BR102016024625B1 - NANOEMULSION AND METHOD FOR PREPARING THE NANOEMULSION - Google Patents

Abstract

NANOEMULSION, AND METHOD FOR PREPARING A NANOEMULSION The present invention concerns a nanoemulsion having reversible continuous and dispersed phases. The nanoemulsion includes an aqueous phase and an oil phase, a weight ratio of the aqueous phase to the oil phase being 1:40 - 100:1. In nanoemulsion, the aqueous phase is dispersed as nanosized droplets in the oil phase or the oil phase is dispersed as nanosized droplets in the aqueous phase. The aqueous phase contains water or an aqueous solution and a water-soluble organic nanostructure stabilizer. The oily phase contains an oil or an oily solution, an organic gel thickener, and a hydrophilic surfactant having an HLB value greater than 8.0. A method for preparing the nanoemulsion described above is also disclosed.

Description

HISTORY OF THE INVENTION

[001] There are two types of nanoemulsions, that is, an oil-in-water (o/w) nanoemulsion and a water-in-oil (w/o) nanoemulsion. An o/w nanoemulsion has a continuous water phase and a dispersed oil phase while the w/o nanoemulsion has a continuous oil phase and a dispersed water phase.

[002] These two types of nanoemulsions are stabilized by emulsifiers that have different hydrophilic-lipophilic balance (HLB) values. An o/w nanoemulsion is stabilized by an emulsifier having an HLB value of 828 and a w/o emulsion is stabilized by an emulsifier having an HLB value of 3-6. As a result, they cannot be easily interconverted.

[003] The absence of easy convertibility can be problematic. An o/w nanoemulsion collapses when its water content decreases. Similarly, a w/o nanoemulsion collapses when its oil content decreases.

[004] Thus, there is a need to develop a nanoemulsion in which its continuous phase and the dispersed phase can be readily converted from one to the other with the same emulsifier contained therein.

SUMMARY OF THE INVENTION

[005] A nanoemulsion containing reversible continuous and dispersed phases is disclosed here.

[006] The nanoemulsion of this invention includes an aqueous phase and an oil phase, a weight ratio of the aqueous phase to the oil phase being 1:40 -100:1. In nanoemulsion, the aqueous phase is dispersed as nanosized droplets in the oil phase or the oil phase is dispersed as nanosized droplets in the aqueous phase. The aqueous phase, which constitutes 2.5% by weight or more of the nanoemulsion, contains water or an aqueous solution and a water-soluble organic nanostructure stabilizer. The water or aqueous solution has a content of less than 75% by weight of the aqueous phase and the water-soluble organic nanostructure stabilizer has a content of less than 99% by weight of the aqueous phase. The oily phase contains an oil or an oily solution, an organic gel thickener, and a hydrophilic surfactant having an HLB value greater than 8.0. The oil or oily solution has a content of less than 80% by weight of the oily phase, the organic gel thickener has a content of less than 60% by weight of the oily phase, and the hydrophilic surfactant has a content of less than 60% by weight of the oil phase. oily phase. This nanoemulsion can be used as a carrier for an active ingredient in a cosmetic, food or pharmaceutical composition.

[007] Also within the scope of the present invention is a method for preparing the nanoemulsion described above. The method includes the following steps: (1) mixing the water or aqueous solution and the soluble organic nanostructure stabilizer to form an aqueous phase, wherein the water or aqueous solution has a content of less than 75% by weight of the aqueous phase and the water-soluble organic nanostructure stabilizer has a content of less than 99% by weight of the aqueous phase; (2) mixing an oil or aqueous solution, an organic thickener, and a hydrophilic surfactant having a hydrophilic-lipophilic balance value greater than 8.0 to form an oily phase, in which the oil or oily solution has a content less than 80% by weight of the oil phase, the organic gel thickener has a content of less than 60% by weight of the oil phase, and the hydrophilic surfactant has a content of less than 60% by weight of the oil phase; and (3) mixing the aqueous phase and the oil phase, a weight ratio of the aqueous phase to the oil phase being 1:40-100:1, to form a nanoemulsion, in which the water or aqueous solution constitutes 74% by weight or less of the nanoemulsion. Each of the mixing steps is carried out at a suitable temperature, for example 5-95 °C.

