WO2021136861A2

WO2021136861A2 - Tissue-normalising material

Info

Publication number: WO2021136861A2
Application number: PCT/ES2020/070830
Authority: WO
Inventors: Francisco SELVA SARZO
Original assignee: Selva Sarzo Francisco
Priority date: 2020-01-03
Filing date: 2020-12-30
Publication date: 2021-07-08
Also published as: WO2021136861A3; ES2839551A1

Abstract

Tissue-normalising material and its use in textiles, orthoses, surgical material and prostheses to help improve the comfort and well-being of the user. The invention is a tissue-normalising material consisting of at least one ferrimagnetic material comprising a plurality of magnetic moments aligned in the same direction, but not with the same orientation, and comprising a plurality of zero magnetic fields.

Description

DESCRIPTION

Tissue normalizing material

Technical sector

The present invention belongs to the technical field of materials that influence the function and performance of the organism, used in bioengineering, medicine, nursing, physiotherapy, podiatry, dentistry, occupational therapy, performance of the organism in the face of different stimuli or physical challenges such as sports and the textile field.

State of the art

The nervous system uses neurons to exchange messages or nerve impulses that connect each area of the body, from the skin to the brain. This is why these connections are so important for well-being and proper functioning. However, sometimes, certain imbalances occur in the nervous system that can affect vessels, muscles, tendons, ligaments, viscera or bones. In order to rebalance the connections, techniques such as ultrasound-guided percutaneous neuromodulation -invasive- appear in physiotherapy that solve many cases of this type. Neuromodulation is the process by which nerve activity is regulated to control the physiological levels of various classes of neurotransmitters.

This invasive technique consists of the application of a current on the peripheral nervous system that influences the central nervous system. This current helps to increase or decrease the excitability of a group of neurons, normalizing the nerve impulse for proper neuromuscular function. This achieves a decrease in pain and an improvement in neuromotor control, that is, an improvement in mobility and coordination. Therefore, it is effective in practically any pathology, especially when the musculoskeletal system is involved.

In Gossling etAI. [Gossling HR, Bernstein RA and Abbott J. Treatment ofununited tibial fractures: a comparison of surgery and pulsed electromagnetic fields (PEMF). Orthopedics. 1992 Jun; 15 (6): 711-9] describe that electromagnetic field treatment in ununited fractures has proven to be more successful than traditional non-invasive treatment and at least as effective as surgical therapies. Given the costs and potential dangers of surgery, magnetic field therapy could be considered an effective alternative as it is a successful treatment of ununited tibial fracture fractures. However, there are currently no techniques or solutions that make it possible to protect, recover, normalize or improve the function of body tissues.

Static electromagnetic fields (EMF) and extremely low frequency (ELF), particularly magnetic fields, probably play an important role in the evolution of living organisms. These are effects that could influence cancer development and treatment, growth and development, regeneration, and healing. This study is expected to provide a roadmap for future studies with the aim of replicating and expanding the little research on human magnetoreception [Lai H. Exposure to Static and Extremely-Low Frequency Electromagnetic Fields and Cellular Free Radicáis. Eiecíromaan Biol Med. 2019: 38 (4): 231-248. doi: 10.1080 / 15368378.2019.1656645]

Document EP 0 728 499 A2 is located in the state of the art, which describes a tissue with a magnetism between 2 and 20 gauss. As will be described later, since our material does not by itself create magnetism like ferrite and neodymium magnets, so it does not create any attraction or repulsion effect on its own. The present invention needs to be in contact with the electromagnetic fields of living beings for this effect to occur. In addition, the magnetism that is created at that moment is practically negligible and less than 2 gauss since a opposed polar structure is not used, but disorganized net magnetic moments are created that are generated by its own ionic structure that, when contacting external magnetic fields produce the effects that will be described below. Nor is apparatus used in the present invention to regulate the intensity of our matter.

In WO2004 / 043539A1 a therapy apparatus is described comprising a layer with a magnetic material on a textile material comprising the use of ferrite causing a series of alternative linear north and south parallel poles.

CN205512384U describes socks that incorporate a series of electro-stimulating elements. In addition, it contains magnets that are placed apart from each other in order to face their magnetic poles. On the contrary, in the present invention, as will be described later, magnetic poles are not used, but net magnetic moments are created that are generated by their own ionic structure that are organized when they come into contact with the magnetic fields of beings. alive and do not need electricity to work.

