RU9745U1 - ELECTROPHOTO STIMULATION DEVICE - Google Patents

Abstract

1. Device for electrophotostimulation containing a power supply, a hollow, at least in a separate section, a tube transparent to radiation with at least one electrode, radiating elements of the infrared and light range connected to the power supply, and a site for delivering radiation to the tube to the zone being processed pathology, characterized in that the said radiating elements are locally combined on the radiation delivery unit, which is equipped with contacts in the operational state connecting the said electrode and the power supply. The device according to claim 1, characterized in that the said electrode on the tube is made in the form of a system of longitudinal or circular electrically conductive sections. The device according to claims 1 and 2, characterized in that the hollow tube is made in the form of segments of glass and metal tubes fastened together. The device according to claims 1 and 2, characterized in that the hollow tube is made of a transparent material such as plastic, for example polystyrene, polyvinyl chloride, etc., with fixed conductive sections in it. 5. The device according to claims 1 to 4, characterized in that the hollow tube in the pathology zone is made with a cross section in the form of a section of a radiation concentrator, for example, a Weierstrass sphere, and the outer surface of the tube is adequate to the surface of the pathology being treated. 6. The device according to claims 1 to 5, characterized in that one or more of the electrically conductive sections are easily replaceable and one or more layers or sections of friendly trace elements from the series are applied to them: zinc, copper, chromium, etc. 7. The device according to claims 1 to 6, characterized in that the radiation delivery unit is made in the form of a transparent rod, n

Description

ELECTROPHOTO STIMULATION DEVICE

The utility model relates to the field of medical instrumentation, in particular, to devices for simultaneous exposure to light radiation during phototherapy and electrical stimulation, and can be used in various fields of medicine for direct physiotherapy of a pathological focus, for example, with intracavitary localization.

There are a large number of laser therapeutic devices for intracavitary phototherapy, equipped with interchangeable intracavitary nozzles: ALTM, TPLA, ALTP, ULGS - NIO Elekon, Kazan; a series of Mustang devices manufactured by Technika, Moscow; Nega apparatus of Voskhod firm, Kaluga, etc. (see catalogs of firms, as well as / 1 - 3 /).

It is known that radiation penetrates into biological tissues quite deeply (up to several centimeters), and since blood and lymph are exposed to radiation, almost any local radiation can have the character of a systemic effect on the body. Nevertheless, the greatest therapeutic effect is achieved when the radiation is delivered directly to the pathological focus with a sufficient level of radiation mopd density. Therefore, for the treatment of internal organs through the body’s cavities, various devices have been created containing in their composition means for channeling radiation from a source to predetermined sites.

It is known, for example, a device for the light irradiation of biological objects, in which, using an optical system, the radiation from the source is directed to the end face of a replaceable intracavitary nozzle, which acts as a fiber / 4 /. However, these known devices allow only light exposure and do not provide for electrical stimulation of tissues.

On the other hand, devices are known for electrical stimulation of tissues of internal cavities of an organism. In particular, electrostimulators of the gastrointestinal tract are known, which are made in the form of a swallowed capsule or in the form of transduodenal probe electrodes / 5,6 /. The stimulator of the gastrointestinal tract contains a body in the form of a drug capsule, in which there is a power supply connected to the electrodes, which constitute two electrically /

M. Cl. A 61 N5 / 06

In a stimulator, an influencing factor is electrical impulses of a certain amplitude and duration. Therefore, the use of this device is advisable mainly in cases of insufficiency of peristalsis of the gastrointestinal tract, and does not imply the use of the device for general stimulation of a living organism by phototherapy methods.

Known electronic stimulator, rectal-vaginal ESRV-01, containing a cylindrical working tool with a pair of conductive ring contacts connected by a cable to the power supply 111. This device is intended for electrical stimulation of the tissues of the vagina, rectum and prostate gland and does not provide phototherapeutic effect, which reduces its therapeutic efficiency.

