BR102016019963A2 - LATEX MANUFACTURED MICROPHERATED STICKER ASSOCIATED WITH LED TYPE LIGHT SOURCES FOR DIRECT APPLICATION IN INTERNAL AND EXTERNAL HUMAN INFLAMMATORY PROCESSES - Google Patents

Abstract

The present invention deals with a microperforated adhesive that adheres to the portion of the human skin that exhibits inflammatory processes and, by means of LED-type light sources, installed in electronic circuits, emits different wavelengths that have effects on the healing of this area. . The adhesive is composed of overlapping layers, being a microperforated lower membrane, which has the adhesive edges to be fixed around the application region, two printed circuit boards and an upper membrane, which is installed over the circuits. The device is suitable for any part of the human skin and can be used to treat inflammation of the necrotic, parenchymal, erythematous, hyperplastic or hypertrophic, allergic and burn types.

Description

(54) Title: MICROPERFURED ADHESIVE MADE IN LATEX, ASSOCIATED WITH LED TYPE OF LIGHT SOURCES FOR DIRECT APPLICATION IN INTERNAL AND EXTERNAL HUMAN INFLAMMATORY PROCESSES (51) Int. Cl .: A61N 5/06; A61K 50/00 (73) Holder (s): UNIVERSIDADE DE BRASILIA FOUNDATION / TECHNOLOGICAL DEVELOPMENT SUPPORT CENTER (72) Inventor (s): SUÉLIA DE SIQUEIRA RODRIGUES FLEURY ROSA; MÁRIO FABRÍCIO FLEURY ROSA; PEDRO HENRIQUE GONÇALVES INAZAWA; AROLDO KENKICHI INAZAWA (57) Abstract: The present invention deals with a microperforated adhesive that adheres to the portion of human skin that presents inflammatory processes and, through LED light sources, installed in electronic circuits, emits different wavelengths that have effects on the healing of this area. The adhesive is composed of overlapping layers, being a microperforated lower membrane, which has adhesive edges to be fixed around the application region, two printed circuit boards and an upper membrane, which is installed over the circuits. The device is indicated for any part of the human skin and allows it to be used to treat inflammation of the necrotic, parenchymal, erythematous, hyperplastic or hypertrophic, allergic types and in burns of all degrees.

2/12 [005] The presence of an infection in the wound slows down the healing process as the pathogen and cells compete for nutrients and oxygen. In addition, the infection prolongs the inflammatory stage of healing as the cells fight a large amount of bacteria and inhibits the ability of fibroblasts to produce collagen (Pedrosa, HC et al. (2004). The diabetic foot in south America: progress with the Brazilian save the diabetic foot project (International. Diabetes Monitor, v. 16, n. 4, p. 17-23.).

[006] Since the advent of the therapeutic laser in 1960, the clinical application in the treatment of wounds is gaining more and more dimensions. The applications of LEDs in health are beginning to arouse much interest in the scientific community due to their advantages, low cost and long useful life of these devices. Exposure to light generated by LEDs accelerates cell growth in relation to cells that are not subjected to light. A set of LEDs that emit light in the visible spectrum increases the energy of the cells, which accelerates the healing process of patients.

[007] LEDs are semiconductor diodes that, when subjected to an electric current, emit light and can be used for phototherapy with wavelengths ranging from 405 nm (blue) to 940nm (infrared). Visible radiation is approximately 384x10 ¹² Hz (for red) and up to 384x10 ¹² Hz (for violet).

[008] When applied to the skin, red light has a healing and anti-inflammatory action, while blue has bactericidal and rejuvenating action. The red light emitted by LEDs assists in cell multiplication (Dover, JS; Phillips, TJ; Arndt, K. (1989). Cutaneous effects and therapeutic uses of heat with emphasis on infrared radiation. Journal of the American Academy of Dermatology, v. 20, n. 2, pp. 278-286, February).). The blue LED (470nm) has a strong bactericidal action, producing the photoinactivation of the bacterium Propionibacterium acnes, through a process called oxidative stress which is the action of oxygen by removing the electrons from the outer layers of the molecules that form the bacterial cytoplasmic membrane . The intensity of the light beams emitted by the LEDs on the skin is lower than the laser, since its cells maintain a good interaction with the incoherent light (Rigau, J. (1996).