Document US6652446B1 describes a textile connected with an infrared means. However, as in the previously described documents, this invention requires the presence of a positive-negative polar structure. However, the present invention does not contain magnets that need to be separated because they need to face their poles, the positive and negative poles or poles of the same charge since our substance does not have opposite poles since it creates net magnetic moments that are generated by its own ionic structure. This means that our substance has magnetic properties, but not magnetic effects if it does not come into contact with the magnetic fields of living beings. That is to say, in the present invention, unlike in this document, magnetic ordering of the magnetic moments of a sample occurs so that all the magnetic moments are aligned in the same direction, but not in the same direction, so the In some sections, the material has null magnetic fields creating little electrical conductivity since they cannot completely cancel the material's own magnetization. It is when it comes into contact with electromagnetic fields such as those of living beings, they generate different effects that are described later creating net magnetic moments that are generated by its own ionic structure.

In order to generate a magnetic field facing polarities, it is necessary to use ferrite or neodymium facing a positive and a negative face, which is not the case with the present invention. That is, in the state of the art facing poles are used, where each of the poles aligns a large number of microscopic magnetic domains in the same direction and sense, in such a way that their individual magnetic fields unite, forming one more field. large and increasing the electrical conductivity always without the possibility of canceling these fields. However, the present invention does not create an effect until it comes into contact with the electromagnetic fields generated by living beings, acting only at that moment since our substance only has electromagnetic properties without the possibility of sticking or repelling, as do the ferrite or neodymium magnets. In the present invention, however, it is not an object of the invention to create a large electromagnetic field, but rather many electromagnetic fields of very low intensity (between -10mV to -90mV) resembling the fields created by cells in different parts of the world. body, never exceeding 2 gauss.

Document EP1516550A1 describes a magnetic element for footwear, clothing and accessories that adheres to objects, but does not integrate into them. This document describes the use of magnetic fields using magnets between 300 to 500 gauss. However, the present invention does not create magnetism by itself, it is necessary that it be in contact with the electromagnetic fields of living beings, therefore, practically negligible. The magnetic substance used does not face its two poles to create magnetism continuously, but has the properties and does not act until it comes into contact with the electromagnetic fields of living beings creating net magnetic moments that are generated by its own ionic structure. To reach 300-500 gauss, it is necessary to use ferrite or neodymium, aligning the microscopic magnetic domains in the same direction and facing a positive and a negative face without the possibility of canceling the continuous magnetism.

Finally, US5720046A describes an advertising article with a magnet attached to a structure of a glove. As with previous documents, this document contains magnets that need to be separated to face the positive and negative poles. However, in the present invention, the material has magnetic properties and only acts when it comes into contact with the body's electromagnetic fields since it has an ionic structure such that it allows to create net magnetic moments, making unnecessary the use of ferrite or neodymium with its positive and negative poles facing each other to create the effects that are described.

All the aforementioned documents are based on a magnet directly attached to the textile, which does not allow the neuromodulation objectives proposed by the present invention to be achieved, which consists of the normalization of surface tissue magnetic fields due to the low intensity that it can create when in contact with the electromagnetic fields of living beings. The fields created by magnets with double polarity continuously reach much deeper, reaching deep elements of the body. Thus, the state of the art closest to the present invention is document ES 2 681 531 A1 of the same inventor of the present invention. Said document proposes a neuromodulator material comprising a complex, flat, knitted fabric and / or combinations of them formed by natural and / or synthetic fibers; and magnetic particles or polymers with magnetic particles with magnets of positive and negative polarity facing each other, causing deep magnetic fields. However, the present invention improves on this structure.

For a better understanding of the operation of the invention presented here, we must take into account certain key concepts. So, as described above, all the materials used in the different documents listed in the previous paragraphs use ferrite or ferrite magnets which are materials where a large number of microscopic magnetic domains are aligned in the same direction and sense but facing negative and positive poles, in such a way that Their small individual magnetic fields come together, aligning a large number of microscopic magnetic domains in the same direction and sense, forming a larger field, increasing electrical conductivity and creating strong permanent magnets and, therefore, a profound effect on the body.

If we break the ferrite magnet into several or thousands of pieces, a positive and a negative pole will always be created in each of the new pieces. Our material will always have the ions with the same attraction so it does not produce opposite poles or a magnetic field significantly appreciable to the eye or to the holding force or repellency as it is clearly seen in ferrite or neodymium magnets, which is why our material It can be separated or joined in all the parts you want without losing or changing its properties. Magnets are elements with significant magnetism, which attract other magnets and / or metals such as iron, cobalt, nickel and / or alloys of these.

