ENHANCED ANTIMICROBIAL EFFICACY (SYNERGY) OF SILVER AND COPPER COMPOUNDS AND MEDICAL USE OF THEIR COMBINATIONS

Abstract

This disclosure provides applications having enhanced antimicrobial efficacy (synergy) of silver and copper components and medical use of their combinations. Antimicrobial materials, dressings and formulations are provided and methods to use the materials, dressings and formulations.

Description

FIELD OF THE INVENTION

This invention is related to antimicrobial compounds and materials, especially antibacterial and antiviral compounds and materials, and antibacterial dressings, and to uses of the same.

BACKGROUND

Development of new antibacterial and antiviral compounds is one of the top priorities flagged by the World Health Organization, WHO. In post SARS-CoV-2 era, there is a growing demand for advanced antiviral medical devices, textiles and personal protective equipment. One of the most critical target group of novel antibacterial compounds are multidrug-resistant bacterial strains that cause infections in the patients with injuries (such as burns, traumatic wounds, surgery etc.) or underlying medical conditions exemplified by pressure ulcers and diabetic ulcers. Every fifth diabetic develops chronic wounds, commonly foot ulcers that are frequently infected by bacteria. In 15-27% cases bacterial wound infection leads to the gangrene that requires an amputation of the leg. This demonstrates that current wound infection management strategies are not efficient enough, and there is a great need for new remedies.

Current wound infection management strategies mainly rely on systemic antibiotics and topical wound care, including antibacterial creams and wound dressings. Systemic antibiotic treatment is a temporary measure and is further complicated by the fact that about 30% of the most common wound bacterial isolates (Staphylococcus aureus, Pseudomonas aeruginosa, Escherichia coli) are multidrug-resistant. Instead, or in addition to antibiotics, antibacterial wound dressings are applied locally (topically).

Metallic Ag has been used as antimicrobial since ancient times and it possesses broad-spectrum antibacterial action, being currently the “gold standard” antibacterial metal. The vast majority of commercial antibacterial medical devices consist of silver (Ag), mostly in ionic or metallic form.

Utilization of Ag nanoparticles instead of ionic/metallic Ag enables controlling Ag ion release, to prevent rapid inactivation of Ag ions by the wound environment, to decrease the probability of bacterial resistance and to enhance the antibacterial effect of Ag ions.

Current wound dressings mainly rely on ionic/metallic Ag. Wound dressing Acticoat® with nanocrystalline Ag is one of the few examples that rely on Ag NPs.

Various antibacterial dressings comprising ionic Ag have been disclosed in patent publications: Cellulose fibers with ionic Ag is disclosed in U.S. Pat. No. 6,471,982B1; WO2003053484 discloses a textile matrix comprising metallic silver coated fibers, polyurethane and alginate with ionic Ag is disclosed in US20030021832A; cellulose and alginate with ionic Ag is disclosed in U.S. Pat. No. 8,058,499B2; nylon plated with metallic Ag is disclosed in US20030176827A1.

There are also publications available disclosing use of Ag nanoparticles, e.g. EP1901723A2 discloses polyethylene fibers with Ag nanoparticles. U.S. Pat. No. 9,838,652 similarly discloses an Ag nanoparticle composition for preventing tissue infections.

Even if for example EP1901723A2 discloses Ag NP containing dressings to provide faster healing time and bacterial clearance compared to antibiotic sulfadiazine and lower frequency of wound sepsis and secondary bacteremias in burn wounds compared to Ag salt (AgNO₃) in randomized controlled clinical trials, they still do not inactivate bacteria and especially bacterial biofilms entirely.

In addition, according to various experiments and publications, Ag has low effect against coronavirus as is also recently demonstrated by our research group. We tested a range of Ag nanoparticles and Ag salt against influenza virus and coronavirus. Surprisingly, the half maximal effective concentrations (EC₅₀) of these tested silver compounds to influenza as well coronavirus were >50 mg/l indicating very low antiviral effect.

Copper as such is known to have weak antimicrobial effects as compared to silver. For this reason, using copper in addition to or instead of Ag, which is known for long to have good antimicrobial efficacy, is not widely used in antibacterial medical devices such as wound dressings.

However, there are some publications providing combinations of Ag and Cu in combination with other metals. For example, US20160022606 discloses a wound care system, where the system includes a mixture of colloidal silver, copper and zinc oxides.

There are growing concerns about ecotoxicity of Ag and Ag NPs and their adverse effects in vitro and in vivo in patients, including allergies.

Therefore, there is a great need for safer (e.g., with lower silver content) and more efficient antibacterial dressings, fabrics and other materials that would inactivate bacteria and their biofilms efficiently, act against various bacterial species, including antibiotic-resistant strains and inactivate viruses, including influenza virus and coronavirus; dressings that would provide faster wound re-epithelization, especially for diabetic ulcers, efficiently healing or preventing bacterial infection in chronic wounds (such as diabetic wounds, pressure ulcers) and in acute wounds (such as burns, traumatic and surgical wounds) and therefore preventing the limb amputations, mortality and days spent in hospital.

SUMMARY OF THE INVENTION

Accordingly, this disclosure solves the above-mentioned problems and more.

It is an object of this disclosure to provide antimicrobial materials, compositions and related solutions for medical devices, including wound care products and personal protective equipment. Especially, an object is to provide antibacterial and antiviral materials.

It is an object of this invention to provide an antimicrobial medical device (such as wound dressing, patch, face mask, ointment, cream, spray, catheter) comprising a silver component and a copper component, wherein the combination of silver and copper components provide a synergistic antimicrobial effect, thus leading to enhanced wound healing efficacy, faster and more efficient inactivation of bacteria, reduced inflammation and hence, better outcome of chronic wounds such as reduced probability of limb amputation. In addition, due to the synergy of silver and copper components according to this disclosure, concentration of silver may be significantly decreased (reducing adverse effects associated with frequent use of silver-based products) without losing antimicrobial efficacy.

The silver component comprises preferably Ag nanoparticles but may also comprise metallic or ionic silver in addition or instead to the nanoparticles.

The copper component comprises copper-based salts, Cu-based nanoparticles, or combinations thereof. Non-limiting examples of Cu-based nanoparticles are CuO, Cu₂O and Cu NPs.

According to certain embodiments the copper and silver components are provided in or on a medical device in such amounts that based on mg/cm², the Cu/Ag ratio in the antimicrobial device (e.g., dressing or facemask) is between 1 to 70, more preferably between 1 to 20 and most preferably between 1 to 8. According to certain embodiments a dressing may have Ag-concentration of 0.1-10 mg/100 cm², preferably, 0.1-1.0 mg/100 cm², and most preferably 0.2-0.75 mg/100 cm². The Cu-concentration may be 0.5-7.5 mg/100 cm² and more preferably 0.6-3.0 mg/100 cm². This combination can be incorporated into various polymers, textiles and materials including but not limited to non-woven as well woven materials, various biodegradable materials (alginate, cellulose (e.g., cellulose ethyl sulphonate, carboxymethylcellulose), collagen, chitin, silk, cotton, polylactic acid), nylon, polyethylene, silicone, polyvinyl alcohol, polyacrylonitrile, polyaniline, polyvinylpyrrolidone, polypropylene, polyurethane, paraffin, viscose, polyester, styrene-acrylonitrile and others using various methods including but not limited to electrospinning, infusion, adsorption, absorption, melt blowing, sonochemistry, plating, impregnation, or electrodeposition etc. techniques to give to these materials excellent antiviral properties.

According to certain embodiments the silver and copper components are provided in or on the medical device such that they create a synergistic antimicrobial effect which can be determined by coefficient of antimicrobial synergy K(Syn) calculated as:

$K\left(\mathrm{Syn}\right)=1/\left(\frac{\mathrm{MBC}\mathrm{of}\mathrm{Ag}\mathrm{compounds}\mathrm{in}\mathrm{mix}}{\mathrm{MBC}\mathrm{of}\mathrm{Ag}\mathrm{compounds}\mathrm{alone}}+\frac{\mathrm{MBC}\mathrm{of}\mathrm{Cu}\mathrm{compounds}\mathrm{in}\mathrm{mix}}{\mathrm{MBC}\mathrm{of}\mathrm{Cu}\mathrm{compounds}\mathrm{alone}}\right),$

• • wherein the K(syn) is higher than 1, preferably higher than 2, more preferably higher than 3, and most preferably higher than 4. Notably, K(Syn) as defined here may as well be used to measure antiviral synergy.

It is an object of this invention provide an antimicrobial medical device comprising Ag nanoparticles, and Cu-compounds selected from a group consisting of Cu-based salts, Cu-based nanoparticles, and their combinations in a ratio such that Cu/Ag ratio is between 1 to 70, more preferably between 1 to 20, and most preferably 1 to 8.

