RU2070077C1 - Device for light therapy - Google Patents

Abstract

FIELD: medical equipment, can be used in laser therapy. SUBSTANCE: the device has an optical radiation head, microphone, phonendoscope and a unit for transduction of signals from the microphone. The microphone can be positioned both in the zone of action of optical radiation and outside it. EFFECT: enhanced efficiency. 8 cl, 6 dwg

Description

 The invention relates to the field of medical instrumentation and can be used in diagnostic treatment systems, mainly in devices for laser light therapy of inflammatory foci of internal organs, localization and can find application in clinical outpatient practice.

 Known laser therapeutic devices on semiconductor emitters containing the head of the optical emitter, a power system and a control unit for the operation of the optical emitter (1). To expand the functionality of the device, it is equipped with nozzles, which allows not only to process biological materials, but also to produce pulsed, optical, biophotometric diagnostics of the tissue under study.

The main disadvantages of such devices are:
bulkiness due to sufficiently large dimensions and mass;
low efficiency of the therapeutic effect of the device due to the impossibility of localizing the zone of exposure to optical radiation, which affects the timing of treatment of patients.

 Also known are devices for magnetic laser therapy, including an annular ferrite magnet and a laser-optical emitter with a control unit for its operation and a power system, which are based on stethophonendoscopes. The presence of a stethophonendoscope sound reception chamber, which is installed at the output of the head of the optical emitter, allows this device to combine diagnostic and therapeutic functions, which in turn increases the effectiveness of the therapeutic effect of optical radiation due to increased localization accuracy of internal lesions, for example, in the treatment of pneumonia, pleurisy, bronchitis and other lung diseases, as well as in the treatment of coronary heart disease.

The main disadvantages of these devices are:
insufficient effectiveness of the therapeutic effect due to the ambiguity of the acoustic direction of diagnosis and the radiating effect, uneven irradiation of the lesion with a non-perpendicular flow;
insufficient efficiency of the device both when diagnosing due to a decrease in the acoustic quality of the phonendoscope due to the location of the emitting head in the cavity of the sound-receiving chamber, and when conducting a session of therapeutic treatment for the patient due to errors in the spatial alignment of the true location of the internal lesion focus and the irradiated area;
low sensitivity during auscultation, which entails an increase in time for the process of localization of the lesion;
the impossibility of automating the process of processing auscultation data and creating an adaptive device for laser light therapy.

 Recently, to increase the sensitivity of stethophonendoscopes, devices have been developed for auscultation using acceleration sensors operating using the piezoelectric effect and designed to record the mechanical manifestations of cardiovascular and other systems in the infrasound and sound frequency ranges, as well as using microphones in which mechanical fluctuations of the patient’s chest are transmitted to the elastic element of the membrane and inductance coil, which moves magnetically field induced electromotive force in it, is proportional to the speed fluctuation of the membrane (3, 4).

 Auscultation devices are also known in which, to eliminate the shortcomings of traditional designs of stethophonendoscopes, due to the dependence of the sensitivity of the latter on the purely individual qualities of the attending physician’s hearing aid, a contact microphone is integrated with an amplified audio signal converted into an electric signal, consisting of an amplifier, a switch and a light telephone (5) .

 A device for magnetic laser therapy is also known, including a stethophonendoscope, an optical emitter, an annular magnet mounted on a stethophonendoscope, and a power system (6).

 This device, in addition to magnetic therapy and light therapy, can, like device (2), perform auscultation, but in order to create optimal conditions for localizing the lesion and increasing the susceptibility of the device to the high-frequency component of auscultatory signs, it solved the issue of the removal of the optical emitter from the sound-receiving cavity camera and perform phonendoscope optically transparent membrane for optical flow. This device is selected as a prototype.

The main disadvantages of this device are:
low sensitivity of the stethophonendoscope, causing, as a consequence, an increase in the localization time of the lesion;
the impossibility of automating the process of processing auscultation data and, on their basis, controlling the process of therapeutic effect.

 The present invention is aimed at achieving the task, which consists in improving the therapeutic and diagnostic properties of the device for light therapy by increasing the sensitivity of the sound receiver, improving the quality of auscultation by conducting the auscultation process simultaneously using a stethophonendoscope and microphone, or using two microphones installed with an offset of one relative to each other in the contact plane and allowing simultaneous auscultation of the patient, taking acoustic signals from two points t la patient, for example the trachea and bronchi simultaneously.

