input of which is connected to an amplifier of heart rate signals.

 The disadvantage of this apparatus is the impossibility of its use for the diagnosis of subsurface layers of a biological object, as well as the impossibility of its operation in an automated system in conjunction with an external computer.

The technical result achieved by the proposed invention is to expand the functionality of the apparatus and is provided by;
- diagnostic capabilities of subsurface layers of a biological object;
- the possibility of the apparatus in an automated system in conjunction with an external computer.

 The specified technical result is achieved in the apparatus for diagnostics and magnetic laser therapy, consisting of a terminal and a control panel.

 The control panel contains a digital indication unit, an audio indication unit, a LED power source connected to the terminal LEDs, a laser emitter power source connected to the terminal laser emitter, and a synchronizer consisting of a heart rate signal amplifier connected in series, the input of which is the signal input of the device , a selector of R-teeth, a pulse shaper, a switch connected to the output of the pulse shaper, a display, the second input of which is connected It is connected with the second output of the heart rate signal amplifier, as well as a microprocessor, an adaptation unit and a mode switching unit connected to the switching input of the microprocessor.

 The terminal contains N (where N> 1) LEDs, a photodiode, a laser emitter, a source of constant magnetic field, one side of which represents the front of the terminal, a photodetector, a second switch, at least one additional photodiode and a camera whose inner surface is configured to reflection of optical radiation, and the camera is placed between the inner surfaces of the source of constant magnetic field, one of the base of the camera represents the front plane of the terminal, and on the other base of the camera LEDs, a photodiode, a laser emitter are rigidly mounted, while at least one additional photodiode is additionally inserted in the hole made in the source of a constant magnetic field, and is connected to a photodetector through a second switch, to which a photodiode is also connected through a second switch, located in the camera, while the output of the photodetector is connected to the indicator input of the microprocessor, the indicator output of which is connected to a digital display unit, while the first and second triggering The 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, while the trigger input of the microprocessor through the first switch is connected to the trigger input of the device, and the information input-output of the microprocessor through the adaptation unit is connected to the information input-output of the device.

 The highest technical result is achieved by performing a constant magnetic field source in the form of a flat ring magnet, which is a typical and most rational solution.

 The implementation of the camera in the form of a cylinder is optimal when performing a source of constant magnetic field in the form of a flat ring magnet.

 The condition 0.8 <H / D <1.2, where H is the height of the chamber and D is the diameter of the chamber, provides a uniform distribution of the radiation density of the laser emitter and LEDs in the terminal aperture.

 The camera is made of non-magnetic metal, such as brass, which eliminates the distortion of the magnetic field.

 The chamber can be made of a weatherproof dielectric material, for example, plastic, which further reduces the cost and makes the construction easier.

The invention is illustrated by drawings, where figure 1 shows a functional diagram of the apparatus, where:
1 - Control Panel
2 - Terminal
3 - Camera
4 - LEDs
5 - Laser emitter
6 - Source of a constant magnetic field
7 - Photodiode
8 - Additional photodiode
9 - Second switch
10 - Photodetector
11 - Digital display unit
12 - Microprocessor
13 - LED power supply
14 - Power source laser emitter
15 - Adaptation unit
16 - Information input-output device
17 - Signal input of the device
18 - Synchronizer
19 - Heart Rate Amplifier
20 - R-teeth selector
21 - Shaper bursts
22 - Display
23 - Trigger input device
24 - First switch
25 - Sound indication unit
26 - Block switching modes
and figure 2 is a fragment of the design of the apparatus, explaining the process of reflection and reception of optical radiation from the layers of the biological object, where:
2 - Terminal
4 - LEDs
5 - Laser emitter
7 - Photodiode
8 - Additional photodiode
10 - Photodetector
27 - Bioobject.

 The apparatus for diagnostics and magnetic laser therapy consists of a terminal 2 and a control panel 1.

