RU2203112C2 - Method for complex photocorrection of weight - Google Patents

Abstract

FIELD: medicine and cosmetology, designed for control of fat in the organism. SUBSTANCE: the invention consists in combined therapeutic influence both directly on the fatty tissues and on the zones that are responsible for metabolism of fat in the organism. For direct influence it is offered to use separately or in different combinations luminous-induced photothermal, photoacoustic and photodynamic effects arising at a selective absorption by fat of radiation in absorption bands of near infra-red band of 900-2500 nm, including areas in region of 920, 1200, 1700 and 2300 nm. Depending on the effect and area of exposure, it is offered to use various sources of radiation: lamps with a light filter, super-luminous light-emitting diodes of lasers both separately and combined in matrices. The main operating conditions: continuous, continuous with a high-frequency modulation of intensity or impulsive, including the use of high-frequency bursts required for generation of ultra-sound vibrations. For a selective delivery of phosensitive-photophoresis, phonophoresis and electrophoresis. Fat removal is attained both due to its transformation in other compounds or by destruction by heat, oxidation, acoustic or ultra-sound vibrations, cavitation inclusive, and due to activation of natural physiological metabolic processes, thermohenesis inclusive. The latter is attained due to programmed temperature variation of the body in special zones. Provision is made for elements of mechanical and vacuum massage, for "drawing" of local zones from the common mass of the fat with a subsequent light irradiation. Offered is the minimum-invasive method based on introduction of thin needles with light-emitting diodes in the underskin fatty tissues. Control of selective action is effected with the aid of ultra-sound and magneto-resonance tomography. EFFECT: enhanced efficiency of regulation of human weight. 12 cl

Description

 The invention relates to medicine, in particular to physiotherapy and cosmetology, and relates to the therapeutic effect of light on various zones of the body, including effects on various physiological processes, including those responsible for regulating the weight of the body.

 The prior art.

 Known methods and devices for light therapeutic effects on various areas of the human body for the treatment of various pathologies [1]. Known therapeutic methods and devices use optical radiation sources, for example, in the form of lasers or LEDs, connected to power supplies [1, p. 70-82]. Sources of radiation, as a rule, are located in the end part of the remote nozzles or connected to optical fibers through which the radiation is directed to a biological object. The practice of using several lasers or narrow-band sources in the form of LEDs with radiation wavelengths lying in the spectral range from 0.25 μm to 3 μm. The radiation sources operate both continuously and pulsed in a wide range of frequencies and duty cycle. Such light sources are used for various medical and cosmetic purposes, including by activating various metabolic processes in the body [1].

 The disadvantage of such methods and devices with respect to the task of photo-correction of weight is the difficulty of simultaneously irradiating extended and separately located zones on the human body with light, for example, with an increased content of adipose tissue or zones responsible for the exchange of fat in the body. An example is the area of localization of the so-called brown adipose tissue, which is responsible for the process of thermogenesis, which consists in the generation of heat through the use of body fat reserves. Such zones are located in the area of the shoulder blades, spine, neck muscles, abdominals and kidneys. The greatest problems arise with the complex spatial geometry of such zones or with their location, for example, from different sides of the biological object, which is typical, in particular, when irradiating limbs or the whole body in the waist area. As a result, in an analogue, for irradiation of spatially extended zones, it is necessary to move the radiation source from one zone to another, which takes a lot of time and does not achieve the desired effect due to the irradiation of different zones at different points in time.

 A definite exception to these shortcomings, i.e. increasing the efficiency of irradiation of spatially extended zones of complex geometry, is achieved in the device described in patent 2145247 [2], which is taken as a prototype. This device is a matrix of many radiation sources placed on a substrate with a shape of the working surface similar to the shape of a spatially extended pathological zone. It is proposed to use various sources as radiation sources, including lamps with light filters, lasers, and arrays of superbright LEDs.

 However, this invention does not fully satisfy the task of photoregulation of weight. Only the device is stated in it and therefore there is no description of the method of application for photo-regulation of weight. There are also no recommendations and criteria for choosing the parameters of radiation sources that satisfy the task. The disadvantage of the prototype is the difficulty of selective irradiation of several separately located extended zones associated with areas of high fat content, since only one substrate with sources of complex geometry is claimed. Using one large matrix for this can lead to undesirable irradiation of tissues with a normal fat content, which can increase the overall burden on the body, reduce the overall positive effect and lead to undesirable side effects, for example, in the form of a general increase in temperature and increased microcirculation throughout the body.

