KR20200133730A - Laundry decontamination formulation - Google Patents

Abstract

As an improvement process for decontamination of surfaces using a step-wise approach, based on D7 formulations with pathogen/agent/toxin destruction on the surface after migration of pathogens/agents/toxins, D7 formulations are used to treat clothing by SSDX -12 is added, and the D7 preparation has the active ingredient of a quaternary amine as a decontamination agent and activator to loosen and solubilize dust and dirt on the garment.

Description

Laundry decontamination formulation

Cross-reference to related applications

This application is a PCT international patent of U.S. Provisional Patent Application Serial Nos. 62/618,095, 62/618,096, 62/618,098, 62/618,100, and 62/618,104, filed on January 17, 2018. It is an application. This application further claims priority to U.S. Provisional Patent Application Serial No. 16/209,960 filed on December 4, 2018, which is PCT International Patent Application Application No. PCT/US18/ filed on June 15, 2018. It is a continuing application of 37817, which claims priority to U.S. Provisional Patent Application Serial No. 62/520,372, filed on June 15, 2017. The disclosure of the above application is incorporated herein by reference in its entirety.

The first need for decontamination is to facilitate exposure of pathogens/agents/contaminants/toxins to reactive mechanisms designed to destroy them. On the surface it requires:

Inducing the ability to desorb material from the surface, or

Enabling hydraulic mobility (displacement) of the material, or

Hydraulically forcing the material into a vulnerable state (melting).

Harmful substances can penetrate deeply into the reticulated grain structure of the microscopic surface, making it difficult to displace. Simply using water or other solvents cannot sufficiently provide a suitable physiochemical environment to overcome the forces of holding or shielding the material in place.

Embodiments of the present invention include improved chemical formulations designed for decontamination, disinfection and regeneration of surfaces exposed to chemical, biological and toxic industrial pollutants and residues, and two patented products (DF-200 and SSDX-12). How to carry out the administration of Both of these products are stand-alone treatments for a decontamination strategy. The combination of the two working together provides a unique approach to decontamination and disinfection strategies.

SSDX-12 is a highly effective decontamination soap specially used for safe decontamination of aircraft. To achieve this requirement, SSDX-12 was required to demonstrate corrosion resistance in aircraft metal alloys and sensitive equipment. In addition, this product was required to remove residues of chemical weapons to an acceptable standard. Although the product has proven to be effective in treating target surfaces, the challenge of improving dissolving and mobile chemistries remains. In many situations, it is simply unacceptable to wash the treatment and send it to the environment.

D7 Formulations (hereinafter "D7" or "D7 Formulations") are highly effective agents used to treat surfaces contaminated with bacteria, viruses, fungi, white fungi, industrial toxic chemicals, chemical weapons and other pathogenic and harmful agents. It is a decontamination/disinfectant. D7 quickly and chemically eliminates these threats, by its unique ability to dissolve targets that are normally insoluble in water and oxidize them chemically directly or directly expose them to regions of the self-assembled micelle structure embodied in the formulation. Can promote things.

As an example, the D7 preparation extends the technology to include both oxidation and reduction reactions. In addition, D7 includes treatment of industrial toxic chemicals. It is also the first criterion for bleach activators.

In another example, D7 extends into the areas of mold, disinfection and sterilization. The chemical has not been altered or modified. In fact, the D7 is the closest to the utility the product has recently liked.

In addition, D7 is expanded to chemicals for DF-200. Additionally, it includes reaction rate data for various toxic agents. In addition, this is an improvement of the original DF-100 for performance against mustard agonists in terms of reaction time and specificity. In one embodiment, D7 also includes a different bleach active.

If the effectiveness of these two decontamination strategies is synergistic, it is a state-of-the-art advance in decontamination and surface restoration in their implementation, and provides much needed improvements in their implementation.

SSDX-12 is designed to achieve a physiochemical formulation that is safe, environmentally harmless and less regrettable, so good conditions for the removal or non-protection of pathogens/agents/contaminants/toxins may be possible. When SSDX-12 is applied, it can remove aggressive substances by hydraulic pressure or make them vulnerable to hydraulic pressure.

