NO854489L - SOLUTION. - Google Patents

Description

The present invention relates to a cleaning agent, especially intended for washing hands, a method for producing the cleaning agent and a method for washing hands using such a cleaning agent.

The inventor has postulated that the principle mode of transmission of bacteria and viruses between humans is by auto-inoculation, i.e. that bacteria, viruses and other disease-causing vectors are captured on the fingers or other parts of the hand and then introduced into the body by touch of eyes, mouth, nose, ears and other body openings and by surface scratching of the skin. Studies conducted in this regard by the inventor and others suggest that the frequency of infection via airborne vectors is relatively low.

It is recognized by the present inventor that the fingertips and especially the area under the fingertips, i.e. the subungual area, is an ideal environment for the survival of pathogenic vectors. These areas show conditions of heat, humidity, blood flow, pulse resonance and contact with saliva and mucus which are favorable for the survival of microorganisms. In addition, substrates such as keratin to which many bacteria and viruses bind electrostatically or otherwise may also be present on the fingertips that allow the microorganism to resist removal by surface washing.

It is believed that at least some bacteria, viruses and fungi can sense the environment they are in and modify their own chemistry to increase inefficiency in the recognized environment. Thus, it is assumed that such organisms, when they settle in the fingertip area where the vascular network in the hand is concentrated and where the skin at least in the subungual area is very thin, are able to recognize the chemical mechanism in the host and prepare themselves to infect this host when introduced into a suitable part of the host's body.

It will also be recognized that the accumulation of cellular debris from other animals such as dogs, cats etc., in addition to infectious substances taken up from other sources, can occur in the subungual area of the hands. These can also be sources of infection for the host.

The present inventor has noticed that in both adults and children there is a strong tendency to touch the eyes, nasal area, mouth and ears as well as to come into contact with the genitalia and possibly the anus. The fingernails also cause coming into contact with smaller and larger skin breaks. Such pathogenic organisms and substances that are on the fingertip area of a host have every opportunity to be transferred to this host's body. If, as has been postulated, infectious organisms located under the fingernails have predisposed themselves to infection from the host, it will be clear that the degree of self-infection, i.e. auto-inoculation, will be high. The fingertips will also represent a source of reinfection so that after treatment with antibiotics, a host can be reinfected from the fingertips where the pathogenic organism has survived the host's antibiotic treatment.

This cycle of infection and re-infection from the fingertips can only be broken by cleaning the fingertip area sufficiently to reduce the population of bacteria, viruses and other pathogenic elements that reside there, and/or by changing the physical and chemical environment in this area so that it represents a less desirable niche for the development of pathogenic organisms and the accumulation of pathogenic substances. Conventional hand washing concentrates the cleansing action on the palms of the hands and leaves the fingertip area largely untouched if the nails are not specially brushed. Even nii-ij i ■>■■!_; 11 ] ,-i>r;^ [ i n gr n. mj 1 •„/, ri; with conventional substances oI>:;.u are not significant long term reduc ions for pathological populations. The present inventor has recognized that the fingertip area can be readily cleaned by placing the fingertips, a term intended to include the tips of the thumbs, down to a position beyond the fingernails, in a cleaning agent which is firm but of such penetrability that the fingertips can be easily inserted in it and that it will come into contact with the subungual area of the fingers. The cleaning agent that sticks to the fingers can then be used to wash the hands.

The invention consists of a water-soluble or -dispersible cleaning agent which is solid at room temperature, has a penetrability (as defined below) of from 50 to 250 mm, a dissolution rate (as defined below) of less than two minutes, and which has such a consistency that when the fingers of the human hand are pushed into the cleaning agent preparation for a length of 30 mm and pulled out, sufficient cleaning agent preparation will adhere thereto and thus enable the user's hand to be washed with the cleaning agent preparation adhering to the fingertips.