The purpose of the utility model is to increase the effectiveness of the therapeutic effect due to the combined effect of electric pulses and radiation from at least two spectral bands - infrared and red, as well as by increasing the density of radiation power supplied to the pathology site. In addition, the goal is to expand the functionality of the apparatus in terms of its use not only in urology, but also in other areas of medicine: gynecology, proctology, otolaryngology and dentistry, that is, in areas associated with exposure to parts of the body through the internal cavities of the body human or animal.

Closest to the proposed utility model for the functional purpose and component parts of the device is the apparatus for laser therapeutic urological AELTU-01 Yarilo / 8-10 /. This therapeutic apparatus is intended for the treatment of patients with chronic inflammatory diseases of the prostate gland, seminal vesicles, urethra, complicated by sexual dysfunction. The device is a desktop type, in the housing of which there is a power supply unit, including a feedback circuit and the formation of a modulated current signal, and a helium-neon laser. A set of working tools is connected to the power supply: a fiber-optic catheter electrode, an irradiator with a matrix of semiconductor infrared lasers, an electrode pad, biorhythm sensors. The catheter is a hollow and, in this case, a tube transparent to laser radiation, at the working end of which is fixed an electrode electrically connected to the distal electrode on the catheter, which, in turn, is connected to one of the poles of the power source. The other pole of the power source is connected to an electrode superimposed on the patient's body. In the known device, an optical fiber is inserted into the catheter to deliver radiation from a helium-neon laser to the urethral region of the prostate gland.

In aggregate common with the proposed device features the prototype is characterized as follows. It contains a power supply, a hollow and at least in a separate section, a tube with at least one electrode transparent for radiation, radiating elements of the infrared and light range connected to the power supply, and a unit for delivering radiation into the tube to the area of the treated pathology.

Using a transurethral catheter, electrostimulation and irradiation of the prostate gland with radiation from a helium-neon laser are performed. An additional radiating head from semiconductor infrared laser diodes irradiates the prostate gland through the perineum. The device has limited functionality - only a transurethral effect on the prostate gland, and the lack of effectiveness of infrared radiation due to the remoteness of the source from the target (exposure through the perineum). In addition, the apparatus turned out to be rather complicated - radiation sources spaced and different in terms of supply loads and means of delivering radiation to the pathology zone, an additional electrode, a complex, although necessary, probably for a specialist doctor, the system of sensors and mode control. In addition, the device is inherent to all the problems of optical and electrical safety of the patient and maintenance personnel associated with the use of lasers, and especially helium-neon. For these reasons, the device is expensive and inaccessible to small organizations and the middle layers of the population.

The proposed utility model is a device with increased impact efficiency, portable, affordable and with advanced features.

Thanks to the implementation of the proposed utility model, the compactness of the device is ensured, a significant increase in the radiation power density in the exposure zone is achieved, which enhances the therapeutic efficiency of the device, and the device’s pathological capabilities expand. At the same time, the possibility of using any complex exposure regimes, including those with bioresonant modulation of influencing factors, is not excluded.

a radiation tube with at least one electrode, radiating elements of the infrared and light range connected to the power supply, and a radiation delivery unit to said tube to the area of the pathology being treated, due to the fact that these radiation elements are locally combined on the radiation delivery unit, which is equipped with contacts in working condition connecting said electrode with a power supply.

It is advisable to mention the electrode on the tube in the form of a system of longitudinal or circular conductive sections.

It is advisable to make a hollow tube in the form of segments of glass and metal tubes fastened together or in the form of a tube made of a transparent material such as plastic, for example, polystyrene, polyvinyl chloride, etc. with electrically conductive sections fixed in it. In this case, one of the electrically conductive sections can be easily replaced by applying one or more layers or sections of friendly trace elements from it: zinc, copper, chromium, etc. - in order to exclude hypermicroelementosis in the human or animal body during electrical stimulation / 11 /.

In addition, a hollow tube can be made with a cross-section in the form of a section of a radiation concentrator, for example, a Weierstrass sphere, and the outer surface of the tube is adequate to the surface of the pathology being treated.

