WO2021195683A1

WO2021195683A1 - Device for neutralizing inert and single-celled pathogens

Info

Publication number: WO2021195683A1
Application number: PCT/AT2021/060112
Authority: WO
Inventors: Alireza ESLAMIAN; Martin SCHIFKO
Original assignee: Ess Holding Gmbh
Priority date: 2020-04-01
Filing date: 2021-04-01
Publication date: 2021-10-07
Also published as: AT522961B1; AT522961A4

Abstract

The invention relates to a device for neutralizing inert and single-celled pathogens (1) in an airflow, having a filter (2) which has open continuous pores (3) the internal walls (4) of which are coated, at least in portions, with positively charged ions (5). In order to design a device of the type described above such that, particularly when used as mouth and nose protection, the risk of infection can be lowered over the long term, it is proposed that a first part of the positively charged ions (5) is bound to a linker (7) which is attached to the internal walls (4) of the pores (3) by means of a water-soluble binding element (8).

Description

Device for neutralizing inanimate and unicellular pathogens

Technical area

The invention relates to a device for neutralizing inanimate and unicellular pathogens from an air stream with a filter which has open, continuous pores, the inner walls of which are coated at least in sections with positively charged ions.

State of the art

To neutralize inanimate and unicellular pathogens such as viruses or bacteria, it is known to use porous filters with open pores, for example made of a multilayer composite of cellulose, polyester and polypropylene. The surface of these filters is coated with positively charged ions in order to bind the negatively charged groups of the pathogen envelopes and thereby neutralize the pathogens themselves. The protective effect is created by immobilizing the pathogens on the filter surface. The disadvantage of such filters is that not all pathogens can be bound to the filter surface and thus there is still a reduced risk of infection and thus disease.

Presentation of the invention

The invention is therefore based on the object of reducing the risk of disease in the long term, a device of the type described above, in particular when it is used as mouth and nose protection. The invention achieves the stated problem in that a first part of the positive ions is bound to linkers which are attached to the inner walls of the pores via a water-soluble binding element. As a result of these measures, the pathogens bound to the positively charged ions do not remain on the surface of the filter, but can leave it after they have been at least partially neutralized by binding to the positively charged ion so that an immune response to the neutralized pathogen residues is possible. In this context, neutralization is understood to mean damaging the outer shell of the pathogen or impairing the function of at least some glycoproteins, which can also take place due to the chemical processes after leaving the filter. Because of the humidity available in the air flow, such as the air we breathe, the water-soluble binding elements are dissolved, so that the remaining linker is released together with the positively charged ion and the pathogen bound to it. However, this effect does not occur immediately, but rather with a time delay and gradually with an increase in the air humidity in the filter, so that the amount of neutralized pathogen residues released remains low. Depending on the binding element used, the heating by the air flow, such as breathing air, can promote the loosening of the binding element. For example, starch molecules can be used as a water-soluble binding element. Suitable linkers between starch and the positively charged ions are well known to the person skilled in the art, depending on the type of ions.

In order to further promote the loosening of the binding elements, the pores in the area of the water-soluble binding elements can have a hydrophilic coating. The air humidity bound in the air flow can thus settle more evenly on the inner walls of the pores, so that a selective loosening of only a few binding elements can be avoided in favor of a uniform loosening behavior. At the same time, pathogens can be prevented from collecting in forming droplets and in this way a disease can be prevented. So that immunization can take place with a reduced risk of an outbreak of disease even with a high concentration of pathogens in the air stream, it is proposed according to the invention that a second part of the positively charged ions be attached to the inner walls of the pores in a water-insoluble manner. In this way, only a first fraction of neutralized pathogens is released, while a second fraction remains in the pores of the filter. The amount of released, neutralized pathogens can be adjusted through the ratio of water-soluble and water-insoluble positively charged ions attached to the inner walls of the pores. In addition, the water-insoluble positive ions attached to the inner walls of the pores prevent renewed accumulation of positively charged ions that have already been dissolved in neutralized pathogens due to the electrostatic repulsion.

To improve the likelihood of binding the positively charged ions, it is proposed that the filter be arranged between two electrodes for applying an alternating electric field. As a result of the energy introduced by the alternating field, not only is a chemical binding reaction facilitated, but a reconfiguration of ligand and / or receptor as binding partner required for binding is also energetically favored.

Tests have shown that when positively charged iron ions are used, their ferromagnetic properties result in a particularly good interaction with the electrical and thus electromagnetic alternating field, so that the energy input via the alternating field can be particularly efficient and, above all, easily controllable. In particular, an iron oxide ion can be used, which can be particularly advantageously attached to a polyethylene glycol chain as a linker.

To improve the filter properties of the proposed device, the filter can form a filter plate through which the air stream flows parallel to a largest plate surface. In contrast to the normal flow through a large plate surface with such filters, the pathogens remain in the pores of the filter for a longer period of time, so that a ne better neutralizing effect is made possible. In addition, with such a configuration, the moisture concentration within the filter increases gradually from the inlet of the air flow to the outlet, so that successive areas of the filter in the direction of the air flow release the neutralized pathogens one after the other and thus keep the total number of released pathogens constantly low over a longer period of time can be.