 The control panel 1 contains a digital display unit 11, an audio display unit 25, a power supply for the LEDs 13 connected to the LEDs 4 of the terminal 2, a power supply for the laser emitter 14 connected to the laser emitter 5 of the terminal 2, and a synchronizer 18, consisting of a series-connected amplifier heart rate signals 19, the input of which is the signal input of the apparatus, the R-wave selector 20, the pulse shaper 21, the first switch 24 connected to the output of the pulse shaper 21, display It 22, the second input of which is connected to the second output of the heart rate signal amplifier 19, the control panel also contains a microprocessor 12, an adaptation unit 15 and a mode switching unit 26 connected to the switching input of the microprocessor.

 The terminal 2 contains LEDs 4, a photodiode 7, a laser emitter 5, a constant magnetic field source 6, one side of which is the front of the terminal 2, a photodetector 10, a second switch 9, at least one additional photodiode 8 and a camera 3, the inner surface of which made with the possibility of reflecting optical radiation, and the camera 3 is placed between the inner surfaces of the source of constant magnetic field 6, one of the bases of the camera 3 is the front plane of the terminal 2, and on the other the base and cameras 3 are rigidly mounted LEDs 4, photodiode 7, laser emitter 5, while an additional photodiode 8 is installed in the hole made in the source of constant magnetic field 6, and through the second switch 9 is connected to the photodetector 10, to which through the second switch 9 is also connected and a photodiode 7, while the output of the photodetector 7 is connected to the indicator input of the microprocessor 12, to the indicator output of which a digital indication unit 11 is connected, and an audio indication unit 25 is connected to the output of the microprocessor 12, while the first and second triggering outputs of the microprocessor 12 are connected respectively to the input of the power supply of the LEDs 13 and the input of the power source of the laser emitter 14, while the triggering input of the microprocessor 12 through the first switch 24 is connected to the triggering input of the device 23, and the information input-output of the microprocessor through the adaptation unit 15 connected to the information input-output device 16.

 The control panel 1 and terminal 2 for ease of operation of the apparatus are located in separate buildings, and the electrical conductors connecting them are laid in the connecting cable.

 Structurally, the terminal 2 casing is made in the form of a remote tube, inside of which there is a constant magnetic field source 6 and a chamber 3 located between the inner surfaces of the constant magnetic field source, and with LEDs 4, a photodiode 7, and a semiconductor pulsed laser emitter 5 installed in the chamber of the magnetic field 6 may take the form of a flat ring magnet, one side of which, corresponding to the flat edge of its north pole, is the front of the terminal 2 and the other side, corresponding to the flat edge of its south pole, faces the inside of the terminal. A magnet with a camera is fixed in the terminal with a nut. The plane of one of the end openings of the terminal 1 housing coincides with the flat surface of its end part. This end hole and the front of the terminal 2 can be closed with a sterilized removable cover that is transparent to light radiation. In the hole made in the source of the constant magnetic field 6, an additional photodiode 8 is installed, connected via a switch 9 to the photodetector 10. A connecting cable is connected to it through the second end hole of the terminal 2.

 The control panel case 1 has a front panel with the buttons of the mode switching unit 26 and the first switch 24 displayed on it, the indicator of the digital display unit 11 and the display screen 22. Three connectors are installed on the control panel case for the signal input 17, which triggers the input 23 of the information input device output 16. The housing of the control panel 1 is connected by an electric cable to terminal 2, and also has an outlet for the power supply cable.

Medical diagnostic laser device can work:
- offline;
- in the external laser start mode from an extraneous generator;
- in cardiology mode.

 In stand-alone operation mode, the microprocessor 12 generates laser start pulses, which through the microprocessor start-up output are supplied to the power source of the laser emitter 14. The pulse repetition rate and time exposure of the apparatus are discretely set by the microprocessor 12 and set using the mode switching unit 26, and their value is displayed on digital indication unit 11. After setting the required repetition frequency of the laser radiation and exposure, a predetermined level of LED radiation is set 4. For this, terminal 2 is placed in a special box on the body of the control panel 1, a photo diode 7 is connected to the photodetector 10 through a switch 9, the LEDs 4 are turned on, and the signal reflected from the terminal bed, according to the indications of the digital display unit 11, the required level of LED radiation power is set 4. The radiation is turned off. The device is ready for use.