 The aim of the present invention is to remedy these shortcomings, that is, the implementation of a method that allows for effective regulation of patient weight.

 This goal is achieved by exposing the body to radiation in the optical range from X-ray to radio wave, both coherent and incoherent using natural or artificial radiation sources. The impact is directed to spatially extended zones of the body, having a high content of adipose tissue and / or functionally associated with the system of regulation of fat in the body. Spectral parameters of exposure are selected in the field of relative transparency of the skin and relatively large absorption by fatty tissues. The requirements are met by the near infrared range of about 700-1100 nm, where the depth of light penetration deep into the biological tissue reaches 10-25 mm, and at the same time, fat absorption bands appear starting from wavelengths of 870-900 nm and higher, including a band near 920 nm . The optical effect provides, due to one or several photochemical, photothermal, photoacoustic and photodynamic effects, the conversion of fat into other biochemical compounds that are easily excreted from the body in one way or another. These effects can also lead to inactivation of the processes responsible for the feeling of hunger. Another consequence of optical exposure is the activation of the processes responsible for the feeling of satiety. And finally, optical inactivation of the processes of fat absorption in the stomach during direct digestion of food entering the body is possible.

One of the proposed methods is to use infrared radiation to heat adipose tissue simultaneously over its entire area with simultaneous cooling of the skin over the entire area of exposure. Short-term cooling is also foreseen until low cryotemperatures are reached using the appropriate cryogenic technique. A preliminary mode of cooling the surface of the body in places of accumulation of adipose tissue or over the entire surface to a temperature that activates the processes of thermogenesis, that is, to temperatures in the range of 5-15 ^o C.

 It is proposed to use the photodynamic effect by introducing one or more photosensitizers into the body, including as food additives. Various routes of administration are proposed: intravenous, or local transcutaneous, or parenteral. In the latter case, the photosensitizer is introduced into the body both separately and as part of various foods of artificial, or plant, or animal origin. The choice of photosensitizer is due to its ability to selectively accumulate in adipose tissue. After achieving this effect, which takes a certain time, the adipose tissue is irradiated with optical radiation with a wavelength that matches the absorption band of the photosensitizer used. The subsequent photodynamic effect provides oxidative processes that contribute to the chemical transformation of fat cells.

 With local administration, the diffusion of the photosensitizer into adipose tissue can be accelerated by the methods of phonophoresis, iontophoresis, electrophoresis, photophoresis of photoacoustic effects, or various combinations thereof. Additionally, various ointments, drug solutions or other biologically active substances (BAS) can also be introduced, which also contribute to the removal of fat, including due to its additional heating.

 It is proposed to choose radiation parameters in such a way as to ensure the activation of biologically active substances (BAS), which are responsible for the metabolism of fat, in particular leptin, as well as serotonin, which is responsible for the feeling of satiety. The latter is achieved on the basis of photochemical photoinactivation of enzymes that inhibit tryptophan biosynthesis, from which marked BAS are formed.

 Optical exposure may include, in various combinations, cutaneous, intravenous or extracorporeal irradiation of blood or its individual components, which inhibits the production of biochemical products responsible for hunger.

 Adipose tissue is irradiated by a minimally invasive method by introducing thin needles into the fat accumulations with optical fiber inside or by squeezing the optical tip.

 The impact can be directed to the brain in the hypothalamic region in order to block the formation of biosignals that form a feeling of hunger. Radiation can also be directed to the retina to form signals in the brain that block hunger.

 In addition, it is proposed to carry out a combined effect on a biological object simultaneously with several physical factors applied in places of fat accumulation in the form of optical radiation with different wavelengths, including a combination of infrared and red spectral radiation, ultrasound, electrical stimulation, temperature and pressure. The fat area is also covered by an elastic pad at least partially transmitting the radiation used. It performs the functions of a mechanical factor, including in combination with its heating or cooling. The action of various factors is carried out sequentially in time one after another or simultaneously in time. A time delay of the action of various factors relative to each other, which is determined by the maximum achieved effect of fat removal, is also provided. Radiation is directed to the stomach and duodenum both transdermally and endoscopically, including the use of an autonomous capsule swallowed before meals with optical sources to activate the production of various biologically active substances in the stomach, including cholecystokinin, which carry information about satiety in the brain. Another effect is the inactivation of the lipase enzyme responsible for the breakdown of fats.