For example, SSDX-12 is a C. sub. 8-22 alkyl dimethylamine oxide surfactant, C. sub. 6-12 alkyl dimethylamine oxide surfactant, C. sub. 8-18 alkyl polyethylene glycol sorbitan fatty acid ester Surfactants, and cleaning compositions such as C. sub. 12-14 secondary alcohol ethoxylate surfactants. The C.sub.8-18 alkyl polyethylene glycol sorbitan fatty acid ester surfactant contains 0 to about 20 ethoxylate functional groups for the C.sub.8-18 alkyl polyethylene glycol sorbitan fatty acid ester molecule. The C.sub.12-14 secondary alcohol ethoxylate surfactant contains about 14 to about 16 ethoxylate functional groups for the C.sub.12-14 secondary alcohol ethoxylate surfactant molecule.

In yet another embodiment, a cleaning composition for cleaning an exterior surface of a vehicle is provided. The cleaning composition comprises from about 0.1% to about 5% by weight of C. sub. 8-16 alkyl dimethylamine oxide surfactant, from about 0.1% to about 5% by weight of C. sub. 6-10 alkyl dimethylamine oxide interface. Activator, from about 0.1% to about 5% by weight of C. sub. 10-14 alkyl polyethylene ester surfactant, and from about 14 to about 16 of the C. sub. 12-14 secondary alcohol ethoxylate surfactant molecule. From about 0.1% to about 5% by weight of C. sub. 12-14 secondary alcohol ethoxylate surfactant including oxylate. The C.sub.10-14 alkyl polyethylene glycol sorbitan fatty acid ester surfactant contains 0 to about 6 ethoxylate functional groups for the C.sub.8-18 alkyl polyethylene glycol sorbitan fatty acid ester molecule. The C.sub.12-14 secondary alcohol ethoxylate surfactant contains about 14 to about 16 ethoxylate functional groups for the C.sub.12-14 secondary alcohol ethoxylate surfactant molecule. C. sub. 8-16 alkyl dimethylamine oxide surfactant, C. sub. 6-10 alkyl dimethylamine oxide surfactant, C. sub. 10-14 alkyl polyethylene glycol surfactant, and C. sub. 12-14 secondary The alcohol ethoxylate surfactant is provided in a 1:1:1:1 ratio in the cleaning composition. When applied to a vehicle, the cleaning composition is effective in removing chemical warfare agents from the exterior surface of the vehicle.

In one application example, a method of cleaning an exterior surface of a vehicle using the cleaning composition may be applied. The method includes providing a cleaning composition, applying the cleaning composition to an exterior surface of a vehicle, and rinsing the exterior surface of the vehicle with water.

However, once displaced at a fine location, a material can be exposed to a reactive spectrum (photoelectron radiation, oxidation, chemical modification by foreign substances) that facilitates its chemical conversion. That is, the fact that, for example, SSDX-12 can be applied to the surface of a vehicle as a cleaning composition does not mean that the dissolved solution is non-toxic or environmentally friendly. That is, in this state, the toxin becomes very vulnerable to natural forces, which inevitably promotes its low energy state.

Concrete surfaces can appear solid from our point of view, but when viewed finely, they can consist of a network of complex passages. It is the same as any porous surface. In many cases, a close examination reveals the maze. Delivery of chemicals into these microscopic environments requires significant surface tensions to be overcome. Surface tension is a property of a liquid, which defines how it diffuses over the surface and how well it will penetrate into the surface. The patented formulation of D7 allows very low surface tension values to be obtained at the surface. These values are not equilibrium values, but rather dynamic values. The turbulent solution thus produced by the foaming of hydrogen peroxide will continuously regenerate itself at the leading edge, which itself penetrates into the surface. These transient and considerably low surface tension values enable deeper penetration of the active chemicals implemented in D7. The cationic quaternary amine surfactant, combined with an alkaline pH carbonate buffer system, creates a pathway for more effective permeable delivery of the complex cleaning chemicals implemented in D7. The product acts in a similar manner to a hydraulic fracturing mechanism without a high pressure pump.

Alkali carbonates (potassium based) interact predominantly with negatively biased surfaces.

Quaternary amines are strongly adsorbed on negatively biased surfaces

The hydraulic channels are opened to deliver detergency in the form of water, peroxides and other nonionic species formulations.

