EP4359019A1

EP4359019A1 - Wound covering, for increasing the no concentration in wounds

Info

Publication number: EP4359019A1
Application number: EP22716081.9A
Authority: EP
Inventors: Ernesto Rafael OSORIO BLANCO; Sara Schröder; Birthe KRAMER
Original assignee: Beiersdorf AG
Current assignee: Beiersdorf AG
Priority date: 2021-06-23
Filing date: 2022-03-22
Publication date: 2024-05-01
Also published as: AU2022298911A1; WO2022268369A1; WO2022268368A1; DE112022003204A5

Abstract

The present invention describes a wound covering and a method for increasing the NO concentration in a wound by means of a wound covering that contains fibers in which a percentage of particulate minerals and/or carbides is embedded.

Description

Beiersdorf AG

Wound covering, to increase the NO concentration in wounds

The present invention describes a wound covering and a method for increasing the NO concentration in a wound by means of a wound covering having fibers in which a proportion of particulate minerals and/or carbides are embedded.

Plasters are medical products that are applied to a wound and seal it. The main goal of a plaster is to prevent dirt and bacteria from entering the body and to support the natural wound healing process.

A wound covering, also popularly known as a plaster, usually consists of a carrier that carries a wound dressing that forms the wound contact layer. The carrier is generally attached to the surface of the body with the aid of an applied skin-compatible adhesive, with the wound contact layer coming to lie over the wound to be covered. It is also possible to make the wound cover not self-adhesive and to fix it with bandages on/over the wound.

The wound contact layer is typically the site of a wound dressing that interacts with the wound. It is the part (surface area) of the dressing that faces the wound. Their task is to prevent, for example, fibers from the wound dressing from penetrating the wound or the carrier from sticking to the wound. The wound contact layer can consist of different materials, but polyethylene, polylactide, viscose nonwovens are usually used.

Due to the direct exchange with the body, it is advantageous if the wound contact layer has a high level of biocompatibility, since possible additional inflammatory processes and allergic reactions can be avoided, which leads to a better wound healing process.

There are numerous terms for biocompatibility. In the context of this invention, biocompatibility means: the ability of a material to fulfill its desired function (in this case to support the wound healing process) without causing undesired local or systemic effects.

The biocompatibility of a substance not only depends on its intrinsic material properties (hydrophilicity, charge, mechanical properties, etc.), but also on the environment (location) and desired function. One way to improve the biocompatibility of a material is to change its surface.

Antimicrobial agents have long been known to those skilled in the art. Basically, all substances above a certain concentration have a cell-damaging effect and thus also against microbes (e.g. bacteria, fungi), i.e. antimicrobial. Antimicrobial agents are characterized by the fact that the cell-damaging effect on microbes is greater than on the cells of higher organisms (humans, mammals, fish, etc.).

A substance that is very interesting for wound healing, which not only promotes wound healing but also has antimicrobial properties, is nitric oxide (NO).

NO is known to contribute positively to wound healing through various mechanisms of action:

NO promotes angiogenesis: the blood vessels are encouraged to form new ones. NO has an anti-inflammatory effect: the immune system is stimulated.

NO has an antimicrobial effect: for example against Pseudomonas aeruginosa, Acinetobacter baumannii, Escherichia coli, Klebsiella pneumoniae and Staphylococcus aureus (also MRSA species).

By increasing the NO production in the wound, the blood circulation in the wound is also increased, which increases the oxygen content of the wound and effectively accelerates wound healing (reference: https://doi.org/1Q.1Q16/sQQ76-6879f 05 )96048-5. httos://doi . oro/10.1038/s41598-5 and https://doi.org/10.1016/i.niox.2QQ9.10.0Q6)

Plaster systems that release NO and thereby contribute to wound healing are already known from WO2014188174A. Here, the patch system releases NO formed by RedOx reactions into the wound, resulting in a costly and complex product build-up.

Natural minerals and carbides are known to reflect, absorb, emit, cause wavelength interactions (wavelength shifting, amplification, cancellation) and polarize electromagnetic radiation. Minerals and carbides in the form of particles are particularly preferred because they have a particularly high surface energy. The shape and size of the particles are particularly interesting, since they can effectively influence the effectiveness, for example through the anisotropic influence of the particle shape. The best-known naturally occurring minerals include SiC, Si02, CaC2, Ti02, Zr02 and AI203.

The object of the invention is to provide a cost-effective wound covering which can increase the NO content in the wound by utilizing ambient radiation, in particular light and body heat.

The object is achieved by a wound covering having a carrier layer, a wound dressing which is fixed to the carrier layer and forms the wound contact layer with its free surface,

- where the wound dressing has a content of synthetic fibers,

- a proportion of particulate minerals and/or carbides being embedded in the synthetic fibers,

- where the fibers are 90 - 99% by weight, based on the total weight of the synthetic fibers, made of a polymer or mixtures of polymers from the group of acrylates, acetates, elastane (especially Lycra, Spandex), polyester, polyamides (especially nylon), viscose (particularly rayon), PU, PE, PET, PP, cellulose or semi-cellulose materials,

- the content of minerals and/or carbides being 1-10% by weight relative to the total weight of the synthetic fibers and

- wherein the maximum particle size of the minerals and/or carbides is less than 1.5 mm and optionally an adhesive mass applied to the backing layer for fixing the wound dressing on the backing and/or fixing the wound covering on the skin.

The present invention offers the advantage that one's own body heat is used to increase NO production within the wound.