According to certain embodiments the medical device comprises Ag nanoparticles either non-functionalized or functionalized with one or more groups selected from carboxyl functional groups (—COOH), quaternary ammonium, polyethylene imine, branched polyethylene imine, PEG, citrate, PVP, dextran coating, amine groups (—NH₂), amino acids, bacteria binding peptides, polyoxometalates (POMs), proteins, antibodies, their fragments, and combinations thereof, and copper component being Cu-based NPs, such as CuO, Cu₂O or Cu nanoparticles selected from a group consisting of NH₂ and COOH-functionalized Cu-based nanoparticles and/or the copper based salts selected from CuSO₄, CuCl₂, CuI, or other copper salts.

According to certain embodiments the medical device, for example an antimicrobial dressing or facemask comprises protein stabilized Ag nanoparticles and optionally ionic silver, and copper compounds comprising Cu-based nanoparticles, Cu based salts or both.

According to certain embodiments the antimicrobial dressing comprises a skin contact layer and an absorbant layer, the skin contact layer comprising the Ag nanoparticles and the copper compound(s), and the absorbant layer is a natural or synthetic polymer.

According to certain embodiments the skin contact layer of the antimicrobial dressing comprises a fiber layer, and the Ag nanoparticles and Cu-nanoparticles, preferably CuO nanoparticles, are embedded in the fibers, preferably by electrospinning.

It is an object of this invention to provide an antimicrobial dressing comprising Ag nanoparticles and Cu-compounds in a ratio such that Cu/Ag ratio is between 1 to 70, more preferably between 1 to 20, most preferably between 1 to 8, and wherein coefficient of antimicrobial synergy when measured as:

$K\left(\mathrm{Syn}\right)=1/\left(\frac{\mathrm{MBC}\mathrm{of}\mathrm{Ag}\mathrm{NPs}\mathrm{in}\mathrm{mix}}{\mathrm{MBC}\mathrm{of}\mathrm{Ag}\mathrm{NPs}\mathrm{alone}}+\frac{\mathrm{MBC}\mathrm{of}\mathrm{copper}\mathrm{compounds}\mathrm{in}\mathrm{mix}}{\mathrm{MBC}\mathrm{of}\mathrm{copper}\mathrm{compounds}\mathrm{alone}}\right)$

• • is higher than 1, preferably higher than 2, more preferably higher than 3, and most preferably higher than 4.

It is an object of this invention to provide antimicrobial materials that are suitable for face masks and/or other protective wearable equipment to prevent exposure to airborne microbes, especially to viruses. It is an object to provide materials especially suitable for face masks and capable of killing coronaviruses (such as SARS Cov-2) and influenza (such as H1N1) viruses.

According to certain embodiments a filter material of a medical mask comprises Ag-nanoparticles and Cu-compounds and the mask is capable of reducing activity or inactivating SARS-CoV-2 and/or H1N1 virus.

According to certain embodiments a filter material of a medical mask comprises a fiber layer, and the Ag-nanoparticles and Cu-nanoparticles, preferably CuO nanoparticles, are embedded in the fibers.

It is a further object of the invention to provide an antimicrobial formulation comprising Ag-nanoparticles and Cu-compounds in such a ratio that Cu/Ag ratio is between 1 to 70, more preferably between 1 to 20 and most preferably 1 to 8.

According to certain embodiments the antimicrobial formulation comprises Ag-nanoparticles selected from either non-functionalized or functionalized with one or more groups selected from carboxyl functional groups (—COOH), quaternary ammonium, polyethylene imine, branched polyethylene imine, PEG, citrate, PVP, dextran coating, amine groups (—NH₂), amino acids, proteins, bacteria binding peptides, polyoxometalates (POMs), antibodies, their fragments, and combinations thereof, and copper compound being CuO-nanoparticles selected from a group consisting of NH₂ and COOH-functionalized CuO-nanoparticles and/or the copper based salt selected from CuSO₄ or CuNH₂.

According to certain embodiments the antimicrobial formulation comprising Ag-nanoparticles and Cu compounds in such a ratio that Cu/Ag ratio is between 1 and 70, more preferably between 1 and 20 and most preferably 1 and 8, and coefficient of antimicrobial synergy of the formulation when measured as

$K\left(\mathrm{Syn}\right)=1/\left(\frac{\mathrm{MBC}\mathrm{of}\mathrm{Ag}\mathrm{NPs}\mathrm{in}\mathrm{mix}}{\mathrm{MBC}\mathrm{of}\mathrm{Ag}\mathrm{NPs}\mathrm{alone}}+\frac{\mathrm{MBC}\mathrm{of}\mathrm{copper}\mathrm{compounds}\mathrm{in}\mathrm{mix}}{\mathrm{MBC}\mathrm{of}\mathrm{copper}\mathrm{compounds}\mathrm{alone}}\right)$

• • is higher than 1, preferably higher than 2, more preferably higher than 3, and most preferably higher than 4.

According to certain embodiments the antimicrobial formulation is effective against bacteria, including multi-drug resistant isolates, fungi, protozoa, viruses, including SARS CoV-2 and H1N1, and pathological proteins, including α-synuclein, prions, and amyloid beta.

According to certain embodiments it is provided a use of the antimicrobial formulation or wound dressing comprising a silver component and a copper component in such proportions that Cu/Ag ratio is between 1 and 70, more preferably between 1 and 20 and most preferably 1 and 8, and a coefficient of antimicrobial synergy is higher than 1, higher than 2, higher than 3 or higher than 4, for preventing or diminishing microbial growth on human tissue or on a surface of a medical device.

According to certain embodiments it is provided a use of the antimicrobial material comprising silver and copper components, preferably silver and copper nanoparticles in such proportion that Cu/Ag ratio is between 1 and 70, more preferably between 1 and 20 and most preferably 1 and 8 for inactivation of virus, preferably SARS-CoV-2 virus or H1N1 virus upon contact with the material.

According to certain embodiments the antimicrobial material comprising silver and copper components, preferably silver and copper nanoparticles in such proportion that Cu/Ag between 1 and 70, more preferably between 1 and 20 and most preferably 1 and 8 is efficient as a face mask to prevent or slow spreading of microbes, especially SARS-CoV-2 virus and H1N1-virus due to inactivation of microbes upon contact with the material.

It is an object of this invention to provide a method to cure or improve healing of a wound, the method comprising the step of administering an antimicrobial dressing on a wound, the dressing comprising silver component, preferably Ag nanoparticles alone or optionally in combination with metallic or ionic silver and copper component comprising compounds selected from a group consisting of copper based salts, Cu-based nanoparticles, and their combinations in a ratio such that Cu/Ag ratio is between 1 and 70, more preferably between 1 and 20 and most preferably 1 and 8.

According to certain embodiments the method to cure a wound comprises the step of administering on a wound an antimicrobial dressing, the dressing comprising silver component, comprising preferably Ag-nanoparticles alone or optionally in combination with metallic or ionic silver, and copper component comprising compounds selected from a group consisting of copper based salts, CuO-nanoparticles, and their combinations in a ratio such that Cu/Ag ratio is between 1 and 70, more preferably between 1 and 20 and most preferably 1 and 8 and wherein coefficient of antimicrobial synergy when measured as

$K\left(\mathrm{Syn}\right)=1/\left(\frac{\mathrm{MBC}\mathrm{of}\mathrm{Ag}\mathrm{compounds}\mathrm{in}\mathrm{mix}}{\mathrm{MBC}\mathrm{of}\mathrm{Ag}\mathrm{compounds}\mathrm{alone}}+\frac{\mathrm{MBC}\mathrm{of}\mathrm{Cu}\mathrm{compounds}\mathrm{in}\mathrm{mix}}{\mathrm{MBC}\mathrm{of}\mathrm{Cu}\mathrm{compounds}\mathrm{alone}}\right)$

• • is higher than 1, preferably higher than 2, more preferably higher than 3, and most preferably higher than 4.

It is an object of this invention to provide a method to treat a wound, the method comprising the step of administering an antimicrobial formulation on a wound, the antimicrobial formulation antimicrobial formulation comprising Ag component, preferably Ag nanoparticles alone or optionally in combination with metallic or ionic Ag, and Cu compounds in such a ratio that Cu/Ag ratio is between 1 and 70, more preferably between 1 and 20 and most preferably 1 and 8 and coefficient of antimicrobial synergy of the formulation when measured as

$K\left(\mathrm{Syn}\right)=1/\left(\frac{\mathrm{MBC}\mathrm{of}\mathrm{Ag}\mathrm{compounds}\mathrm{in}\mathrm{mix}}{\mathrm{MBC}\mathrm{of}\mathrm{Ag}\mathrm{compounds}\mathrm{alone}}+\frac{\mathrm{MBC}\mathrm{of}\mathrm{Cu}\mathrm{compounds}\mathrm{in}\mathrm{mix}}{\mathrm{MBC}\mathrm{of}\mathrm{Cu}\mathrm{compounds}\mathrm{alone}}\right)$

• • is higher than 1, preferably higher than 2, more preferably higher than 3, and most preferably higher than 4.

According to certain embodiments additional metal-based nanoparticles or metal ions selected from Al, Au, Ce, Co, Fe, Ga, Ir, Mo, Ti, Zn may be added to the dressing or the formulation.