In its ability to penetrate/eradicate biofilms over traditional forms, D7 offers advantages over prior art. For example, a biomembrane consists of a matrix of secreted chemicals, which protects the pathogen colony from the threat of invasion. These membranes have nutrient pathways, respiratory pathways, and transpiration pathways, and their exact nature is subject to intense vaginal questions. The physiochemical solution properties of D7 interact in a way that effectively and thoroughly destroys these surfaces. Solvent properties and oxidation from peroxide and peracetic acid species effectively "explore" to open the surface of the film and, in some cases, assist in breaking the functional pathway, resulting in terminal breakdown. Biomembrane effectively organizes the water in the secreted extracellular matrix, and these membranes are destroyed in many cases by the D7 cleaning mechanism.

Embodiment D7 describes a chemical formulation designed and improved for the decontamination, disinfection and regeneration of surfaces exposed to chemical, biological and toxic industrial pollutants and residues. These formulations improve the prior art by expanding the efficacy spectrum, reducing treatment time, modifying chemical properties, allowing lower effective dosages, and broadening the list of chemicals that are thereby restored. The formulations described herein can also be applied in variable concentrations to achieve decontamination purposes (cleaning, sanitation, disinfection, high level disinfection, mold removal, biofilm removal, targeted decontamination).

The implementation of D7 targets incremental variants designed to perform a specific task, which is the intent of this effort. In one embodiment, aspects of the invention can be formulated with a first generation version of a quaternary amine (ADBAC). It is believed that broadening the types of quaternary amines may bring advantages in efficacy against a wider range of pathogens or greater effect on biofilms. Among the two, the biofilm effect can be a task of remarkable value.

In addition, D7 provides a brief list of ingredients. D7 is not made with foreign ingredients. It is assembled with materials that are common, harmless and readily available. Their combination produces a net effect greater than each simple sum.

The physical properties implemented in D7 represent some of the success stories. Things like dynamic surface tension, critical micelle concentration, number of micelle structure aggregates, solvent potential and solution polarity all contribute to the mysterious behavior of D7.

One of the more potent actions of D7 arises from micelle formation. These micelles act as small reaction plants, where toxins react with activated oxygen species to neutralize or harmless.

If D7 is applied first in response to the biofilm problem, it is expected to show important effects to customers. Destroying the biofilm that protects the bacterial colonies virtually guarantees the destruction of the prokaryotic bacteria itself. Listed below is a list of the efficacy of D7 in relation to various organisms:

From a fourth generation perspective, the following comparison is relevant.

5th generation quaternary amine. This category is a mixture of first and fourth generations. When considering permutation of different first-generation chemicals with fourth-generation variants, this innovation option can grow rapidly. In one embodiment, the D7 formulation comprises:

In one embodiment, the fifth generation surfactant and dimethyl dialkyl quaternary amine provide improved structure to micelles developed in the D7 formulation.

These surfactants can modify the Gouy-Chapman-Stern layer to the point of having an improved and improved ability to dissolve the agent more rapidly into the micelle body.

In one embodiment, the surfactant may modify the Gouy-Chapman-Stern layer, and the degree of modification may be linked to the rate at which the agent is decontaminated, or may be the degree of decontamination.

Embodiments of the present invention may have different physical properties. The efficacy profile of this version is also different. The progression of the efficacy profile should be extended to the full version, with a diluted version, perhaps a 1:100 dilution of the final product. The diluted version can be considered for surfaces that are already clean and where no biofilm is present. In one embodiment, the concentrated version is contemplated for environments with more heavy dirt (living animal facilities, processing plants, sites with high potential for biofilm). Various embodiments of the present invention with respect to different diluents (bacteria, biofilm, spray efficacy) may enable various levels of application in addition to those disclosed in FIG. 1.

This improvement over the prior art allows consideration of the entire spectrum of products that can handle sensitive cleaning and sanitation situations, such as those encountered in food contact environments. In these circumstances, it may be possible to apply the product to the target surface by spraying, generally and to distribute the cleaning/sanitization formulation over the entire surface to wipe it off. In one embodiment, aspects of the invention may need to be approved by regulatory oversight bodies prior to use. In this case, it is commonly known as a "residual" product. The legal limits of the ingredients allowed for this type of use are labeled. It is the embodied intent of this improvement to enable this type of use. The full century version of the product is intended for use in highly damaged environments, such as live animal cages where severe dirt is expected. This represents the other end of the product spectrum. Regulatory oversight is also a necessary requirement with regard to pesticide implementation. Between these two extremes, it is expected that there will be many situations requiring intensity control products. An example of this situation is given in the spectrum above.