 One of the mechanisms of optical action is the selective effect on mitochondrial energy targets in order to accelerate the oxidation of fatty acids. Another area of optical exposure is the area of brown adipose tissue between the shoulder blades, along the spine, neck muscles, abdominals and the surface of the body in the region of the kidneys. The purpose of this effect is to activate the processes of thermogenesis. A combination of optical exposure and vacuum therapy is also proposed to enhance blood flow followed by exposure to blood light. One option for combined exposure is to use optical radiation in conjunction with drugs or chemicals. Optical effects on the body are carried out in some cases before the introduction of drugs into it or on the drugs themselves, respectively, before their introduction. In other cases, this is carried out after the introduction of these drugs into the body. The time delay between the irradiation of the drug before it is introduced into the body or the introduction of the drug and the subsequent irradiation of the biological object is determined by the maximum achievement of the positive effect of removing fat.

 This method uses optical exposure sources connected to respective power supplies and control units. Sources are fixed in space in such a way as to provide irradiation of spatially extended zones of the body having a high content of adipose tissue and / or functionally associated with the system of regulation of fat in the body. The parameters of the sources are selected in such a way as to provide optically induced conversion of fat into other biochemical compounds excreted from the body, and / or inactivation of the processes responsible for the feeling of hunger, and / or activation of the processes responsible for the feeling of satiety, and / or inactivation of the processes of fat absorption in the stomach during digestion of food entering the body.

 As sources, a matrix of powerful infrared sources in the form of lasers or superbright LEDs is used, and between these sources and the surface of the irradiated skin, a matrix of optically transparent skin-cooling devices in contact with the skin is introduced. As cooling devices, Peltier elements are used, combined with optical plates that are pressed against the skin, or plates in the channels in which the coolant circulates.

 Additionally, various physiotherapeutic methods and corresponding modules are introduced to provide vibration and / or electrical stimulation and / or ultrasound. The use of optical sources with different wavelengths, including infrared and red spectral ranges, is simultaneously envisaged to accelerate general metabolic processes and thermogenesis processes. You can also use modules that provide temperature changes. Another solution is to cover body fat with an elastic pad that at least partially transmits the radiation used. The listed modules can operate individually or in various combinations, and the action of the individual modules is carried out sequentially in time one after another, or simultaneously in time, or with a time delay relative to each other, determined by the maximum effect of fat removal.

 Optical tips and / or thin needles with optical fiber inside are also inserted, which are compressed or inserted in the area of fat accumulation. Ultrasonic vibrations can also be superimposed on these elements.

 It is proposed to use a matrix of optical sources covering areas around the head, including the frontal and temporal zones. Radiation from them is sent to the brain in the hypothalamic region in order to block the formation of biosignals that form a feeling of hunger.

 The matrix of radiation sources is built into the spectacle frame and / or superimposed on the glasses of these glasses. In this case, the wavelengths are selected in such a way as to stimulate the formation of signals in the brain that block the feeling of hunger in the retina through the mechanism of vision.

 The matrix of radiation sources can be fixed in the abdomen or duodenum to activate the production of cholecystokinin in the stomach, which carries information about satiety in the brain, or inactivate the enzymes responsible for digesting food.

 Additionally, the vacuum therapy method is used in the form of an optically transparent cap connected to a local decompression system with optical sources docked to the external surface. Such a module is applied in the area of accumulation of fatty deposits.

 Additionally, a mechanical massage method is introduced in the form of a couch with a varying angle of inclination, consisting of two frames. One of them is external, motionless, on which the patient is placed. Another internal with rotating rollers on several axes located parallel to the surface of the frames. It is driven in reciprocating motion relative to the outer frame. On top of the couch is a matrix of radiation sources in the form of a half cylinder resting on the base of the couch, with the sources placed on the inner surface of the cylinder facing the patient.

 It is proposed the introduction of a mechanical massage method, implemented using rollers in a combination of a decompression device, which ensures the extraction of fat and radiation sources, which provide optical irradiation of the thus thinner layer of fat.

 In another embodiment, radiation sources are built into various everyday objects of a person, including clothes in contact with the surface of a person’s body, pillows, mattress, blanket, bathroom walls, elements of chairs, seats in cars, trains, etc.

 One of the modifications of the method is its implementation with the help of a blanket and a mattress, in which infrared radiation sources are simultaneously built-in to heat fat deposits and cooling elements in contact with the body surface. At the same time, part of the surface of the mattress is optically transparent, and cooling is carried out by both Peltier elements and running cold water.

 Thanks to the listed features, the proposed method compares favorably with all known methods and devices. One of the distinguishing features is the optical effect simultaneously on all spatially extended areas of high fat content, which has not been achieved before. The advantage of the invention is the complex nature of the optical exposure using various mechanisms to remove excess fat.

