RU2596452C1 - Method for production of textile material containing nano- and microencapsulated biologically active substances of prolonged release(versions) - Google Patents

Abstract

FIELD: textile.

SUBSTANCE: invention is designed to produce intensified and prolonged therapeutic action of biologically active substances on a patient's skin in affected areas when treating bedsores and burns. Said technical result is achieved due to treating textile material with nano- and microemulsion with included encapsulated biologically active substances in the form of natural sea-buckthorn or silver fir oil. To prepare nano-and microemulsion the following components are used, g/l: anionic surfactant 2-5, nonionic surfactant 0.1-1.0, natural sea buckthorn (fir) oil 1-10, cationic polyelectrolyte 3-7, water up to 1 l, nano- and microcapsules are affixed on material surface by additional impregnation with solution of anionic polyelectrolyte.

EFFECT: produced textile material is used for production of anti-decubital and fluidized articles.

6 cl, 1 tbl

Description

The invention relates to methods for the production of textile material intended for direct contact with the skin, and for use in medicine or in domestic conditions, namely, the creation of therapeutic and prophylactic agents with natural components for external use with anti-inflammatory, anti-decubitus and anti-burn effects, and can be used in the manufacture of textile material for decubitus and anti-burn products, for example, in the form of elements of bed and underwear.

Currently, in connection with complex diseases, including surgical ones, a large number of bedridden patients with different etiologies are observed. In medicine, the demand for drugs for the treatment of pressure sores and burns is growing rapidly.

Pressure ulcer-necrosis of the skin, due to prolonged compression of soft tissues with impaired trophism, mainly occurs in bedridden patients.

Unfortunately, modern scientific research is mainly aimed at the development of new methods of treating pressure ulcers that have already formed. Treatment of pressure sores, and more importantly, prevention should be started as soon as possible. Pressure sores and burns are associated with significant pain.

Topical treatment for an emerging pressure sore ulcer includes a thorough toilet area of the changed skin. Depending on the stage of pressure sores, adhesive polyurethane dressings (transparent films) are applied to the affected area, which provide oxygen from the atmosphere to the affected area and evaporation of moisture.

Recently, there has also been an increasing number of inflammatory and burn effects on the skin. Therefore, the prevention and treatment of inflammatory and burn diseases of the skin requires a scientific and convenient everyday approach to solving this issue.

Herbal remedies for the treatment of pressure sores are widely known:

- Vegetable fatty oils containing carotenoids (sea buckthorn, mountain ash, rosehip oil and others) have a wound healing ability due to the presence of a complex of natural biologically active substances, in particular carotenoids, and are widely used in folk medicine in the treatment of pressure sores. (Collection of traditional medicine and alternative methods of treatment, G.Z. Minejyan, M., 1991).

- Anti-decubitus oil, RF patent No. 2416425, publ. 04/20/2011.

In the treatment of skin burns in folk medicine, common flax has a reliable fungicidal and keratolytic effect.

Known agent having anti-inflammatory, antiparasitic, antifungal and anti-burn effect based on fir oil, characterized in that it contains vegetable, or linseed, or cedar oil, 10-20% alcohol tincture of propolis and fir oil the rest (RF patent No. 2192273 published on November 10, 2002).

The therapeutic effect of fir oil is quite large, for example, in particular, with pneumonia, inhalation with fir oil can be combined with rubbing the chest. It is also widely used for radiculitis, plexitis, burns, etc. in the form of ointment and grinding (Handbook of folk and alternative medicine, 1996, Tula, "Ariel", from 171-172).

Sea buckthorn oil and fir oil are biologically active substances that have a healing effect on the affected areas of the skin with their direct use in the case of treatment and prevention of pressure sores and burns, respectively.

However, the direct effect of these substances on the affected areas is short-term and requires constant physical and mechanical effects on these areas, which creates inconvenience in their use and reduces the expected therapeutic effect.

There are various bedding and underwear made of non-woven material. For example, manufactured imported decubitus sheets (http://www.terviseabi.ee/) are 100% polyester non-woven material.

