RU2492883C1 - Ultraviolet and infrared phototherapeutic apparatus - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: invention refers to medicine and medical equipment, particularly to ultraviolet and infrared phototherapeutic apparatuses. The apparatus comprises one or more actuating element consisting of a first emitter and a second IR emitter, an emitter actuation assembly as a part of first and second firing channels, and also an actuating element heat set assembly, a control unit and an apparatus actuation unit. The first emitter represents a gas-discharge mercury-filled lamp with a silica glass bulb attached in the centre of a lamp reflector made of oxide-coated aluminium. An inner surface of the bulb is coated with stabilisng ittrium oxide, while an outer surface is coated with titanium-silicone with a maximum UV-IR transmission of 280-315 nm and 1000 nm. Cesium salt is added to the dosed amount of mercury in the bulb. The second IR emitter is mounted additionally on the second lamp reflector which is arranged circumferentially in relation to the first lamp reflector with the first emitter and cooled by the heat set assembly between the lamp reflectors of the second and first emitters. A first firing electrode of the first emitter is connected through the first firing channel to a second active working electrode and through the IR emitter with a first input of the emitter actuation assembly. A second firing electrode of the first emitter is connected through the second firing channel to a first active working electrode and with a second input of the emitter actuation assembly. Outputs of the apparatus actuation unit are connected with inputs of the control unit. First and second inputs of the control unit are connected to the first and second inputs of the emitter actuation assembly respectively; third and fourth outputs of the control unit are connected to inputs of the heat set assembly respectively.

EFFECT: using the invention enables the stable and controlled therapeutic effect ensured by coupling the biologically active ultraviolet and infrared inputs.

2 cl, 2 dwg

Description

The invention is intended to compensate for ultraviolet insufficiency or solar starvation - a violation of the human body as a result of a prolonged absence or insufficient direct exposure to sunlight on the skin, as well as for therapeutic purposes in violation of metabolic, regulatory processes and a decrease in the protective functions of the body.

The use of the device is indicated for the prevention of rickets (vitamin D synthesis) for the prophylaxis and treatment of colds, viral and infectious diseases, diseases of the peripheral nervous system, joints and respiratory organs, treatment of skin diseases, provides a steady light tan and stimulates skin properties that are protective from exposure to sunlight.

The principle of the device’s operation is based on the effect of reproducing the basic spectrum of solar radiation necessary for humans - from the long-wave ultraviolet to the thermal infrared ranges.

The design feature is the maximum radiation effect in the biologically active range of UV-B and the exclusion of harmful effects leading to photoaging of the skin and carcinogenesis, components of ultraviolet radiation in the UV-A range.

The biological effect of the use of the device is determined by the accompanying infrared radiation, which provides the penetrating effect and biological effectiveness of ultraviolet radiation by the infrared stream in the near infrared region of 760-1500 nm with a maximum radiation in the frequency spectrum of 1000 nm.

Known devices based on the principles of irradiating a human body surface with radiation in the UV-A range (315-400 nm) with a maximum radiation of 340 nm maximum pigmentation using fluorescent UV-A lamps. The effect of the use of devices is mainly aimed at achieving the cosmetic effect of darkening of melanin (tanning), which leads to the rapid destruction of melanocytes, photoaging of the skin and carcinogenesis "General physiotherapy", M. Pravda, 1998, p.196, Bogolyubov V.M. and etc.

For example, professional and mini-tanning salons with low-pressure ultraviolet fluorescent lamps are known, tanning devices are equipped with safety filters, a timer is provided for emergency shutdown of the electronically controlled apparatus. The list of products of firms IONTO COMED (Germany), Dr. KERN (Germany) and PHILIPS (Holland), Official product catalogs of companies, as well as WWW. Mediaprofit.ru.

A disadvantage of the known solution is the lack of therapeutic and prophylactic effects, as well as the established suppression of immunity and allergic reactions associated with the rapid, subsequent after tanning, destruction of melanocytes.