The advantages provided by the invention disclosed and claimed here includes among others a synergy of two antimicrobial components such that bacterial film is completely removed with several times lower silver concentrations than any known silver-based solution. The advantages include faster wound healing compared to dressings currently in use and the reduction of silver amount in wound treatment.

The advantages provided in this invention also include prevention of microbe growth on surface of material of medical devices comprising the antimicrobial materials disclosed here.

The advantages provided by this invention also include a high efficacy against a large variety of microbes, including antibiotic resistant bacterial strains and their biofilms as well as viruses, especially SARS-CoV-2 and H1N1.

BRIEF DESCRIPTION OF THE FIGURES

FIG. 1 illustrates the synergy of Ag and CuO NPs against Escherichia coli K12. Test was performed using slightly modified ISO 20645 (Textile fabrics—Determination of antimicrobial activity—Agar diffusion plate test). Commercial silver-based wound care product (Hansaplast) is on the left, in-house prepared wound care material containing CuO—COOH NPs is on the right. Material contact area with bacteria (surface area=2.5 cm²) is denoted by the white dashed line; unexpected bacteria-free area suggesting the synergy between commercial silver material and our nano copper-based material is denoted by the red dashed line.

FIG. 2 is an example of synergy of NPs. E. coli suspension was incubated with different concentrations of either Ag NPs, CuO NPs or their combinations for 24 h, and 3 μL of bacteria-NP mixture was pipetted onto agarized broth.

FIGS. 3A and 3B show the synergistic effect of CuO NPs and CuSO₄ with Ag NPs (A) or AgNO₃ (B) to a range of Gram-negative and Gram-positive bacteria commonly colonizing wounds. Bacterial suspension was incubated with Ag NPs, CuO NPs, respective ions or their combinations for 24 h, plated on agarized broth, and MBC was determined.

FIG. 4 shows the synergistic effect of CuO NPs and CuSO₄ with various Ag NPs. E. coli K12 suspension was incubated with Ag NPs, CuO NPs, respective ions or their combinations for 24 h, plated on agarized broth, and MBC was determined.

FIG. 5 shows coefficient of antibacterial synergy between Ag NPs and copper components depending to Cu/Ag ratio (calculated on the basis of metal) in the mixture.

FIGS. 6A and 6B Scratch closure (re-epithelization) of BALB/c fibroblasts in vitro after 24-h exposure to the control (medium alone) or medium with copper.

FIG. 7 illustrates the design of the wound dressing containing an antibacterial skin contact layer and an absorbent layer according to this disclosure. Nylon 6 was dissolved in formic acid at various concentrations (15-20 wt %) and the solutions were stirred overnight at magnetic heated plate stirrer at 40° C. to ensure the full dissolution. 0-2000 ppm Cu—AgNP suspensions were stirred with nylon 6-formic acid for 1 h at 40° and then subjected to the electrospinning as described by Javed et al 2. The polymer solutions were electrospun with a fixed mass flow rate of 0.12 mL/h and a voltage of 15 kV for 2 hours. After preparation of the fibers, scanning electron microscopy was used to determine the morphology and the average diameter of the fibers (FIG. insert).

FIG. 8 shows scanning transmission electron microscope images coupled with high-angle annular dark-field (HAADF) and Energy Dispersive X-Ray Analysis (EDX) demonstrated presence of Cu and Ag NPs in the electrospun fibers.

FIG. 9 shows antibacterial efficiency of electrospun skin contact layer with CuSO₄, Ag NPs or their combinations against E. coli K12. Concentrations are recalculated on metal (Ag or Cu) content to enable comparison.

FIG. 10 shows improved antibacterial efficiency (larger zone of inhibition) of the wound dressing according to this disclosure with CuSO₄ and Ag NPs against antibiotic-resistant Pseudomonas aeruginosa compared to the popular commercial antibacterial wound dressings. Legend: a: Nanordica wound dressing: skin layer of silk fibroin with Cu and Ag NPs and absorbent layer; b: commercial wound dressing 1, and c: commercial wound dressing 2. The darker color indicates growth of bacteria.

FIGS. 11A and 11B demonstrate representative Petri dishes with bacteria isolated from wounds of rats after 24-h treatment with placebo (dressing without antibacterial components) (1), Aguacel Ag+ Extra (2), or a wound dressing according to this disclosure (AAWD=advanced antibacterial wound dressing) prepared on the basis of Cu—Ag nanoparticle combination (3); n=27.

FIG. 12 shows the number of P. aerunginosa cells in wound swab on different days in experiments conducted with rats.

FIG. 13 Wound healing progress after 5-day treatment with different wound dressings in rat wound infection model. Representative images from blind histology of tissue biopsy after treatment with placebo (A), Aquacel Ag+ Extra (B) or the wound dressing according to this disclosure (C). n=27. There was lower number of inflammatory cells (leukocytes) and more mature epidermis and collagen tissue after the treatment with wound dressing disclosed here.

FIGS. 14A-14D show antiviral activity of material according to this disclosure with Ag and Cu nanoparticles against SARS-CoV-2 virus (A and B) and against H1N1 virus (C and D).

FIG. 15 shows results from clinical trials (see Example 6 below) where a wound area was treated with Nanordica Medical Dressing according to this invention (AAWD) (Line B) or with Aquacel Ag+ Extra dressing (Line A). Vertical axis shows the non-re-epithelized area of the wound. After 7 days of treatment the non-re epithelized area treated with Nanordica dressing was 56%, while corresponding area on wounds treated with Aquacel Ag+ Extra was 87%, demonstrating the effectiveness of the Nanordica dressing.

FIG. 16 shows proportion of full wound closure of diabetic foot ulcers (n=30) after 1 week treatment with Nanordica dressing or with Aquacel Ag+ Extra dressing and 2 weeks follow up period. (see Example 6 below). 17.6% of ulcers treated with Nanordica dressing (Column B) were closed after the 3 weeks, while only 7.7% of ulcers treated with Aquacel Ag+ Extra (Column A) were closed.

DETAILED DESCRIPTION OF THE INVENTION

Definitions

Nanoparticle as used in this disclosure means a particle of matter that has at least one dimension between 1 and 1000 nm in diameter, preferably between 1 and 100 nm, more preferably between 1 and 60 nm, and most preferably between 1 and 40 nm. In case the particle is in the form of a fiber or a tube, the diameter of the fiber or tube is between 1 and 100 nm, preferably between 1 and 60 nm and most preferably between 1 and 40 nm regardless of the length of the tube or fiber.

Antibacterial Synergy as used in this disclosure means interaction or cooperation of two or more compounds that produce a combined antibacterial effect greater than the sum of their separate effects. The antibacterial synergy is measured as Coefficient of antibacterial synergy K(Syn). According to this disclosure there is antibacterial synergy when the coefficient is higher than 1, more preferably higher than 2, even more preferably higher than 3, and most preferably higher than 4.

Surface functionalization of nanomaterials as used in this disclosure refers to assembling different organic and/or inorganic materials together in nanoscale through covalent bonds or noncovalent bonds including hydrogen bonds, electrostatic force, or van der Waals force.

A formulation is effective against microbes as used in this disclosure means that treatment with the formulation is capable of killing at least 90%, preferably at least 99%, more preferably 99.9%, and most preferably more than 99.99% of the microbes.

Silver compound, as used in this disclosure includes Ag nanoparticles alone, or in a combination with ionic or metallic silver.

Copper compound, as used in this disclosure includes Cu nanoparticles, Cu salts or combinations thereof.

Medical device, as used in this disclosure includes wound care products, personal protective devices and it generally means devices, structures, and compositions intended for use in the diagnosis of disease or other conditions, or in the cure, mitigation, treatment, or prevention of disease in a living organisms, preferably in a mammal, most preferably in a human being. The term medical device thus includes for example stents, catheters, abdominal plugs, adhesive films, contact lenses, bandages, face masks, textiles, filter materials, injectors of drugs, wound dressings, patches, ointments, creams, sprays, without limiting the definition to these examples.

MBC, minimum bactericidal concentration is the lowest concentration of Ag or Cu compounds required to kill particular bacterium. In reference to antiviral effect MBC would mean the minimum concentration of Ag or Cu compounds require to kill particular virus.

This disclosure provides combinations of Ag nanoparticles (Ag NPs) alone or in combination with ionic or metallic silver, and Cu compounds, preferably Cu salts, Cu-based nanoparticles (Cu NPs) or combinations thereof in medical devices, dental materials, antimicrobial dressings, antibacterial fabrics. Even if Cu is known to have antimicrobial effects, its use as antibacterial compound in medical devices or wound dressings has been limited due to the fact that its antimicrobial effects are known to be considerably weaker than those of silver. It was now surprisingly and unexpectedly found that combining Ag NPs with the Cu compounds the antimicrobial effects are 3 to 5 times higher than with Ag NPs alone. This allows making medical devices, dental materials, antibacterial dressings, and other applications while using less Ag. One preferred embodiment is a wound dressing containing less Ag than wound dressings that are commercially available with higher antimicrobial efficacy and improved wound healing properties. In referring to the appended figures various embodiments are now described.