 In addition, the invention is aimed at improving the medical and diagnostic properties of devices for light therapy by expanding the functionality of the device by creating conditions for controlling the therapeutic effect depending on the directly obtained results of auscultation of the patient.

 Achieving this task is ensured by the fact that in the device for light therapy containing the head of the optical emitter, the optical emitter operation control unit and a power source are additionally integrated into the optical emitter head housing at the output of the optical radiation microphone, the output of which is connected to the microphone via the microphone control unit with a telephone. In this case, the microphone can be placed both outside the range of the light flux of the optical emitter and so that its sensitive element, which is made of material that is optically transparent in the range of the optical emitter or has an optically transparent window, is in the path of the light flux. As a microphone, either an electromagnetic or a piezoelectric transducer of sound signals can be selected.

 Achieving this task is also ensured by the fact that the device can be equipped with a stethophonendoscope funnel installed at the output of the optical radiation head, the geometric axis of the cavity of the sound-receiving chamber of which coincides, and the contact plane of which is perpendicular to the maximum of the indicatrix of optical radiation, and the microphone is located outside the cavity of the sound-receiving camera of the stethophonendoscope. In this case, the microphone may have an acoustic connection with the cavity of the sound receiving chamber of the stethophonendoscope. In addition, the task is achieved in that the device for light therapy can be equipped with an additional microphone, also installed in the head housing of the optical emitter with an offset in the cross section of the head relative to the main microphone. In this case, the operation control unit of one or both microphones is connected to the operation unit of the optical emitter through the switch.

 A comparative analysis of the claimed light therapy device with the prototype (6) shows that the proposed device is distinguished by the presence of an optical emitter built into the body of the head of the head of the optical radiation of the microphone, the output of which is connected via the microphone control unit to the stethotelephone.

 A comparative analysis also confirms that the proposed device differs from the prototype in all design features set forth in paragraphs 2 to 8 of the proposed claims.

 Thus, the claimed design of the device for light therapy meets the criteria of the invention of "NOVELTY."

 Technical solutions are known (3, 4,), in which microphones, including those made in the form of electromagnetic or piezoelectric transducers of sound vibrations, have found application in the design of auscultation devices (stethophonendoscopes), however, the question of the possibility of installing microphones directly in the head of the optical emitter of the device for light therapy, which, firstly, would not complicate the parameters of its optical system, and, secondly, would ensure that the acoustic Board diagnostics (with auscultation) and radiating effects during light therapy. Only with the achievement of such unambiguity of the factors of acoustic diagnostics and radiative forcing therapy, the right to exist devices for laser (magnetic laser) therapy, built on the basis of stethophonendoscopes, as well as using microphones (2). The proposed solution to this problem with the simultaneous enhancement of the sensitivity of the sound receiver by supplying the device for light therapy with a microphone, and even more with two microphones installed offset from each other in the contact plane, allows for simultaneous auscultation of the patient, taking acoustic signals from two points of the patient’s body. In addition, if the device for light therapy is equipped with a stethophonendoscope funnel, the presence of two microphone sound detectors makes it possible to realize the advantages of duostetophonendoscopes, or (if the stethophonendoscope of the auditory tubes are connected to the cavity of the receiving chamber (not shown in the drawings), combine the acquisition of the acoustic signal using the auditory tubes from the stethophonendoscope and the converted signal using the stethotelephone from the microphone. The implementation of the microphone sensor element from optically transparent to the range of operation of the optical emitter of the material or the provision of its optically transparent window allows, without compromising the optical parameters of the optical system of the device for light therapy, to ensure the uniqueness of the acoustic voltage of the diagnostic and therapeutic effects of optical radiation, as well as to increase the sensitivity of the sound receiver, which ultimately leads to improvement medical and diagnostic properties of the device.In addition, this embodiment of the sensitive element allows using the use of two microphones to ensure their most optimal placement for diagnosis (one on the maximum axis of the scattering indicatrix of the optical emitter, and the second is displaced in the contact plane relative to the first).

