BRPI0805782A2 - nanometrics bioceramic emitting infrared radiation incorporated in polymers and textile article - Google Patents

Abstract

It is designed to stimulate the self-regulation of human body tissues by the mechanical compression action that prevents the skin from distending, while its contact with body heat excites bioceramics, which refracts the long infrared, promoting the biostimulation of the skin. affected tissues, where its main effect is drainage, controlling the action of edema, providing its return to lymphatic vessels, where they will be filtered and eliminated by the kidneys or metabolized again, favoring the increase of cellular metabolism.

Description

NANOMETRIC BIOCERAMIC ISSUER OF INFRARED RADIATION INCORPORATED IN POLYMERS AND TEXTILE ARTICLE

APPLICATION FIELD

This descriptive report refers to BIOCERAMICANANETRIC ISSUER OF INFRARED RADIATION INCORPORATED IN POLYMERS AND TEXTILE ARTICLE, which is intended to stimulate the self-regulation of human body tissues.

BACKGROUND ART

In the area of health and, more particularly, personal aesthetics, there are various treatments aimed at improving skin quality, pain control, and inflammation control, among others.

Every chemical reaction processed in the body results in the formation of free radicals and toxins, which need to be eliminated to prevent premature aging and the onset of edema and inflammation.

In order to perform these procedures, drugs are usually used, topical or allopathic, associated or not with the use of mechanical equipment with technology for the stimulation of organism; However, at the end of treatment there are usually recurrences or side effects resulting from these techniques, which require constant maintenance treatments.

Laser light or Ied is a type of therapy already widely used in the area of health and personal aesthetics, with very positive effects, providing an alternative to the use of medicines, as it stimulates self recovery of the body, minimizing the side effects from treatment.

Currently known therapies have the following disadvantages:

- The treatments are performed only in clinics or clinics;

- treatments are costly;

- possibility of recurrence after termination of treatment;

- need for medication use;

- need to use equipment;

- constant updating of equipment;

- possibility of side effects arising from medication use;

- discomfort during treatment;

- longer time to return to normal activities;

- need for displacement for treatment BACKGROUND OF THE INVENTION

From the analysis of the properties of ceramics, it was observed that some of them have photo-thermal effects; that is, when heated, they have infrared radiation emission / reflection properties.

The nanometric bioceramics are formed by ultra-fine and ultra-fine particles, with thermo-excitable nanometric granulometry, capable of emitting long infrared, consisting mainly of alumina, titanium oxide; magnesium oxide and silica,

Nanotechnology is a technological innovation considered to be the origin of modern science, and with this new molecular engineering, one can get the best out of each material, intelligently, by minimizing space occupied, and more effectively.

Nanometric bioceramics are a thousand times smaller than a cell and a billion times smaller than the meter, so it is able to occupy very small spaces between the fibers of the tissue, making it possible to incorporate a larger number of nanoparticles. close to the fibers, thus achieving an unmatched long infrared emissivity capability, without losing the mechanical properties of the wire.

BRIEF DESCRIPTION OF THE DRAWINGS For a better understanding of the present BIOCERAMICANOMETRIC ISSUER OF INFRARED RADIATION INCORPORATED IN POLYMERS AND TEXTILE ARTICLE, reference is made to the attached drawings in which:

Figure 1 - Electron microscopy photo, with a 20-fold magnification, of the bioceramic dust scan, in which the extension of the bar (blue) shows an area of 0.7 micrometres, and it can be observed bioceramic particles smaller than 100 nm;

Figure 2 - Electron microscopy photo, with 20,000-fold increase, of the scanning of the nanometric particles forming groups by the force of molecular attraction between them, and the nanometric bioceramics with these characteristics can be efficiently incorporated into polymers and can be extruded into fibers. with nanometric bioceramics embedded inside or externally incorporated into the fiber as a varnish, so as to exert a strong interweaving to the wire, not detaching when washed and without losing its characteristics of texture and compression;

Figure 3 - Larger photo of the wire weft externally impregnated with nanometric bioceramics;

Figure 4 - Photo with a larger magnification of the wire impregnated externally with nanometric bioceramics;

Figure 5 - Reflectance graph of the textile article incorporating unwashed nanometric abioceramics at room temperature (blue) and 37 ° C (red), where the increase in infrared reflectance in heated tissue is evident in almost the entire infrared spectrum.

Preferred Description of the Invention

Through research, it was possible to incorporate nanometric dabioceramics in textile polymers, when melting the same ones, applied in the form of varnish containing bioceramicanometric, on the outer surface of fibers, such as cotton, lycra, polyamide, elastane, nylon, polyester and others, enabling the development of various accessory articles such as gloves, girdles, bandages, shorts, t-shirts, socks, socks, among others, without losing their elasticity and texture properties.