One of the main effects is thermal exposure using infrared radiation sources that heat the adipose tissue to temperatures at which photothermal conversion of fat into soluble compounds that are easily eliminated from the body occurs. The required temperature ranges from 40 to 80 ^o C. At relatively low temperatures, there is an increase in the metabolism of fat metabolism, an increase in blood circulation, lymph microcirculation, acceleration of energy processes in mitochondria, requiring the use of fat reserves to generate additional energy. At higher temperatures, phase transitions and denaturation occur, the result of which is as if thermal melting with transition to other compounds (laser thermal liposuction). Further removal of these compounds can occur naturally, including due to the work of the immune system, and artificially using various suction devices, such as those used in liposuction. The radiation wavelength is selected in the range of transparency of the skin and the presence of absorption bands of adipose tissue, that is, approximately in the range of 900-1100 nm. The radiation intensity on the skin surface is selected in the range of 0.1-100 W / cm ² . The corresponding exposure time ranges from tenths of a second to several tens of minutes. The number of sources is selected based on the size of the irradiated area with excess fat reserves. As radiation sources, powerful lamps, arrays of superbright LEDs or semiconductor lasers can be used. The supply of radiation to the skin can be both with the help of many optical fibers, and with the direct location of miniature sources near the irradiated surface. The operating mode is both continuous and pulsed with a repetition rate of individual pulses. To eliminate unwanted radiation overheating of the skin surface, it is proposed to cool it using various systems, including air cooling, including forced cooling using several miniature fans, using running water flowing through tubes and channels transparent to radiation. The most radical solution is the use of cooled optically transparent plates pressed to the skin surface. Cooling in them can be using Peltier elements or a special flowing cooling fluid, for example, using freons.

 A distinctive feature of the proposed cooling systems is their placement over the entire irradiated surface, while in known systems exclusively local cooling is performed, for example, by laser hair removal or coagulation of vascular pathologies.

The present invention also provides a combination of optical exposure with other physiotherapeutic methods, of which one of the main is the change in body surface temperature in the area of high fat content. In particular, it is proposed to carry out surface cooling in places where the so-called brown or brown adipose tissue lies (the surface of the back in the area of the shoulder blades and spine, the neck, abdominal surface, etc.). According to recent discoveries, it is this tissue that is the zone of active metabolism, primarily in cases where the body needs to generate heat. The huge role of this tissue in animals hibernating during cooling (thermogenesis without chills) and in people who, despite consuming large amounts of food, do not grow stout. On the other hand, in people with obesity, brown adipose tissue is slightly or little active in the processing of fat. The idea of the invention is to activate the metabolism of this tissue using physical methods, in particular light. In addition to the action of light, as indicated above, the skin is cooled to temperatures below 15 ^o C, at which thermal receptors give signals to enable the thermogenesis system. The combination of thermogenesis activation by cooling the skin with simultaneous heating of adipose tissue, located at a depth of 3-10 mm, allows to obtain a synergistic effect.

 The idea of concomitant methods is the light activation of the production of biologically active substances, indicating a feeling of satiety and pleasure from eating. That is, figuratively speaking, instead of eating, it is proposed to “feed” a person with light, which will dull an acute hunger. One of these substances is serotonin, which is low in obesity, depression, and insomnia and other functional disorders. With a large consumption of carbohydrates, increased production of insulin begins, which in turn contributes to the production of tryptophan, which enters the brain and activates the production of serotonin, giving a feeling of pleasure from eating. In the absence of food, the concentration of serotonin decreases. Thus, an addiction to food is formed, similar to the action of drugs, leading to overeating. To eliminate this dependence, it is proposed to irradiate a person with light both cutaneously in the places of blood vessels accumulation, as well as by acting on the retina with the help of special glasses with built-in miniature radiation sources. One of the most radical regimes is extracorporeal blood irradiation. One of the mechanisms of photoactivation of serotonin production is the known properties of light by suppressing enzymes that inhibit the formation of tryptophan, from which serotonin is formed. In the blood under the action of light, corresponding mediators are formed, contributing to the manifestation of these effects. Further, photochemical products, including after dark reactions, are transferred to the brain. The technical implementation of this idea consists in the use of light light arrays, consisting of many LEDs, mounted on the surface of the body in the area of blood vessel congestion, in particular around the wrist and glasses built into the frame. To exclude frequent irritation of the retina by visible radiation in the latter case, it is proposed to use near infrared radiation, which provides an equally significant biological effect due to absorption by the main blood components, in particular hemoglobin, while the visual effect is practically not formed.