It is sometimes necessary to promote metastasis to a less harmful state. Pathogens, industrial toxic chemicals, or other undesirable substances are not challenged in the surrounding environment, except for these reactive agents common to the environment. Natural therapeutics for the treatment of invasion into the body include predation by organisms, hydrolysis by water, photolysis by electromagnetic radiation, absorption by substrates, and shielding of pathogens by environmental membranes, to name a few. If the pathogen is dissolved in water, a simple rinse may be sufficient. The kinetic time frames for these actions can range from medium to very long periods of slow transitions. Transferring the activity of reactive chemicals in the form of oxidative or nucleophilic substitutions is a well-known and effective therapeutic strategy in common practice. This is the route through which numerous agents deliver their effective doses. Once a material is oxidized, it is generally more susceptible to environmental decay through one or more of the above-mentioned mechanisms. Delivering oxidative activity to the target is not always right. For example, the use of bleach is a common practice in the field of disinfection and decontamination. Bleach is an aqueous solution whose ability to penetrate and bind pathogens is limited by the physiochemical barriers embodied in the substrate being treated. If the active fungicide does not react in the vicinity with the target pathogen, nothing happens. For this reason, disinfection and decontamination agents are formulated into a material that can deliver the material to where it reacts nearby by overcoming the physiological barrier of interfacial tension and surface energy. Also, substances that are not soluble in water may not be susceptible to reactions based on limited exposure to reactive conditions.

As mentioned above, D7 is an agent that overcomes physiochemical barriers for the delivery of reactive oxidizing species to pathogenic targets, and by its design assists the ability to bring resistant substances into solution, and pathogenic targets are then It is vulnerable to oxidation by the mechanism implemented in D7. This new version of the formulation is an improvement over the previous version and demonstrates a more robust and effective ability to perform decontamination/disinfection operations. By changing the surfactant properties of the formulation, faster decontamination time and complete destruction of the pathogenic layer protective film results in further improved removal.

D7 is a dilute decontamination agent that safely transfers chemical oxidative energy with the aim of promoting the oxidation of toxins to less harmful or completely harmless destruction, so D7 accelerates the oxidation and decontamination process to chemically Treated with As such, D7 acts to promote decontamination. Applying the SSDX-12 before D7 improves the net effect by enabling displacement of the adsorbed material.

D7 was applied to select a laundry problem and succeeded in decontaminating and disinfecting serious clothing. The D7's ability to perform these tasks has been well proven in independent laboratory tests. D7 has a quaternary amine as one of its main active ingredients, which functions as a powerful disinfectant and surfactant to loosen and dissolve dirt and grime common to clothing. It is already known that detergents based on cationic surfactants as well as anionic or neutral surfactants do not perform well in laundry environments.

The SSDX-12 has been applied to high-level decontamination operations involving aircraft and is qualified by numerous testing and military agencies. It has demonstrated a very effective ability to remove immobile material from inside the microscopic grain structure of aircraft aluminum. As a detergent for primary applications on major surfaces, this is an option to take.

Using the modified SSDX-12 as a primary detergent for laundry purposes, followed by treatment with D7 for final decontamination, is presented as a patentable combination.

The foregoing description and drawings merely describe and illustrate the invention, and do not limit the invention thereto. While this specification has been described with respect to a particular implementation or implementation, many details are presented for purposes of illustration. Thus, the above description merely illustrates the principles of the present invention. For example, the invention may have other specific forms without departing from its spirit or essential features. The described arrangement is illustrative and not limiting. To those skilled in the art, the present invention is possible with additional implementations or embodiments, and these details described in this application can be significantly changed without departing from the basic principles of the present invention. Accordingly, those skilled in the art will understand that, although not explicitly described or illustrated in the present invention, various arrangements can be devised, within the scope and spirit of the present invention, to embody the principles of the present invention.

While various implementations have been described above, it should be understood that this disclosure has been presented by way of example only and is not limiting. Accordingly, the breadth and scope of the present compositions and methods should not be limited by any of the foregoing exemplary embodiments, but should be defined only in accordance with the following claims and their equivalents.