Nanometric bioceramics have a basic or similar composition of 20% alumina (AI2O3), 3% titanium Ti, 11% magnesium oxide (MgO), 6% difro trioxide (Fe2O3) and 60% silica (SiO2), It is capable of emitting / reflecting infrared at an approximate spectral range of 3 to 15 μιτι, and this product, in contact with the skin, is capable of absorbing 97% of the infrared emitted by the body. The tissues impregnated by nanometric bioceramics have a mechanical action. compression that prevents the skin from distending, and its contact with body heat excites bioceramics, which refract the long infrared, promoting the biostimulation of the affected tissues, and on the healthy tissues does not develop any action, where its main effect is the drainage, controlling the action of the edema, providing its return to the lymphatic vessels, where they will be filtered and eliminated by the kidneys or metabolized again.

Infrared has a high affinity for water, promotes molecular vibration, stimulates chemical mediators, such as nitric oxide, to promote vessel dilation, which will allow toxin drainage, regulating tissue pH and oxygenation, optimizing cellular ometabolism, favoring synthesis of ATP, as well as each cell's own subunits.

Products with nanometer-shaped bioceramic in textiles can be used as adjuvants in invasive procedures, helping control inflammation, being useful in the postoperative period, reducing pain, promoting noticeable improvement in healing and maintenance of results, and improved quality.

With the use of therapeutic accessories containing the bioceramicanometric in the form of textile articles, it will be possible to perform treatment at home or at work, stimulating the body to react in the presence of offending agents in the extra cellular environment.

The textile article incorporated with nanometer bioceramics, when applied in a region of the body, at 37 0C has the capacity to absorb the infrared spectrum emitted by this area covered by it, with emissivity band ranging between 1 μηι and 50 μιτι, with reflective capacity. emission in the spectrum between 3μΓη to 14.8 μιη, 97% efficient, practically promoting infrared transmission shielding to the external environment.

Texts without nanometer bioceramics, on the other hand, have inverse reflective behavior; that is, almost all the infrared emitted by the body is transmitted through the tissue and is lost to the environment, presenting no therapeutic effects.

Using the bioceramic-incorporated textile article, its emissivity in contact with the skin is in the order of 20pW / cm2, which is equivalent to the application of an infrared energy of 0.72mJ / cm2 per hour of use of the textile with the nanometric bioceramics, being recommended the use of at least 6 hours / day with a total energy of the order of 4,32J / cm2, to obtain the desired therapeutic effects, being this dosage of energy compatible with the therapeutic lasers.

Thus, therapeutic accessories produced from the textile incorporated with nanometric bioceramics can be used at rest as well as in physical activities of any magnitude, performing the body's biostimulation, which will react in the presence of long, self-regulating infrared light, as well as medication use, maintaining the results obtained with the treatment, besides accelerating inflammation and postoperative stages, minimizing the time wasted with other types of procedures.

A small amount of nanometric bioceramics may be incorporated into the polymeric mass upon melting of the polymer and then extruded in the form of yarn which will be used to make a therapeutic accessory such as gloves, shorts, t-shirts, socks and others which may be Be seamless fabrics with different types of fibers, to provide several different mechanical compression factors in the same piece, which prevent skin distension, activating, with the long infrared, the physiological factors that will facilitate lymphatic drainage.

Nanometric bioceramics can be applied externally to the yarn so that it is prevented from loosening during the washes of the textile article, or it can be applied inside the fiber, thus being able to weave with compression factors in different areas, allowing its reuse for a period of time. longer.

Nanometric bioceramics may also be incorporated into resins and polymers through chemical reactions and may be found in dental medical products such as surgical cements, endodontic cements, lining cements, skin and mucous protection films, absorbent and non-adherent gauze, skin adhesives.

Infrared emitted by nanometric bioceramics, stimulates the molecular vibration of the water contained in cells, can have bacteriostatic effects and pH change, having important effects on food preservation and acidity control, and packaging can be made with the biometric nanometer for this purpose.

Claims (15)