It is advisable to make the radiation delivery unit in the form of a transparent rod, on the distal end of which emitting elements are placed, and in the working area there is a means for deflecting radiation in a given direction, for example, in the form of a mirror inclined, conical or other shape of the end. Or the radiation delivery unit can be in the form of a printed circuit board with radiating elements placed on it, the radiation indicatrix of which is directed towards the surface to be treated.

Justification of the distinguishing features.

The local combination of radiating elements, mainly LEDs, on one radiation delivery unit, in contrast to the prototype, leads to the compactness of the device, while achieving an increase in the radiation power density in the exposure zone. The proposed device does not exclude the possibility of placing elements with different emission spectra, for example, infrared and red, on one radiation delivery unit; infrared, red and green; green, yellow and blue, etc. The implementation of the contact system, mainly contact springs, on the radiation delivery unit provides in working condition

electrical connection of electrically conductive sections on the tube with the power supply. Due to this, the tube can be removable and individualized for each patient.

There may be many options for the implementation of the tube. Making it in the form of segments of glass and metal tubes fastened (by welding, soldering, gluing) to each other removes sterilization issues - this design allows processing at a high (180-250) ° C temperature.

The manufacture of a tube from a transparent material such as plastic, for example, polystyrene, polyvinyl chloride, etc., with electrically conductive, mainly metal sections fixed in it, apparently allows only washing in disinfectant solutions, but promises to simplify the manufacturing process. It is preferable to individualize such tubes for each patient.

And, finally, the implementation of a tube with a cross section in the form of a section of a radiation concentrator, for example, a Weierstrass sphere, with an external surface adequate to the surface of the pathology being treated, will further increase the energy of radiation supplied to the pathological zone.

The implementation of one of the electrically conductive sections is easily replaceable by applying one or more layers or sections of friendly trace elements from it: zinc, copper, chromium, etc. allows during the treatment process to additionally introduce the necessary trace elements into the body.

The implementation of the radiation delivery unit in the form of a transparent rod, on the distal end of which emitting elements are placed, and in the working area, means are made for deflecting radiation in a given direction, or in the form of a printed circuit board with emitting elements placed on it, the radiation indicatrix of which is directed towards the surface to be treated , allows you to concentrate the exposure to radiation directly on the pathology zone in the internal cavity of the body.

The listed features of the proposed device are interconnected and aimed at increasing its therapeutic effectiveness due to the combined effect of electrical pulses and radiation of at least two of the most biologically active spectral bands - infrared and red, and the introduction of trace elements, as well as by increasing the radiation power density, brought to the pathology site. It should be noted that there are no restrictions on the use of radiation sources of any other spectrum and in any combinations in the proposed device. The proposal extends the functionality of the apparatus in terms of its use not only in urology, but also in other areas of medicine: gynecology, proctology, otolaryngology and dentistry, that is, in areas associated with exposure to parts of the body through the internal cavities of the human or animal body . The device is suitable for electrophotostimulation and surface (cutaneous) zones by applying it with electrodes to the pathology zone. And, finally, the utility model determines the high consumer quality of the product due to its compactness with multi-factor impact.

The invention is further illustrated in FIG. 1 to 7, which schematically show some possible layout options for the device.

Figure 1 is a simplified block diagram of a device. Here 1 is a power supply, 2 is a tool holder, 3 is an intracavitary feed, various embodiments of which are illustrated below. Note that the device can be powered both from the network and from an autonomous source (battery, battery, etc.). In addition, the power supply may not be remote, but rigidly fastened to the working tool - the irradiator (Fig. 2, here 1 is the power supply, 3 - intracavitary irradiator).