Explanation of the invention

The object of the present invention is a tissue normalizing material, that is, a normalizing material of the electromagnetic fields of body tissues that stimulates only the elements of the skin (cells, proteins and / or nerve endings, among others) since The layers of the skin send signals to the brain in different ways so that it produces correct responses to the stimuli received, affecting and normalizing all the tissues of the organism.

In the present invention, it will be understood that an aberrant magnetic field is a magnetic field that is not considered normal or correct. Depending on the patient's dysfunctions, aberrant fields are created that oppose the normal magnetic fields that should appear at that location. Those fields are unusual and deviant from normal. The function of the present invention is to act on these aberrant or abnormal magnetic fields to make them normal, usual and reasonable again.

Therefore, it is an object of the invention to help reduce the pain of problems arising from incorrect vascularization, tissue innervation, helping to carry out the appropriate polarity changes from the different stimuli that the body receives, whether internal or external, continuously, painlessly and for prolonged periods of time if deemed appropriate, in such a way as to avoid the inconveniences existing in techniques or materials described in the state of the art such as the weight of magnets and strong, continuous and deep electromagnetic fields. This object is achieved with the material of claim 1. Different aspects and particular embodiments of the present invention are described in the dependent claims.

In the present invention, the normalizing material for the electromagnetic fields of body tissues consists essentially of the presence of at least one ferrimagnetic material or a combination of ferrimagnetic materials. Ferrimagnetism is a physical phenomenon in which magnetic ordering of magnetic moments occurs, so that all magnetic moments are aligned in the same direction, but not in the same direction. Therefore, some of them are opposite and cancel each other, in part or completely. However, these magnetic moments that can be annulled are randomly distributed and fail to completely annul the material's own magnetization.

The normalizing material of the present invention, therefore, creates an ordering of the own and permanent or almost permanent magnetic domains, since over time they can lose their magnetic powers very slowly. The material of the invention does not produce significant magnetism by itself, since it produces little electrical conductivity so it does not attract or repel itself, differing from the documents described in the state of the art, which use magnets that attract or repel each other. repel depending on the polarities they face. In the present invention it is necessary to come into contact with the electromagnetic fields of living beings to be productive. However, the low magnetism that our material induces when it comes into contact with the electromagnetic fields of living beings is powerful enough to affect skin cells, therefore superficial, which, through the different connection routes with the brain, can have an effect on the body's tissues even if they are deep. Thus, in the material of the invention, small differences between neighboring domains make possible a plurality of magnetic fields with little electrical conductivity thanks to the creation of net magnetic moments that are generated by its own ionic structure that produce an effect in living organisms when they come into contact with the electromagnetic fields of living beings. Thanks to the present invention, the existing problems in the state of the art are solved by means of a material that is perfectly coupled to any tissue, material, textile, orthosis, prosthesis, utensil or device for any body segment of the user, being able to extend the time of painless treatment thanks to its physical and mechanical properties, composition and structure.

The material of the present invention can be used in any type of fabrics, materials, textiles, hides and skins, osteosynthesis, surgical elements, appliances, prostheses, splints, technical aids and supports used in medicine, nursing, orthopedics, physiotherapy, dentistry, podiatry, performance of the body in the face of different stimuli or physical challenges such as sports and occupational therapy such as foot and ankle orthoses, upper limbs, knee, hip, back and skull. More specifically, the material object of the present invention can be inserted or can be part of the different materials with which the prostheses - hip, knee, vertebrae or teeth - and the orthoses - insoles, 3D orthotics for fractures, knee braces, are manufactured. plantar supports, elbow pads, slippers or footwear. Therefore, it manages to improve the comfort and the feeling of well-being of the user.

The material is composed of a combination of ferrimagnetic minerals that consist of a plurality of disorganized anions and cations without the ability to create magnetic fields with perceptible attraction and repulsion capacity and because it can be placed, adhered or embedded, in solid, liquid or gaseous state - in the form of a spray-.

In textiles, a combination of knitted fabrics can be used, preferably by warp, weft or three-dimensional knit (3D), flat fabrics (simple or composite), preferably plain, twill and satin or satin, complex fabrics and / or combinations thereof. The term "fabric", as it is understood in the present invention, refers to the fabric obtained in the form of a sheet that is more or less resistant, elastic and flexible, through the crossing and linking of series of threads or fibers in a coherent way when interlacing them or unite them by other means. It is also possible to place the material on a very fine grid that is adhered to the textile. The particles can also be adhered between the structure of the textile. The grid can be adhered to the textile or simply sewn or held in its limits or making different stitches or in the seams forming all kinds of accessories, such as hats, elbow pads, girdles or any other.