The closest in technical essence is a device for ultraviolet-infrared phototherapy, patent for invention of the Russian Federation No. 2149660, 1998, containing the first and second radiation source, radiation source switching circuits, thermostabilization fan, device switching unit and control unit.

A disadvantage of the known solution is the lack of stable efficiency of light therapy, the lack of conjugation of biologically active ultraviolet and infrared radiation.

The objective of the invention is stable and manageable results of therapeutic effects due to the conjugation of biologically active flows of ultraviolet-infrared radiation.

The problem is solved by the device, characterized in that the ultraviolet-infrared light-curing device containing one or more actuators is included in the first radiation source, which is designed as a gas-discharge mercury lamp with a quartz glass bulb, and fixed in the center of the reflector made of oxidized aluminum and the second infrared radiation source, the inclusion of radiation sources in the first and second ignition circuit, the first ignition electrode of the first source and the radiation through the first ignition circuit is connected to the second active working electrode and through the infrared source to the first input of the radiation source switching unit, and the second ignition electrode of the first radiation source is connected through the second ignition circuit to the first active working electrode and to the second input of the radiation source switching unit , as well as thermostabilization unit of the executive body, the control unit, and the device switching unit, the outputs of which are connected to the inputs of the control unit, the first and second the control unit outputs are connected respectively to the first and second inputs of the radiation source switching unit, the third and fourth control unit outputs are connected respectively to the inputs of the thermal stabilization unit, characterized in that the second infrared radiation source is mounted on an additionally introduced second reflector, which are placed around the circumference of the first reflector with a first radiation source with the possibility of cooling from a thermal stabilization unit between the reflectors of the second and first radiation sources, at Ohm, a stabilizing coating of yttrium oxide was applied to the inner surface of the flask of the first radiation source, cesium salt was introduced to the dosed amount of mercury, and a silicon-titanium coating with a maximum transmission in the range of 280-315 nm and 1000 nm, ultraviolet radiation was applied to the outer surface of the flask infrared.

The control unit of the device contains a program unit for setting parameters, an inclusion unit, a first and second actuator key, the first and second inputs of which are connected to the inputs of the control unit and the first second inputs of the program unit for setting parameters, the control outputs of which through the unit are connected to the control inputs of the first and second executive keys. The outputs of the first executive key are connected respectively to the first and second outputs of the control unit, the third and fourth outputs of which are connected respectively to the outputs of the second executive key.

The device of FIG. 1, contains an executive body 1, one or several, A front view and B side view, as the next executive body, comprising the first 2 ultraviolet-infrared radiation sources, the second 3 infrared radiation sources, the first 4 and second 5 reflectors, and an inclusion unit 6 radiation sources with the first 7 and second 8 ignition circuit, as well as thermostabilization unit 9, the inclusion unit 10 and the control unit 11.

Figure 2 presents the unit 10 of the inclusion of the device and the control unit 11 containing the software node 12 for setting parameters, the node 13 enable, the first 14 and second 15 executive key.

The actuator 1 of the device of Fig. 1 is made of a decorative assembly, where the ultraviolet-infrared radiation source 2 is placed in the center of the infrared radiation source 3, made, for example, in the form of a ring, each of which is installed in its own reflector with an air cooling flow from the unit thermal stabilization between the reflectors of the first and second radiation sources.

The first reflector 4 is made of oxidized aluminum, which has a reflection coefficient of ultraviolet radiation, not worse than 75%. It should be borne in mind that other materials either have a negligible reflection coefficient or practically do not reflect ultraviolet radiation.