[008] In the nanoemulsion thus prepared, the aqueous phase is dispersed as nanosized droplets in the oil phase or the oil phase is dispersed as nanosized droplets in the aqueous phase. In other words, the continuous and dispersed phases in the nanoemulsion are reversible.

[009] Details of one or more realizations are set out in the description below. Other aspects, objectives and advantages of the achievements will be apparent from the specification and claims.

DETAILED DESCRIPTION

[010] The present invention is based, at least in part, on an unexpected discovery that a nanoemulsion, containing a hydrophilic surfactant having an HLB value greater than 8, can have either the aqueous phase dispersed as nanosized droplets in the oily phase or the oily phase dispersed as nanosized droplets in the aqueous phase. In other words, the nanoemulsion has reversible continuous and dispersed phases.

[011] This nanoemulsion can contain both oil-soluble active ingredients and water-soluble active ingredients, an advantage over conventional nanoemulsions. The advantage is especially important in the preparation of cosmetics, food, household chemicals, agriculture, printing, paints, veterinary, diagnostic, vaccine and pharmaceutical products, as demonstrated by the following two examples.

[012] An o/w emulsion is preferably used in a cosmetic product, as it is less sticky and oily than a w/o emulsion and has the desirable ability to retain water. However, when a cosmetic product is applied to the skin or exposed to air, the nanoemulsion in the cosmetic product loses water through evaporation. Loss of water causes the collapse of a conventional o/w nanoemulsion, but not the o/w nanoemulsion of this invention. Instead, the latter nanoemulsion slowly converts into a w/o nanoemulsion in which its water phase is uniformly dispersed as nanosized droplets in its oil phase.

[013] Differently, for an oil-soluble drug, a w/o emulsion is preferably used due to its high loading capacity. However, as body fluids are aqueous, when a w/o nanoemulsion comes into contact with body fluids, its water content inevitably increases. As a result, the conventional w/o nanoemulsion collapses. Furthermore, the w/o nanoemulsion of this invention slowly converts into an o/w nanoemulsion in which its oil phase is uniformly dispersed as nanosized droplets in the aqueous phase. Notably, the conversion not only maintains the integrity of a nanoemulsion but also provides a sustained release of the drug therein.

[014] As indicated above, the nanoemulsion of this invention includes an aqueous phase and an oily phase. In nanoemulsion, the aqueous phase can be dispersed as nanosized droplets in the oil phase. Alternatively, the aqueous phase can be dispersed as nanosized droplets in the aqueous phase.

[015] The aqueous phase includes a water-soluble organic nanostructure stabilizer. The term “water-soluble organic nanostructure stabilizer” herein refers to any water-soluble organic ingredient that can stabilize the isotropic structure of a nanoemulsion, thereby resulting in a thermodynamically stable or translucent nanoemulsion. It can be a water-soluble vitamin, a water-soluble peptide, a water-soluble oligopeptide, a polyol, a water-soluble saccharide, a water-soluble oligosaccharide, a disaccharide, a monosaccharide, a hydrogenated carbohydrate, an amino acid, an amino sugar, or a combination of these. Specific examples include urea, methylsulfonylmethane, hydroxyethyl, urea, glucosamine, mannitol, sorbitol, xylitol, lactose, fructose, dextrose, ribose, trehalose, raffinose, maltilol, isomalt, lactitol, erythritol, inositol, taurine, glycerin, propylene glycol, dipropylene glycol, butylene glycol , hexylene glycol, polyethylene glycol, ethoxydiglycol, carnitine, arginine, sodium pyrolidine carboxylic acid and hydrolyzed collagen.

[016] The oily phase contains an oil or an oily solution. A vegetable oil, a silicone oil, a synthetic oil, a mineral oil, an oil of animal origin, an essential oil, or a combination of these can be used to form the oily phase. Specific examples include coconut oil, palm oil, grapeseed oil, olive oil, grapefruit seed oil, flax seed oil, avocado oil, evening primrose oil, lavender oil, rosemary oil, essential oil of tea tree, eucalyptus oil, horse fat, fish oils, lanolin oil, squalene, cyclomethicone, cyclopentasiloxane, phenyl trimethicone, caprylic/capric triglyceride, isopropyl myristate, isostearyl isostearate, decyl oleate, ethylhexyl isononate, isohexadecane, octyldodecanol, paraffin oil, polydecene, polyisobutene, menthol or a combination of these. Note that the oily solution contains one or more oils as solvents to dissolve one or more oil-soluble solutes.