As is well known, magnets have a positive and a negative side. In the different Known products described in the state of the art can only place a magnet with a negative pole on one side of the textile and its positive pole on the opposite side of the textile so that the magnetic field can be created. If they place alternating polarities (pole +, pole-, pole +, pole-) they create different fixed magnetic fields on the same side, invariable and with a deep effect where each one of them encompasses a large area of action compared to the material of the invention. . These fields, compared to the field created in the material of the present invention, are very large and deep. The material of the invention has the positive and negative charges -anions and cations- distributed over the entire surface of the textile substrate on one side or both of said textile and on the surfaces of the orthoses and prostheses creating, when they come into contact with the electromagnetic fields of living beings, many small magnetic fields of very low intensity and superficial compared to the textile of magnets that creates few fields and much stronger and deeper compared to our material. By creating so many fields, there are many interactions with the body, which is not possible according to the different techniques described in the state of the art.

The material of the invention can comprise a formulation with different minerals such as particles of iron, cobalt, nickel, manganese, copper, oxides of said compounds and / or binary or ternary combinations of them that do not create a perceptible and visible electromagnetic field. or to the touch, as it happens in the materials used in the patents of the state of the art since the ions - cations and anions - are located in disorder distributed throughout the tissue that serves as a base, being able to generate one or more magnetic fields making use cations and anions of the same surface. The material that is the object of the present invention uses the two charges -anions and cations- indistinctly and at the same time in each millimeter of the entire surface, so we go from talking about sides like the previous patents, to surface either sides or elements three-dimensional (orthotics and prostheses).

In addition, the tissue normalizing material can serve to help isolate us or minimize the effect created by magnetic fields that fluctuate 24 hours a day around us. This reduction or elimination is necessary for people with hypersensitivity or different diseases or simply to improve the quality of life by regulating the electromagnetic fields that collide with us daily. The material of the invention can be in clothing, bedding, walls and ceilings of houses or buildings in combination with paints, varnishes, cement, plaster, tiles, ducts, etc. or also forming part of the anti-shock protectors or covers of the mobile phones, computers or any similar electronic product and in the future to become part of the elements or structures of the electrical appliances themselves, of all kinds of machinery, of all kinds of vehicles, such as cars, airplanes, space shuttles or rockets since many people has diagnosed or undiagnosed pain, dysfunctions, limitations or problems, in such a way that the normalizing material can improve the comfort or the feeling of well-being of the user.

The material, once adhered or embedded in the surface of the textile fabric, orthosis or prosthesis, is difficult to separate. Both the surface of the textile, orthosis or prosthesis can be totally or partially covered with the material object of the present invention.

Throughout the description and the claims the word "comprises" and its variants are not intended to exclude other technical characteristics, additives, components or steps. For those skilled in the art, other objects, advantages and characteristics of the invention will emerge in part from the description and in part from the practice of the invention. The following examples and drawings are provided by way of illustration, and are not intended to restrict the present invention. Furthermore, the present invention covers all the possible combinations of particular and preferred embodiments indicated herein.

Brief description of the drawings

A series of drawings that help to better understand the invention and that expressly relate to an embodiment of said invention, which is illustrated as a non-limiting example thereof, will now be described very briefly.

FIG. 1 shows the electomyographic activation of the vastus medialis and biceps femoris muscles of the right leg of a basketball player with a strain on the biceps femoris, according to example 2 of the present specification.

Detailed explanation of an embodiment of the invention

The object of the present invention is a tissue normalizing material that is configured to generate a magnetic ordering of the magnetic moments so that all the magnetic moments are aligned in the same direction, but not in the same direction, due to what the material has in some sections, null magnetic fields creating little electrical conductivity since they fail to completely cancel the magnetization of the material creating its own permanent or almost permanent magnetic domains. The material of the invention does not produce a significant magnetism since it does not attract or repel itself, differentiating itself from other patents that use magnets that attract or repel each other depending on the polarities that face each other. The low magnetism produced by our material is powerful enough to affect cells when it comes into contact with the electromagnetic fields of living beings.

The tissue normalizing material can be inserted, adhered or embedded in a fabric that is formed by natural or synthetic fibers or a combination of both that allow a significant variety of points and patterns. The tissue normalizing material of the present invention makes it possible to create breathable, light, highly resistant fabrics, with great resilience and compliance, providing rigid structures that can produce more or less elasticity in the fabrics and that do not represent a discomfort for the user.