The therapeutic and prophylactic effect of the use of such products has a minor and short-term effect on the skin of a constantly lying patient (in the case of using anti-decubitus products) and on the patient's skin (in the case of using anti-burn products). It is often necessary to change these products in a bedridden patient and in a patient with burn injuries, which is simply unacceptable under such patient care conditions, since frequent replacement of underwear and bedding can bring unreasonable pain and suffering to patients.

Also known is “Nano-emulsion with biologically active substances” (RF patent 2362544 dated 02.27.2010), which relates to the pharmaceutical, food industry and cosmetology, in particular to the field of creating nano-emulsion systems used as carriers of active substances in pharmaceutical compositions, and also in the manufacture of food and cosmetic products. A transparent or slightly opalescent water-in-oil nanoemulsion for oral, transdermal use, for use in ophthalmic practice, with biologically active compounds is characterized by the fact that it contains 35-80% hydrophobic phase, 17-43% surfactant, 3-7% co-solvent and 1-15% aqueous phase, a mixture of mono-, di- and triglycerides with mono- and di-esters of saturated and unsaturated fatty acids is used as the hydrophobic phase, the surfactant is selected from the group of nonionic surfactants active substances - sorbitans in a mixture with an auxiliary surfactant (from the group of polyhydroxyalkanes or monohydric alcohols). The nanoemulsion is biocompatible and well tolerated, and also provides uniform, sustained release of the active substance.

But this emulsion cannot be used to implement the proposed method for the manufacture of textile material with medicinal properties, since it is intended only for oral and direct transdermal use.

When conducting a comparative search from the prior art is not revealed closest to the proposed technical solution.

Achievable when using the present invention, the technical result is to increase the therapeutic effect and increase the duration of exposure to the skin of the patient in the affected area when used for bedridden patients and for patients with burn injuries, as well as maintaining the therapeutic effect even after 5 washes.

The technical result is achieved by options.

The first option is for the treatment and prevention of pressure sores:

in a method for the production of textile material containing biologically active substances with delayed release, by sequentially treating it with nano- and microemulsions containing microcapsules, with encapsulated biologically active substances included in them, pressing and then fixing nano- and microcapsules on the surface of the material, pressing and drying , as a biologically active substance, natural sea buckthorn oil is used, the nano- and microemulsion is prepared as follows: t water, then sequentially injected, with constant stirring at a speed of 900-6500 rpm, anionic surfactant, nonionic surfactant, natural sea buckthorn oil and gradually increase the volume of microemulsion to a predetermined volume with water, mix thoroughly for 1-5 minutes to obtain homogeneous nano- and microemulsions, after which a cationic polyelectrolyte is added to the obtained nano- and microemulsions and again everything is thoroughly mixed for 0.5-1 min, while the above components are used from the calculation, g / l:

anionic surfactant 2-5 nonionic surfactant 0.1-1.0 natural sea buckthorn oil 1-10 cationic polyelectrolyte 3-7 water up to 1 l

Then, textile material is lowered into the impregnation bath with the prepared nano and microemulsion, kept for 15-30 s and squeezed, the nano and microcapsules are fixed on the surface of the material by additional impregnation at room temperature for 30-60 with an aqueous solution of anionic polyelectrolyte with concentration of 5-10 g / l, followed by extraction to 70-100% humidity, after which they are dried at a temperature of 60-100 ° C until completely dry.

For the preparation of nano- and microemulsions, at least an anionic surfactant is used — carboxypaw AF 6.35 or surfactant AF 6.90, as a nonionic surfactant — Neonol AF 9/10, and as a cationic polyelectrolyte — VPK-402 or Kaustamin M.

The fixing of nano- and microcapsules on the surface of a textile material is carried out at least by treating it with an aqueous solution of Akremon B-1 anionic polyelectrolyte or sodium alginate.