[017] As also pointed out above, the oily phase includes a hydrophilic surfactant having an HLB value greater than 8.0. Preferably the HLB value of the hydrophilic surfactant is greater than 10, and more preferably the HLB value is greater than 13. Examples of hydrophilic surfactant include polyoxyethylene sorbitan fatty acid esters (Tween 20, Tween 21, Tween 60, Tween 61, Tween 65, Tween 80, Tween 81, Tween 85), polyoxyethylene sorbitol fatty acid ester, fatty acid esters of polyoxyethylene acid esters (Myri 45, Myri 52, Myri 53, Myri 59), fatty acid esters of acid polyoxyethylene (Myri 45, Myri 52, Myri 53, Myri 59), polyoxyethylene alcohol ester (Brij 30, Brij 35, Brij 56, Brij 58, Brij 76, Brij 78, Brij 96, Brij 97, Brij 98, Brij 99) , nonylphenol alkoxylates (nonylphenol-based non-ionic surfactants Witconol™), alkyl alkoxylates (non-ionic surfactants from the Ethylan™ family), Pluronic F-127, PEG dimethicone, polyoxyethylene fatty acid ester (40), polyoxyethylene fatty acid ester polyoxyethylene saccharide (20), glyceryl fatty acid ester PEG-15, hydrogenated castor oil PEG-35, hydrogenated castor oil PEG-40, polyglycerol fatty acid ester, fatty amino derivatives or a combination thereof.

[018] In addition, the oily phase contains an organic gel thickener. The term “organic gel thickener” here refers to any substance that increases viscosity and causes the structural formation of a nanoemulsion. The organic gel thickener can be saturated fatty acid, fatty acid alcohol, a fatty acid derivative having a melting point above 45 ° C, or a combination thereof. Examples of organic gel thickener include stearic acid, lauric acid, glycerol monostearate, PEG 6000 diesterate, monoglyceride, diglyceride, saccharide fatty acid ester, propylene glycol fatty acid ester, glycol fatty acid ester, decylhexyl fatty acid ester , fatty acid alcohol, cetylesterate, ascorbyl fatty esters, glyceryl fatty esters, hexyldecyl fatty esters or a combination thereof.

[019] In one embodiment, the water or aqueous solution of the nanoemulsion of this invention has a content of less than 60% by weight of the aqueous phase and the water-soluble organic nanostructure stabilizer has a content of less than 70% by weight of the aqueous phase; the oil or oily solution has a content of 30-70% by weight of the oily phase, the organic gel thickener has a content of less than 45% by weight of the oily phase, and the hydrophilic surfactant has a content of less than 45% by weight from the oily phase; and the water or aqueous solution constitutes 38% by weight or less of the nanoemulsion and a weight ratio of the aqueous phase to the oil phase of 1:3-4:1. Preferably, the water or aqueous solution has a content of less than 45% by weight of the aqueous phase and the water-soluble organic nanostructure stabilizer has a content of less than 50% by weight of the aqueous phase; the oil or oily solution has a content of 45-65% by weight of the oily phase, the organic gel thickener has a content of less than 25% by weight of the oily phase, and the hydrophilic surfactant has a content of less than 35% by weight from the oily phase; and the water or aqueous solution constitutes 30% by weight or less of the nanoemulsion and a weight ratio of the aqueous phase to the oil phase of 1:2-3:1.

[020] The nanoemulsion of this invention is transparent or translucent in solid gel form or liquid form at a pH of 3-11. Additionally, it exhibits a nano characteristic, i.e., Tyndall effect of light refraction. See Gold and Silver Nanoparticles, Center for Nanoscale Chemical-Electrical-Mechanical Manufacturing Systems, University of Illinois, http://Nano-cémms.illinois.edu/media/content/teaching_mats/online/gold_and_silver_nanoparticles/docs/presentation.pdf.

[021] The nanoemulsion of this invention whose water or aqueous solution constitutes 38% by weight or less of the nanoemulsion has a self-preservation capacity and, therefore, there is no need to include an antimicrobial preservative in it. A preservative often raises safety concerns, as it can pose health hazards ranging from a mild headache to more serious illnesses, for example, cancer.