 Technical solutions are also known (5), in which the microphone built into the stethophonendoscope is connected to the stethotelephone via the control unit, which, in addition to amplification of the recorded acoustic signal, allows for separate listening to different phases of the recorded signal, for example, phases of the cardiac cycle. The proposed binding of the microphone operation control unit (and especially two microphones) to the optical emitter operation control unit (for controlling the moment and duration of turning on the laser, laser LEDs, LEDs, or both) using the optical emitter built-in between the power source and the control unit the switch allows you to expand significantly the functional capabilities of the device for light therapy and provide, in contrast to known similar devices (1, 2, 6), the ability to control Procedure optical radiation to the patient based on a weighted auscultation picture when the captured audio signal.

 A comparative analysis of the claimed solution, not only with the prototype, but also with other technical solutions in this area, reflected in sources 1-6, gives the right to conclude that it meets the criteria of the invention - "INVENTIVE LEVEL".

 In FIG. 1 is a schematic view of the head of an optical emitter with a microphone integrated in the head housing located in the path of the light flux; in FIG. 2 is a schematic view of the head of an optical emitter with a microphone integrated in the head housing located outside the optical radiation coverage area; in FIG. 3 embodiment of a microphone in the form of an electromagnetic phonocardiographic contact microphone integrated in the head of an optical emitter; in FIG. 4 embodiment of a microphone in the form of a piezoceramic acceleration sensor built into the head of an optical emitter; in FIG. 5 embodiment of a device for light therapy, when the head of the optical emitter is equipped with a funnel of a stethophonendoscope; in FIG. 6 electric block device diagram.

 The device for light therapy is a head of an optical emitter, in the housing 1 of which there is an optical radiation source 2, which can act as a laser 3, for example, semiconductor grade LPN 203A with a radiation power of 2 2.5 MW and a radiation wavelength of 0.88 ± 0.001 μm or a pulse laser of the ЛПИ 12 brand with a pulse power of 4 W, and a set of LEDs 4, for example, АЛ 118А brand with a radiation power of 2 2.5 mW and a radiation wavelength at the maximum of the spectral characteristic - 0.88 ± 0.001 μm. There may be a combination of LEDs with a laser located in the center. The optical system of the emitter in the simplest case may consist only of optical radiation sources or may additionally include elements such as optical diagram 5, filters, optical lenses (not shown in the drawings). As a use as a concept of the axis of the optical system of the emitter, by it we mean the direction of the maximum of the indicatrix of radiation (total radiation of LEDs 4 and laser 3). In the case of the execution of the housing 1 of the head of the optical emitter in the form of a body of revolution, for example a cylinder, the axis of the optical system coincides with the axis of the (geometric) body of the head. Optical radiation sources 2 (laser 3 and LEDs 4) are connected to the power source 7 through the optical emitter operation control unit 6. The electrical circuit of the optical emitter operation control unit, in turn, consists of parts: a laser control unit 8 and LED control unit 9, which are connected to the power source 7 through the switch 10. The laser 3 and the LEDs 4 are connected to their control units 8 and 9, respectively, through tuning variable resistors 11 and 12, respectively, for smooth adjustment of their power zlucheniya. At the output of the optical system of the emitter (at the output of the head of the optical emitter), a microphone 13 is placed in its housing 1, which can be made in the form of an electromagnetic or piezoelectric transducer of sound signals, for example, in the form of a contact (or non-contact) phonocardiographic sensor (3) or a piezoceramic acceleration sensor (4). The microphone 13 can be installed in the housing 1 of the head of the optical emitter either outside the range of the light flux of the optical emitter (Fig. 2), or so that its sensitive element is in the path of the light flux of the optical emitter (Fig. 1, 3, 4). In this case, the sensitive element is made of a material that is transparent in the operating range of the optical emitter (infrared spectrum) or has an optically transparent window (Fig. 3).

 In the case of the microphone 13 in the form of a contact phonocardiographic sensor (Fig. 3), the latter is a sensing element located on the axis of the housing 1 of the optical radiation head at the output of the optical radiation in the form of a membrane 14 mounted in the housing 1 with a pellet 15 and an inductor 16, as well as a permanent magnet 17 and magnetic circuits 18 of the magnet core that are installed in the housing 1 and encloses the inductor 16. The power of the microphone 13 and the optical radiation source 2 are output to the boards 19 and 20, respectively. The protrusion of the pilot 15 can be adjusted using the frame 21 by turning it (when screwed to the housing 1). The pilot 15 and the housing of the inductance coil 16 of the microphone 13 can be made of optically transparent plastic or equipped with an optically transparent window with a central through hole 22 for passage of the light flux of the optical emitter. To protect against damage and ingress of dust and dirt into the head, the head is provided with a cover 23 covering the outlet of the head of the optical emitter.