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3/12 LASER light at low intensity in modulating cellular function. Reus, Thesis (Doctorate in Histology) - Faculty of Medicine i Ciencia de La Salut. Univ. Rovira i Virgili).

[009] One of its great advantages is the emission of light in a wide spectrum, from near infrared to ultraviolet. Some uses in which the LED can be applied as a therapeutic treatment:

i. Use of light to aid the healing of skin lesions: acceleration of the healing process through the local application of light of specific wavelengths, irradiated power and the determined time for application.

ii. Use of light to aid in the treatment of injuries in diabetics: light can provide normalization of biochemical and physiological processes in wounds of diabetic patients.

iii. Treatment of lesions with the aid of light in hemophiliac patients: possibilities for light to provide the production of deficient coagulating factors in the blood.

iv. Photosensitive procedures in the treatment of cancer: use of light as an energy source to trigger processes of destruction of cancer cells amid photosensitizing agents (Ramos, PE; Abe, GC; Conrado. Treatment of neuropathic pain with bioceramics. Proceedings of Congress Walt, 2004).

[010] These uses can be justified by the physiological effects promoted by light such as increased production of ATP (Adenosine Triphosphate), increased proliferation of fibroblasts and collagen synthesis, increased synthesis of RNA and DNA, stimulated angiogenesis and alterations induced on nociceptive afferences (Souza, APC (2008). Effects of LED and laser radiation associated or not in the repair of skin wounds on the back of rats: histological study. Doctoral Thesis, Department of Dentistry, Federal University of Bahia, Salvador, BA, 142p.).

[011] The depth of light penetration is directly proportional to the

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4/12 wavelength. The luminous intensity in the LED and the laser, with high length, penetrate more deeply than the small ones. This is because the shorter the wavelength, the greater the frequency of light and vice versa (Karu, T .; Ryabykh, TP; Fedoseyeva, GE, Puchkava, NI (1989). HeliumNeon LASER induced respiratory burst of phagocytes cells. LASERs Surg Med,

v.9, p.585-588).

[012] The functional differences between LEDs and lasers must be noted when choosing their application in human tissues. The laser and the LED are slightly different light sources. The laser is a coherent radiation source, it has a single color and a wavelength. The LED is an incoherent radiation source and emits light at various wavelengths, in a given range, depending on the color of the light emitted by it (Moreira, MC (2009). Use of electronic converters that power high-brightness LEDs in the application in human tissue and its therapeutic interaction (Doctoral Thesis, Department of Electrical Engineering, Federal University of Santa Maria, Santa Maria, RS, 190p). The difference between them is that laser therapy is used to make some modification in biological tissues, specifically directional; in LEDs, on the other hand, the coverage may be greater due to its incoherent radiation, where the spectrum of activity increases. LEDs are gradually replacing lasers for being painless, inexpensive and having a significant response after being applied to the skin, in addition to not being aggressive.

[013] Table 1 shows the differences between the LED and the laser, making a comparison between its intrinsic characteristics.

Table 1

Characteristics Laser LED Optical power High Low Cost High Low Use Complex Simple Spectrum width Narrow Wide Lifetime Smaller Bigger velocity Quick Slow Divergence in the issue Smaller Bigger

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Temperature sensitivity Highest Low [014] Table 2 shows a comparison between the LED and the laser, highlighting its advantages and disadvantages.

Table 2

LED Laser Advantage Disadvantage Advantage Disadvantage Less Invasive - natural stimulus Not consistent Coherent Invasive - stimulus unnatural Availability of Colors Less accurate More accurate Fewer colors Low cost Gradual visualization of the effect Visualization of the immediate effect High cost Can be applied in Whole body Slower therapy Faster therapy It's not appropriate for the whole body Suitable for chronic conditions and sharp Lower accuracy in length of wave Greater accuracy in length of wave It depends on the type of injury, more specific