While the present compositions and methods have now been fully described, those skilled in the art will understand that the same can be performed within a broad and equivalent range of conditions, formulations and other variables without affecting its scope or any embodiment thereof. All cited patents, patent applications, and publications are incorporated by reference in their entirety.

Appendix

Formulation of surface decontamination

Background

The first need for decontamination is to facilitate exposure of pathogens/agents/contaminants/toxins to reactive mechanisms designed to destroy them. On the surface it requires:

Inducing the ability to desorb material from the surface, or

Enabling hydraulic mobility (displacement) of the material, or

Hydraulically forcing the material into a vulnerable state (melting).

Harmful substances can penetrate deeply into the reticulated grain structure of the microscopic surface, making it difficult to displace. Simply using water or other solvents cannot sufficiently provide a suitable physiochemical environment to overcome the forces of holding or shielding the material in place.

Content of the invention

Embodiments of the present invention include improved chemical formulations designed for decontamination, disinfection and regeneration of surfaces exposed to chemical, biological and toxic industrial pollutants and residues, and two patented products (DF-200 and SSDX-12). How to carry out the administration of Both of these products are stand-alone treatments for a decontamination strategy. The combination of the two working together provides a unique approach to decontamination and disinfection strategies.

SSDX-12 is a highly effective decontamination soap specially used for safe decontamination of aircraft. To achieve this requirement, SSDX-12 was required to demonstrate corrosion resistance in aircraft metal alloys and sensitive equipment. In addition, this product was required to remove residues of chemical weapons to an acceptable standard. Although the product has proven to be effective in treating target surfaces, the challenge of improving dissolving and mobile chemistries remains. In many situations, it is simply unacceptable to wash the treatment and send it to the environment.

D7 Formulations (hereinafter "D7" or "D7 Formulations") are highly effective agents used to treat surfaces contaminated with bacteria, viruses, fungi, white fungi, industrial toxic chemicals, chemical weapons and other pathogenic and harmful agents. It is a decontamination/disinfectant. D7 quickly and chemically eliminates these threats, by its unique ability to dissolve targets that are normally insoluble in water and oxidize them chemically directly or directly expose them to regions of the self-assembled micelle structure embodied in the formulation. Can promote things.

As an example, the D7 preparation extends the technology to include both oxidation and reduction reactions. In addition, D7 includes treatment of industrial toxic chemicals. It is also the first criterion for bleach activators.

In another example, D7 extends into the areas of mold, disinfection and sterilization. The chemical has not been altered or modified. In fact, the D7 is the closest to the utility the product has recently liked.

In addition, D7 is expanded to chemicals for DF-200. Additionally, it includes reaction rate data for various toxic agents. In addition, this is an improvement of the original DF-100 for performance against mustard agonists in terms of reaction time and specificity. In one embodiment, D7 also includes a different bleach active.

If the effectiveness of these two decontamination strategies is synergistic, it is a state-of-the-art advance in decontamination and surface restoration in their implementation, and provides much needed improvements in their implementation.

Specific contents for carrying out the invention

SSDX-12 is designed to achieve a physiochemical formulation that is safe, environmentally harmless and less regrettable, so good conditions for the removal or non-protection of pathogens/agents/contaminants/toxins may be possible. When SSDX-12 is applied, it can remove aggressive substances by hydraulic pressure or make them vulnerable to hydraulic pressure.

For example, SSDX-12 is a C. sub. 8-22 alkyl dimethylamine oxide surfactant, C. sub. 6-12 alkyl dimethylamine oxide surfactant, C. sub. 8-18 alkyl polyethylene glycol sorbitan fatty acid ester Surfactants, and cleaning compositions such as C. sub. 12-14 secondary alcohol ethoxylate surfactants. The C.sub.8-18 alkyl polyethylene glycol sorbitan fatty acid ester surfactant contains 0 to about 20 ethoxylate functional groups for the C.sub.8-18 alkyl polyethylene glycol sorbitan fatty acid ester molecule. The C.sub.12-14 secondary alcohol ethoxylate surfactant contains about 14 to about 16 ethoxylate functional groups for the C.sub.12-14 secondary alcohol ethoxylate surfactant molecule.