Certain pathogens can be filtered out of the air stream in a more targeted manner by binding ligand molecules to the ions. As a result of these measures, the positive charge of the ion is used to create a bond with the ligand molecule, so that the latter forms a bond complex with the ion. The ligand molecule comprises a binding site to a receptor of a specific pathogen. This allows specific pathogens to be filtered out of the air flow, while other components of the air flow that might also react with the charge of the positive ion can pass through the filter. The binding of the ion to the ligand molecule can take place, for example, via negatively charged amino acids on the outside of the ligand molecules. The ligand molecules can also be antibodies, for example, which can be particularly easily bound to iron or selenium ions. A ligand molecule can also be bound to several ions as long as its binding site for binding the pathogen remains free.

To filter specific viruses from the air stream, the ligand molecules can include mannose-binding lectins. Mannose-binding lectins (MBL) play a role in many immune processes by binding pathogens such as viruses. In this case, too, the mannose-binding lectins can, for example, be bound to the positive ion directly via negatively charged amino acids on their outside, or indirectly via functionalized antibodies that establish a bond between the ion and mannose-binding lectin. For example, point mutations of amino acids can generate MBL mutations that can be more easily bound directly to the ion. An indirect bond can be established, for example, by binding anti-MBL immunoglobulins to iron ions by means of ferritin. Brief description of the invention

In the drawing, the subject matter of the invention is shown, for example. Show it

Fig. 1 is a schematic section through a pore of the Fil age according to the invention with unbound pathogens,

Fig. 2 shows a section corresponding to Fig. 1 with partially bound Patho genes,

Fig. 3 shows Figs. 1 and 2 corresponding section with partially loosened bin elements and

Fig. 4 is a perspective view of a device according to the invention in egg nem larger scale and

Fig. 5 shows a section corresponding to FIG. 3 with partially loosened Bindeele elements and a ligand molecule bound to the ion.

Ways of Carrying Out the Invention

A device for neutralizing inanimate and unicellular pathogens 1 has a filter 2 through which several open pores 3 pass through. These pores 3 are provided on their inner walls 4 with positively charged ions 5, some of which are water-soluble, attached to the inner walls 4, and positive ions 6, some of which are insoluble in water, attached to the inner walls.

The positively charged ions 5 attached in a water-soluble manner are bound to linkers 7, which in turn are attached to the inner walls 4 of the pores 3 via a water-soluble binding element 8. The positively charged ions 5, 6 can, for example, be iron ions, while the binding element 8 can be a starch molecule. The linker 7 can for example consist of a functionalized polyethylene glycol chain which is coupled either directly or indirectly, for example via antibodies, to the binding element 8 and / or the positively charged ions 5. If an air stream flows through the filter 2 according to the invention, the pathogens 1 floating in the air stream pass through the pores 3 of the filter 2, as can be seen from FIG. 1.

Due to the negatively charged groups of the envelopes of the pathogens 1, there is an attraction between the pathogens 1 and the positively charged ions 5, 6, so that, as a result, there are bonds between the pathogens 1 and the positively charged ions 5, 6, such as this is shown in FIG. The air humidity present in the air flow leads to an accumulation of air moisture on the inner walls 4 of the pores 3 with increasing use of the filter 2 , which is not shown in the drawing.

In a preferred embodiment, which is shown in an overview in FIG. 4, the filter 2 is arranged between two electrodes 9, 10, which by applying an alternating voltage in the space between the electrodes 9, 10 and thus also within the pores 3 of the filter 2 generate an electromagnetic alternating field. Especially in this context and to increase the dwell time of the air flow to be filtered in the pores 3, the Fil ter 2 can form a filter plate that is traversed by the air flow parallel to a largest plate surface, for example in the flow direction 11 shown.

As can be seen from FIG. 5, ligand molecules 12 can be bound to the positively charged ions 5, 6 in order to selectively filter certain pathogens 1 from the air stream. The charge of the positively charged ions 5, 6 is used in this case to bind the ligand molecules 12, which in turn enter into a selective bond with certain pathogens 1, while other particles that are not recognized by the ligand molecules 12 are simpler Filters can pass.

Claims

1. A device for neutralizing inanimate and unicellular pathogens (1) from an air stream with a filter (2) which has open, continuous pores (3), the inner walls (4) of which are at least partially coated with positively charged ions (5), thereby characterized in that a first part of the positively charged ions (5) is bound to linker (7) which is attached to the inner walls (4) of the pores (3) via a water-soluble binding element (8).

2. Device according to claim 1, characterized in that the pores (3) in the area of the water-soluble binding elements (8) have a hydrophilic coating.

3. Device according to claim 1 or 2, characterized in that a second part of the positively charged ions (6) is insoluble in water on the inner walls (4) of the pores (3).

4. Device according to one of claims 1 to 3, characterized in that the filter (2) is arranged between two electrodes (9, 10) for applying an electrical alternating field.

5. Device according to one of claims 1 to 4, characterized in that the positively charged ions (5, 6) are iron ions.

6. Device according to one of claims 1 to 5, characterized in that the filter (2) forms a filter plate through which the air flow flows parallel to a largest plate upper surface.

7. Device according to one of claims 1 to 6, characterized in that ligand molecules (12) are bound to the ions (5, 6).

8. The device according to claim 7, characterized in that the ligand molecules (12) comprise mannose-binding lectins.