Referring now to FIG. 1 a comparison between antimicrobial efficacy of a dressing with silver (Ag) and copper oxide nanoparticles (CuO NP) was conducted as an agar diffusion plate test. A commercial wound care material incorporating silver and in-house produced wound care material incorporating copper oxide nanoparticles (CuO NPs) were placed on the same agar plate. The results shown in FIG. 1 establish the initial surprising and unexpected observation that in the area between the two materials there was a bacteria-free area.

In order to investigate this synergy effect further, detailed experiments were conducted.

A synergistic effect between CuO NPs and Ag NPs was demonstrated in an experiment shown in FIG. 2. Antimicrobial efficacy of NPs was compared by determining minimal bactericidal concentration (MBC, the lowest tested concentration of NPs yielding no visible bacterial growth). As can be seen from FIG. 2, already 10 mg/l Ag NPs+12.5 mg/l CuO NPs efficiently inactivated E. coli, when used in combination, while the MBC was as high as 40 mg/l for Ag NPs and 400 mg/l for CuO NPs. This clearly proves the synergistic effect.

In order to quantify and compare the synergistic effect between different Ag and Cu compounds and among various bacterial strains, we introduced the term “Coefficient of antimicrobial synergy”, K(Syn), showing the antimicrobial efficiency of Ag compound and Cu compound combinations (mix) compared to the sum of the MBC values of individual compounds and calculated as follows:

$K\left(\mathrm{Syn}\right)=1/\left(\frac{\mathrm{MBC}\mathrm{of}\mathrm{Ag}\mathrm{compound}\mathrm{in}\mathrm{mix}}{\mathrm{MBC}\mathrm{of}\mathrm{Ag}\mathrm{compound}\mathrm{alone}}+\frac{\mathrm{MBC}\mathrm{of}\mathrm{Cu}\mathrm{compound}\mathrm{in}\mathrm{mix}}{\mathrm{MBC}\mathrm{of}\mathrm{Cu}\mathrm{compound}\mathrm{alone}}\right)$

It is to be understood that in case silver compound includes NPs only and the Cu compound includes CuO NPs only, the equation can be written:

$K\left(\mathrm{Syn}\right)=1/\left(\frac{\mathrm{MBC}\mathrm{of}\mathrm{Ag}\mathrm{NPs}\mathrm{in}\mathrm{mix}}{\mathrm{MBC}\mathrm{of}\mathrm{Ag}\mathrm{NPs}\mathrm{alone}}+\frac{\mathrm{MBC}\mathrm{of}\mathrm{CuO}\mathrm{NPs}\mathrm{in}\mathrm{mix}}{\mathrm{MBC}\mathrm{of}\mathrm{CuO}\mathrm{NPs}\mathrm{alone}}\right)$

This disclosure provides a wound dressing comprising silver compounds comprising Ag nanoparticles alone or in combination with ionic or metallic silver or ionic silver alone and copper compounds selected from a group consisting of copper-based salts, Cu-based nanoparticles, and their combinations.

The dressing preferably comprises Ag-nanoparticles and copper-based salts, Cu based nanoparticles, and their combinations in a ratio such that Cu/Ag ratio is between 1 to 70, more preferably between 1 to 20 and most preferably 1 to 8. The combination of Ag nanoparticles and Cu compounds as described here provides an unexpected synergy between the Ag nanoparticles and Cu compounds resulting antimicrobial effects 3 to 5 times higher than Ag nanoparticles alone. Cu alone is a weak antimicrobial compound and was not expected to increase the effect of Ag nanoparticles.

The antimicrobial synergy is measured by a coefficient of antibacterial synergy defined as K(Syn) (see above).

According to certain embodiments the synergistic effect is used to make highly efficient antibacterial wound dressings.

According to certain embodiments the synergistic effect is used to various wound care treatment products such as woven or non-woven wound dressings, cotton gauzes, hydrofibers, gels, creams, ointments, hydrogels, hydrocolloids, foams, films, patches, pads to enhance their antimicrobial efficiency and anti-inflammatory and wound healing properties. For example, NP combination can be incorporated into or combined with different synthetic or natural polymers such as alginate, carboxymethyl cellulose, cellulose, cellulose ethyl sulphonate chitosan, chitin, fibroin, nylon, polyurethane, silicone, paraffin, polyethylene or polyvinyl with or without additional components to produce fibers, woven or non-woven wound dressings, cotton gauzes, hydrofibers, gels, creams, ointments, hydrogels or foams produced by sonochemistry, plating, electrospinning, freeze-drying, deposition or other techniques. Additional components may include Al, Au, Ce, Co, Fe, Ga, Ir, Mo, Ti, Zn as nanoparticles or as salts.

According to further embodiments the synergistic effect can be used in topical treatment of chronic or acute skin damage caused by infection, injury, inflammation, or medical condition: acne, herpes, skin irritations, inflammations excoriations or abrasions, traumatic injuries, foot and pressures ulcers, burns and surgical, necrotic, chronic or neuropathic/diabetic wounds, graft sides, under compression bandages.

According to even further embodiments the synergistic effect can be used in antimicrobial agents in medical devices like stents, catheters, abdominal plugs, adhesive films, face masks, contact lenses, lens cases, bandages, injectors of drugs and other devices that pass through the skin or contact with the skin, as well as prostheses, spokes, screws, and other implants introduced into the body.

According to further embodiments the synergistic effect can be used in antimicrobial, preservative, antioxidative or regenerating components in cosmetics: creams, ointments, lotion, sprays, lipsticks, gels, soaps, shampoos, scrubs.

According to even further embodiments the synergistic effect can be used in antimicrobial component for disinfecting in liquids: for washing and disinfecting hands, wounds, surfaces, and items.

According to still further embodiments the synergistic effect can be used in textiles to reduce the number of microorganisms and reduce the unpleasant smell from the fabric.

According to even further embodiment the synergistic effect can be used in antimicrobial components used in dentistry for disinfection on antimicrobial component for dental materials.

According to certain embodiments the synergistic effect can be used in anti-inflammatory components or additives for the treatment of local and systemic autoimmune and allergic diseases, including psoriasis, allergic and non-allergic dermatitis, acne, pemphigus, and pemphigoid.

According to certain embodiments the synergistic effect can be used in antimicrobial components of the material printed on 3D printers or produced by other technologies and afterwards implanted into the body; electrospun tissue scaffolds part of the nanorobots and electronic devices injected into blood or into organs or used on the body surface.

According to certain embodiments the medical device of this disclosure may be a dressing or a formulation comprising a first and a second component. The first component is an Ag-based component, and the second component is a Cu-based component. The first component may be an Ag salt or an Ag based nanoparticle, or the first component may be a combination of Ag salt and Ag based nanoparticle. The second compound may be a Cu salt, a Cu based nanoparticle, or combinations thereof. The copper compounds preferably have a positive charge.

According to certain embodiments further components may be added to the medical device, dressing and/or formulation. For example, a third component may include Al, Au, Ce, Co, Fe, Ga, Ir, Mo, Ti, Zn as nanoparticles or as salts.

The Ag based nanoparticles may be functionalized or non-functionalized. They may be stabilized by surfactants, proteins, polyvinyl pyrrolidone (PVP), citrate, polyethylene glycol (PEG), however this is not a limiting list, but other stabilizers may also be used. The Ag NPs may be modified with one or several surface functionalizations, non-limiting list of functional groups includes carboxyl functional groups (—COOH), quaternary ammonium, polyethylene imine, branched polyethylene imine, PEG, citrate, PVP, dextran coating, amine groups (—NH₂), amino acids, bacteria binding peptides, polyoxometalates (POMs), antibodies, their fragments, and combinations thereof.

According to certain embodiments the copper-based component may be a copper salt or copper (oxide)-based nanoparticle. The nanoparticles may be CuO— or Cu₂O— nanoparticles but other nanoparticles may also be used. The surfaces of the nanoparticles may be functionalized or not. A non-limiting list of functionalizing groups includes carboxyl groups, PEG, citrate, PVP, dextran coating, amine groups (—NH₂), proteins, quaternary ammonium, polyethylene imine, branched polyethylene imine, peptides, POMs, antibodies, their fragments, and combinations thereof. Preferably, the copper compounds have a positive charge.