[015] Laser radiation has a narrow wavelength range, while the LED emits several wavelengths. The LEDs exhibit gradual degradation. The laser shows to be more punctual and with a faster cure time, however it can be used in only some areas of the human body, due to the thermal factors that it can generate and the inadequate penetration in some types of tissues due to its length of wave and its directionality. The LED, on the other hand, shows the advantage of having low cost, greater flexibility, greater color availability, natural stimulation in the fabric, but it is less accurate than the laser and the curing time is longer, depending on the application. LEDs do not provide enough energy to damage tissue, but they do provide enough energy to stimulate a response by the body at the cellular level, helping the patient to heal (Moreira, MC (2009). Use of electronic converters that power high-brightness LEDs in the application in human tissue and its therapeutic interaction (Doctoral Thesis, Department of Electrical Engineering, Federal University of Santa Maria, Santa Maria, RS, 190p).

[016] Another advantage given to LEDs is greater ease of application,

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6/12 since light emissions are able to penetrate a wider area of the tissue. In addition, the multiplicity of LED wavelengths, which, unlike a single laser wavelength, can allow a wide range of tissue types to be affected and also produce photochemical reactions in the tissue via the cellular photoreceptor system .

[017] The search for new synthetic materials for the treatment of tissue alterations encourages the study of a technique supported by technological development, still little explored, that of biomaterial. A biomaterial is any synthetic or natural substance that can be used as a treatment to replace part of a living system or to function in close contact with living tissue. They are designed to repair and / or reconstitute parts or functions of organs and tissues and may or may not serve as a matrix, vehicle, support or stimulator for the formation of new tissue (Dallan, PRM (2005). Synthesis and Characterization of Chitosan Membranes for Application in Skin Regeneration, Doctoral Thesis, Faculty of Chemical Engineering, State University of Campinas, Campinas, SP, 212p .; Cunha, ALCP (2008). Development of degradable biological adhesives. 107f. Master's Dissertation Faculty of Sciences and Technology , University of Coimbra, Coimbra.).

[018] In recent decades, several studies have been carried out in order to identify substances capable of promoting healing. The search for substances with angiogenic activity has also been intense, due to their great potential for clinical application (Wang, W .; Lin, S .; Xiao, Y .; Huang, U .; Tan, Y .; Cai, L .; Li, X. (2008). Acceleration of diabetic wound healing with chitosancrosslinked collagen sponge containing recombinant human acidic fibroblast growth factor in healing-impaired STZ diabetic rats.Life Sciences, Amsterdam, v.82, n.3-4, p.190 -204.). Synthetic or natural materials have been compared or suggested for clinical and experimental use in several species. The substitute material to be considered ideal must be of low production cost, be easy to handle, promote the growth of tissues in the host, allow the scar tissue to have similar strength to normal tissue, be resistant to infections, not promote an exacerbated inflammatory response , not forming adhesions and fistulas, not having their physical characteristics altered by tissue fluids,

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7/12 be flexible, inert, porous and resistant (Wang, W .; Lin, S .; Xiao, Y .; Huang, U .; Tan, Y .; Cai, L .; Li, X. (2008). Acceleration of diabetic wound healing with chitosan-crosslinked collagen sponge containing recombinant human acidic fibroblast growth factor in healing-impaired STZ diabetic rats.Life Sciences, Amsterdam, v.82, n.3-4, p.190-204 .; Dallan, PRM (2005). Synthesis and

Characterization of Chitosan Membranes for Application in Skin Regeneration. Doctoral Thesis, Faculty of Chemical Engineering, State University of Campinas, Campinas, SP, 212p.).

[019] Among these characteristics, biocompatibility is the most important, as it is only through it that the biofunctionality of the material can manifest itself. When a foreign material comes into contact with biological fluids, protective responses are triggered and manifest as inflammatory or immunological processes, aiming at the elimination of the foreign body. Therefore, the good performance of a post-implant biomaterial is associated with a balance between biocompatibility and biofunctionality (Dallan, PRM (2005). Synthesis and Characterization of Chitosan Membranes for Application in Skin Regeneration. Doctoral Thesis, Faculty of Chemical Engineering , State University of Campinas, Campinas, SP, 212p .; Cunha, ALCP (2008). Development of degradable biological adhesives. 107f. Master's Dissertation Faculty of Science and Technology, University of Coimbra, Coimbra.).

[020] Some technologies have already been developed aiming at the use of phototherapy to assist in the healing process.