In wounds, NO is usually produced enzymatically by macrophages and fibroblasts. NO can be produced from the guanidine group in arginine in an oxidative process. An alternative to this biologically internal process is the production of NO by radiation. For this purpose, nitrite-rich compounds on the skin are photolytically converted into NO. This is also a natural process and can be caused by UV-A radiation, however, UV imaging of wounds can be counterproductive as they can often lead to scarring. In order to circumvent this problem and at the same time use the positive properties of NO, wound coverings according to the invention can be used to promote the self-production of NO in the covered wound.

Wound coverings according to the invention can be used for this, having a content of fibers that enable the absorption and reflection of electromagnetic radiation. Such fibers are known from WO 2020150493 A1. As a result, the UV-A rays are converted into other wavelengths and replaced by wavelengths in the NIR or FIR range, which promote the body's own NO production.

In another embodiment of the invention, the wound dressing used in a wound covering according to the invention is doped with minerals and/or carbides, in particular with SiC, Si02, CaC2, Ti02, Zr02 and/or Al203, by embedding it in the interstices of the wound dressing from a lacquer layer applied to the wound dressing or by incorporation into the respective material of the wound contact layer.

The subject of a further invention is a method for increasing the NO concentration in a wound by means of a wound covering comprising:

a backing layer,

A wound dressing that is fixed to the carrier layer and forms the wound contact layer with its free surface,

Wherein the wound dressing has a content of SiC, SiO 2 , CaC 2 , TiO 2 , ZrO 2 and/or Al 2 O 3 and

Optionally an adhesive mass applied to the carrier layer, the wound being covered with the wound covering.

The wound dressing in a wound covering according to the invention preferably has a special wound contact layer that is characterized by biodegradability and high biocompatibility and/or has a wound contact layer with anti-inflammatory properties and/or has a wound contact layer with bacteriostatic properties.

According to the invention, the carrier system is advantageous, which is breathable at the same time, but also enables moist wound healing as a semi-occlusive barrier. A wound dressing according to the invention that promotes wound healing, creates a favorable environment for wound healing through physical processes, increases blood circulation in the area surrounding the wound, increases the oxygen content of the wound by releasing or producing nitrogen monoxide using (body) heat radiation

The NO release within a wound ensures better blood circulation, which promotes faster healing.

In principle, all rigid, flexible and elastic fabrics made of synthetic and natural raw materials are suitable as carrier material.

Textiles such as wovens, knits, scrims or fleeces, further nets, foils, foams and laminates made from the above materials and papers may be mentioned by way of example.

The carrier material is preferably a film, a woven fabric or a fleece, particularly preferably with a thickness of 20 to 200 μm, in particular with a basis weight of 20 to 200

In principle, both natural and synthetic carrier materials can be considered. The carrier material is preferably selected from the group consisting of cotton, viscose, polypropylene, polyesters, polyamides, PET, PVC, polyethylene, polyurethanes, silicones and polylactic acid. The carrier material is preferably selected from the group consisting of cotton, viscose, polyesters, polyethylene and polyurethanes. g/m2.

The carrier material is particularly preferably a polyurethane film, a polyethylene film, a polyester fleece, a woven fabric made from viscose, polyester or cotton or a woven fabric made from any mixtures of viscose, polyester and/or cotton.

The backing material preferably has an air- and water-vapor-permeable but water-impermeable layer of adhesive with a thickness of about 10 to 200 μm.

Preference is given to backing materials which, after application of the adhesive, can be used in such a way that they meet the requirements for a functional skin contact.

These materials can preferably be pre-treated or post-treated. Common pre-treatments are plasma or corona treatment and hydrophobing; Common post-treatments are calendering, tempering, laminating, punching, covering and sterilizing. The wound dressing can include a substrate for absorbing wound exudate.

Suitable materials for wound dressings are viscose fibers, which can consist of cellulose, bamboo and similar materials. Other suitable polymers for the production of wound dressings are PLA (polylactide), PHA (polyhydroxyalkanoate) and PP (polypropylene).

Different encapsulated active ingredients can also be stored in the wound dressings, with the active ingredients also promoting wound healing. In particular, antimicrobial active ingredients, active ingredients that promote wound healing, active ingredients that relieve pain are advantageous.

The synthetic fibers used in wound coverings according to the invention are preferably produced by common manufacturing processes (extrusion, spinning), for which purpose the main fiber material is dissolved in suitable ionic solvents and minerals and/or carbides are added to this solution. These resulting suspensions are spun or extruded to give the synthetic fiber to be used according to the invention.

These synthetic fibers can be processed into the wound dressing according to the invention as a woven fabric or fibrous web (particularly a nonwoven fabric).

Claims

patent claims

1. Wound covering comprising a carrier layer, a wound dressing which is fixed on the carrier layer and forms the wound contact layer with its free surface,

- where the wound dressing has a content of synthetic fibers,

2. Method for increasing the NO concentration in a wound by means of a wound covering comprising: a carrier layer, a wound dressing which is fixed to the carrier layer and forms the wound contact layer with its free surface,

- where the wound dressing has a content of synthetic fibers,

- the content of minerals and/or carbides being 1-10% by weight relative to the total weight of the synthetic fibers and - where the maximum particle size of the minerals and/or carbides is less than 1.5 mm and optionally an adhesive mass applied to the backing layer for fixing the wound dressing on the backing and/or fixing the wound covering on the skin, the wound being covered with the wound covering will.

3. Wound dressing according to claim 1 or method according to claim 2, characterized in that the cellulose or semi-cellulose of the synthetic fibers was produced from renewable raw materials, in particular bamboo, soya, wood or sugar.

4. Wound dressing according to at least one of the preceding claims, characterized in that the fibers have one or more natural, in particular minerals and/or carbides from the group SiC, SiO 2 , CaC ₂ , T1O 2 , ZrO ₂ and Al ₂ O ₃ .