In yet another embodiment, a cleaning composition for cleaning an exterior surface of a vehicle is provided. The cleaning composition comprises from about 0.1% to about 5% by weight of C. sub. 8-16 alkyl dimethylamine oxide surfactant, from about 0.1% to about 5% by weight of C. sub. 6-10 alkyl dimethylamine oxide interface. Activator, from about 0.1% to about 5% by weight of C. sub. 10-14 alkyl polyethylene ester surfactant, and from about 14 to about 16 of the C. sub. 12-14 secondary alcohol ethoxylate surfactant molecule. From about 0.1% to about 5% by weight of C. sub. 12-14 secondary alcohol ethoxylate surfactant including oxylate. The C.sub.10-14 alkyl polyethylene glycol sorbitan fatty acid ester surfactant contains 0 to about 6 ethoxylate functional groups for the C.sub.8-18 alkyl polyethylene glycol sorbitan fatty acid ester molecule. The C.sub.12-14 secondary alcohol ethoxylate surfactant contains about 14 to about 16 ethoxylate functional groups for the C.sub.12-14 secondary alcohol ethoxylate surfactant molecule. C. sub. 8-16 alkyl dimethylamine oxide surfactant, C. sub. 6-10 alkyl dimethylamine oxide surfactant, C. sub. 10-14 alkyl polyethylene glycol surfactant, and C. sub. 12-14 secondary The alcohol ethoxylate surfactant is provided in a 1:1:1:1 ratio in the cleaning composition. When applied to a vehicle, the cleaning composition is effective in removing chemical warfare agents from the exterior surface of the vehicle.

In one application example, a method of cleaning an exterior surface of a vehicle using the cleaning composition may be applied. The method includes providing a cleaning composition, applying the cleaning composition to an exterior surface of a vehicle, and rinsing the exterior surface of the vehicle with water.

However, once displaced at a fine location, a material can be exposed to a reactive spectrum (photoelectron radiation, oxidation, chemical modification by foreign substances) that facilitates its chemical conversion. That is, the fact that, for example, SSDX-12 can be applied to the surface of a vehicle as a cleaning composition does not mean that the dissolved solution is non-toxic or environmentally friendly. That is, in this state, the toxin becomes very vulnerable to natural forces, which inevitably promotes its low energy state.

Concrete surfaces can appear solid from our point of view, but when viewed finely, they can consist of a network of complex passages. It is the same as any porous surface. In many cases, a close examination reveals the maze. Delivery of chemicals into these microscopic environments requires significant surface tensions to be overcome. Surface tension is a property of a liquid, which defines how it diffuses over the surface and how well it will penetrate into the surface. The patented formulation of D7 allows very low surface tension values to be obtained at the surface. These values are not equilibrium values, but rather dynamic values. The turbulent solution thus produced by the foaming of hydrogen peroxide will continuously regenerate itself at the leading edge, which itself penetrates into the surface. These transient and considerably low surface tension values enable deeper penetration of the active chemicals implemented in D7. Cationic quaternary amine surfactants combined with an alkaline pH carbonate buffer system create a pathway for more effective permeable delivery of complex cleaning chemicals implemented in D7. The product acts in a similar manner to a hydraulic fracturing mechanism without a high pressure pump.

Alkali carbonates (potassium based) interact predominantly with negatively biased surfaces.

Quaternary amines are strongly adsorbed on negatively biased surfaces

The hydraulic channels are opened to deliver detergency in the form of water, peroxides and other nonionic species formulations.

In its ability to penetrate/eradicate biofilms over traditional forms, D7 offers advantages over prior art. For example, a biomembrane consists of a matrix of secreted chemicals, which protects the pathogen colony from the threat of invasion. These membranes have nutrient pathways, respiratory pathways, and transpiration pathways, and their exact nature is subject to intense vaginal questions. The physiochemical solution properties of D7 interact in a way that effectively and thoroughly destroys these surfaces. Solvent properties and oxidation from peroxide and peracetic acid species effectively "explore" to open the surface of the film and, in some cases, assist in breaking the functional pathway, resulting in terminal breakdown. Biomembrane effectively organizes the water in the secreted extracellular matrix, and these membranes are destroyed in many cases by the D7 cleaning mechanism.