 In the case of the microphone 13 in the form of a piezoceramic acceleration sensor (Fig. 4), the latter is a sensitive element located in the housing 1 of the head of the optical emitter in the form of a fixed in the housing 1 of the membrane 14 with a fixed (soldered) piezoelectric element 24 in it, for example, in the form piezoelectric element bimorph) from a thin polarized piezoelectric ceramic plate TsTS-19. A membrane 26 is attached to the membrane 14 by means of a screw 25, which acts as an inertial mass. Thus assembled the node of the microphone element of the microphone ring (threaded) 27 is pressed against the housing 1 of the head of the optical emitter. To pass the light flux of the optical emitter in the ring 27, screw 25, membrane 14 and the piezoelectric element 24, through-holes can be made through optically transparent windows, or a part of the listed elements, for example, ring 27, screw 25 or piezoelectric element 24 can be made of optical material transparent for the operating range of the optical emitter (optically transparent plastics, corundum for the piezoelectric element). The output hole of the head of the optical emitter is also closed by a cover 23. To adjust the axial position of the source of optical radiation 2 relative to the housing 1 of the head (removal from the contact plane of the end face of the head), the optical radiation source 2 can be installed in the housing 1 by means of a sleeve 28 movable along its axis.

 In the case of using microminiature versions as microphones, the head housing of the optical emitter allows, without any significant increase in its dimensions, to place an additional at least one microphone 29, which allows using this device to simultaneously conduct auscultation, removing acoustic signals from two points of the surface of the patient’s body, for example, when listening to blood vessels with a determination of the blood flow velocity in them, to carry out the (bistereo) auscultation regimen.

 The proposed device can be equipped with a funnel 30 stethophonendoscope made in the housing 1 at the exit of the optical radiation. The optical radiation source 2 is taken out from the cavity of the sound-receiving chamber 31 of the stethophonendoscope funnel 30 and placed in the head housing 1 so that the maximum indicatrix of the optical radiation in direction coincides with the geometric axis of the sound-receiving chamber 31. The sound-conducting channel is made in the funnel body 30, in which a fitting is installed (not shown in the drawing) for connecting auditory tubes or a microphone 13 is placed (Fig. 5), while the sound-conducting channel provides acoustic communication of the sound-receiving cameras 31 stethophonendoscope with a sensitive element of the microphone 13, which is also removed from the cavity of the sound-receiving chamber 31. An additional microphone 29 (Fig. 5) is placed in the housing of the funnel 30 of the stethophonendoscope from the contact plane of the funnel, may have the ability to install (displacement in the transverse plane) relative to the housing funnels 20, and therefore, lateral displacement relative to the microphone 13 (not shown in the drawing), which allows you to adjust the distance between them, and therefore between auscultated points rhnosti patient's body. The funnel 30 of the stethophonendoscope can be equipped with a permanent magnet 32 installed in its housing from the side of the working end of the funnel, for example, a ring ferrite, covering the cavity of the sound-receiving chamber 31 from the outside, which allows using this device to carry out not only light therapy, but also magnetic therapy, as well as installed on the working end of the funnel with a 33 phonendoscope membrane. The output of the head of the stethophonendoscope, in this case the output of the funnel, which is also the output of the head of the optical emitter, is closed by a cover 23 to prevent dirt from entering and prevent mechanical damage, as in previous versions. To localize the action of the magnetic field, the permanent magnet 32 is equipped with a magnetic screen made, for example, of transformer steel (screen 34). The sound-conducting channel 35 connected to the cavity of the sound-receiving chamber 31 of the stethophonendoscope funnel may have two branch channels (not shown) for simultaneous connection of the microphone 13 and auditory tubes, which allows receiving information about the auscultation process both directly through the hearing tubes and from the microphone on the stethotelephone. In addition, a similar design of the device for light therapy allows you to make two sound-conducting channels in the funnel of the stethophonendoscope and place a movable partition between them (according to the well-known diagram, not shown in the drawing), which makes it possible to maintain mono- and stereo-auscultation without interfering (with the partition removed) ) light therapy.