[021] The Brazilian utility model patent application BR202012033571 deals with a flexible device consisting of a set of pairs of LED and / or OLED light sources, arranged in concentric circles. The device simultaneously emits two wavelengths on a wound, and its light-emitting unit can be printed on clothes to be worn by the user or on pieces in the form of bandages and bandages. The invention is portable and anatomically adjustable to the area to be treated.

[022] The Brazilian patent application BRPI11033710 contemplates a light emitting device that performs phototherapy, using a light source of the type

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LED and / or laser, providing an increase in muscle physical performance. In addition to accelerating the repair of these muscle tissues when they are subjected to excessive stress. The invention has an anatomical shape and, therefore, adapts to each part of the body.

[023] The Chinese utility model patent application CN203539893 is a phototherapy device composed of a circuit board inserted between two layers composed of flexible material, where electroluminescent tubes are located. The inner layer, which is in contact with the skin, has several holes for the passage of light rays. The device can be attached to any part of the body using an adhesive or a bandage.

[024] US patent application US2007233208 deals with a device that performs medical treatments through phototherapy, formed by layers through which a flexible serpentine composed of several light emitters passes. For contact with the skin, a transparent semipermeable membrane is used that controls the flow of moisture to the tissues.

[025] US patent application US2008058689 details an invention used in photodynamic therapies to provide pain relief. The invention has a light source that allows the selection of the wave spectrum of light radiation, being able to select the various spectra between visible and infrared light. The bandage-like device is flexible and allows the user to have freedom of movement when it is attached to their body.

[026] The US patent application US2013144364 presents a flexible device, similar to a bandage, that uses phototherapy for medical treatments that require heating of a body part. A light source feeds the system to provide and manage heat over the target treatment area. In addition, the heat management system enables uniform and controlled distribution throughout the area.

[027] The US patent application US20020143373 details a device that can be used in several modalities of therapeutic systems. The device consists of photon emitting diodes in

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MICROPERFURATED ADHESIVE MADE IN LATEX, ASSOCIATED WITH LED LIGHTING SOURCES FOR DIRECT APPLICATION IN INTERNAL AND EXTERNAL HUMAN INFLAMMATORY PROCESSES

FIELD OF THE INVENTION [001] The present invention deals with a microperforated adhesive made of latex that contains a system with LED light sources that are used to assist in the healing process of inflammation in human skin. This adhesive is a device in the biomedical area that uses irradiation of light combined with biocompatible materials with human skin.

STATE OF THE TECHNIQUE [002] Regarding the healing process, healing is a succession of phases that take place in the bed of the ulcer in order to restore the integrity of the injured tissue. These phases are: hemostasis, inflammation, proliferation, epithelialization and scar maturation (repair). The presence of hyperglycemia or infection is always unfavorable in the healing process. It can evolve slowly or unable to reach the final repair stage (Baum, CL; Arpey, CJ (2005), Normal cutaneous wound healing: clinical correlation with cellular and molecular events. Dermatol. Surg., V. 31, n 6, p. 674-86, June.).

[003] Immediately after the injury, the hemostasis process begins. This step is dependent on the interaction between endothelial cells, platelets and fibrins, resulting in vasoconstriction and clot formation. In addition to stopping bleeding, the clot acts as a temporary trellis for inflammatory cells, fibroblasts and growth factors that arrive at the site (Baum, CL; Arpey, CJ (2005). Normal cutaneous wound healing: clinical correlation with cellular and molecular events. Dermatol. Surg., v. 31, n. 6, p. 674-86, June.).

[004] Several factors can impair and delay the healing process. The most commonly found include hypoxia of ulcer, presence of infections, slough and necrotic tissue, malnutrition, environmental factors, metabolic disorders such as diabetes mellitus and use of medications such as corticosteroids (Stadelmann, WK; Digenis, AG; Tobin, GR ( 1998) Impediments to wound healing Am. J. Surg., V. 176 (Suppl. 2A), p.39S - 47S, 24).

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9/12 combination with electrical stimulators, thus transmitting the necessary energy to the user's body. The structure is composed of materials with shape memory, thus facilitating the positioning of the device on the user's body.