The first ultraviolet-infrared radiation source mounted in the center of the first reflector is designed as an arc gas discharge lamp with a quartz glass bulb. A stabilizing coating of yttrium oxide was applied to the inner surface of the lamp bulb, and cesium salt was added to the lamp bulb in addition to the dosed amount of mercury. A silicon-titanium coating is applied to the outer surface of the lamp, which provides maximum radiation transmission in the ultraviolet range of UV-B 280-315 nm and infrared spectral region 1000 nm. Such a solution provides ultraviolet-infrared radiation from a gas-discharge mercury lamp with a quartz glass bulb used in the irradiator in the necessary biologically active spectral regions of radiation from the point of view of the therapeutic effect.

So, the stabilizing coating of yttrium oxide deposited on the inner surface of the bulb crystallizes, and the formed crystalline coating of yttrium oxide during the deposition reaction forms a stabilizing layer that prevents cesium salt from reacting with quartz of the lamp bulb and ensures stable radiation over a specified range throughout the lamp life .

The introduction of cesium salt, provides maximum radiation and stable operation of the lamp in the ultraviolet range of 280-315 nm and additionally generates radiation in the near infrared region of 760-1500 nm with radiation maximums in the frequency spectrum of 1000 nm.

A silicon-titanium selective coating deposited on the surface of the quartz tube of the first radiation source, for example, with a solution consisting of the main components containing silicon-tetraethoxysilane and titanium-tetrabutoxytitanium, prevents ultraviolet radiation from the UV-C and UV-A ranges that are harmful to humans.

With simultaneous ultraviolet and infrared radiation, the short-wave radiation is superimposed on the long-wave radiation. Modulated by ultraviolet radiation, the infrared stream is a carrier of ultraviolet energy, ensuring its deep penetration into the subcutaneous layer, providing its energy interaction with biochemical processes, for example, the synthesis of provitamin D3.

The second infrared reflector is made of metal with a reflective surface, such as mirror stainless steel.

The second infrared radiation source, mounted around the circumference of the first reflector, is made in the form of a wide-range infrared radiation source, for example, with a heating element inside an annular quartz tube.

A wide-range infrared emitter prepares the patient’s body surface for a more complete and effective ultraviolet therapeutic effect on the carrier wave, radiation in the near infrared region of 760-1500 nm and above.

The infrared power must be at least 500 watts. For this, a radiation source, for example, a nichrome filament in the form of a spiral, is placed in an annular tube made of pearl quartz and filled with an inert gas, for example, argon.

The node 6 of the inclusion of radiation sources with the first 7 and second 8 ignition circuit is designed to start and ensure the operation of the first 2 source of ultraviolet-infrared radiation of the Executive body 1 and is in its composition. In this case, the ignition schemes can be made either in the form of a high-frequency converter or, in a more simplified version, as the ballast resistance of the power supply to provide a glow discharge of the ignition in the quartz radiation source between the ignition electrodes and the active working electrodes. Moreover, the power load of the first 2 sources of ultraviolet-infrared radiation is supplied through the first input of the inclusion unit 6 of the radiation sources and through the second 3 source of infrared radiation, which simultaneously functions as a current absorber, to the second active working electrode of the first 2 sources of ultraviolet-infrared radiation, and through the first 7 ignition circuit - to the first ignition electrode of the first 2 radiation source. Through the second input of node 6, the power load is supplied directly to the first active working electrode of the first 2 radiation source, and through the second ignition circuit 8 to the second ignition electrode of the first 2 ultraviolet-infrared radiation source. Thus, the optimal mode of inclusion and support of the discharge in mercury vapor and cesium salt of a gas-discharge mercury lamp with a quartz glass bulb of ultraviolet-infrared radiation is ensured. When the lamp is turned on, a glow discharge is formed between the ignition electrodes and the active working electrode, which heats up the active working electrode and due to the avalanche-like exit of electrons between the active working electrodes, an arc discharge is formed and the lamp ignites.

However, sequentially connected with the first 2 ultraviolet-infrared radiation source, the second 3 infrared radiation source ensures that the power load is maintained to the required level and the operation of the first 2 ultraviolet-infrared radiation source is stabilized. The first and second inputs of the inclusion unit 6 are connected to the first and second outputs of the control unit 11.