 In addition to the photothermal effect, the present invention proposes to use the accompanying photoacoustic effect, which consists in the formation of acoustic waves during thermal expansion of laser-heated tissues.

 This effect is especially pronounced with pulsed laser irradiation or with a high repetition rate of laser pulses. In fact, this is an analogue of ultrasonic exposure, but the advantage of the proposed method is the distance of exposure, that is, the absence of mechanical contact with the surface of the body and the possibility of flexible changes in exposure parameters. The action of the photoacoustic effect is the thermo-photoacoustic massage of adipose tissues.

 One of the key points in optical exposure is to ensure the selectivity of radiation absorption in adipose tissue in the absence of absorption in the surrounding biomedium. In part, these requirements, as noted above, are satisfied by the near-IR range. To increase the selectivity, it is proposed to additionally use various absorbing additives introduced in one way or another into adipose tissue. You can enter them due to transcutaneous impregnation, enhanced by the phenomena of phonophoresis, electrophoresis or photoacoustic effects. Another method is to inject these substances into the fat layer using various minimally invasive agents, including a matrix of thin needles. A wide variety of substances can be injected in this way, including photosensitizers.

 One of the key ways to remove excess fat is to use the photodynamic effect, which has already found effective use in oncology and in the treatment of dermatological and infectious diseases. The present invention proposes a new application of this effect for the photodynamic conversion of adipose tissues by enhancing the oxidative processes accompanying the interaction of radiation with photosensitizers accumulated in these tissues.

 In addition to the local truncated administration of photosensitizers, the present invention proposes it to be administered as a food supplement or as an additive to ordinary food.

 In general, the photodynamic method of weight correction consists in the introduction of a photosensitizer and after a temporary pause, determined by the time of its selective accumulation in adipose tissue, by irradiating this tissue with radiation of the corresponding wavelength. Irradiation can be carried out using conventional lamps with light filters, as well as an array of lasers or superbright LEDs. In the latter case, the matrix is fixed on the body and worn by the patient for some time, sufficient for the manifestation of the photodynamic effect. The power supply can be either using wires or autonomous. From the point of view of economical energy consumption of autonomous batteries, their prolonged use is possible together with relatively low-intensity LEDs. One of the technical solutions is to use a blanket or mattress with built-in radiation sources.

 As a result, weight loss can occur during the patient’s sleep. Thus, the present invention involves its use at home, as well as at work, while traveling, etc.

 One suggested effect is to use light to reduce hunger. One of the ways to implement this idea is to irradiate the brain in order to block signals that carry information about hunger. To do this, it is proposed to use an optical matrix worn on the head (optical cap). Another solution is transdermal irradiation with an optical matrix of the stomach and duodenum to block signals from the stomach to the brain about hunger. It is also possible to swallow a miniature ellipsoid capsule with optical sources inside and self-powered before eating. As it naturally moves through the stomach and duodenum, optical radiation due to photochemical effects will inhibit the formation of the corresponding nerve signals from the stomach. The action of radiation can also be carried out during meals in order to inhibit the absorption of fats from food entering the stomach. Blood irradiation in various ways, including percutaneous and extracorporeal, also serves the same purposes.

 One of the additional methods to the optical effect is mechanical massage. Its main task is to accelerate the metabolism of fat metabolism.

 An additional function is to stretch the skin with excess fat so that this part can be illuminated by radiation from two sides while cooling the surface of the skin. It is also assumed that ultrasound will additionally affect this area of the skin from two sides using, for example, piezo-nozzles.

 The most simple and economical massage option is to use several spherical tips, at least three, located in the same plane and fastened together by a rigid mechanical connection. These tips can be made of any material, but plastics are preferred. Massage by circular motions in the area of fat accumulation can be carried out manually, for example, using the fourth tip, and all four tips are spatially oriented in the form of a tetrahedron. For better movement on the surface of the body, it is recommended to use a thin elastic pad or any fabric material that transmits optical radiation. Optical radiation can be supplied either by independent sources or directly integrated into said nozzles. It is possible to combine such nozzles with various types of vibrators.

 The most radical solution is to use a special couch with a reciprocating movement and a varying angle of inclination for mechanical massage. In its middle part rotating rollers are placed. When fixing the patient in a large external frame, he is periodically exposed to periodically moving rollers. Light irradiation can be carried out both with the help of a flat matrix of sources placed in the space under the rollers, and with the help of a matrix in the form of a half cylinder resting on the couch with its base so that the cylindrical part covers the patient from above.