Fig. 3 shows a possible embodiment of the irradiator, in which the radiation delivery unit is made in the form of a board with radiating elements placed on it. Here 1 is a hollow tube on which electrically conductive sections 4 and 6 are made. The radiation delivery unit 2 is made in the form of a board on which the radiating elements 5 and contact springs 3 and 7 are mounted. When the radiation delivery unit is inserted into the hollow tube of the spring 3 and 7 come into contact with the electrically conductive parts 4 and 6 of the tube and, thereby, electrically connect them to the power supply.

Figure 4 shows a possible design of the irradiator, in which the radiation delivery unit is made in the form of a transparent rod 4, on the distal end of which there are emitting elements 6 (for simplicity, one emitting diode is shown, but it can be multi-chip), and in the working area means for deflecting radiation in a given direction - 10, for example, in the form of a mirror inclined, conical or other form of the end face of the rod. Contacts 3 and 8 are fixed to the rod, electrically connecting in working condition the electrically conductive sections 5 and 7 of the tube with the power supply unit.

modify the electrostimulation procedure: specify transverse stimulation (longitudinal electrodes) or traveling wave stimulation (ring electrodes), which can significantly increase the efficiency of electrostimulation.

In FIG. 7 shows the simplest embodiment of a device based on the details of a known autonomous gastrointestinal electrical stimulator (GIT nuclear power plant). Here 1 and 4 are electrodes for electrical stimulation, 2 is a radiator, 3 is a tube transparent to radiation, 5 is a holder of a radiator (can be in the form of a board, tube, frame, etc.), 6 is a wire connecting the electrodes and the radiator with power supply 7.

It is preferable to carry out emitters by multiwave ones by placing several emitting crystals with different radiation wavelengths from the range from 400 to 1600 nanometers on the holder.

Powerful infrared emitters - AL 148, TOM120C diodes, TOM120K, TOM 1203 LEDs, TOM120D two-wave diodes and other developments of GNIPP NIIPP can be used as radiating elements in any of the proposed embodiments of the radiation delivery means. For the placement of emitters on the board, it often turns out to be more expedient to use not diodes, but emitting crystals from GaP, AlGaAs and InGaAsP of different compositions (radiation wavelengths differ) on the boards, for example, from foil fiberglass.

The hollow tube in the first experimental samples was a medical glass tube with an external diameter of 12-14 mm with stainless steel rings soldered into it. Further development is aimed at using optically transparent polystyrene or ABS plastic as a material approved for use in medical instrumentation. In addition, tubes of the corresponding shape and diameter of fused silica glass were ordered for urethral and rectal probes.

The electronic part of the device, that is, the power supply and control unit can be performed both in a single housing with a block of emitters - a means of delivery of radiation, and a separate unit. At the same time, it can be connected to an alternating current network or it can be made autonomous with battery or battery power. Various elements can be built into the power supply — modulators, timers, and other circuits and controls for the magnitude of the voltage across the electrodes and radiating elements, the frequency of the sending pulses, synchronization with an external signal, etc. However, in all cases it is desirable to keep the device compact, and modern means microelectronics allow this.

The device operates as follows. After appropriate sterilization or disinfection, the hollow tube is put on the radiation delivery device and fixed. The outer surface of the tube, as a rule, is lubricated with special petroleum jelly or medicinal ointments before being introduced into the cavity. The device is turned on by plugging the power supply into a 220 V, 50 Hz power outlet and / or by turning on the power button of an autonomous source. In this case, the visible LEDs light up, and the device is ready for operation.

General principles for the use of a device for treatment.

Depending on the purpose, the device uses tubes of various diameters and lengths, as well as with a different arrangement of light-emitting windows. After turning on the device, the nozzle is inserted into the cavity (vagina, rectum, mouth, urethra, etc.) and kept there for a period of time in accordance with the doctor’s recommendations.

Due to the features of the device - the combination of various factors (the use of emitters with different wavelengths and electrical stimulation) and an increased density of radiation power due to the localization of the placement of emitters directly in the exposure zone - increases the therapeutic efficiency of the device.

This utility model is implemented in the form of experimental samples that were transferred to the medical co-executor - FDI of Balneology and Physiotherapy (Tomsk) for clinical testing and for developing treatment methods in the gynecology and andrology departments.