The second option is for the treatment and prevention of burns:

- in a method for the production of textile material containing biologically active substances with sustained release, in which the textile material is treated with nano- and microemulsions containing nano- and microcapsules, with encapsulated biologically active substances included, followed by squeezing and fixing the microcapsules on the surface of the material, final extraction and drying, natural fir oil is used as a biologically active substance, nano- and microemulsion are prepared as follows: an water bath is poured, then anionic surfactant, nonionic surfactant, natural fir oil are introduced successively with constant stirring at a speed of 900-6500 rpm, and the reaction mixture is gradually brought up to a predetermined volume with water, everything is thoroughly mixed for 1-5 min until a homogeneous nano- and microemulsion is obtained, after which a cationic polyelectrolyte is added to the emulsion obtained and again everything is thoroughly mixed for 0.5-1 min, while the above components are used from the calculation, g / l:

anionic surfactant 2-5 nonionic surfactant 0.1-1.0 natural fir oil 1-10 cationic polyelectrolyte 3-7 water up to 1 l

Then, textile material is lowered into the impregnation bath with the prepared nano- and microemulsion, held for 15-30 s and squeezed, the microcapsules are fixed on the surface of the material by impregnating it at room temperature for 30-60 with an aqueous solution of anionic polyelectrolyte with a concentration of 5-10 g / l, followed by extraction to 70-100% humidity, after which they are dried at a temperature of 60-100 ° C until completely dry.

For the preparation of microemulsions, at least anionic surfactants — carboxypav AF 6.35 or surfactants AF 6.90 — are used, as a nonionic surfactant — Neonol AF 9/10, and as a cationic polyelectrolyte — VPK-402 or Kaustamin M.

The nano- and microcapsules are fixed on the surface of the material by at least treating it with an aqueous solution of Akremon B-1 anionic polyelectrolyte or sodium alginate.

To achieve the claimed technical result, the proposed method encapsulates biologically active substances: in the first embodiment, sea buckthorn oil, in the second embodiment, fir oil.

Encapsulation is a process in which the smallest particles of a liquid, solid or gaseous active ingredient (in the present invention it is a liquid ingredient - sea buckthorn and fir oil) are packed in another material (a shell that protects it from environmental influences). The capsule is a miniature container (nano- or micro-sized) that protects the contents from evaporation, oxidation and contamination until it is released when certain conditions are met (Layer-by-layer method. For details on the process, see Ariga, K. Layer-by- layer assembly as a versatile bottom-up nanofabrication technique for exploratory research and realistic application / K. Ariga, JP Hill, Q. Ji // Phys. Chem. Chem. Phys. - 2007. - V. 9. - P. 2319- 2340).

In the present invention, encapsulation is carried out as follows: for this, water is poured into the impregnation bath, then anionic surfactant, nonionic surfactant, natural sea buckthorn oil (for the first embodiment) or natural fir oil (for the second option) and gradually bring the volume of the reaction mixture to a predetermined volume with water, mix everything thoroughly for 1-5 minutes (necessary and sufficient time for thorough mixing and obtaining a uniform nano and microemulsions), after which a cationic polyelectrolyte is added to the resulting nano and microemulsions and again everything is thoroughly mixed for 0.5-1 min (necessary and sufficient time for thorough mixing and obtaining a homogeneous nano and microemulsion), while the above components use from calculation, g / l:

anionic surfactant 2-5 nonionic surfactant 0.1-1.0 natural sea buckthorn or fir oil 1-10 cationic polyelectrolyte 3-7 water up to 1 liter

Get nano- and microemulsion containing nano- and microcapsules with biologically active substances - either natural sea buckthorn oil (for the first option), or with natural fir oil (for the second option).

In the proposed composition of the reaction mixture, the encapsulation of biologically active substances occurs in several stages. At the initial stage, the nucleation of spherical micelles occurs, which subsequently form more complex structures. When an oppositely charged polyelectrolyte, for example, such as PDADMAH (VPK-402), is introduced into the system, an electrostatic interaction occurs between the cationic polyelectrolyte and the anionic surfactant. This leads to the formation of “soft” nano- and microcapsules, and accordingly stabilizes the system under consideration. In the process of impregnating textile material with anionic polyelectrolyte, the outer shell of the nano- and microcapsules is formed, providing its mechanical strength and resistance to external influences.

The production of textile material for the manufacture of anti-decubitus products (first option) containing a biologically active substance in the form of encapsulated natural sea buckthorn oil is carried out as follows.