 Monitoring the patient's weight can be carried out by standard methods, including weighing and measuring body sizes around the circumference in various directions. It is possible to use a special bath with water to measure the volume of individual parts of the body, including the volume of the whole body by measuring the displacement of water when these parts are placed in it. Another solution is to use ultrasound diagnostics. However, from the point of view of implementing interactive control during photo-correction of weight, it is proposed to use magnetic resonance imaging, which allows visualizing the structure and places of fat accumulation with high spatial resolution. A very important advantage of this method is the ability to control the conversion of fat to other compounds, including the boundaries of optical exposure. On the tomographic image, the places of the optical or combined treatment of adipose tissue will look lighter or, on the contrary, darker in accordance with the program compared to unirradiated tissue. These diagnostic tools essentially play the role of feedback, allow you to adjust the exposure during the complex weight correction.

 Thus, in general, the main advantage of the invention is the possibility of complex and selective photocorrection of weight by simultaneously combining exposure to any extended zones of the body, both directly associated with an increased concentration of fat, and with zones associated with increased metabolism and physiological processes responsible for metabolism fats in the body with simultaneous interactive exposure control using various diagnostic methods with an emphasis on the magnetic method th resonance imaging. None of the known inventions has previously achieved this.

 As a result of introducing various channels of exposure and clarifying specific mechanisms of complex photocorrection of weight, this invention for the first time made it possible to quantify radiation parameters, including energy doses, wavelengths and their dependence on the area and number of irradiated zones, to compare the irradiation efficiency of different zones at different wavelengths and exposure modes (continuous and pulsed) at various frequencies of modulation and duty cycle and a combination of various physical factors. Particularly promising is the determination of the effectiveness of the proposed various combinations of light with ultrasound, temperature and other factors of physical impact, as well as with various drugs and photosensitizers. These methods can advantageously complement each other and in combination provide a significant synergistic effect.

 Examples of specific implementations of the method.

 Example 1 (Best option). Method and corresponding device for photothermal treatment of fat deposits. The device consists of separate optical modules, each of which has a rectangular shape with dimensions of 20 x 50 mm. On this area is a matrix of diode lasers in an amount of 40 pieces, each of them with a power of 0.5 watts. Together, these lasers provide a total power of 20 watts. The entire surface of the matrix facing the skin is made of an optical material, for example sapphire, which is cooled using Peltier elements docked to it. The device is equipped with feedback sensors that allow you to control the temperature both in the area of contact of the matrix with the skin, and the temperature of the adipose tissue heated by radiation. In the latter case, radiation thermometers are used that record thermal radiation both in the near infrared region, about 0.7-1.2 microns, and in the radio range, where biological tissues are more optically transparent to radiation. The power of the matrix can be increased due to the more frequent placement of laser diodes up to a power of several hundred and even thousands of watts. In this case, a quasi-pulse mode of operation is recommended by briefly irradiating the fat from fractions of a millisecond to fractions of a second. When using relatively powerful sources, this cooling system has a double role: it cools both the skin and the sources themselves.

 Example 2. Method and device for photodynamic treatment of body fat. A flat photomatrix on a flexible substrate is used as a radiation source. As the radiation sources, red LEDs with a wavelength of 660 nm and a power of 10 mW each are used. The area of the rectangular photomatrix is 50 x 150 mm, the total number of sources is 675. Type of photosensitizer, aluminum phthalocyanine, method of administration: local by phonophoresis, as well as by subcutaneous injection using a syringe. The photocorrection technique consists in introducing a photosensitizer followed by attaching the matrix to the body at the injection sites.

 The exposure time is 15-30 minutes. When using less powerful sources, the exposure time increases to several hours. In the first case, power is supplied using a conventional network and power is supplied via wires. In the second case, the battery is autonomous.

 Example 3. Method and device for photocorrection of weight by accelerating natural physiological processes. Optical sources of the near infrared range in the form of LEDs are built into the mattress, the upper part of which is made of optically transparent material, for example, in the form of a mesh or plastic. Cooling elements in the form of channels with running water or Peltier elements are built into this part.

According to the program, during sleep, the indicated part of the mattress is cooled to temperatures at which the activation of the thermogenesis process begins with the help of signals from the skin's thermal sensors. The temperature range ranges from 10-15 ^o C and even slightly lower. At the same time, the radiation of infrared sources activates the energy processes of metabolism in the mitochondria, provides a balance of temperatures in the fat layer and a sense of thermal comfort. The duration of one session is 5 hours, the number of sessions is from 20 to 40.