Sources of information used in compiling the description

1.V.E. Illarionov, Technique and methods of laser therapy procedures (Handbook), M., Laser Market, 1994.

2. Catalog of medical electronic devices, M., ed. AO Stars and C, 1994.

3.V.A. Builin, Pisco-intensive laser therapy of prostatitis. Information-methodical collection., M., Aspect-Press, 1995.

4.G.L.Shingarev, V.K. Martynov, Device for the light irradiation of biological objects. RF patent No. 2000129 Cl. A 61 N 5/06 dated 06/23/92.

5.V.V. Pekarsky, V.F. Agafonnikov, G.Ts. Dambaev, O.S. Popov, F.G. Martusevich, Autonomous electrical stimulators of the human and animal body., Tomsk, SSMU, 1995.

6. The author's certificate of the USSR Cl. A 61 N 1/36 N936931 dated 06/23/82 (V.V. Pekarsky, V.F. Agafonnikov, G. Ts. Dambaev, V.I. Kobozev, O.S. Popov)

7. The catalog of the company Postman, issue 2, autumn-winter 97/98, M.

8.E.A. Mishanin, V.P. Zharov, A method for the treatment of chronic prostatitis with impaired sexual function. RF patent No. 2022577 from 08/10/93. Cl. 5 A 61 N 5/06, 1/36.

9. V.P. Zharov, E. A. Mishanin, New advances in laser therapy: a combination with electrical stimulation for urology., Actual issues of laser medicine and operating endoscopy Materials of the 3rd International Conference, 1994, Moscow-Vidnoe, (prototype )

10.V. Zharov, E. Mishanin, N. Mishanin. Yarilo - help the urologist., Honey. newspaper No. 84 dated 10.28.94.

11. V.F. Agafonnikov, Electrical stimulator of the gastrointestinal tract .. RF Patent No. 2036671 Mcl. A61 N 1/375, dated 07/11/89, publ. 06/10/95

Authors: A.A. Vilisov .id4ii t; K5.A. Belyavsky

G.N. Zakharova

.Lavrenkov A.A. Ponomarev

Claims (8)

1. Device for electrophotostimulation containing a power supply, a hollow, at least in a separate section, a tube transparent to radiation with at least one electrode, radiating elements of the infrared and light range connected to the power supply, and a site for delivering radiation to the tube to the zone being processed pathology, characterized in that the said radiating elements are locally combined on the radiation delivery unit, which is equipped with contacts in the operational state connecting the said electrode and the power supply.  2. The device according to claim 1, characterized in that the said electrode on the tube is made in the form of a system of longitudinal or circular electrically conductive sections.  3. The device according to claims 1 and 2, characterized in that the hollow tube is made in the form of segments of glass and metal tubes fastened together.  4. The device according to claims 1 and 2, characterized in that the hollow tube is made of a transparent material such as plastic, for example polystyrene, polyvinyl chloride, etc., with fixed conductive sections in it.  5. The device according to claims 1 to 4, characterized in that the hollow tube in the pathology zone is made with a cross section in the form of a section of a radiation concentrator, for example, a Weierstrass sphere, and the outer surface of the tube is adequate to the surface of the pathology being processed.  6. The device according to claims 1 to 5, characterized in that one or more of the electrically conductive sections are easily replaceable and one or more layers or sections of friendly trace elements from the series are applied to them: zinc, copper, chromium, etc.  7. The device according to claims 1 to 6, characterized in that the radiation delivery unit is made in the form of a transparent rod, on the distal end of which radiating elements are placed, and in the working area there is a means for deflecting radiation in a given direction, for example, in the form of a mirror inclined , conical or other shape of the butt. 8. The device according to claims 1 to 6, characterized in that the radiation delivery unit is made in the form of a printed circuit board with radiating elements placed on it, the radiation indicatrix of which is directed towards the surface to be treated.