Embodiment D7 describes a chemical formulation designed and improved for the decontamination, disinfection and regeneration of surfaces exposed to chemical, biological and toxic industrial pollutants and residues. These formulations improve the prior art by expanding the efficacy spectrum, reducing treatment time, modifying chemical properties, allowing lower effective dosages, and broadening the list of chemicals that are thereby restored. The formulations described herein can also be applied in variable concentrations to achieve decontamination purposes (cleaning, sanitation, disinfection, high level disinfection, mold removal, biofilm removal, targeted decontamination).

The implementation of D7 targets incremental variants designed to perform a specific task, which is the intent of this effort. In one embodiment, aspects of the invention can be formulated with a first generation version of a quaternary amine (ADBAC). It is believed that broadening the types of quaternary amines may bring advantages in efficacy against a wider range of pathogens or greater effect on biofilms. Among the two, the biofilm effect can be a task of remarkable value.

In addition, D7 provides a brief list of ingredients. D7 is not made with foreign ingredients. It is assembled with materials that are common, harmless and readily available. Their combination produces a net effect greater than each simple sum.

The physical properties implemented in D7 represent some of the success stories. Things like dynamic surface tension, critical micelle concentration, number of micelle structure aggregates, solvent potential and solution polarity all contribute to the mysterious behavior of D7.

One of the more potent actions of D7 arises from micelle formation. These micelles act as small reaction plants, where toxins react with activated oxygen species to neutralize or harmless.

If D7 is applied first in response to the biofilm problem, it is expected to show important effects to customers. Destroying the biofilm that protects the bacterial colonies virtually guarantees the destruction of the prokaryotic bacteria itself. Listed below is a list of the efficacy of D7 in relation to various organisms:

From a fourth generation perspective, the following comparison is relevant.

5th generation quaternary amine. This category is a mixture of first and fourth generations. When considering permutation of different first-generation chemicals with fourth-generation variants, this innovation option can grow rapidly. In one embodiment, the D7 formulation comprises:

In one embodiment, the fifth generation surfactant and dimethyl dialkyl quaternary amine provide improved structure to micelles developed in the D7 formulation.

These surfactants can modify the Gouy-Chapman-Stern layer to the point of having an improved and improved ability to dissolve the agent more rapidly into the micelle body.

In one embodiment, the surfactant may modify the Gouy-Chapman-Stern layer, and the degree of modification may be linked to the rate at which the agent is decontaminated, or may be the degree of decontamination.

Embodiments of the present invention may have different physical properties. The efficacy profile of this version is also different. The progression of the efficacy profile should be extended to the full version, with a diluted version, perhaps a 1:100 dilution of the final product. The diluted version can be considered for surfaces that are already clean and where no biofilm is present. In one embodiment, the concentrated version is contemplated for environments with more heavy dirt (living animal facilities, processing plants, sites with high potential for biofilm). Various embodiments of the present invention with respect to different diluents (bacteria, biofilm, spray efficacy) may enable various levels of application in addition to those disclosed in FIG. 1.

This improvement over the prior art allows consideration of the entire spectrum of products that can handle sensitive cleaning and sanitation situations, such as those encountered in food contact environments. In these circumstances, it may be possible to apply the product to the target surface by spraying, generally and to distribute the cleaning/sanitization formulation over the entire surface to wipe it off. In one embodiment, aspects of the invention may need to be approved by regulatory oversight bodies prior to use. In this case, it is commonly known as a "residual" product. The legal limits of the ingredients allowed for this type of use are labeled. It is the embodied intent of this improvement to enable this type of use. The full century version of the product is intended for use in highly damaged environments, such as live animal cages where severe dirt is expected. This represents the other end of the product spectrum. Regulatory oversight is also a necessary requirement with regard to pesticide implementation. Between these two extremes, it is expected that there will be many situations requiring intensity control products. An example of this situation is given in the spectrum above.