The technical textiles developed so far are designed primarily to collect information from the body and help protect it from cold, heat or fire, orthoses to support body segments due to injury (ankle sprain) or fracture (3D orthosis) and function of prostheses is to replace damaged joints or teeth that do not perform their function. None of them have been trained with the physical properties like that of the present invention to be able to act on the different systems and different functions of the body both globally and analytically.

The substance does not act directly on skin nerve endings. It acts on the epidermal cells and it is these that influence the A-Beta, A-Delta and C nerve endings.

Embryologically, the circulatory system was created first to be able to nourish the fetus and later and following the vessels, the nervous system was created to be able to perform vasoconstriction or vasodilation when necessary. Therefore, by acting on the innervation through the skin cells, it influences the vascularization and therefore the temperature.

In order to understand the effects of this material, it is necessary to take into account the importance of the correct oxygenation of the body tissues and influencing the correct pH of each part of the body. If a correct depolarization of the Ca ²⁺ ions does not take place, waste substances accumulate creating surface electromagnetic fields. aberrant so that the pH becomes more acidic creating inflammation, restriction of mobility, vascularization, dysfunctions and pain. This excessive accumulation of Ca ²⁺ is the cause of pain and if this accumulation is maintained, the pain can become chronic.

If the depolarization is correct, the aberrant electromagnetic fields disappear, the pH of the area increases, so it becomes alkaline, increasing oxygen in the tissues creating a quality vascularization and improving the oxidation of the tissues, improving their motility and mobility. reason why the dysfunctions and the pain will diminish creating a plurality of magnetic fields in the surface where it is. For example, if the textile where the tissue normalizing material is found is a T-shirt, when the T-shirt is placed and comes into contact with the superficial aberrant electromagnetic fields, different magnetic fields are created that eliminate the accumulation of Ca ²⁺ in different parts of the body. . As the accumulation of calcium and other waste products normalizes, the stimuli they produce on the tissue normalizing material will vary, so the magnetic fields will also vary. This solution is different from that proposed in the state of the art, where magnets - previously magnetized elements - are used that would produce few, permanent, strong and therefore deep magnetic fields without fluctuating, although the accumulation of Ca ²⁺ varies.

Therefore, by creating magnetic fields on suitable surfaces in each patient, calcium depolarization of painful areas is favored by acting on the electromagnetic fields of the cells, on free radicals and on those that begin to accumulate and are not yet painful. preventing the generation and / or accumulation of excessive waste substances. Helping to eliminate them in each patient, it favors the elimination of aberrant electromagnetic fields and the depolarization of calcium and that excessive waste substances are not generated and / or accumulated, helping to eliminate them and improving homeostasis.

The function of the tissue normalizing material is to correctly modulate tissue stimuli, helping to eliminate aberrant magnetic fields produced by internal dysfunctions of the organism or by external electromagnetic fields that collide with us daily to improve the oxygenation of body tissues, facilitating their recovery and favoring the correct function of these tissues and improving their performance, reducing the pain perceived by the patient, normalizing the temperature and helping to consolidate bone fractures or improving the state of the bone. It allows a joint rehabilitation, helping to avoid the loss of muscle mass in the immobilized area, being able to act for long periods of time, speeding up the recovery time of patients by oxygenating the immobilized or replaced area, thanks to the creation of stimuli that They influence aberrant electromagnetic fields that facilitate depolarizations to occur during immobilization time where it is difficult for them to occur.

The structure of the textile contains different fabrics to take advantage of the properties of each of the fabrics included in the invention and thus define a suitable textile combining said fabrics for each user, whether they are athletes who need a breathable, comfortable material without limiting movements of large amplitudes, difficult to unweave, that weighs little, protects you and can be a complete garment like the case of motor pilots, in addition to a modern and striking design.

On the other hand, a totally different textile would need to be used for a bedridden person with pressure ulcers or bedsores to use, where part of the tissue must have certain characteristics or properties, especially in pressure areas, creating seamless, stable textiles, with greater production capacity as there are more and more elderly people in our society, improving the feeling of comfort.

In addition, it can be used for users who want to feel better since it can help normalize the heart rate since the stimulation of the heart is also electrical and therefore electromagnetic or who simply want to feel more comfortable improving the feeling of well-being.