 In essence, this method partially models the conditions of hibernation of animals and especially the process of awakening from hibernation, which is accompanied by a sharp increase in the processes of thermogenesis and the conversion of fat reserves into thermal energy. A similar system can also be implemented in the form of a belt around the abdomen with built-in optical sources and a cooling system based on Peltier elements.

 A modification of the method considered can be the placement of miniature sources in other pastel accessories, including a blanket, sheets and pillows.

 One of the known facts of the influence of light on physiological processes is the regulation by light of the formation of melatonin, which affects sleep. In particular, with the onset of darkness, light inhibition of the formation of melatonin ceases, its concentration begins to increase and block the nerve channels, as a result of which a person falls asleep. However, a high concentration contributes to the formation of adipose tissue. In accordance with these effects, it is advisable to reduce the concentration of melanin during sleep. For this, it is proposed to use LEDs in the visible range, including those that form a white color close to daylight.

 One of the established channels of exposure to light on the content of melatonin is the retina. Recently it has been established that the effect is also due to the transdermal effect on the blood in peripheral vessels. This makes it possible to influence the content of melatonin during sleep by irradiating the body with the help of optical sources built into the mattress and / or blanket and, accordingly, to prevent nightly fat formation. A side positive effect is the elimination of the so-called winter depression of the northern peoples due to the lack of sufficient lighting in the winter-fall period. Currently, the solution to the latter problem is achieved through the use of fluorescent lamps. The decision to irradiate the body during sleep is more optimal and does not require loss of working time.

 It is important to note once again that a unique feature of the invention is the combination of effects, when individual factors, both individually and especially in combination, allow you to activate the natural physiological processes of accelerated processing of fat reserves.

 Intermediate technical solutions can be irradiation of exposed body surfaces, including the face and eyes throughout the day by using a matrix of infrared LEDs installed on the TV, on the desktop, in the kitchen and in other places of frequent human presence.

 A very significant addition is the regulation of body temperature, especially in places of localization of brown adipose tissue. To enable the mechanism of thermogenesis, you can use the cooling of the surface of the head and the respiratory system, where there are also many cold sensors.

 A similar effect in lowering the fat content can be achieved by a change in temperature that is opposite in sign, that is, by a general increase in temperature, approaching a state of hyperthermia, when a lot of internal energy is required to exclude overheating of the body due to increased blood circulation and other known physiological reactions. For heating, you can also use in this case a matrix of infrared radiation sources.

 Irradiation in the described invention can also be implemented on a modular principle using separate rectangular flat segments with dimensions, for example, 15x60 mm with different sources of parameters. For uniform coverage of the hand in the wrist area, a section comprising about 9-12 such segments connected by a flexible connection is necessary. One such section can be used to irradiate blood, the other to irradiate body fat. In the case of larger areas, up to 4-5 of these sections can be used. Within one segment, it is possible to place up to 10 LEDs in two rows of 5 LEDs in each row.

 Photomatrix for irradiation of local fat deposits. The shape of the flexible matrix irradiator is close to a plane with a radius of 30 mm. The wavelength of the red LEDs is 0.63 microns and infrared 0.85 microns. The radiation power is about 10 mW at a wavelength of 0.63 microns and 0.3 W at a wavelength of 0.85 microns. The number of LEDs is 88. The irradiator on the surface of the body is fixed due to medical adhesive tape or patch. Battery powered. There can be several such irradiators for simultaneous irradiation of several zones located in different parts of the body. One session of light therapy lasts 15 minutes. A total of six sessions in one week.

In general, practically many sources already used in phototherapy can be used as a radiation source in the present invention, for example, various types of lasers, incandescent lamps with light filters, gas-discharge and fluorescent lamps (neon, xenon, mercury, etc.), etc. In the latter case, it is advisable to minimize the size of the gas discharge elements. In the case of irradiation of a biological object in a form close to cylindrical, for example, limbs, gas-discharge flasks can be made in the form of thin cylinders evenly spaced around the limbs with axes parallel to the averaged axis of the limb. The mirror surface of the substrate may span these sources, i.e. the design of the irradiator is similar to the design of pump sources in laser systems, except that a limb is placed in the region where the active element was located. Depending on the medical task, the sources can operate in various modes in the spectral ranges mainly from 0.2 to 3 μm with varying degrees of monochromaticity from 10 ^-3 to 10 ³ nm.

Literature
1. V.E. Illarionov. The basics of laser therapy. M .: Respect, 1992, p. 26, 31, 71-80.