 Terminal 2 is superimposed onto the bioobject and the Start button turns on the radiation of the laser emitter 5 and LEDs 4, the signal reflected from the bioobject goes to photodiodes 7 and 8, respectively, and the signal reflected from the surface layers of the bioobject goes to photodiode 7, and from 8 subsurface (inner) layers (Figure 2). The magnitude of these reflected signals depends on many factors, including the presence of pathology (tumor, pus, fracture, burn, etc.). By connecting a photodiode 7 or a photodiode 8 to the photodetector 10, it is possible to diagnose the presence of pathology on the surface or inside the biological object and its localization according to the readings of the digital indication unit 11.

 The microprocessor 12 generates a signal supplied to the sound indication unit 25, the signal of which notifies the device is ready for operation and the end of the exposure (end of exposure).

 The adaptation unit 15 of the apparatus allows controlling the microprocessor by setting the necessary operating mode for a particular patient from an external computer and receiving information on the results of working with the patient on the computer (LED radiation power, laser emitter repetition rate, energy (dose) received by the patient during the session, coefficient reflections from a bioobject, etc.).

 In the external start-up mode of the device, a start-up pulse is received from the external generator to the start-up input of the device 23, which, through the first switch 24, is supplied to the microprocessor 12, where a laser start-up pulse is generated with a frequency determined by the external generator. All other operations when working with the apparatus and bioobject are the same as in stand-alone mode, except for setting the repetition frequency of laser radiation, which is now set by an external generator.

 In the cardiological mode of operation, the signals from the electrodes mounted on the biological object are fed to the signal input of the apparatus 17 and through the amplifier of the heart rhythm signals 19 to the display 22 and the selector R of the teeth 20. The amplifier of the heart rhythm signals 19 generates an electrical signal corresponding to the electrocardiogram of the patient’s heart, which is observed on the display 22. The selector of the R-waves 20 generates a pulse synchronous with the R-wave, which is fed to the shaper of the pulse train 21.

 The operator using the control panel 1 can adjust the number of pulses in the packet from 1 to 20 and their delay with respect to the R-wave within the cycle of cardiac activity. The signal generated in the shaper of the pulse packets 21 through the first switch 24 is fed to the microprocessor 12, where a packet of pulses is formed, which starts the laser emitter 5.

 At the same time, a strobe pulse is sent to the display 22 from the pulse train driver 21, allowing the phase (delay time) of the pulse train to be observed on the cardiogram with respect to the R wave.

 When working with a patient, terminal 2 is superimposed on the region of the heart from the side of the chest. All other operations when working with the apparatus and the bioobject are the same as in stand-alone mode, except for setting the repetition frequency of laser radiation, which in this case is determined by the heartbeat frequency.

 In all three operating modes of the device, camera 3 provides the required aperture of terminal 2, i.e. a certain diameter of the spot at the exit of the chamber 3 and the angular divergence of the light emissions of the LEDs 4 and the laser emitter 5 when the radiation exits from the hole of the annular source of constant magnetic field 6, terminal 2, determined by the established ratio of the height and diameter of the chamber, made in the form of a cylinder, based on condition 0 , 8 <H / D <1.2, and performs a uniform mixing of light emissions over the area of this hole by combining spots or bases of light emission cones in each of LEDs 4 and laser 5, with than the area of these spots is equal to the area of the hole. The light radiation collected by the camera 3 of the terminal 2 in the hole of the source of the constant magnetic field 6, which plays the role of an irradiation aperture in the front of the terminal 2, leaves it and exerts a physiotherapeutic effect on the biological object within the exposure along with the constant magnetic field.

 During the irradiation of a biological object, photodiodes 7 and 8 get a fraction of the power of the acting light radiation reflected from the irradiated object, interconnected with the amount of light energy absorbed by the tissues of the latter. At the same time, a signal reflected mainly from the surface of the biological object falls on photodiode 7, and on its subsurface layers on photodiode 8.

 Through the photodetector 10, the signals from the photodiodes 7 and 8 through the microprocessor 12 arrive at the digital display unit 11, the readings of which are proportional to the levels of electrical signals, which makes it possible to determine the absorption and reflection coefficients of the tissues of the irradiated biological object in the field of physiotherapy.