The thermal stabilization unit 9 is designed at the same time to separate the heat fluxes of the first 4 and second 5 reflectors, to cool the actuator 1, and to provide a stream of warm air from the actuator to the patient, which creates additional comfort during the phototherapy procedure.

At the same time, separate control of the inclusion and operation of radiation sources and the thermal stabilization unit ensures complete cooling of the executive body by the thermal stabilization unit 9 after switching off the radiation sources. Full cooling is ensured by the fact that the thermal stabilization unit turns off five minutes after the radiation sources are turned off, which is ensured by the parameter setting unit 12.

The control unit 11 is an adjustable timer with the ability to work in the delay on time, the specified operating time of the executive body and the sound signal of the delay period for turning on the device. Management of operating modes is carried out by the software node 12 for setting parameters of the control unit 11, which is a programmable standard processor. The software node 12 controls the inclusion node 13 and through the actuator key 14 and, respectively, the first and second outputs of the block 11 controls the inclusion of the radiation sources of the actuator 1, and through the second 15, the actuator key and the third and fourth outputs of the node 11 respectively controls the inclusion of thermostabilization node 9. In this case, through the first control output of the switching unit 13, the first and second radiation sources of the executive 1 organ are switched on with a delay of, for example, 30 seconds. At the same time, through the second control output of the switching unit 13, a switching signal is supplied to the control input of the second 15 actuating key to start the thermostabilization unit 9. Modes of operation are set depending on the number of sessions of light treatment exposure and special indications for their use. After the device is finished, first, the program unit for setting parameters 12 through the program unit 13 for turning on and, accordingly, through the first 14 executive key, the radiation sources of the executive 1 body are turned off and after five minutes the program unit 12 for setting parameters through the unit 13 turns off the second 15 executive key for the load of the unit 9 thermal stabilization. Such time is quite enough for complete cooling of radiation sources and reflectors of the executive 1 body.

Switching on the device is possible only after it is restarted by unit 10. At the same time, each switching on of the device is accompanied by a sound signal, a switching delay of 25-30 seconds, sufficient for the patient to prepare to receive a light treatment procedure. After completing the work cycle necessary for a specific session, the device turns off in the specified sequence.

The biological effect of ultraviolet radiation is due to its effect on the biochemical and energy processes of a living cell. Insufficiency of ultraviolet exposure leads to a violation of trophic, metabolic processes and a decrease in the protective functions of the body. So, radiation with a wavelength of 280-400 nm to a greater extent stimulates the production of antibodies, phagocytosis, and the accumulation of blood agglutinins. At the same time, 280-310 nm stimulates the synthesis of provitamin D3, 297-302 nm - erythema formation, 340 nm - pigmentation, which in this solution of the irradiator as a particularly harmful process of exposure is minimal.

Combined with ultraviolet, infrared radiation penetrates through the layers of the skin into the tissues located beneath it, expanding blood vessels, enhances blood supply and thereby enhances the therapeutic effect. Combined ultraviolet and infrared exposure also prevents the formation of a burn of the epidermis.

In the implementation technology of the present invention, it has been taken into account that individual regions of ultraviolet radiation have different effects on the physiological reactions of tissues and the body as a whole.

Darkening of melanin (a light, fast-passing tan) occurs under the influence of UV-A radiation after a few hours. Slow tanning (melanin synthesis and an increase in the number of melanosomes) develops after about three days and is caused by radiation in the UV-B range. This reduces the supply of ultraviolet radiation to the basal layer and melanocytes. Slow tan is more sustainable. There is also a proliferation of keratinocytes, which leads to a thickening of the stratum corneum, which ensures the dispersion and weakening of the perception of ultraviolet radiation (protection from solar radiation harmful to human ranges of UV radiation). These changes are adaptive in nature.