In order to quantify and compare the synergistic effect between different Ag NPs and Copper compounds among various bacterial strains, we introduced the term “Coefficient of antibacterial synergy”, K(Syn), showing the antimicrobial efficiency of Ag- and copper compound combinations (mix) compared to the sum of the MBC values of individual Ag- and Cu compounds and calculated as follows:

$K\left(\mathrm{Syn}\right)=1/\left(\frac{\mathrm{MBC}\mathrm{of}\mathrm{Ag}\mathrm{compounds}\mathrm{in}\mathrm{mix}}{\mathrm{MBC}\mathrm{of}\mathrm{Ag}\mathrm{compound}s\mathrm{alone}}+\frac{\mathrm{MBC}\mathrm{of}\mathrm{Cu}\mathrm{compound}\mathrm{in}\mathrm{mix}}{\mathrm{MBC}\mathrm{of}\mathrm{Cu}\mathrm{compound}\mathrm{alone}}\right)$

Bacterial suspensions were incubated with Ag NPs, CuO NPs, respective ions or their combinations for 24 h, plated on agarized broth, and MBC was determined. The bacterial strains included Streptococcus aureus, Pseudomonas aeruginosa, Escherichia faecalis, Staphylococcus dysgalactiae and Escherichia coli. Results are shown in FIG. 3. Synergy between Ag NPs and CuO NPs with different surface functionalizations was observed in case of all tested bacterial strains and was the highest for CuO NPs with the positive surface charges (CuO and especially CuO—NH₂ NPs) and for positively charged CuSO₄ (ionic metal) (FIG. 3A), suggesting that positive charges enhanced synergy. In line with this hypothesis, the lowest K(Syn) was observed for negatively charged CuO—COOH NPs. When ionic silver (as AgNO₃) was used instead of Ag NPs, synergistic effect was considerably lower. Even if ionic silver salt alone with the copper compounds was not specifically efficient demonstrating that the surface of Ag NPs is pivotal for the enhanced synergistic effect (FIG. 3B), the combination of Ag NPs with ionic or metallic silver with Cu compounds can still provide a substantially high antimicrobial synergy (not shown).

Three different Ag NPs (size, surface functionalizations) were tested for synergy with Cu compounds. In FIG. 4 AgNP1 is protein-functionalized silver, AgNP 2 is unfunctionalized metallic silver, and Ag NP3 is Ag₂O. Test species here was E. coli K12. (FIG. 4). E. coli suspension was incubated with Ag NPs, CuO NPs, respective ions or their combinations for 24 h, plated on agarized broth and MBC was determined. Synergy with positively charged CuO NPs in case of all three tested Ag NP types was observed. This suggests synergistic effect is universal.

Experiments were conducted to define the optimal range of the metal components to achieve highest coefficient of antimicrobial synergy K(Syn). FIG. 5 shows that a synergy is highest when Ag NPs are applied with CuSO₄ and the Cu/Ag ratio is between 1 and 10. However, ratios being as high as 70-100 still provided substantial synergy benefit. Similarly, by using CuO NH₂ provided a good synergy with Ag NPs at Cu/Ag ratio being 1 to 10. With CuO and Ag NPs the synergy was best when Cu/Ag ratio was 7 to 10, and with CuO—COOH and Ag NP the best synergy was achieved when Cu/Ag ratio was about 0.7. Accordingly, it seems that the combination of CuSO₄ and Ag nanoparticles provides the best synergy and enable decreasing the amount of silver in the dressing.

Experiments were made to test the efficiency of selected NP combination (Ag NPs+CuO—NH₂ NPs, 1:4) on a range of multidrug-resistant clinical bacterial isolates. Experiments showed that NP combination was efficient against all tested bacterial isolates and pathogenic yeast Candida albicans according to slightly modified IS020645:2004 standard:

• • E. coli ATCC 25922; E. coli ATCC 13846; E. faecalis ATCC 29212; E. faecalis ATCC 51299 VRE(+); K. pneumoniae ATCC 700603 ESBL(+); S. aureus ATCC 25923
  • S. aureus NCTC 12493 MRSA(+); S. epidermidis ATCC 12228; P. aeruginosa ATCC 27853; S. epidermidis L20030902207; E. coli ESBL(+) L20030700513; C. albicans L20030700230

Test was performed according to modified ISO 20645:2004. Bacterial suspension (0.5 McFarland) was plated onto nutrient broth, and Whatman paper discs impregnated with 100 μl of nanoparticle combination (0.067% Ag NPs and 0.15% CuO—NH₂ NPs were placed on top. After 24-h the area under the discs was visually inspected.

According to ISO20645:2004, “good effect” is assigned to the antibacterial material that renders no growth under material. Good effect was verified with all the above strains.

The potential of Cu component to support the wound healing using BALB/c fibroblasts and in vitro scratch assay as a proxy for the wound healing was tested. The test was conducted as described in Chun-Chi Liang, Ann Y Park & Jun-Lin Guan. (2007). In vitro scratch assay: a convenient and inexpensive method for analysis of cell migration in vitro. Nature Protocols, 2: 329-333. As is shown in FIG. 6a, b, Cu enhanced the migration of fibroblasts, showing the potential for the improved wound healing.

In further tests with animals, bacterial count in wound was found 26 times lower than using wound dressing without active components and 7.6 times lower than using Ag+ as active component only (cf. FIGS. 11A and B). Moreover, number of pathogenic P. aeruginosa PAO1 was 40 times lower when the wound was treated with dressing comprising the AgNPs and Cu-compounds of this invention as compared to placebo (no active ingredients) and 12 lower than in wounds treated with dressings having only Ag+ as active ingredient (cf. FIG. 12). It was found that the dressing comprising AgNPs and Cu-compounds as active ingredients supported formation of mature epidermis, and that new epithelium achieved after treatment of the dressing comprising AgNPs and Cu-compounds was more mature, more homogenous and less inflamed than epithelium achieved after treatment with only Ag+ containing dressing (FIG. 13). Further advantages found in using the AgNP and Cu-compound comprising dressings were that neurophilis in blood of the test rats when measured on day 7 of the treatment was substantially lower than in rats treated with only Ag+ containing dressings (results not shown).

Accordingly, this disclosure provides an effective wound dressing that eliminates bacteria and supports the wound healing. The dressing comprises Ag compound including AgNPs alone or in combination with metallic or ionic Ag and Cu compounds. The Cu compounds may be Cu salts or Cu NPs or combinations thereof. The Cu compounds preferably have positive charge. Cu salts may be selected from CuSO₄, CuNH₂, Cu NPs are preferably CuO NPs. CuSO₄ and Ag NPs may be incorporated into fibers by electrospinning. Proposed technology implies that bacteria will be entrapped into the skin contact layer having a pore size of 100-300 nm, preferably approximately 200 nm, and become inactivated on the surface of the wound dressing, where moist wound bed will induce high local release of Cu ions and their interaction with AgNP surface.

Cu—Ag nanoparticles based wound dressings are safe and efficient when applied on patients (voluntary tests). They cause less side effects (like allergic reaction, dizziness, nausea, headache compared to competing commercial Ag-based dressing Aquacel Ag+). In addition, Cu—Ag compounds based wound dressings reduce bioburden, inflammation and support the wound healing, when applied on the wounds of patients with diabetic foot ulcer infection, patients with burns and beyond.

In in vitro tests the highest synergy was found when Ag NPs are applied with CuSO₄ and the Cu/Ag ratio is between 1 and 10. Similarly, by using CuO NH₂ provided a good synergy with Ag NPs at Cu/Ag ratio being 1 to 10. With CuO and Ag NPs the synergy was best when Cu/Ag ratio was 7 to 10, and with CuO—COOH and Ag NP the best synergy was achieved when Cu/Ag ration was about 0.7.

After performing efficacy and toxicity tests with rats, the best safety/efficacy balance was obtained when the dressing had Ag-concentration of 0.5-3 mg/100 cm² (1-2% of contact layer) and 3-7.5 mg/100 cm² of Cu (3-5% of contact layer). These concentrations were nontoxic for the mammalian fibroblasts and had an effective concentration of components against bacteria.

According to at least some embodiments the wound dressing comprises two layers (skin contact and absorbent layer). Ag compound and Cu compound are located in or on the skin contact layer. Cu compound may include Cu ion added as CuSO₄. (FIG. 7). Additional layers may be added. According to a preferred embodiment the absorbent layer is preferably alginate—a biocompatible and highly absorbent advanced polymer that is known in the art and used in treating chronic wounds. The alginate layer may comprise Cu-alginate gel.

The skin contact layer may be produced by electrospinning method enabling incorporation of NPs into polymers and getting tiny antimicrobial fibers. According to certain embodiment Na-alginate is mixed with Ag NPs and Cu compounds in electrospinning solutions, and NPs-containing alginate fibers are produced by electrospinning. To enforce the strength of the fibers, additives such as polyethylene glycol or cellulose may be added. According to certain embodiments the skin contact layer has pore sizes between 100 and 300 nm, preferably 150-250 nm, and most preferably about 200 nm (i.e., 190-210 nm).

Accordingly, this disclosure provides antimicrobial medical devices for use in preventing or diminishing microbial growth on mammal, preferably human tissue. Especially the medical devices include antimicrobial dressings and formulations, but other variations are also possible. The antimicrobial medical devices are effective on a large number of microbes, including antibiotic resistant strains of various bacteria. The medical devices according to this disclosure are efficient against at least Escherichia coli, Pseudomonas aeruginosa, Enterococcus faecalis, Staphylococcus aureus, Klebsiella pneumoniae, Staphylococcus epidermidis, Staphylococcus dysgalactiae and Candida albicans.