It is sometimes necessary to promote metastasis to a less harmful state. Pathogens, industrial toxic chemicals, or other undesirable substances are not challenged in the surrounding environment, except for these reactive agents common to the environment. Natural therapeutics for the treatment of invasion into the body include predation by organisms, hydrolysis by water, photolysis by electromagnetic radiation, absorption by substrates, and shielding of pathogens by environmental membranes, to name a few. If the pathogen is dissolved in water, a simple rinse may be sufficient. The kinetic time frames for these actions can range from medium to very long periods of slow transitions. Transferring the activity of reactive chemicals in the form of oxidative or nucleophilic substitutions is a well-known and effective therapeutic strategy in common practice. This is the route through which numerous agents deliver their effective doses. Once a material is oxidized, it is generally more susceptible to environmental decay through one or more of the above-mentioned mechanisms. Delivering oxidative activity to the target is not always right. For example, the use of bleach is a common practice in the field of disinfection and decontamination. Bleach is an aqueous solution whose ability to penetrate and bind pathogens is limited by the physiochemical barriers embodied in the substrate being treated. If the active fungicide does not react in the vicinity with the target pathogen, nothing happens. For this reason, disinfection and decontamination agents are formulated into a material that can deliver the material to where it reacts nearby by overcoming the physiological barrier of interfacial tension and surface energy. Also, substances that are not soluble in water may not be susceptible to reactions based on limited exposure to reactive conditions.

As mentioned above, D7 is an agent that overcomes physiochemical barriers for the delivery of reactive oxidizing species to pathogenic targets, and by its design assists the ability to bring resistant substances into solution, and pathogenic targets are then It is vulnerable to oxidation by the mechanism implemented in D7. This new version of the formulation is an improvement over the previous version and demonstrates a more robust and effective ability to perform decontamination/disinfection operations. By changing the surfactant properties of the formulation, faster decontamination time and complete destruction of the pathogenic layer protective film results in further improved removal.

D7 is a decontamination agent in a dilute form that safely transfers the energy of chemical oxidation with the aim of promoting the oxidation of toxins into less harmful or completely harmless destruction. D7 chemically treats toxins by promoting oxidation and consequently accelerating the decontamination process. As such, D7 acts to promote decontamination. Applying the SSDX-12 before D7 improves the net effect by enabling displacement of the adsorbed material.

In one embodiment, a 15:1 equivalent unit dose of SSDX-12 and D7 is desirable to achieve targeted results with the correct properties and effects on surface decontamination.

In another embodiment, in improving the foaming properties of the combination of D7 and SSDX-12, BTC 8358 can be used for the fifth generation quaternary instead of BTC 888. In one embodiment, the fifth generation quaternary so modified at about 4.0% treats contaminants by applying a combination of D7 (with an added 15:1 or 30:1 equivalent unit dose of SSDX-12) to a given surface. If so, the foam can preferably be reduced.

The foregoing description and drawings merely describe and illustrate the invention, and do not limit the invention thereto. While this specification has been described with respect to a particular implementation or implementation, many details are presented for purposes of illustration. Thus, the above description merely illustrates the principles of the present invention. For example, the invention may have other specific forms without departing from its spirit or essential features. The described arrangement is illustrative and not limiting. To those skilled in the art, the present invention is possible with additional implementations or embodiments, and these details described in this application can be significantly changed without departing from the basic principles of the present invention. Accordingly, those skilled in the art will understand that, although not explicitly described or illustrated in the present invention, various arrangements can be devised, within the scope and spirit of the present invention, to embody the principles of the present invention.

While various implementations have been described above, it should be understood that this disclosure has been presented by way of example only and is not limiting. Accordingly, the breadth and scope of the present compositions and methods should not be limited by any of the foregoing exemplary embodiments, but should be defined only in accordance with the following claims and their equivalents.

While the present compositions and methods have now been fully described, those skilled in the art will understand that the same can be performed within a broad and equivalent range of conditions, formulations and other variables without affecting its scope or any embodiment thereof. All cited patents, patent applications, and publications are incorporated by reference in their entirety.

Claims (2)

As an improvement process for decontaminating the surface using a stepwise approach, based on a D7 formulation with pathogen/agent/toxin destruction on the surface after migration of the pathogen/agent/toxin, the D7 formulation is used to treat the garment. In order to add SSDX-12, the D7 preparation has an active ingredient of a quaternary amine as a decontamination agent and an activator to loosen and become soluble in dirt and grime on the garment. As an improvement process for decontaminating the surface using a stepwise approach, based on a D7 formulation with pathogen/agent/toxin destruction on the surface after migration of the pathogen/agent/toxin, the D7 formulation comprises SSDX-12. An improvement process, adding in a ratio of 15:1 or 30:1 equivalent unit capacity, and BTC 8358 replacing BTC 888 at about 4.0% for D7's fifth-generation quaternary.

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