Textile material is lowered into the impregnation bath with the prepared nano- and microemulsion (with sea buckthorn oil); for impregnation, the material is kept in nano- and microemulsion for 15-30 s, which are necessary for diffusion of the nano- and microemulsion into the depth of the fibrous textile material. Then squeeze.

The nano- and microcapsules are fixed on the surface of the textile material by processing it at room temperature for 30-60 with an aqueous solution of anionic polyelectrolyte with a concentration of 5-10 g / l, followed by extraction, and then drying is carried out at a temperature of 60-100 ° C to completely dry.

The production of textile material for the manufacture of anti-burn products (second option) containing a biologically active substance in the form of encapsulated natural fir oil is as follows.

Textile material is lowered into the impregnation bath with the prepared nano- and microemulsion (with fir oil); for impregnation, the material is kept in nano- and microemulsion for 15-30 s, which are necessary for diffusion of the nano- and microemulsion into the depth of the fibrous textile material. Then squeeze.

The microcapsules are fixed on the surface of the material by treating it at room temperature for 30-60 with an aqueous solution of anionic polyelectrolyte with a concentration of 5-10 g / l, followed by pressing, and then drying is carried out at a temperature of 60-100 ° C until completely dry.

The required volume of nano- and microemulsions for processing fibrous material depends on the degree of extraction and the surface density of the textile material. For a fabric with a surface density of 100 g / m ² with a spin of 100%, 100 g of nano- and microemulsions are required to process textile material in an amount of 1 m ² .

In both the first (with sea buckthorn oil) and the second (with fir oil) versions, carboxypow AF 6.35 or surfactant AF 6.90 can be used as anionic surfactant, Neonol AF 9/10 as a nonionic surfactant, and as a cationic polyelectrolyte VPK-402 or Caustamine M.

Use as anionic surfactant - carboxypav AF 6.35 or surfactant AF 6.90, as a nonionic surfactant - Neonol AF 9/10, as a cationic polyelectrolyte - VPK-402 or Kaustamine M provides a uniform and time-stable nano- and microemulsion and the formation of a stable soft shell microcapsules.

Using for the preparation of nano- and microemulsions of anionic surfactants in an amount of 2-5 g / l, nonionic surfactants in an amount of 0.1-1.0 and natural fir oil in an amount of 1-10 g / l allows to obtain a nanoemulsion with the required particle size (in nanometer range), in this case, the most effective emulsification of both sea buckthorn and fir oils occurs, with obtaining capsules of nano- and micrometer size.

In the first and second options, the nano- and microcapsules are fixed on the surface of the material by treating it with an aqueous solution of Akremon V-1 anionic polyelectrolyte or sodium alginate, which do not require additional preparation stages and, which is not least important, which are domestic products.

Textile material prepared.

Anti-decubitus or anti-burn products are made from the textile material obtained by the proposed method, for example, for bedridden patients and for patients with burn injuries.

The physical process of exposure to problem areas of the skin when using products from textile material produced by the proposed method will be as follows.

The therapeutic effect on problem areas of the skin, in the case of non-volatile sea buckthorn oil, begins immediately after the patient begins to move, that is, in the process of mechanical action on the treated textile material. The release of volatile fir and sea buckthorn oils begins with a slight thermal and mechanical effect, as soon as the patient is put on knitted underwear or spread a sheet under the back. In this case, capsules of various sizes begin to break down with the release of encapsulated biologically active substances.

The invention is as follows.

Example 1

300 ml of water is poured into the impregnation bath, then anionic surfactant - carboxypav AF 6.35 in the amount of 2 g, nonionic surfactant - Neonol AF 9/10 in the amount of 0.3 g, natural sea buckthorn oil in the amount of 3 g and gradually added at a constant rate are added with constant stirring. while stirring, bring the volume of the mixture to 1 l with water; everything is thoroughly mixed for 5 minutes until a homogeneous microemulsion is obtained; then to the obtained microemulsion, add VPK-402 cationic polyelectrolyte in an amount of 7 g and again everything is thoroughly mixed for 0.5 min.