As used herein, the term "penetrability" means the distance in mm that a 30 mm cone and a 50 g weight in a "Stanhope - Seta" penetrometer will penetrate the cleaning agent after the cone has been aligned with the surface thereof and then released. As used herein, "dissolution rate" means the time taken for 10 g of the cleaning agent to dissolve or disperse when placed in 100 g of water at 55°C and stirred vigorously with a manually operated spatula.

The cleaning agent according to the invention differs from conventional hard soaps which have a penetrability of 5 mm or less and into which the fingers cannot be pushed. It must also be seen as distinct from conventional liquid soaps which have an infinite penetrability and into which the fingers can freely move without resistance. The liquid soaps do not have sufficient penetration resistance to ensure that the cleaning agent is forced into the subungual area and other cavities around the fingertip where bacteria, viruses and other pathogens can reside.

The cleaning agent according to the invention differs further due to the rapid dissolution rate or dispersion of the cleaning agent in water. This ensures that the cleaning agent is forced into the subungual and other areas but does not remain there after washing the hands. If the cleaning agent were to remain under the fingernails after washing the hands, there would be a tendency for dried particles of the cleaning agent to be introduced into the user's mouth, nose or eyes. Conventional hand soaps have been found to have dissolution rates substantially in excess of two minutes and typically in excess of five minutes and later in excess of an hour.

The cleaning agent according to the invention preferably has a consistency such that from 0.5 to 1 g of cleaning agent remains on the fingers and a hand of a typical adult man when the hand is pushed into the cleaning agent for a length of 30 mm and then pulled out. This amount of detergent is typically enough to wash your hands. If the cleaning agent did not stick to the user's hand to some extent, there would be less cleaning effect in the subungual area of the fingers.

It is preferred that the cleaning agent according to the invention is such that the pH value on the surface of the washed skin is from 7.5 to 8.5. It is believed that under these mildly alkaline conditions the keratin of the skin is essentially isoelectric and the ability of pathogenic microorganisms to adhere to the skin by electrostatic forces is reduced. For this reason, the cleaning agent preferably has a pH value of 7.5 to 9.5. Typical conventional hand soaps have a pH value above 9.5.

The pH value in the cleaning agent is tied to another preferred characteristic of cleaning agents according to the invention when a

main active ingredient is a soap, e.g. a salt of a long-chain fatty acid. The soaps are usually produced by reacting caustic soda with long-chain fatty acids. In preferred embodiments of the cleaning agents according to the invention, the fats and oils from which the fatty acids are derived are present in a substantial stoichiometric excess in relation to the caustic soda. Such cleansers are known as "super-fat" soaps. The super grease has two desirable properties. Firstly, the pH value will generally be lower in such a soap and secondly, excess fats and oils in the soap will prevent "drying out" of a user's hands and leave a film on the hands that can carry antimicrobial agents as well as providing a pleasant "feeling".

Such soaps will, as a result of the stoichiometric inferiority of caustic soda, have a very small degree of free alkalinity. The preferred cleaning agents according to the invention have less than 0.02% free alkalinity, measured according to Australian Standard AS1877-1976. This is in contrast to typical hand soaps, which have a free alkalinity of approx. 0.1%.

While the cleaning agents according to the invention will usually be soap-based, it is possible to formulate cleaning agents according to the invention from synthetic detergents. In this case, however, care must be taken in the overall formulation if a high fat content is to be achieved. It is highly preferred that the soap on which the cleaning agent is based contains fatty acids from at least four sources. The fatty acids preferably include those derived from at least four of the fats selected from the group:

lard,

coconut oil,

palm oil e,

beeswax,

paraffin wax,

continued

castor oil,

mixed non-hardening oils, a

lanolin,"

butter and

tallow

The weight ratio between fat and caustic soda used in the manufacture of the soap base is preferably 7.3 to 8.5.