 The microphone 13 or the microphones 13 and 29 are connected through the control unit of their work 35 and connected to the stetho-telephone 36 (Fig. 2.6). The microphone operation control unit can be performed in a known manner, for example, as described in source 5, and contains a preamplifier 36 with a correction element 37, an output amplifier 36 with a correction element 39, and a pulse shaper 40 connected between them with a controlled delay unit 41 and a generating unit a gate pulse 42 at the output, as well as a controlled key 43, the input of the driver 40 and the first input of the controlled key 43 connected to the output of the pre-amplifier 36, and the output of the controlled key 43 and the second input of it about connected respectively to the input of the output amplifier 38 and to the output of the block 41 of the formation of the strobe pulse. To ensure the possibility of the proposed device in the "clean" diagnostic mode with the perception of the acoustic signal by the stetotelephone 36 and to use the signal received during auscultation to control the operation of the optical emitter (laser 3 and / or LEDs 4), the microphone control unit 35 (microphones, not shown) shown) is equipped with a switch 44 and is connected through it to the second input of the switch 10, which controls the operation of the optical emitter control unit 6, that is, the operation of the laser control unit 8 3 ohms, and the control unit 9 LEDs 4, because the first output of switch 10 is connected to the input of the laser control unit 8, and the second output switch 10 is connected to the input of the control unit 9 4 LEDs.

 The operation of the device for light therapy is as follows. Using a microphone 13 (or a microphone 13 and 14) built into the body of the head of the optical emitter, auscultation of the patient is performed (in mono or stereo auscultation mode), performing phonocardiographic, for example, examination in the full phonocardiographic range, and localization of the lesion foci is determined. The location and sound phenomena also determine the disease of the organ. During auscultation, the signal from the microphone 13 (electromagnetic or piezoelectric type) is fed to the input of the preamplifier 36 with the correction element 37, where, for example, when separately listening to the phases of the cardiac cycle, high frequencies are raised, as described in source 5. From the output of the preamplifier 36 the signal is fed simultaneously to the first input of the controlled key 43 and to the input of the driver 40, in which a pulse is generated from the first tone of the phonocardiogram to start the controlled delay unit 41. From the shaper 40, a gate pulse generating unit 42 is launched, which is supplied to the second input of the controlled key 43 and unlocks it. From the controlled key 43, the signal is fed to the input of the output amplifier 38, in which high frequencies are also boosted, and from the output of the amplifier 38, the signal is fed to the stethotelephone. Using the switch 44, the signal amplified from the microphone 13, with a predetermined delay, can be applied not to the stetotelephone, but to the switch 10 (to its second input) by starting the laser control unit 8 or LED control unit 9.

 Thus, depending on the need (from the picture of the acoustic signal obtained by auscultation of the separate drying of the phases of the cardiac cycle), the possibility of targeted exposure to optical radiation synchronized with the corresponding phases of the cardiac cycle (systole or diastole) is provided. The range of control of the degree of delay within 0.01 0.6 s allows you to listen to the systole with a delay of 0.01 s, and a second tone with a delay of 0.3, while diastole is heard with a delay of 0.4 0.6 s. Due to the large linear increase in high frequencies in amplifiers 36 and 38 of such a microphone control unit, as stated in source 5, anomalies of valve insufficiency or noise from blood clots in coronary vessels can be distinguished during auscultation.

 In the process of light therapy using this device, depending on the results of auscultation, the dosage of optical exposure is determined, and the radiation power is set using resistors 11 and 12.

 In the process of diagnosis, using the proposed device, mono-auscultation options are possible using a single microphone installed in the path of the light flux or removed from the zone of its action, in the full phonocardiographic frequency range (up to 500 1000 Hz) or using a microphone and direct listening through auditory tubes when using a device made according to the variant with a built-in funnel of a stethophonendoscope, auscultation options are possible simultaneously at two points on the surface of the patient’s body. When using a device with two microphones 13 and 29 built into the body of the head of the optical emitter, for example, when listening to blood vessels, stereo-auscultation options with a stethophonendoscope with two microphones, or microphones and hearing tubes, are possible.