 2. V.P. Zharov. RF patent 2145247 "Photomatrix therapeutic device for the treatment of extended pathologies" with a priority of 04/10/1998, published in the Bulletin of inventions 4, 2000.

Claims (12)

 1. The method of complex photocorrection of weight by exposing the body to radiation in the optical range, coherent or incoherent, using natural or artificial sources of radiation, characterized in that the effect is directed to spatially extended zones of the body containing an increased content of adipose tissue and / or functionally associated with system of regulation of fat in the body, and the spectral parameters of exposure are chosen in the field of relative transparency of the skin and relatively large absorbed fat, provide optically induced due to one or several photochemical, photothermal, photoacoustic and photodynamic effects, the conversion of fat into other biochemical compounds removed from the body and / or inactivation of the processes responsible for hunger and / or activation of the processes responsible for a feeling of satiety, and / or inactivation of the processes of absorption of fat in the stomach during digestion of food entering the body.  2. The method according to claim 1, characterized in that the use of infrared radiation to heat adipose tissue simultaneously over the entire area of its occurrence while cooling the skin over the entire exposure area up to cryo temperatures, and there is a mode of preliminary artificial cooling of the body surface in places of accumulation of fat tissue or over the entire surface to a temperature that activates the processes of thermogenesis.  3. The method according to p. 1, characterized in that the photodynamic effect is provided by intravenous or local transcutaneous or parenteral administration of one or more photosensitizers selectively accumulated in adipose tissue into the body, including as a food additive, either separately or as part of various food products of artificial and / or vegetable and / or animal origin, followed by irradiation of fatty tissues with optical radiation with a wavelength matching the absorption band the photosensitizer used, and the time delay relative to the time of administration, determined by the time of selective accumulation of the photosensitizer in body fat.  4. The method according to claim 3, characterized in that when the photosensitizer is introduced locally into the adipose tissue or when ointments or a solution of drugs or biologically active substances are added additionally to further heat the fat deposits, their diffusion is accelerated by using the methods of phonophoresis, iontophoresis, electrophoresis, photophoresis , photoacoustic effects or their various combinations.  5. The method according to p. 1, characterized in that the radiation parameters are selected in such a way as to ensure the activation of biologically active substances, including serotonin, responsible for the feeling of satiety, due to the photochemical photoinactivation of enzymes that inhibit the tryptophan biosynthesis, from which biologically marked active substances.  6. The method according to claim 1, characterized in that the effect includes, in various combinations, cutaneous, intravenous or extracorporeal irradiation of blood or its individual components, which inhibits the production of biochemical products responsible for hunger.  7. The method according to p. 1, characterized in that the exposure of the adipose tissue by irradiation is carried out in a minimally invasive way, by introducing ultrafine needles with optical fiber inside the fat accumulations or by compressing the optical tips.  8. The method according to claim 1, characterized in that the radiation is directed to the brain in the hypothalamic region, and / or to the retina of the eye to form signals in the brain that block the feeling of hunger.  9. The method according to claim 1, characterized in that it additionally carries out a combined effect on the biological object simultaneously by several physical factors superimposed in the places of accumulation of fat in the form of optical radiation with different wavelengths, including a combination of radiation from the infrared and red spectral ranges and / or ultrasound, and / or vibration, and / or electrical stimulation, and / or temperature, and / or pressure, and / or a combination with vacuum therapy to enhance blood flow followed by exposure to blood light, and / or fat covered by an elastic pad, at least partially transmitting the radiation used, and the action of various factors is carried out sequentially in time one after another and / or simultaneously in time, and / or with a time delay relative to each other, determined by the maximum achieved effect of removing fat.  10. The method according to claim 1, characterized in that the radiation is directed to the region of the stomach and duodenum to activate the production of cholecystokinin in the stomach, which carries information to the brain about satiety and / or inactivation of the lipase enzyme responsible for the breakdown of fats.  11. The method according to p. 1, characterized in that the radiation selectively affects the mitochondria and the area of brown adipose tissue between the shoulder blades, along the spine, neck muscles, abdominal press and body surface in the region of the kidneys to activate the processes of thermogenesis.  12. The method according to claim 1, characterized in that they additionally use the combined effect of optical radiation and drugs and / or chemical preparations, the optical effect is carried out on the biological object before and / or after the introduction of drugs, and / or on the drugs themselves, respectively, until their introduction, and / or after introduction into the biological object, and the time delay between irradiation of the drug before its introduction into the biological object and / or the introduction of the drug and subsequent irradiation of the biological object is determined by the maximum achievement of positive ffekta fat removal.