It has been found desirable to use non-drying fats and oils in the cleaning agents according to the invention as these fats and oils do not have a tendency to cross-link during storage, which happens with the hardening oils. The choice of palm oil with its high content of palmitic acid and the use of cholesterol-containing fats are thought to underpin the cleaning agent's antiviral properties. It is believed that these substances dissolve the lipid coatings on viruses and denature the virus. However, it is believed that the presence of dissolved viral materials on the fingertips contributes to a "self-vaccination" of the user with these viral antigens. The self-vaccination supports body-resistant infection from this virus in the future.

The cleaning agent according to the invention preferably contains an antimicrobial agent. The use of the term "antimicrobial: agent" herein denotes an agent that either inhibits the growth of bacteria or other microorganisms or actually kills them. The term includes fungicides, fungistats, bactericides and bacteriostats. The antimicrobial agent is preferably both fungicide and bactericide. In practice, it has been found desirable to include a number of antimicrobial agents in the cleaning agent.

It is strongly preferred that the antimicrobial agent does not kill all pathogenic organisms on the fingertips. It is preferred that a small population is allowed to remain so that self-vaccination of the person using the cleanser will occur. The invention postulates that if a small, non-viable population of weakened organisms is left in the area around the fingertips, these organisms will be introduced into the user's body through the nose , mouth, eyes, etc. where they will induce an antibody reaction. The body's antibody response mechanism will then adapt to the microorganism with which the body comes into contact. The body's immune system will thus be better able to deal with any significant invasion by such organisms.

It is believed that the weakening of microorganisms is improved by the presence of a superfatting agent in the cleaning agent. A super-fatty cleaning agent, when used in the method according to the invention, introduces a thin film of fat on the fingertips and under the fingernails. This film is non-conductive and interferes with the bioelectric currents in the fingertip area shown in Kirlian high-voltage photography of the fingers. It is postulated by the present invention that the isolation of microorganisms in the subungual area from the bioelectricity in this area will inhibit the growth and ineffectiveness of organisms.

In preferred embodiments of the invention, the antimicrobial agents include what is marketed under the designation "Irgasan" such as "Irgasan" DP300, whose active ingredient is 2,4,4'-trichloro-2'-hydroxy diphenyl ether in an amount by weight from 0 ,1 to 5% and preferably approx. 1%. It is also preferred that the cleaning agent includes iodine, potassium iodide or a mixture thereof as an additional microbial agent. Other antimicrobial agents such as formalin and zinc oxide may be incorporated in addition to or instead of the preceding preferred antimicrobial agents.

In the event that iodine-based antimicrobial agents are used, the present inventor has found that the best antimicrobial activity is achieved when iodine and an iodide are used together in a weight ratio of from 1:20 to 1:60 and preferably 1:50.

The cleaning agent according to the invention will then have a water content of from 30 to 85 weight-V. The higher the water content, the lower the price for the product, but likewise the cleaning and antimicrobial activity will probably be less with a greater water content. The fat and soap content is preferably from 10 to 50% by weight of the cleaning agent.

The cleaner may include random ingredients for a number of purposes. Honey is preferably incorporated as it is hygroscopic. It is believed that the presence of small amounts of honey in the film that remains on the hands will tend to dry out. the skin in the riulnunjii.-xl o oror "idr-: . iv ;[.L ug u.t the tips and, which makes the area less suitable for residence and growth for pathogenic microorganisms. The cleansing preparations preferably have a color that will not stand in significant contrast to the skin and thus pink, beige, pale brown or other skin tones are preferred.Suitable dyes may be added if desired so that any light film remaining on the skin or under the nails will not be obviously visible.

In another aspect, the invention consists in a method for washing the hands comprising dipping the dry fingers including the thumb substantially vertically into a cleaning agent according to the invention to a depth sufficient to at least cover the fingernails, but without introducing the entire finger into the cleaning agent, and withdrawing the fingers from the agent, and moistening the hand with water and then washing the hands with the cleaning agent that adhered to the fingers.