Then, textile material is loaded into the impregnation bath with the prepared microemulsion (the product can also be used immediately) and kept for impregnation with the microemulsion for 30 s, after which the material is removed from the bathtub, squeezed to a weight gain of 100%, placed in another bathtub and microcapsules are fixed on the surface material by additional processing for 30 s in a solution of anionic polyelectrolyte Akremon with a concentration of 5 g / l at room temperature to form an interpolyelectrolyte complex due to electrostatic forces interaction, followed by a spin up to a gain of 100%.

The final drying is carried out at a temperature of 60 ° C for 7 min until completely dry.

Products with microcapsules applied are designed to restore blood circulation and skin structure, and the applied composition nourishes the skin with useful trace elements, which include about 35 sea buckthorn oil. Thus, there is a preventive anti-decubitus effect.

Example 2

300 ml of water is poured into the impregnation bath, then anionic surfactant - carboxypav AF 6.90 in the amount of 3 g, nonionic surfactant - Neonol AF 9/10 in the amount of 0.1 g, fir oil in the amount of 5 g and gradually with stirring is added with stirring with constant stirring. adjust the volume of the mixture to 1 liter with water; everything is thoroughly mixed for 1 min until a homogeneous emulsion is obtained; then to the emulsion obtained add cationic polyelectrolyte VPK-402 in an amount of 5 g and again everything is thoroughly mixed for 1 min.

Then a textile material (product) is loaded into the impregnation bath with the prepared nano- and microemulsion and soaked for impregnation with the microemulsion for 15 s, after which the material is removed from the bath, squeezed to a weight gain of 100%, placed in another bath and microcapsules are fixed on the surface the material by processing it for 60 s in an Akremon anionic polyelectrolyte solution with a concentration of 8 g / l to form an interpolyelectrolyte complex due to electrostatic interaction forces, followed by extraction to weight gain of 100%.

Final drying at 100 ° C for 4 minutes until dry.

Such textile materials have bactericidal and wound healing properties, it is recommended to use them in the processes of post-burn therapy.

Example 3

300 ml of water is poured into the impregnation bath, then anionic surfactant - carboxypaw AF 6.35 in the amount of 5 g, nonionic surfactant - Neonol AF 9/10 in the amount of 0.2 g, natural fir essential oil in the amount of 7 g and gradually added with successive stirring. with stirring, bring the volume of the mixture to 1 liter of water; everything is thoroughly mixed for 2 minutes until a homogeneous emulsion is obtained; then 3 g of cationic polyelectrolyte Caustamine M is added to the emulsion obtained and again everything is thoroughly mixed for 1 min.

Then, in the impregnation bath with the prepared nano- and microemulsion, textile material (product) is loaded and held for impregnation with a microemulsion for 20 s, after which the material is removed from the bathtub, squeezed to a weight gain of 100%, placed in another bathtub and the nano- and microcapsules on the surface of the material by processing it for 45 s in an Akremon solution of anionic polyelectrolyte with a concentration of 10 g / l to form an interpolyelectrolyte complex due to the forces of electrostatic interaction, followed by Imom to gain 100%.

Final drying is carried out at a temperature of 90 ° C for 6 min until completely dry.

This composition prevents suppuration of small wounds, helps restore the structure of the skin and is suitable for the treatment of most skin diseases, including pressure sores and burns. Obtained on the basis of the proposed method of production of textile materials, as well as products based on it were tested for resistance to washing.

The test results of various textile materials obtained using the proposed method are shown in the table.

All tests were carried out at room temperature.

The table shows that the textile materials obtained using the proposed method can withstand up to 12 washings without reducing their therapeutic effect, which is much more profitable than using ointments and disposable applications and dressings.

The prolonged release of medicinal oil, such as sea buckthorn, helps prevent the formation of pressure sores, improving blood circulation, and has a bactericidal effect. In this case, the degree of invasiveness of the skin of a disabled person (bed patient) is reduced.