[022] When used in cosmetic, food and pharmaceutical compositions, this nanoemulsion can contain various active ingredients, for example, terbinafine, diclofenac, lorazepam, propofol, metronidazole, indomethacin, clotrimazole, ketoconazole, erythromycin, clibazole, kinetin, bifonazole, miconazole, tonalphtate, clobetasol, econazole, bezocaine, phenytoin, lovastatin, isosorbide, dinitrate, nitroglycerin, pharmotidine, bisabodol, lutein ester, melatonin, water-soluble vitamins, lycopene, resveratrol, ginsenoissides, vanillyl butyl ester, curcumin, and CoQ10. A nanoemulsion including a drug can be administered via various routes, for example, oral, topical, vaginal, rectal, sublingual, pulmonary and parenteral. If desired, certain sweeteners, flavorings, coloring agents or fragrances may also be added.

[023] The method of this invention for preparing the nanoemulsion described above includes first forming an aqueous phase and an oil phase separately, and then mixing the two phases. The water or aqueous solution and a water-soluble organic nanostructure stabilizer can be mixed by constant stirring (manually or otherwise), high-speed or high-shear mixing (e.g., using a colloid crusher), high-pressure mixing (e.g. using a micro fluidizer) or sonication mixture to form the aqueous phase. An oil or aqueous solution, an organic thickener, and a hydrophilic surfactant can also be mixed to form the oily phase. The resulting aqueous phase and the oil phase can then be mixed in a similar manner to form a nanoemulsion. It is worth noting that all mixing steps can be carried out at elevated temperature, e.g. 45-85°C, if necessary. Still of great importance, the oily phase and the aqueous phase thus obtained can be used to prepare either an o/or nanoemulsion or a w/o nanoemulsion, indicating that the continuous and dispersed phases are reversible.

[024] Without further elaboration, it is believed that the above description has adequately enabled the present invention. Therefore, the following examples should be construed as merely illustrative, and not limiting the rest of the revelation in any way. The publication cited here is incorporated herein by reference in its entirety.

EXAMPLE 1: DETERMINATION OF THE TYPE OF NANOEMULSION

[025] 60 ml of water were placed in a 100 ml beaker. A nanoemulsion to be tested was added in drops to the water. If the nanoemulsion dispersed in water creating a clear or translucent solution, the tested nanoemulsion was an o/w nanoemulsion. However, if the nanoemulsion formed oil-like droplets in water, the tested nanoemulsion was a w/o nanoemulsion.

EXAMPLE 2: PREPARATION OF COCONUT OIL NANOEMULSIONS

[026] The nanoemulsions were prepared following the procedure described below.

[027] Preparation of the aqueous phase of nanoemulsions

[028] A combination of 210 g of purified water, 90 g of urea, 60 g of xylitol, 60 g of Trehalose and 30 g of methyl sulfonyl methane were mixed under constant manual stirring in a 500 ml beaker at 65-75 ° C to form the aqueous phase.

[029] Preparation of the oil phase of nanoemulsions

[030] A combination of 80 g of coconut oil, 20 g of paraffin oil, 50 g of cyclomethicone, 20 g of beeswax, 10 g of glyceryl monostearate, 16 g of stearic acid, 14 g of sorbitan monostearate , 36 g of polyethylene glycol sorbitan monostearate and 42 g of PEG-40 hydrogenated castor oil were mixed by constant manual stirring in a 500 ml beaker at 65-75 °C to form the oily phase.

[031] Preparation of nanoemulsions

[032] A combination of the oil phase and aqueous phase prepared above in a weight ratio shown in Table 1 was mixed by constant manual stirring in a 200 ml beaker at 65-75 ° C for less than 0.5 hours to form a w/o or o/w nanoemulsion.

[033] All nanoemulsions were stable at room temperature for at least 3 months and exhibited Tyndall effect of light refraction.

[034] The type of each nanoemulsion prepared in this example was described following the procedure described in Example 1.

[035] An antimicrobial test was conducted following the procedure described in USP 35 <51>, Antimicrobial Effectiveness Testing, on page 52, and all nanoemulsions prepared in this example passed the antimicrobial test. EXAMPLE 3: PREPARATION OF PALM OIL NANOEMULSIONS

[036] The nanoemulsions were prepared following the procedure described below.

[037] 150 g of a w/o nanoemulsion composed of 30 g of the aqueous phase and 120 g of the oily phase was prepared following the procedure described in Example 2 except that palm oil was used instead of coconut oil. The nanoemulsion of this form was translucent and stable at room temperature for at least 3 months. The nanoemulsion exhibited the Tyndall effect of light refraction.