 The acoustic unit of the device in the case of a microphone in the form of a contact phonocardiographic sensor (Fig. 3) works as follows. Mechanical vibrations of the surface of the patient’s body at the point of contact with the head housing 1 act on the pilot 15, and from it to the membrane 14 and, respectively, the inductor 16, which moves in the magnetic field of a permanent magnet 17, equipped with magnetic circuits of a special shape 18. When moving the inductor 16 A magnetic field is induced in it by an electromotive force proportional to the speed of oscillation of the pelot. The electric signal taken from the inductor 16, as mentioned above, is supplied to the microphone operation control unit 35, where it is generated and amplified and fed to the stetotelephone 36 or to the switch 10 for controlling the light therapy mode.

 The acoustic unit of the device in the case of the microphone in the form of a piezoceramic acceleration sensor (Fig. 4) works as follows.

 Mechanical vibrations of the surface of the patient’s body at the point of contact with the head housing 1 act on the head housing in which the piezoceramic sensor is mounted, while with the accelerated movement of the body, the load 26 mounted on it on the membrane 14 acts on the piezoceramic plate (piezoelectric element 24) with a deforming force, proportional to acceleration. The plate bends and an electric charge appears on its plates proportional to the deformation of the plate, the signal of which is fed to the input of the microphone operation control unit 35, where it is formed and amplified, and then fed to the stetotelephone 36 or to the switch 10, controlling the operation of the optical emitter. When working in the region of frequencies low in comparison with the resonant frequency of the sensor, the bend is proportional to the acceleration of its body, therefore, to the acceleration of mechanical vibrations of the surface of the patient’s body.

 Equipping the head housing of the optical emitter (funnel body 30 of the stethophonendoscope) with a permanent magnet 33, for example of a samarium-cobalt alloy, which can create a magnetic field with a magnetic induction value of 40 to 400 mT, allows not only laser, but also magnetic therapy, expanding the functional device capabilities. The device can also be equipped with a set of interchangeable optical and magnetic diaphragms mounted on the working end of the head housing 1, as well as a set of filters, which greatly expands the device's capabilities in the field of light therapy, controlling the degree of illumination by area, chromaticity, and frequency of radiation.

 The proposed device for light therapy allows to improve the medical and diagnostic properties of this type of device by increasing the sensitivity of the sound receiver, improving the quality of auscultation, by conducting the auscultation process simultaneously with a stethophonendoscope and a microphone or two microphones, providing the possibility of auscultation simultaneously at several points on the patient’s body surface, and also extends the functionality of the device by creating conditions for controlling the therapeutic regimen exposure to optical radiation, depending on the directly obtained results of auscultation of the patient.

 Thus, the proposed technical solution has features that meet the criteria of the invention "Industrial Applicability".

Claims (8)

 1. A device for light therapy comprising a head of an optical emitter, a power supply unit and a control unit for emitter operation, characterized in that the device further comprises a microphone, a light phonendoscope and a microphone signal conversion unit connected to a microphone output and an input of the light phonendoscope, the microphone being mounted on the output surface emitter heads.  2. The device according to p. 1, characterized in that the microphone is installed outside the coverage area of the optical emitter.  3. The device according to p. 1, characterized in that the microphone is installed within the coverage area of the optical emitter, and the sensitive element of the microphone is either made of a material that is transparent in the operating range of the emitter, or has a window transparent to the specified range.  4. The device according to paragraphs. 1 to 3, characterized in that the microphone is made in the form of an electromagnetic or piezoelectric transducer of sound signals.  5. The device according to paragraphs. 1, 2 and 4, characterized in that the funnel of the light path is installed at the output of the head of the emitter so that the geometric axis of the funnel coincides with the optical axis of the emitter, while the microphone is placed outside the cavity of the funnel.  6. The device according to claim 5, characterized in that the microphone is acoustically connected to the cavity of the funnel.  7. The device according to paragraphs. 1 to 6, characterized in that the device further comprises at least one other microphone mounted on the output surface of the head of the emitter with an offset in the output cavity of the head relative to the first microphone.  8. The device according to paragraphs. 1 to 7, characterized in that the unit for signal conversion from the microphone is connected to the control unit of the emitter through the switch.

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