While the cleaning preparations according to the invention are particularly useful for cleaning the hands and especially the fingertips, it should be clear that this preparation can also effectively clean the rest of the human body and is also used for other cleaning purposes. It can be applied with the fingers, with a sponge or in any other suitable way. However, the cleanser is particularly preferred for use as a hand cleanser due to its ability to penetrate the subungual areas and other cavities surrounding the fingertips and to remove dirt and debris therefrom as well as supporting the physical removal of pathogenic organisms. As outlined above, the cleaning agent can thus change the physical and chemical environment of the fingertips so that they no longer provide any supportive niche that is normally found there for pathogenic organisms.

The soap according to the invention can be produced using one of two preferred methods, hereinafter called the cold or hot method.

In the cold method, fats and oils, antimicrobial agents etc. heated and mixed together and allowed to cool. At the same time, water and caustic soda are mixed and allowed to cool. The two cooled mixtures are then thoroughly mixed together to form an emulsion and the emulsion is poured into a small container in which the finished cleaning agent is to be sold. In this method, the soap base is produced in the final container in which it is to be sold, by a reaction between the fatty acids of the fats and oil and caustic soda.

In the heat method, the formed soap is boiled with water, superfatting ingredients and antimicrobial agents are added and dispersed as the soap solution cools, the soap being present in sufficient amounts to cause the solution to gel or settle to a solid consistency on cooling. The cleaning agent according to the invention, its manufacturing method and its use for cleaning hands shall be described below in greater detail with reference to the following examples.

Example 1

This example shows the preparation of a cleaning agent according to the invention by the cold method. The following ingredients were heated together, mixed and cooled:

At the same time, 160 g of caustic soda was dissolved in 1400 g of water in a separate container and the solution was allowed to cool.

The cooled mixtures were mixed together and poured into containers each containing 100g. The containers were set aside for a few days to allow time for the caustic soda to react with the fatty acids in the fats and oils contained in the first mixture. The resulting product was found to work excellently as a hand cleanser with a penetrability of approx. 90 mm and a resolution rate of approx. 1 to 2 minutes. It was found that the fingers of the hand could easily be introduced into the cleanser although there was sufficient resistance to force the cleanser under the fingernails.

Example 2

This example describes the production of a cleaning agent by the heat method.

1000 g of soap flakes were dissolved in water and boiled and allowed to cool. After the soap solution reached approx. At 40°C, the following was added and dissolved or dispersed in the soap solution:

After this mixture was further cooled to 30°C, the following ingredients were added and dissolved or dispersed:

This finished soap mixture was cooled to 25°C and poured into small containers where they gelled to a solid. This soap also gave a good performance as a cleanser for the fingers.

Example 3

The antimicrobial properties of the soap according to example 1 were tested and the results are given below. Two trained microbiologists washed under the fingernails and bacterial flora was counted using PCA/30°/72 hours: Pouring plate technique. During the first test week, normal hand washing techniques were used, i.e. iodine surfactant solution after laboratory work and household soap after ablutions, meals, etc. During the second test week, the subjects replaced the iodine hand washing with the soap according to example 1 which was used in the method according to the invention.

It appears that by using a conventional iodine/surfactant solution, an average bacterial count from the fingernails of 1.16 x 106 is achieved, while by using the cleaning agent according to the invention, one gets a count all the way down to 3.73 x 105.

Example 4

Detergent according to Example 1 was subjected to a "Primary Skin Irritation Test" according to the method of J.H.Draize, 1959, DermalToxicity Inst., Association of Food and Drug Officials of the U.S., Austin, Texas, "Appraisal of Safety of Chemicals in Foods, Drugs and Cosmetics", pp. 46-59.

Three albino rabbits were selected and both sides of the carcass were shaved free of hair. On one side, the skin was scraped up to break the stratum corneum but not the derma (ie, not to force bleeding). The other side was left intact.

The sample was diluted 1:2 with sterile distilled water and mixed to form a paste.