FIG. 15 shows results from clinical trials where wound areas were treated with Nanordica Medical Dressing (AAWD) according to this invention or with Aquacel Ag+ Extra dressings. Nanordica Advanced Antibacterial Wound Dressing (AAWD) is composed of two layers: a wound contact layer and an absorbent layer (FIG. 7). The wound contact layer is preferably made of silk fibroin fibers. The absorbent layer is made of 3-dimensional low-density polyethylene (LDPE) on cellulose foam (AIRLAID). The silk fibers are a blend of fine fibers with embedded copper and silver nanoparticles with the purpose to inactivate pathogens, including gram-positive and gram-negative bacteria, molds and yeasts in the wound environment. AAWD is designed to provide a moist and absorbing environment for excess wound exudates that promotes wound healing. Aquacel Ag+ Extra is one of the most successful wound dressings commercially available. Aquacel Ag+ Extra contains ionic silver (antibacterial), carboxymethylcellulose fibers and ethylenediaminetetra-acetic acid disodium salt (EDTA) and benzethonium chloride. Vertical axis in FIG. 15 shows the non-re-epithelized area of the wound. After 7 days of treatment the non-re epithelized area treated with Nanordica dressing was 56%, while corresponding area on wounds treated with Aquacel Ag+ Extra was 87%, demonstrating the effectiveness of the Nanordica dressing comprising Ag nanoparticles and positively charged Cu-component. FIG. 16 compares the effectiveness of the same dressings in treatment of diabetic foot ulcers. Proportion of full wound closure of diabetic foot ulcers (n=30) after treatment with Nanordica dressing (AAWD) or with Aquacel Ag+ Extra dressing for one week after which two weeks follow up was conducted with non-antibacterial gauze. 17.6% of ulcers treated with Nanordica dressing were closed after 3 weeks, while only 7.69% of ulcers treated with Aquacel Ag+ Extra were closed. Again the result shows the importance of the combination of Ag component and Cu-component of the dressings of this invention.

Further experiments were conducted to verify the antiviral efficiency of the materials and compounds comprising Ag and Cu nanoparticles. Especially interest was to verify the antiviral efficiency against SARS-Cov2 and H1N1 virus. Accordingly, this disclosure provides antiviral material for use for example as face masks or other protective material to reduce or eradicate viral populations. Mask filter material was produced by electrospinning as described in Example 1 with incorporation of 3.2% copper and 0.4% silver nanoparticles. Pore size of skin contact layer was about 200 nm. Materials containing Ag and Cu compounds significantly inactivated SARS-CoV-2 and influenza viruses already after 5 minutes of exposure (FIGS. 14A and 14C, respectively), whereas after 1 hour the inactivation of the virus was almost complete: 100% in case of SARS-CoV-2 (FIG. 14B) and 94% in case of influenza (FIG. 14D). Thus, this disclosure provides combination of Ag and Cu compounds as an excellent antiviral agent effective against influenza and SARS-CoV-2. The filter materials intended for the antiviral and antibacterial face masks and produced by electrospinning by incorporating a mixture of Ag and Cu compounds into the silk fibers showed high and fast antiviral effects.

Example 1. Preparing Antimicrobial Material

In making a prototype, Nylon 6 was dissolved in formic acid at various concentrations (15-20 wt %) and the solutions were stirred overnight at magnetic heated plate stirrer at 40° C. to ensure full dissolution. 0-2000 ppm Cu—AgNP suspensions were stirred with nylon 6-formic acid for 1 h at 40° and then subjected to the electrospinning as described by Javed et al 2. The polymer solutions were electrospun with a fixed mass flow rate of 0.12 mL/h and a voltage of 15 kV for 2 hours. After preparation of the fibers, scanning electron microscopy was used to determine the morphology and the average diameter of the fibers (FIG. 7, insert). FIG. 8 demonstrates that CuSO₄ and Ag NP were successfully incorporated into fibers during electrospinning.

Proposed technology implies that bacteria will be entrapped into the skin contact layer (pore size ˜200 nm) and will be inactivated on the surface of the wound dressing, where moist wound bed will induce high local release of Cu ions and their interaction with AgNP surface. FIG. 9 demonstrates that the wound dressings containing 2% metal from combination of Ag NPs and CuSO₄ (1:1) completely inhibited the growth of E. coli bacteria, in contrast to the wound dressings that contained 2% metal from Ag NPs or CuSO₄ alone.

FIG. 10 demonstrates that our wound dressing prepared from the optimal Cu—Ag nanoparticle combination inactivates Escherichia coli better (larger inhibition zone) (a) compared to commercial Ag-based dressings Aquacel Ag+ by ConvaTec (b) and Mepilex by Mo{umlaut over (l)}nlycke (c).

Example 2 Preparing Cu-Alginate Gel

A wound dressing comprising Cu ion-based alginate incorporating Ag NPs (and CuO NPs, optionally) can be made as follows: In the first step, Cu-alginate gel will be synthetized from Na-alginate and CuSO₄. In the second step, the obtained gel containing Na- and Cu-alginate will be stirred with AgNO₃ to obtain in situ reduction of Ag ions and formation of Ag NPs or subjected to direct addition of Ag NPs. In a final (optional) step CuO NPs will be added to the gel. Resulting Cu-alginate gel containing NPs may be used on wounds directly in the form of gel or freeze-dried in several cycles to obtain wound dressing.

In alternative technological solutions for the wound dressing, ion exchange-enabled Cu-alginate incorporating Ag NPs is possible. Upon contact with the wound, Cu-alginate will form a hydrophilic gel releasing NPs and metal ions in the wound environment.

Example 3 Electrospinning nanoparticle containing silk fibroin can be mixed with Ag NPs and Cu compounds in electrospinning solutions, and NPs-containing fibers will be produced by electrospinning. To enforce the strength of the fibers, additives such as polyethylene glycol or cellulose may be added.

The AAWD dressing used in the clinical trials (example 6 below) were prepared as follows: During the manufacturing process, copper and silver nanoparticles were mixed with presolubilized silk fibroin. The mixture was subsequently used in the process of electrospinning. Electrospinning is a technique enabling efficiently incorporate copper and silver into fibers in the composition of wound contact layer of the AAWD. The incorporation of the metals was visualized and qualitatively analyzed by means of HAADF-STEM electron microscopy (FIG. 8). The AAWD was designed and is manufactured according to applicable, state-of-art safety principles, including the ISO 13485, 11135 and 11737 standards for medical devices. The sterilization process, the validation and the manufacturing routine is carried-out according to ISO-11135:2014. The packaging is validated according to ISO 11607-1.

Example 4 Antibacterial Effects of Ag Nanoparticles Alone and in Combination with Cu-Compounds

Table 1 demonstrates the raw data (MBCs of Ag NPs and different Cu compounds alone or in combination) used for calculations in FIG. 3. The results demonstrate that antibacterial effect (MBC) can be achieved with remarkably low concentrations of Ag NPs, if used in combination with Cu compounds.

TABLE 1
Minimal inhibitory concentration (MBC) (mg/l) of Ag NPs and different Cu compounds
alone or in combination.
Bacteria		MBC (CuX)	MBC (Ag NPs)
(Gram staining)	MBC alone	in combination	in combination	K (Syn)
E. coli K-12 (G−)
Ag NPs	34.04 ± 13.1
CuO	215.4 ± 114.4	41.67 ± 14.43	7.441 ± 2.577	2.387 ± 1.179
CuO—NH2	157.1 ± 51.4	18.75 ± 7.22	5.208 ± 3.348	3.047 ± 0.289
CuO—COOH	350 ± 90.5	12.5 ± 0	11.90 ± 5.16	2.75 ± 0.915
CuSO4	217.6 ± 72.8	22.5 ± 16.3	2.679 ± 0.998	5.055 ± 0.383
E. coli ESBL (G−)
Ag-col	45.83 ± 9.73
CuO	133.3 ± 57.7	41.67 ± 14.43	7.292 ± 4.774	2.222 ± 0.801
CuO—NH2	100 ± 0	20.83 ± 7.22	5.208 ± 1.804	3.17 ± 0.536
CuO—COOH	333.3 ± 115.5	58.33 ± 38.19	20.83 ± 7.22	1.621 ± 0.352
CuSO4	200 ± 0	25 ± 0	4.167 ± 1.804	4.727 ± 0.63
P. aeruginosa PAO1 (G−)
Ag NPs	28.91 ± 15.63
CuO	1400 ± 400	43.75 ± 12.5	15.63 ± 10.83	2.089 ± 0.867
CuO—NH2	200 ± 122.5	20 ± 6.85	8.75 ± 3.423	2.324 ± 0.653
CuO—COOH	800 ± 0	34.38 ± 18.75	21.88 ± 6.25	1.31 ± 0.592
CuSO4	720 ± 178.9	20 ± 6.85	8.75 ± 3.423	2.783 ± 0.687
S. aureus ATCC 25923 (G+)
Ag NPs	16.25 ± 5.88
CuO	60 ± 22.36	17.5 ± 6.85	2.969 ± 2.096	2.18 ± 0.447
CuO—NH2	80 ± 27.39	12.5 ± 7.65	1.875 ± 0.699	3.958 ± 0.858
CuO—COOH	110 ± 54.8	11.25 ± 2.8	8.125 ± 4.193	1.918 ± 1.106
CuSO4	90 ± 22.36	16.25 ± 8.39	1.875 ± 0.699	3.659 ± 1.083
E. faecalis ATCC 29212 (G+)
Ag NPs	58.33 ± 19.46
CuO	233.3 ± 152.8	29.17 ± 19.09	9.375 ± 5.413	3.81 ± 1.374
CuO—NH2	266.7 ± 115.5	12.5 ± 0	10.42 ± 3.61	4.655 ± 1.62
CuO—COOH	400 ± 0	16.67 ± 7.22	12.5 ± 0	3.936 ± 0.983
CuSO4	200 ± 0	20.83 ± 7.22	8.333 ± 3.608	4.254 ± 0.977
S. dysgalacticae DSM 23147 (G+)
Ag NPs	10.07 ± 3.76
CuO	133.3 ± 57.7	16.67 ± 7.22	1.302 ± 0.451	3.766 ± 0.979
CuO—NH2	133.3 ± 57.7	15.625 ± 13.26	3.125 ± 0	2.481 ± 0.065
CuO—COOH	200 ± 0	12.5 ± 0	6.25 ± 0	1.44 ± 0.119
CuSO4	133.3 ± 57.7	12.5 ± 0	1.563 ± 0	3.909 ± 0.832