[028] The US patent application US20120253432 comprises a system that uses phototherapy for medical treatments. This system is formed by an elastic sheet, where light emitters are arranged, and a deformable ring that allows the sheet to be remodeled in any direction, according to the user's needs, that is, depending on which area of the body needs treatment.

[029] The Brazilian patent application BRPI1103690 refers to an insole capable of promoting tissue neoformation in diabetic patients. The active element of this insole is the electronic tissue regeneration circuit, in which an irradiating signal cell based on the principle of tissue regeneration using the laser diode is used. The invention is operated by the user himself, different from techniques only used in hospital environments. In addition, it is made in an individualized and personalized way, following the anatomy and characteristics of the user's feet, causing the radiating cells to be installed at specific points to promote healing.

[030] Most devices for light therapy available on the market have only palliative objectives, not acting directly on the healing and healing process of diseases. They promote effects such as muscle relaxation, pain relief and others. The present invention has a decisive role in healing, accelerating the regeneration process through the skin - light - biomaterial iteration.

[031] In addition, other devices for light therapy are very large and / or heavy, and often require a station to be operated. The sticker exposed in this document is small, and can be used and stored easily, requiring no greater care than any mobile device, such as a cell phone.

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12/12 ii) construction of the layer structure using the Van Gogh technique;

iii) vulcanization;

iv) cooling.

[043] The lower membrane is manufactured with the minimum possible thickness so that it fulfills its functions and, in this way, has an adequate transparency, so that the irradiation of the LED light sources surpasses it and reaches the skin.

[044] The device has a coupled interface that makes manipulation by the user more direct and objective. It is enough for the health professional to guide you in the correct mode of lighting, that is, to change and select the wavelengths to obtain each color, and the continuous or alternate mode of irradiation and the time of use, and thus, the user you can easily use the patch outside a hospital environment.

[045] The present invention has the option of being built in a standard or customized size, depending on the size and location where it will be applied, and it can be on an internal or external wound or injury. The lower membrane is biocompatible with the skin. The upper and lower membranes protect the two printed circuit boards from the environment, and can be cleaned after use, allowing the reuse of the adhesive.

[046] Both circuits are electrically powered by a battery, positioned between the two printed circuit boards. As soon as the battery reaches the end of its life, it can be replaced. Access is through an opening in the adhesive, dedicated for this purpose. A small, light, rechargeable 9 V battery with a capacity of 450 mAh is used.

[047] The dispersion of light generated by the LED reaches a larger surface, this results in a faster result, than the unidirectionality of the laser. The use of LED is safer, provides a smooth and effective delivery of light energy and a higher energy yield per unit area in a given application period.

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BRIEF DESCRIPTION OF THE FIGURES [032] Figure 1 shows the image containing one of the membranes that make up the structure of the present invention. The image represents both the upper and the lower membrane, as there are no differences in their construction.

[033] Figure 2 shows a schematic drawing of the operation of the first printed circuit board containing the interface between the user and the microcontroller.

[034] Figure 3 shows the schematic of the assembly and operation of the components of the second printed circuit board that performs the interface between the microcontroller and the LEDs.

DETAILED DESCRIPTION OF THE INVENTION [035] The present invention is a microperforated adhesive containing LED light sources installed in electronic circuits, which when adhered to a portion of human skin that has inflammatory processes, emits different wavelengths that have effect on wound healing. In this case, the adhesive, which is manufactured with natural latex biomembranes, is an alternative dressing for various inflammations, effective, economical, easy to handle and capable of accelerating healing. In addition, it has a debridement and neoangiogenic potential, which makes the healing process dynamic and fast.

[036] The device is indicated for any part of human skin and allows to be applied in inflammation of the necrotic, parenchymal, erythematous, hyperplastic or hypertrophic, allergic types and in burns of all degrees.

[037] The adhesive is composed of overlapping layers, being a microperforated lower membrane, which has adhesive edges to be fixed around the application region, two printed circuit boards and an upper membrane, which is installed over the printed circuits.

[038] The material for making the upper and lower membranes is the natural latex extracted from the rubber tree (Hevea brasiliensis), which has neovascularization-inducing properties, facilitates autolytic debridement, promotes

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11/12 vascular neoformation and stimulates tissue proliferation and granulation. In addition to reepithelization, proven in several species and in different studies of the organism. All these researches that used this material as an implant, in different tissues, showed very satisfactory results, which motivates the realization of new works in this area, in different species.