The use of textile materials with immobilized encapsulated fir oil facilitates the patient's condition in the process of post-burn rehabilitation, the constant effect on the scarring wound allows to reduce the degree of contamination with its microbes, which reduces the possibility of keloid scar formation and, accordingly, the number of people with disabilities in the environment of burn convalescents. At the stage of general strengthening and physiotherapeutic treatment, prolonged release of fir oil has a positive effect on the formation of the skin scar, softens it, while it is possible to increase the range of movements in scarred joints, which reduces the number of people with disabilities in the environment of burn convalescents and greatly facilitates the lives of people with disabilities.

Thus, the claimed technical solution fully ensures the achievement of the claimed technical result.

Claims (6)

1. A method of manufacturing a textile material containing nano- and microencapsulated biologically active substances with sustained release, in which the textile material is treated with nano- and microemulsions containing nanocapsules and microcapsules, with encapsulated biologically active substances included in them, followed by squeezing and fixing nano- and microcapsules on the surface of the material, final extraction and drying, while natural buckthorn oil is used as a biologically active substance, n an ano- and microemulsion is prepared as follows: water is poured into the impregnation bath, then anionic surfactant, nonionic surfactant, natural sea buckthorn oil are added, with constant stirring at a speed of 900-6500 rpm, and the volume of nano- and microemulsion is gradually adjusted to the specified volume of water, everything is thoroughly mixed for 1-5 minutes until a homogeneous nano- and microemulsion is obtained, after which a cationic polyelectrolyte is added to the obtained nano- and microemulsion and again everything is thoroughly mixed for 0.5-1 min, this, the above components are used from the calculation, g / l:
anionic surfactant 2-5 nonionic surfactant 0.1-1.0 natural sea buckthorn oil 1-10 cationic polyelectrolyte 3-7 water up to 1 l
then the textile material is lowered into the impregnation bath with the prepared nano- and microemulsion, kept for 15-30 seconds and squeezed out, the nano- and microcapsules are fixed on the surface of the material by additional impregnation with a solution of anionic polyelectrolyte, and then drying is carried out until it is completely dry, the resulting textile material is used for the manufacture of anti-decubitus products. 2. The method according to p. 1, characterized in that for the preparation of nano- and microemulsions, at least anionic surfactants are used — carboxypav AF 6.35 or surfactants AF 6.90, as a nonionic surfactant — Neonol AF 9/10, as cationic polyelectrolyte - VPK-402 or Caustamine M. 3. The method according to p. 1, characterized in that at least Acremon B-1 or sodium alginate is used as the anionic polyelectrolyte. 4. A method for the production of textile material containing nano- and microencapsulated biologically active substances with sustained release, in which the textile material is treated with nano- and microemulsion containing nanocapsules and microcapsules, with encapsulated biologically active substances included, while being a biologically active substance natural fir oil is used, a nano- and microemulsion is prepared as follows: water is poured into the impregnation bath, then it is sequentially introduced, etc. and constant stirring at a speed of 900-6500 rpm, anionic surfactant, nonionic surfactant, natural fir oil and gradually bring the volume of the reaction mixture to a predetermined volume with water, all mix thoroughly for 1-5 minutes until a homogeneous microemulsion is obtained, after which the resulting emulsion is added a cationic polyelectrolyte and again everything is thoroughly mixed for 0.5-1 min, while the above components are used from the calculation, g / l:
anionic surfactant 2-5 nonionic surfactant 0.1-1.0 natural fir oil 1-10 cationic polyelectrolyte 3-7 water up to 1 l
then the textile material is lowered into the impregnation bath with the prepared nano- and microemulsion, kept for 15-30 seconds and squeezed, the microcapsules are fixed on the surface of the material by additional impregnation with the solution of anionic polyelectrolyte, after which drying is carried out until it is completely dry, while the resulting textile material Designed for the manufacture of anti-burn products. 5. The method according to p. 4, characterized in that for the preparation of nano- and microemulsions, at least anionic surfactants are used — carboxypav AF 6.35 or surfactants AF 6.90, as a nonionic surfactant — Neonol AF 9/10, as cationic polyelectrolyte - VPK-402 or Caustamine M. 6. The method according to p. 4, characterized in that at least Acremon B-1 or sodium alginate is used as the anionic polyelectrolyte.