[038] 150 g of a w/o nanoemulsion composed of 60 g of the aqueous phase and 90 g of the oily phase was prepared following the procedure described in Example 2 except that palm oil was used instead of coconut oil. The nanoemulsion of this form was clear and stable at room temperature for at least 3 months. The nanoemulsion exhibited the Tyndall effect of light refraction.

[039] 150 g of an o/w nanoemulsion composed of 60 g of the aqueous phase and 90 g of the oily phase was prepared following the procedure described in Example 2 except that palm oil was used instead of coconut oil. The nanoemulsion of this form was clear and stable at room temperature for at least 3 months. The nanoemulsion exhibited the Tyndall effect of light refraction.

[040] 100 g of an o/w nanoemulsion composed of 75 g of the aqueous phase and 25 g of the oily phase was prepared following the procedure described in Example 2 except that palm oil was used instead of coconut oil. The nanoemulsion of this form was clear and stable at room temperature for at least 3 months. The nanoemulsion exhibited the Tyndall effect of light refraction.

[041] The type of each nanoemulsion prepared in this example was described following the procedure described in Example 1.

[042] All nanoemulsions prepared in this example passed the antimicrobial test, which was conducted following the procedure described in USP 35 <51>, Antimicrobial Effectiveness Testing, on page 52. EXAMPLE 4: PREPARATION OF HORSE FAT NANOEMULSIONS

[043] The nanoemulsions were prepared following the procedure described below.

[044] 150 g of a w/o nanoemulsion composed of 60 g of the aqueous phase and 90 g of the oily phase was prepared following the procedure described in Example 2 except that horse fat was used instead of coconut oil.

[045] 100 g of an o/w nanoemulsion composed of 60 g of the aqueous phase and 40 g of the oily phase was prepared following the procedure described in Example 2 except that horse fat was used instead of coconut oil.

[046] The nanoemulsions prepared in this way were clear and stable at room temperature for at least 3 months. Both exhibited the Tyndall effect of light refraction.

[047] The type of each nanoemulsion prepared in this example was described following the procedure described in Example 1.

[048] An antimicrobial test was conducted following the procedure described in USP 35 <51>, Antimicrobial Effectiveness Testing, on page 52, and both nanoemulsions prepared in this example passed the antimicrobial test. EXAMPLE 5: Preparation of horse fat nanoemulsions

[049] The nanoemulsions were prepared following the procedure described below.

[050] Preparation of the aqueous phase of nanoemulsions

[051] A combination of 150 g of purified water, 150 g of urea, 40 g of mannitol was mixed with constant manual stirring in a beaker at 65-75 ° C to form the aqueous phase.

[052] Preparation of the oil phase of nanoemulsions

[053] The oily phase was prepared following the procedure described in Example 2 except that horse fat was used instead of coconut oil.

[054] Preparation of nanoemulsions

[055] 150 g of a w/o nanoemulsion composed of 60 g of the aqueous phase and 90 g of the oil phase was prepared following the procedure described in Example 2.

[056] 100 g of an o/w nanoemulsion composed of 60 g of the aqueous phase and 40 g of the oily phase was prepared following the procedure described in Example 2.

[057] The nanoemulsions prepared in this way were clear and stable at room temperature for at least 3 months. Both exhibited the Tyndall effect of light refraction.

[058] The type of each nanoemulsion prepared in this example was described following the procedure described in Example 1.

[059] An antimicrobial test was conducted following the procedure described in USP 35 <51>, Antimicrobial Effectiveness Testing, on page 52, and the two nanoemulsions prepared in this example passed the antimicrobial test. EXAMPLE 6: Preparation of palm oil/squalene nanoemulsions containing only a hydrophilic surfactant

[060] The nanoemulsions were prepared following the procedure described below.

[061] Preparation of the aqueous phase of nanoemulsions

[062] A combination of 180 g of purified water, 100 g of urea, 20 g of butylene glycol was mixed with constant manual stirring in a 500 ml beaker at 65-75 ° C to form the aqueous phase.

[063] Preparation of the oil phase of nanoemulsions

[064] A combination of 100 g of palm oil, 20 g of squalene, 25 g of cyclomethicone (DC-345), 10 g of beeswax, 20 g of stearic acid, 16 g of sorbitan monostearate, and 60 g of PEG-40 hydrogenated castor oil was mixed by constant manual stirring in a 500 ml beaker at 65-75 °C to form the oily phase.