[039] The control system of the present invention consists of two printed circuit boards, to which other electronic components are connected. The first one is the interface between the user and the microcontroller, with two buttons - one with the “menu” function, and the other with the “select” function - a piezoelectric buzzer sound device and 2 7-segment LCD displays, which make the user interface. The second board aims to connect the light sources to the microcontroller. In it, 30 LED light sources (10 of each color - red, green and yellow) are installed, and there are 3 control inputs so that the first plate can control the drive. In addition to these components, the second board has current drivers and voltage regulators.

[040] The adhesive radiates three types of wavelength, related to the colors red, green and yellow, over areas of the skin with a diameter of up to 7.8 cm. It has two modes of operation: continuous and alternating. In the first, the user selects the lighting session time, the desired color combination; and they stay on for the entire time interval. In the second, the user chooses color combinations and the total time, but each color will call separately, and for equal time intervals within the session. An audible warning is activated at the end of the application time.

[041] The electronic circuit, built to apply a density of 2 to 3 J / mm2 per portion of irradiated skin, is microcontrolled and features an audible warning of irradiated color change and completion of the irradiation process that lasts between 15 and 30 minutes.

[042] The process of making the top and bottom layers is divided into four stages:

i) latex treatment and cooling;

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Claims (9)

1. MICROPERFURATED ADHESIVE characterized by being composed of overlapping layers, being a microperforated lower membrane, made of latex, with adhesive edges and biocompatible with the skin; an electronic control system containing two printed circuit boards, LED light sources, battery and components for user interface; and an upper membrane, also in latex; that when adhered to a portion of the human skin and activated, the LED light sources emit different wavelengths that have an effect on the healing of wounds and inflammation. 2. MICROPERFURATED ADHESIVE, according to claim 1, characterized in that the control system consists of two printed circuit boards, having two buttons - one with the “menu” function, and the other with the “select” function - a sound device the piezoelectric buzzer type and two 7-segment LCD displays, and the second plate that interfaces the light sources and the microcontroller, has 30 LED light sources installed, 10 of each color - red, green and yellow, and three control inputs so that the first plate can control the drive; in addition to these components, the second board has current drivers and voltage regulators. 3. MICROPERFORATED ADHESIVE, according to claims 1 or 2, characterized by radiating three types of wavelength over portions of the skin up to 7.8 cm in diameter. 4. MICRO-PERFORATED ADHESIVE, according to one of claims 1 to 3, characterized by having two modes of operation: continuous and alternating; the first with selection of the time of the lighting session, and combination of desired colors, which remain on for the entire time interval; and the second where color combinations and total time are selected. 5. MICRO-PERFORATED ADHESIVE, according to one of claims 1 to 4, characterized in that the light sources of the LED type, of each color, are Petition 870160047654, of 08/29/2016, p. 22/41 2/2 triggered separately, and at equal intervals within the session; and an audible warning is activated at the end of the application time. 6. MICROPERFURATED ADHESIVE, according to one of claims 1 to 5, characterized by applying a density of 2 to 3 J / mm ² per portion of irradiated skin, with an audible warning of color change and completion of the process that lasts between 15 and 30 minutes. 7. MICRO-PERFORATED ADHESIVE, according to one of claims 1 to 6, characterized by the process of making it carried out by four methods in sequence: i) latex treatment and cooling; ii) construction of the adhesive via the Van Gogh technique; iii) vulcanization and iv) cooling. 8. MICRO-PERFORATED ADHESIVE, according to one of claims 1 to 7, characterized in that it is made of standard size or customized for the dimension and the place where it will be applied, which may be on an internal or external wound or injury. 9. Use of MICROPERFURATED ADHESIVE, according to one of claims 1 to 8, characterized in that it is indicated for any part of human skin and allows the treatment of inflammation of the necrotic, parenchymal, erythematous, hyperplastic or hypertrophic, allergic and burn types of all the degrees. Petition 870160047654, of 08/29/2016, p. 23/41 1/2 FIGURES