Each of the rabbits had 0.2 ml of this paste absorbed onto a 5 cm x 5 cm double strength gauze pad on the intact and scraped skin. These were held in place with adhesive tape and the entire animal carcass was covered with an impermeable rubber cuff. After 24 hours, the rubber and material were removed and the reactions assessed. These were assessed again 24 hours later.

The primary irritation index of 0.23 suggests negligible irritation.

Example 5

This experiment was conducted to determine the effect of the cleaning agent according to Example 1 on the bacterial density under the fingernail area. Samples were performed to determine the change in the population of mesophilic aerobic bacteria as well as any change in the presence of coagulase positive Staphylococcus spp. and any change in the presence of coagulase positive Staphylococcus spp.

Materials and methods

Contact was made with the committee in N.S.W. Car Club and agreed that they should use the product over a period of time and allow microbiological samples to be taken.

Samples were taken using sterile Aims Transport medium dot and stored for a maximum of 18 hours under refrigeration before testing. Total mesophilic aerobic bacterial counts were performed according to the A.S.A. 1766 but using Letheen agar instead of the more common Plate Count agar. This was done to denature any soap residue transferred to the sample.

The presence of Staphylococcus spp was carried out by pre-enrichment in Tryptone Soya broth with 101 NaCl, followed by plating on Baird-Parker Medium (Oxoid CM275). Suspect colonies were confirmed by the slide coagulase test.

Results

The presence of coagulase +ve Staphylococcus spp.

Claims (12)

1. Water-soluble or dispersed cleaning agent, characterized in that it is solid at room temperature, has a penetrability of from 50 to 250 mm, a dissolution rate of less than 2 minutes, and has such a consistency that the fingers of a human hand are pushed into the cleaning preparation 30 mm and is pulled off, sufficient cleaning agent preparation will adhere to it to enable the user's hand to be washed with the cleaning agent that has adhered to the fingertips. 2. Cleaning agent according to claim 1, characterized in that it has a consistency such that 0.5 to 1 g of the cleaning agent remains on the dry fingers of a typical adult man when the finger is pushed into the cleaning agent a length of 30 mm and pulled out again. 3. Detergent according to claim 1 or 2 can be characterized by having a pH value of from 7.5 to 9.5. 4. Detergent according to any one of claims 1 to 3, characterized in that they contain from 10 to 50% by weight of soap. 5 . Detergent according to claim 4, can be acted upon by the fact that the soap is super-fatty. 6. Cleaning agent according to claim 5, characterized in that in the soap the weight ratio between lard and caustic soda is from 7.3:1 to 8.5:1. 7 . Detergent according to any one of claims 4 to 6, characterized in that the soap contains fatty acids derived from at least 4 of those specified in the group comprising: lard, coconut oil, beeswax, paraffin wax, castor oil, mixed non-hardening oils, lanolin, butter and tallow 8 . Cleaning agent according to any one of claims 1 to 7, characterized in that the cleaning agent includes an antimicrobial agent. 9 . Cleaning agent according to claim <8,> characterized in that the antimicrobial agent is selected from the group comprising 2,4,4'-trichloro-2'-hydroxy diphenyl ether, iodine and formalin. 10. Method for washing the hands, characterized in that it comprises pushing the fingers, including the thumb, essentially vertically downwards into a cleaning agent according to the invention to a depth sufficient to at least cover the fingernails but without introducing the entire finger into the cleaning agent, withdrawing the fingers from the cleaning agent , wetting the hand with water and washing the hands with the cleanser on the fingers. 11. Process for the preparation of a cleaning agent according to any one of claims 1 to 9, characterized by heating together fats and oils and at least one antimicrobial agent, cooling the mixture, preparing a solution of caustic soda, mixing the mixture and the solution together thoroughly to form an emulsion and pouring the emulsion directly into containers in which the cleaning agent is to be sold. 12 . A method of preparing a cleaning agent according to any one of claims 1 to 9, characterized in that it comprises boiling a soap, superfatting ingredients and at least one antimicrobial agent with water and then allowing the boiled mixture to cool and gel.