[065] Preparation of nanoemulsions

[066] A combination of the oil phase and aqueous phase prepared above in a weight ratio shown in Table 2 was mixed by constant manual stirring in a 500 ml beaker at 65-75 ° C for up to 0.5 hour to form a nanoemulsion also listed in Table 2.

[067] All of the above nanoemulsions were stable at room temperature for at least 3 months and exhibited Tyndall effect of light refraction.

[068] The type of each nanoemulsion prepared in this example was described following the procedure described in Example 1.

[069] An antimicrobial test was conducted following the procedure described in USP 35 <51>, Antimicrobial Effectiveness Testing, on page 52, and all nanoemulsions prepared in this example passed the antimicrobial test. EXAMPLE 7: PREPARATION OF PHARMACEUTICAL NANOEMULSIONS BASED ON COCONUT OIL

[070] The nanoemulsions were prepared following the procedure described below.

[071] 50 g of an o/w nanoemulsion composed of 29.5 g of the aqueous phase and 20 g of the oily phase dissolving 0.5 g of an oil-soluble pharmaceutically active ingredient was prepared following the procedure described in Example 2. Oil-soluble pharmaceutically active ingredient is terbinafine, diclofenac diethylamine, dithylamine, metronidazole, indomethacin clotrimazole or erythromycin.

[072] The six nanoemulsions prepared in this way were clear and stable at room temperature for at least 3 months. They exhibited the Tyndall effect of light refraction.

[073] The type of each nanoemulsion prepared in this example was determined following the procedure described in Example 1.

[074] An antimicrobial test was conducted following the procedure described in USP 35 <51>, Antimicrobial Effectiveness Testing, on page 52, and all nanoemulsions prepared in this example passed the antimicrobial test. EXAMPLE 8: PREPARATION OF PHARMACEUTICAL NANOEMULSIONS BASED ON PALM OIL

[075] The nanoemulsions were prepared following the procedure described in Example 7 except that palm oil was used instead of coconut oil and the oil-soluble pharmaceutically active ingredient is terbinafine, diclofenac diethylamine, metroconazole, kinetin, bifonazole and miconazole.

[076] The six nanoemulsions prepared in this way were clear and stable at room temperature for at least 3 months. They exhibited the Tyndall effect of light refraction.

[077] The type of each nanoemulsion prepared in this example was described following the procedure described in Example 1.

[078] An antimicrobial test was conducted following the procedure described in USP 35 <51>, Antimicrobial Effectiveness Testing, on page 52, and all nanoemulsions prepared in this example passed the antimicrobial test. EXAMPLE 9: PREPARATION OF ESSENTIAL OIL NANOEMULSIONS CONTAINING CLIMBAZOLE

[079] The nanoemulsions were prepared following the procedure described below.

[080] Preparation of the aqueous phase of nanoemulsions

[081] A combination of 150 g of purified water, 150 g of urea, 40 g of propylene glycol was mixed with constant manual stirring in a 500 ml beaker at 65-75 ° C to form the aqueous phase.

[082] Preparation of the oil phase of nanoemulsions

[083] The combination of 40 g of tea tree essential oil, 20 g of eucalyptus oil, 30 g of menthol, 50 g of paraffin oil, 50 g of cyclomethicone (DC-345), 20 g of beeswax, 10 g of glyceryl monostearate, 16 g of stearic acid, 14 g of sorbitan monostearate, 36 g of polyethylene glycol sorbitan monostearate and 42 g of PEG-40 hydrogenated castor oil was mixed in a 500 ml beaker by manual stirring. constant at 65-75 °C to form the oily phase.

[084] Preparation of nanoemulsions

[085] 150 g of a w/o nanoemulsion composed of 60 g of the aqueous phase and 90 g of the oil phase was prepared following the procedure described in Example 2.

[086] 150 g of an o/w nanoemulsion composed of 90 g of the aqueous phase and 60 g of the oil phase was prepared following the procedure described in Example 2.

[087] 100 g of an o/w nanoemulsion composed of 59 g of the aqueous phase dissolving 10 g of climbazole and 40 g of the oily phase was prepared following the procedure described in Example 2.

[088] All of the above nanoemulsions were clear and stable at room temperature for at least 3 months. They exhibited the Tyndall effect of light refraction.