The presence in the apparatus of the power supply of LEDs 13 allows you to set the power of the LEDs 4 from zero to the maximum level by smoothly adjusting their supply current using a microprocessor 12. The maximum radiation power density created, for example, by four LEDs of the type AL-119 A, B in the irradiating the opening of terminal 2, reaches 25 mW / cm ² . The pulse power and pulse duration of the light radiation generated in the apparatus by a modulated semiconductor pulsed laser emitter type ЛПИ-101 or ЛПИ-102, respectively, is about 5 W and 150 ns. The repetition rate of radiation lies in the range from 5 Hz to 500 Hz and is set by microprocessor 12 or an external triggering generator.

 The AL-119 LEDs and lasers ЛПИ-101 or ЛПИ-102 used in the apparatus are sources of low-energy light radiation with a wavelength lying in the near infrared range of the optical spectrum (0.84 - 0.89 μm) and provide the possibility of exposure to this radiation on tissue of a biological object to a depth of 7-8 cm. Determination of the reflection coefficient (absorption) of a biological object using an integrated photorecorder, consisting of a photodetector 10 and a digital display unit 11, as well as the known parameters of the emitters, the exposure time (exp zitsii) it allows us to calculate the amount of energy absorbed bioobject, that is, to clarify the dosage of radiation biological object.

 Using in the apparatus of adaptation block 15 with an external computer, for example, microcircuit type AMD-232 allows you to automate the process of physiotherapy and accounting information about the procedure, systematization and processing of the results.

Claims (6)

 1. Apparatus for diagnostics and magnetic laser therapy, consisting of a terminal containing N (where N> 1) LEDs, a photodiode, a laser emitter, a source of constant magnetic field, one side of which represents the front of the terminal, and a control panel containing a digital display unit, sound indication unit, power supply of LEDs connected to the LEDs of the terminal, power supply of the laser emitter connected to the laser emitter of the terminal, as well as a synchronizer, consisting of connected in series heart rate signal amplifiers, the input of which is the signal input of the apparatus, the R-wave selector, the pulse shaper, a switch connected to the output of the pulse shaper, a display, the second input of which is connected to the second output of the heart rhythm signal, characterized in that the remote control the control further comprises a microprocessor, an adaptation unit and a mode switching unit connected to the switching input of the microprocessor, and the terminal further comprises a photodetector, a second switch a sensor, at least one additional photodiode and a camera whose inner surface is capable of reflecting optical radiation, the camera being placed between the inner surfaces of a constant magnetic field source, one of the camera bases is the front plane of the terminal, and LEDs are rigidly mounted on the other camera base , a photodiode, a laser emitter, while at least one photodiode is additionally inserted, is installed in the hole made in the source of the permanent magnet field, and through the second switch it is connected to the photodetector, to which the photo diode installed in the camera is also connected through the second switch, while the output of the photodetector is connected to the indicator input of the microprocessor, a digital indication unit is connected to the indicator output of the microprocessor, and to the first and second The microprocessor triggering outputs are connected respectively to the input of the LED power source and the input of the laser emitter power source, while the microprocessor triggering input is connected through the first ereklyuchatel connected to the trigger input apparatus and an information input-output microprocessor via the adaptation unit connected to the information input-output apparatus.  2. The apparatus for diagnostics and magnetic laser therapy according to claim 1, characterized in that the source of the constant magnetic field is made in the form of a flat ring magnet.  3. The apparatus for diagnosis and magnetic laser therapy according to claim 1, characterized in that the camera is made in the form of a cylinder.  4. The apparatus for diagnostics and magnetic laser therapy according to claim 1, characterized in that the camera is made from the condition 0.8 <H / D <1.2, where H is the height of the chamber and D is the diameter of the chamber.  5. The apparatus for diagnosis and magnetic laser therapy according to claim 1, characterized in that the camera is made of non-magnetic metal, such as brass.  6. The apparatus for diagnosis and magnetic laser therapy according to claim 1, characterized in that the camera is made of a weather-resistant dielectric material, for example, plastic.

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