The tissue normalizing material can be incorporated into the textile by adhering to it. The textile is first generated and then the tissue normalizing material is attached or inserted or the tissue normalizing material adheres to the threads that will later make up the textile. The tissue normalizing material can be part of the textile or of the glue that is adhered to the textile. It can be used in bandages that are usually used in medicine, nursing or physiotherapy such as rigid bandages, rigid adhesive (strapal), elastic (crepe), elastic adhesive (tensoplasi kinesiology tape or Dinamic Tape®), cohesive or any other bandages or dressings on the market.

The same procedure will be carried out for the manufacture of surgical elements, orthotics or prostheses. The tissue normalizing material could be part of the material of the different elements of the orthosis or prosthesis or once created, a layer of tissue normalizing material would be applied using the solid, liquid or gaseous medium. Logically, the tissue normalizing material proposed by the invention could be integrated into the actual manufacturing process of surgical elements, orthoses or prostheses during their creation.

These properties allow the tissue normalizing material to also be part of the prosthesis, orthosis or textile fastening systems, whether they are garments that adhere to the body in specific parts and can be used in the manufacture of inner and outer garments, sports garments, clothing suits. swimwear, baby clothes or be part of fashion trends. Additionally, it can be used for health purposes (prevention and treatments) and sports (assessment, prevention, treatment, rehabilitation and performance) or in any other format of clothing or accessories that is considered appropriate to improve the comfort or the feeling of well-being of the user, being able to be included in the fashion market. Example 1

Three electromyographic (EMG) measurements were performed on the multifid muscles when performing a hip extension in the prone position for 5 seconds each repetition in 3 women with left low back pain. Subsequently, the textile pieces with the tissue normalizing material were placed on the back, creating multiple magnetic fields of very low intensity and the muscle activation tests were carried out again.

Placing the tissue normalizing material significantly increased the force and improved the coactivation between the muscles. This coordination in activation helps to prevent injuries. The data obtained are presented in Table 1:

-Table 1- Example 2

Electo-myographic activation of the vastus medialis and biceps femoris muscles of the right leg of a basketball player with overload on the biceps femoris was assessed. The player was asked to perform three controlled jumps. Subsequently, the textile with the tissue normalizing material was placed on the lumbar spine and the electromyographic evaluations were carried out in another three jumps. As can be seen in the graph, the activation of the biceps femoris decreased from 32.58 to 23.64% compared to the vastus medialis, improving and normalizing muscle activation in the jump time. The percentages obtained are presented in Figure 1.

From the above examples it can be concluded that the present invention allows: (a) to improve joint mobility of internal hip rotation, ankle dorsiflexion and hip joint flexion; (b) normalize the autonomic nervous system; (c) it decreases the perceived pain of the spine; (d) normalize dermal body temperature; (e) increases the maximum and average force in isometry; and (f) improves rear chain flexibility.

Claims

1.- A tissue normalizing material configured to normalize aberrant electromagnetic fields of body tissues and consisting of a ferrimagnetic material or a combination of ferrimagnetic materials inserted, adhered or embedded on a base tissue characterized by: said ferrimagnetic material, or A combination of ferrimagnetic materials, once inserted, adhered or embedded on the base tissue, induces a plurality of surface magnetic fields by coming into contact with the electromagnetic fields of a living being with a force of less than 2 gauss randomly distributed on said base tissue .

2.- The material according to claim 1 where the combination of minerals is inserted, adhered or embedded in a leather, natural or synthetic or in a knitted, flat, complex fabric and / or combinations thereof and which is composed of a plurality of natural and / or synthetic fibers.

3.- The material according to claim 2, wherein the natural and / or synthetic textile fibers that form the fabric are chosen from the group comprising natural textile fibers of vegetable origin, natural textile fibers of animal origin, cotton, nylon, polyester, polypropylene and elastane or combinations of them.

4. The material according to one of claims 1 to 3, wherein the combination of minerals comprises iron, cobalt, nickel, manganese, copper, oxides of said compounds and / or binary or ternary combinations of them.

5. The material according to any one of claims 1 to 4 wherein the combination of minerals can be adhered, inserted or embedded to the tissue in solid, liquid or gaseous format.

6. The material according to any one of claims 1 to 4, wherein the mineral combination is arranged in an adhesive film that is bondable with the fabric.

7.- Use of the material of claims 1 to 6 in the manufacture of textiles, orthotics, surgical elements and prostheses.

8.- Use of the material of claims 1 to 7 in the manufacture of structures, elements, supports, components, accessories, fabrics and protections that help to improve the comfort and well-being of the user.