Example 5 In Vivo Experiments with Rats

Preclinical testing of antibacterial dressing with Wistar rats using the infected wound model was conducted at the Tallinn University of Technology in 2021. The rat's dorsal hair was removed, and the wound site was infiltrated locally with a 1% lidocaine solution to block pain. A round wound about 12 mm in diameter was made using a skin scalpel. 100 μl of bacterial suspension was placed in the wound. The bacterial suspension was a mixture of 4 bacteria (1:1:1:1): Escherichia coli MG1655, Pseudomonas aeruginosa PAO1, Enterococcus faecalis ATCC 29212 and Staphylococcus aureus ATCC 25923. The bacterial concentration was 10⁷/ml. After wound inoculation, the rats were randomly divided into three groups:

• • Group 1—used the wound dressings without active substance (negative control, 9 animals).
  • Group 2—used a commercial antibacterial wound dressing containing the active substance silver—Aquacel Ag+ Extra (positive control, 9 animals).
  • Group 3—used the Advanced Antibacterial Wound Dressing with Ag-col and CuSO₄ (test group, 9 animals). Concentration of Ag and Cu in active part of wound dressings were 4% and 8% respectively. The wound dressing was changed every 2^nd day. At the same time, the wound was controlled for healing process and also photographed. Wound size, wound edge redness and swelling, wound secretions (blood, transudate, pus) were documented. The general condition of the rat was scored daily.

On days 1, 5, 9, a bacterial inoculum was taken from the wound for bacterial quantitative and qualitative analysis. On days 0, 7 and 21 of the experiment, a blood samples were taken for markers of inflammation (clinical blood, markers of inflammation). On day 21, rats were humanely killed by inhalation of CO₂. Blood tests, biopsy at the wound site for histology, microbiology, and biochemical analysis were carried out on the same day. The experiment has shown that the dressing of this disclosure (Advanced Antibacterial Wound Dressing (AAWD) is several orders of magnitude more effective against infection in the wound compared to commercial dressing Aquacel Ag+ Extra (FIG. 4). The number of bacteria in the wound has decreased with remarkable speed during the first 24 hours. Bacterial count in wound was 26 times lower than using wound dressings without active substance (negative control group) and 7.6 times lower than using Aquacel Ag+ Extra (group 2). Only P. aeruginosa and S. aureus have been detected, since they outcompeted other bacterial strains

According to in vivo tests, the wound dressing prepared on the basis of Cu—Ag nanoparticle combination according to this invention inactivated pathogenic bacteria Pseudomonas aeruginosa 8 times better (3) compared to commercial Ag-based dressing Aquacel Ag+ Extra by ConvaTec (2) (FIG. 11)

Cu—Ag nanoparticles based wound dressings are safe and efficient, if applied on patients. They cause less side effects (like allergic reaction, dizziness, nausea, headache compared to competing commercial Ag-based dressing Aquacel Ag+). In addition, Cu—Ag compounds based wound dressings reduce bioburden, inflammation and support the wound healing, when applied on the wounds of patients with diabetic foot ulcer infection, patients with burns and beyond. In addition to the ongoing in vivo tests clinical trials are conducted to prove the safety and efficacy:

Example 6. Clinical Trials

Randomized Clinical Trial was conducted in the largest Estonian hospital, North Estonia Medical Centre with 30 patients having diabetic foot ulcers (DFU). Patients were divided into two groups, with one treated for 1 week with Nanordica Medical Wound Dressing (also called Advanced Antibacterial Wound Dressing (AAWD) (3 dressing changes per the week) and the second group was treated similarly with Aquacel Ag+ Extra wound dressing. In both groups the 1-week treatments were followed up for 2 weeks with a non-antibacterial dressing. The study evaluated wound healing outcomes, including wound closure rate and reduction of would surface area. 17 patients were treated with Nanordica Medical Wound Dressing (Also called AAWD) and 13 patients with Aquacel wound dressing. All the patients met all of the inclusion criteria and none of the exclusion criteria: Inclusion Criteria: males and females aged ≥18 suffering chronic infection of DFU with a size 58 cm in diameter and DFU infection grade 2.

Exclusion Criteria: patients receiving antibiotic therapy 7 days before the enrolment, osteomyelitis, cardiac disorder NYHA IV, hepatic disorder Child-Pugh C, cancer stage IV and CLTI, defined as Rutherford's Category 24 or Fontaine's stage 11l.

Results of wound surface reduction size is shown in FIG. 15, and results of wound closure after three weeks is shown in FIG. 16.

Example 7. Wound Healing of Individual Patients

To characterize wound healing of individual patient's photographs were taken and below is verbal description of some of the findings. Before entering this trial the ulcers of each patient had been treated with various commercially available dressings and antibiotics since emergence of the DFU without substantial healing of the ulcer.

Case 1. DFU of 72 years old woman having had a permanent DFU since 2017. Patient is described as obese and having hypertension. During the 3 week trial period (1 week AAWD, 2 weeks follow up with antibacterial dressing) a significant reduction of pain was reported. The DFU was 14×6 mm on the first trial day, while on day 21 the size was reduced to 6×3 mm.

Case 2. DFU of 65 years old man having had a recurrent DFU since 2021. Patient is described as obese and having hypertension. The patient used AAWD for 45 days. The DFU was 15×14 mm on day 1, and 5×5 mm on day 21, and on day 45 the DFU was fully closed.

Case 3. A 54 years old man, with history of Diabetes mellitus 1, and hypertension. On the right foot the patient underwent amputation of the first toe proximal phalanx 7 years ago. Four months before this trial unhealing ulcer appeared on the surgical site with continuous discharge and bleeding. During the trial (one week AAWD, 2 weeks follow up with non antimicrobial dressing, further follow up for 5 months without a dressing) on day 1 the ulcer was 25×25 mm, on day 14 still 25×25 mm, but the bleeding has stopped and exudate production decreased, on day 45 20×20 mm, and on day 150 only 10×7 mm.

The antimicrobial dressing and formulation according to this disclosure provides at least the following benefits:

1) Broad antimicrobial effect. The nanoparticle combination is effective against bacteria (including multi-drug resistant isolates), bacterial biofilms, fungi, protozoa, viruses, and pathological proteins (α-synuclein, prions, amyloid beta). Lower amounts of Ag can be used without compromising the antimicrobial effect.

2) Regenerative function. The nanoparticle combination and fibers accelerate the growth of connective tissue cells (fibroblasts, keratinocytes etc.), accelerates wound re-epithelization, helps to revitalize damaged tissues, reduces oxidative stress, restores normal cell structure after damage, reduces the effects of aging, increases tissue concentration of vascular endothelial growth factor (VEGF), platelet-derived growth factor (PDGF), nerve growth factors (NGFs), angiogenin, matrix metalloproteinases (MMP-1, -2, and -9 etc.), copper peptide GHK, fibrinogen which are necessary to restore the tissues.

3) Anti-inflammatory function. Due to the above two points, the nanoparticle combination reduces inflammation in the area of damage and alleviates inflammatory reactions, and thereby reduces further destruction of the tissues. Nanoparticle combination reduces the level of inflammatory factors (such as Tumor Necrosis Factor-α, inflammatory interleukins, cytokines, and cyclooxygenases).

4) Anesthetic function. Due to the above properties, these nanoparticle combinations alleviate pain from the wound site.