1. NANOMETRIC BIOCERAMICS ISSUED OF INFRARED RADIATION INCORPORATED IN POLYMERS AND ARTICCOTEXTILES, characterized in that their incorporation in polymers can occur when they are fused, applied in the form of a varnish containing nanometric bioceramics, on the face external fibers. 20% aluminium (Al 2 O 3), 3% titanium Ti, 11% magnesium oxide (MgO), 6% difroide trioxide (Fe2O3) and 60% silica (SiO2), and capable of Infrared Emitting / Reflecting in a spectrum that can be approximately between 3 and 15 pm and which, in contact with the skin, is capable of absorbing 97% of the infrared emitted by the body. NANOMETRIC BIOCERAMIC ISSUING POLYMER AND ARTIGOTTEX INFRARED INFRARED RADIATION, according to claim 1, characterized in that it can be applied to the outer face of cotton fibers, lycra, polyamide, elastane, nylon, polyester and others. 3. NANOMETRIC BIOCERAMIC ISSUING POLYMER AND ARTIGOTTEX INFRARED RADIATION EMITTER according to claim 1, characterized in that it may enable the development of various accessory articles such as gloves, straps, bandages, shorts, t-shirts, socks, socks , among others. 4. NANOMETRIC BIOCERAMIC ISSUING POLYMER AND ARTIGOTTEX INFRARED INFRARED RADIATION, according to claim 1, characterized in that the fiber impregnated by nanometric bioceramics has a mechanical action of compression that prevents the skin from distancing with the contact of the body with its heat contact. bioceramics, which refract the long infrared, promoting the biostimulation of the affected tissues. 5. NANOMETRIC BIOCERAMIC ISSUING POLYMER AND ARTIGOTTEX INFRARED INFRARED RADIATION, according to claim 1, characterized in that the long infrared emitted by the fiber impregnated by bioceramic has no effect on the healthy tissue of the skin. Controlling the action of edema, accelerates the removal of lactic acid from the muscles during exercise, providing its return to the lymphatic vessels, relieving pain. 6. NANOMETRIC BIOCERAMIC EMITTERING INFRARED POLYMER AND ARTIGOTTEX INFRARED RADIATION according to claim 1, characterized in that the infrared stimulates chemical mediators such as nitric oxide, enhancing the dilatation vessel, which will allow the drainage of toxins and pH tissue oxygenation, optimizing cellular ometabolism, favoring ATP synthesis, as well as each cell's own sub-substances. 7. NANOMETRIC BIOCERAMICS EMITTING POLYMER AND ARTIGOTTEX INFRARED INFRARED RADIATION, according to claim 1, characterized in that the textile materials with nanometric bioceramics can be used as adjuvants in invasive procedures, being useful in the post-surgical control, being useful in the post-inflammation control. decreased pain, promoting a marked improvement in healing and maintenance of results, and improved quality of life. 8. NANOMETRIC BIOCERAMIC ISSUING POLYMER AND ARTIGOTTEX INFRARED INFRARED RADIATION, according to claim 1, characterized in that the textile article incorporated with nanometric bioceramics, when applied to a body region at 37 ° C, has the ability to absorb the entire spectrum of infrared emitted by this area covered by it, emissivity range ranging from 1 μιη to 50 μιτι, reflective / emissive spectrum capacity between 3μιτι to 14.8 μπι, shielding infrared transmission to the external environment. 9. NANOMETRIC BIOCERAMIC ISSUING POLYMER AND ARTIGOTTEX INFRARED INFRARED RADIATION, according to claim 1, characterized in that by the use of the textile article incorporated with nanometric bioceramics, its emissivity in contact with the skin is of the order of 20pW / cm2, equal to the application of an infrared energy of the order of 0.72mJ / cm2, per hour of use of the textile article with the bioceramicanometric, being recommended the use of at least 6 hours / day, making a total energy of the order of 4,32J / cm2. cm2, to achieve desired therapeutic effects, this energy may vary according to thermal variations. 10. NANOMETRIC BIOCERAMIC ISSUING POLYMER AND ARTIGOTEXTIL INFRARED RADIATION, according to claim 1, characterized in that a small amount of nanometric bioceramics can be incorporated into the polymeric mass upon melting and subsequently extruded into the form of wire. fiber, thus enabling seamless textile articles with mechanical compression factors in different areas maintaining adequate texture and compression characteristics that prevent skin distension, activating, with the long infrared, the physiological factors that will facilitate lymphatic drainage. 11. NANOMETRIC BIOCERAMICS EMITTING INFRARED POLYMER AND ARTIGOTTEX INFRARED RADIATION, according to claim 1, characterized in that the incorporation of nanometric bioceramics can be made within the textile fiber by mixing at the time of polymer fusion or chemical exchange. 12. NANOMETRIC BIOCERAMIC ISSUING POLYMER AND ARTIGOTTEX INFRARED INFRARED RADIATION, according to claim 1, characterized in that the incorporation of nanometric bioceramics can be made in polymers or medical / dental resins, with the aim of relieving pain and accelerating the stages of inflammation and healing. may be incorporated into surgical cements, liner cements, endodontic cements, gauze and films or skin protective adhesives NANOMETRIC BIOCERAMIC ISSUING POLYMER AND ARTIGOTEXTILE INFRARED INFRARED RADIATION, according to claim 1, characterized in that the incorporation of nanometric bioceramics can be achieved by mixing in cosmetics and pharmaceuticals. 14. NANOMETRIC BIOCERAMICS EMITTING INFRARED POLYMER AND ARTIGOTEXTIL INFRARED RADIATION according to claim 1, characterized in that the incorporation of nanometric bioceramics can be made with implant-like embiomaterials. 15. NANOMETRIC BIOCERAMIC EMITTING POLYMER AND ARTIGOTTEX INFRARED INFRARED RADIATION, according to claim 1, characterized by the fact that it emits long infrared, capable of stimulating the molecular vibration of water contained in cells, with bacteriostatic effects and pH alteration. foods and do not control their acidity.