The ultraviolet radiation of the UV-A region does not cause sunburn and is considered safe. However, it is this region of ultraviolet radiation that is mainly responsible for the appearance of signs of photoaging of the skin, as well as for carcinogenesis, since it is the main factor in the cytotoxic effect of radiation in the basal layer of the epidermis due to the formation of free radicals and damage to DNA chains.

UV-A radiation does not give a thickening of the epidermis, the tan caused by it, although it seems attractive from a cosmetic point of view, is ineffective as protection against subsequent ultraviolet irradiation, in contrast to pigmentation caused by UV-B radiation. In addition, UV-A irradiation does not significantly increase the synthesis of melanin, tanning will be short-lived, and the absence of UV-B in the emission spectrum will not increase the synthesis of vitamin D. On the other hand, the damaging effect on the skin (photoaging, formation of free radicals) will not only persist, but, possibly, be enhanced, since determining the minimum energy exposure of ultraviolet radiation, causing noticeable erythema of previously unirradiated skin (Minimum erythema dose of MED) for UV-A is extremely complicated. Recent data also allow us to conclude that the suppressive effect of ultraviolet radiation on the UV-A region on immunity.

The presence of radiation in the "UV-C" range (up to 280 nm), which is not more than 5% of the radiation power of the entire "A + B + C" range, significantly increases the antimicrobial and antiviral effects and therapeutic effect. At the same time, the irradiation process becomes safer by reducing the fraction of radiation from the 340 nm spectrum of pigmentation (tanning), which creates only a cosmetic effect and is dangerous to health (provocation of neoplasms, photoaging of the skin).

The tests performed on the device showed extremely high therapeutic efficacy and the ultraviolet-infrared light therapy irradiator in various technical versions was approved by the Federal Service for Supervision of Health and Social Development and entered into the State Register of Medical Products and Medical Equipment of the Russian Federation as ultraviolet-infrared light-treating irradiators " SOLIS. "

Claims (2)

An ultraviolet-infrared light-treatment device containing one or more executive organs as part of a first radiation source made as a gas discharge mercury lamp with a quartz glass bulb and fixed in the center of a reflector made of oxidized aluminum and a second infrared radiation source, a radiation source inclusion unit in the composition of the first and second ignition circuit, the first ignition electrode of the first radiation source through the first ignition circuit is connected to the second active a working electrode and through an infrared radiation source with the first input of the radiation source inclusion unit, and the second ignition electrode of the first radiation source is connected through the second ignition circuit to the first active working electrode and the second input of the radiation source inclusion unit, as well as thermostabilization unit of the actuator, control unit and a unit for switching on the device, the outputs of which are connected to the inputs of the control unit, the first and second outputs of the control unit are connected respectively to the first and second by the odes of the radiation source switching unit, the third and fourth outputs of the control unit are connected respectively to the inputs of the thermal stabilization unit, characterized in that the second infrared radiation source is mounted on an additionally introduced second reflector, which are placed around the circumference of the first reflector with the first radiation source with the possibility of cooling from the thermal stabilization unit between the reflectors of the second and first radiation sources, while on the inner surface of the flask of the first radiation source is applied o stabilizing a coating of yttrium oxide, cesium salt is introduced into the flask at a metered amount of mercury, and a silicon-titanium coating with a maximum transmission in the range of 280-315 nm and 1000 nm of ultraviolet-infrared radiation is applied to the outer surface. 2. The device according to claim 1, where the control unit contains a program unit for setting parameters, an enabler, a first and second actuator key, the first and second inputs of which are connected to the inputs of the control unit and the first second inputs of the program unit for setting parameters, the control outputs of which through the node inclusions are connected to the control inputs of the first and second executive keys, the outputs of the first executive key are connected respectively to the first and second outputs of the control unit, the third and fourth outputs of which are connected Nena respectively to the outputs of the second actuator key.

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