The antimicrobial effects of materials made according to this invention have proven not only to be efficient as wound dressings but also in other antimicrobial uses, including antiviral use:

Example 8 Testing Antiviral Effects of the Antimicrobial Material

Mask filter material was produced as described in Example 1 with incorporation of 3.2% copper and 0.4% silver nanoparticles. The material was tested for antiviral activity against influenza virus and coronavirus SARS-CoV-2.

1) Testing with SARS-CoV-2

Three independent experiments have been performed. Autoclaved 2×2 cm material pieces were placed into 50 ml falcon tubes using single-use forceps. 30 μl of SARS-CoV-2 virus stock (recombinant, Delta isolate, titer 5.68×10⁵ pfu/ml) was added to each material piece and incubated for 0 h and 1 hour at 28° C. After incubation, 470 μl of 1×PBS (phosphate-buffered saline) was added to each tube after a brief vortexing the tubes were centrifuged at 3200×g for 3 min at room temperature. The supernatants were transferred into the 1.5 ml reaction tubes. Serial 10-fold dilutions of the supernatants (starting from 10⁰ to 10³) were prepared in a U-bottom 96 well plate using Virus Growth Medium (VGM-DMEM, 0.2% BSA, 100 IU/ml Penicillin, 100 μg/ml Streptomycin), and Vero E6 cells pre-seeded on the flat-bottom 96-well plate were infected with 100 μl of dilutions for 1 hour at 37° C. Next, infected cells were overlaid with VGM/1% CMC (carboxymethyl cellulose) and incubated in a humidified atmosphere at 37° C. and 5% CO₂. After 48 hours, infected cells were fixed with ice-cold 80% acetone/PBS for 1 hour at −20° C., and the plate was dried under the hood overnight. Next, an immunoplaque assay was performed to count the microplaques. Cells treated with supernatants from materials without antimicrobial compounds were used as negative controls.

Immunoplaque Assay

96-well plate fixed with acetone was blocked using 1× Pierce Clear Milk blocking buffer (Thermo Scientific, Cat. Nr. 37587) for 1 hour at 37° C. Next, the plate was probed using anti-SARS-CoV2-N monoclonal rabbit antibody 82C3 (Icosagen AS, Tartu, Estonia) at a dilution 1:5000 in 1× Pierce Clear Milk blocking buffer for 1 hour at 37° C., and secondary anti-rabbit goat IRDyeCW800-conjugated antibody (LI-COR Biosciences, NE, USA) diluted 1:5000 in 1× Pierce Clear Milk blocking buffer for 1 hour at 37° C. The plate was then dried under the hood for 30 minutes, and the fluorescent signal was read using LI-COR scanning machine (wavelength 800 nm). The number of fluorescent plaques was counted in the appropriate dilution wells (5-50 plaques per well), the average of the three experiments was calculated and compared to the viral titers in the wells treated with negative controls.

2) Testing with Influenza Virus

Three independent experiments have been performed. 2×2 cm autoclaved materials were placed into the wells of 12-well plates. 30 μl of influenza virus (A/WSN/1933 (H1N1)) stock (6*10⁵ pfu/ml, 1.8*10⁴ pfu-s in 30 μl) was added to materials and then 470 μl pure DMEM medium was added per well (final volume of the sample was 500 μl). Materials were incubated with the virus for 0 h or 1 h. 1 h incubation was carried out at 28° C., 5% CO₂ in a humidified atmosphere. To collect the sample, the liquid from the well was transferred into 1.5 ml tube. 10 times serial dilutions were prepared from each sample in pure DMEM and these dilutions were used to infect 100% confluent Madin-Darby canine kidney (MDCK-2) cells on 12-well plates to titrate the samples by plaque assay. Cells were infected in 150 μl per well for 1 h at 37° C., 5% CO₂, humidified atmosphere, gently shaking the plates. After 1 h the medium was replaced with 3:2 virus growth medium:2% carboxymethylcellulose (˜1.5 ml/well) containing N-tosyl-L-phenylalanine chloromethyl ketone (TPCK) trypsin (final concentration 1 μg/ml) and plates were incubated for 96 h until the plaques formed. 96 h post-infection the medium was removed and cells were dyed using crystal violet. Plates were washed, plaques were counted, virus titers of the samples were calculated and compared to control titers.

Materials containing Ag and Cu compounds significantly inactivated SARS-CoV-2 and influenza viruses already after 5 minutes of exposure (FIGS. 14A and 14C, respectively), whereas after 1 hour the inactivation of the virus was almost complete: 100% in case of SARS-CoV-2 (FIG. 14B) and 94% in case of influenza (FIG. 14D).

The experiments show that a combination of Ag and Cu compounds according to this disclosure is an excellent antiviral agent effective against influenza and SARS-CoV-2. The filter materials intended for the antimicrobial face masks and produced by electrospinning by incorporating a mixture of Ag and Cu compounds into the silk fibers showed high and fast antiviral effects.

This combination can be incorporated into various polymers, textiles and materials including but not limited to non-woven as well woven materials, various biodegradable materials (alginate, cellulose (e.g., cellulose ethyl sulphonate, carboxymethylcellulose), collagen, chitin, silk, cotton, polylactic acid), nylon, polyethylene, silicone, polyvinyl alcohol, polyacrylonitrile, polyaniline, polyvinylpyrrolidone, polypropylene, polyurethane, paraffin, viscose, polyester, styrene-acrylonitrile and others using various methods including but not limited to electrospinning, infusion, adsorption, absorption, melt blowing, sonochemistry, plating, impregnation, or electrodeposition etc. techniques to give to these materials excellent antiviral properties.

Claims

1. A medical device comprising a silver component and a copper component, wherein the silver component comprises Ag nanoparticles alone or in combination with metallic or ionic silver, and the copper component comprises copper-based salts, copper-based nanoparticles, or combinations thereof, wherein the copper-based nanoparticles have a positive charge.

2. The medical device of claim 1, wherein the silver and copper components are in such amounts that Cu/Ag ratio is between 1 and 70, more preferably between 1 and 20, most preferably between 1 and 8.

3. The medical device of claim 1, wherein Ag nanoparticles are either non functionalized or functionalized with one or more groups selected from carboxyl functional groups (—COOH), quaternary ammonium, polyethylene imine, branched polyethylene imine, PEG, citrate, PVP, dextran coating, amine groups (—NH2), amino acids, proteins, bacteria binding peptides, proteins, polyoxometalates (POMs), antibodies, their fragments, and combinations thereof.

4. The medical device of claim 1, wherein the copper-based nanoparticles are NH2-functionalized CuO, or Cu2O nanoparticles and the copper-based salts are preferably selected from CuSO4, CuI and CuCl2.

5. The medical device of claim 1, wherein the medical device has a coefficient of antimicrobial synergy K(Syn) higher than 1, preferably higher than 2, more preferably higher than 3, and most preferably higher than 4 when measured as

6. The medical device of claim 1, wherein the device is an antimicrobial dressing or facemask.

7. The medical device of claim 6, wherein the device is an antimicrobial dressing and has Ag concentration in a range of 0.1-10 mg/100 cm2, 0.5-3.0 mg/100 cm2, and most preferably 0.6-1.0 mg/100 cm2, and Cu-concentration is in a range of 0.5-7.5 mg/100 cm2, preferably 2.5-3.0 mg/100 cm2.

8. The medical device of claim 6, wherein the nanoparticles are embedded in fibers of the dressing or facemask by electrospinning.

9. The medical device of claim 6, wherein the device is antimicrobial dressing having a skin contact layer comprising the Ag and Cu components, and an absorbent layer comprising a natural or synthetic polymer.

10. The medical device of claim 5, wherein the medical device is an antimicrobial dressing capable, when applied on wound or inflamed tissue, of improving healing outcome in comparison to applying a dressing with only an Ag-component.

11. The medical device of claim 6, wherein the device is a face mask capable of reducing activity/viability or inactivating SARS-CoV-2 and/or H1N1 virus.

12. An antimicrobial formulation comprising silver compounds and copper compounds, wherein the silver compounds include Ag nanoparticles alone or in combination with ionic and/or metallic Ag, and the copper compounds include Cu-based salts, Cu-based nanoparticles, or combination thereof in such proportions that Cu/Ag ratio is between 1 and 70, more preferably between 1 and 20, most preferably between 1 and 8, and wherein the Cu-based nanoparticles are positively charged, and wherein a coefficient of antimicrobial synergy of the formulation when measured as

13. The antimicrobial formulation according to claim 12, wherein the formulation is effective against bacteria, including multi-drug resistant isolates, fungi, protozoa, viruses, including SARS-CoV-2 and/or H1N1, and pathological proteins, including α-synuclein, prions, and amyloid beta.

14. A method to treat a wound or an inflamed tissue area, the method comprising a step of administering the medical device of claim 7 on the wound or inflamed area.

15. The method of claim 14, wherein the medical device is a medical dressing and the wound is an ulcer.

16. A method to prevent or diminish microbial growth on human tissue, wherein the antimicrobial formulation of claim 12 is applied directly or indirectly via a medical dressing onto human tissue.