[089] The type of each nanoemulsion prepared in this example was described following the procedure described in Example 1.

[090] An antimicrobial test was conducted following the procedure described in USP 35 <51>, Antimicrobial Effectiveness Testing, on page 52, and all nanoemulsions prepared in this example passed the antimicrobial test. EXAMPLE 10: PREPARATION OF ESSENTIAL OIL NANOEMULSIONS HAVING AN AQUEOUS PHASE DIFFERENT FROM THOSE IN EXAMPLE 9

[091] The nanoemulsions were prepared following the procedure described below.

[092] Preparation of the aqueous phase of nanoemulsions

[093] A combination of 210 g of purified water, 90 g of urea, 60 g of xylitol, 60 g of Trehalose and 30 g of methyl sulfonyl methane was mixed by constant manual stirring in a 500 ml beaker at 65- 75 °C to form the aqueous phase.

[094] Preparation of the oil phase of nanoemulsions

[095] The combination of 40 g of tea tree essential oil, 20 g of eucalyptus oil, 30 g of menthol, 50 g of paraffin oil, 50 g of cyclomethicone (DC-345), 20 g of beeswax, 10 g of glyceryl monostearate, 16 g of stearic acid, 14 g of sorbitan monostearate, 36 g of polyethylene glycol sorbitan monostearate and 42 g of PEG-40 hydrogenated castor oil was mixed by constant manual stirring in a 500 ml beaker. ml at 65-75°C to form the oily phase.

[096] Preparation of nanoemulsions

[097] 150 g of a w/o nanoemulsion composed of 60 g of the aqueous phase and 90 g of the oil phase was prepared following the procedure described in Example 2.

[098] 150 g of an o/w nanoemulsion composed of 90 g of the aqueous phase and 60 g of the oily phase was prepared following the procedure described in Example 2.

[099] The two nanoemulsions prepared were clear and stable at room temperature for at least 3 months. Both exhibited the Tyndall effect of light refraction.

[0100] The type of each nanoemulsion prepared in this example was described following the procedure described in Example 1.

[0101] An antimicrobial test was conducted following the procedure described in USP 35 <51>, Antimicrobial Effectiveness Testing, on page 52, and both nanoemulsions prepared in this example passed the antimicrobial test. EXAMPLE 11: PREPARATION OF ESSENTIAL OIL NANOEMULSIONS CONTAINING TOLNAFTATE OR KETOCONAZOLE

[0102] The nanoemulsions were prepared following the procedure described below.

[0103] Preparation of the aqueous phase of nanoemulsions

[0104] A combination of 150 g of purified water, 150 g of urea, 40 g of propylene glycol was mixed with constant manual stirring in a 500 ml beaker at 65-75 ° C to form the aqueous phase.

[0105] Preparation of the oil phase of nanoemulsions

[0106] The combination of 50 g of tea tree essential oil, 20 g of eucalyptus oil, 15 g of menthol, 15 g of methyl salicylate, 50 g of cyclomethicone (DC-345), 10 g of beeswax, 10 g of lauric acid, 6 g of stearic acid, 14 g of sorbitan monostearate, 40 g of polyoxyethylene glycol stearate (40) and 40 g of PEG-40 hydrogenated castor oil was mixed by constant manual stirring in a 500 ml beaker. ml at 65-75°C to form the oily phase.

[0107] Preparation of nanoemulsions

[0108] 150 g of a w/o nanoemulsion composed of 60 g of the aqueous phase and 90 g of the oil phase was prepared following the procedure described in Example 2.

[0109] 150 g of an o/w nanoemulsion composed of 90 g of the aqueous phase and 60 g of the oil phase was prepared following the procedure described in Example 2.

[0110] 150 g of a w/o nanoemulsion composed of 60 g of the aqueous phase and 88.2 g of the oily phase dissolving 1.8 g of tolnaftate was prepared following the procedure described in Example 2.

[0111] 150 g of a w/o nanoemulsion composed of 60 g of the aqueous phase and 88.2 g of the oily phase dissolving 1.8 g of ketoconazole was prepared following the procedure described in Example 2.

[0112] All of the above nanoemulsions were clear and stable at room temperature for at least 3 months. They exhibited the Tyndall effect of light refraction.

[0113] The type of each nanoemulsion prepared in this example was described following the procedure described in Example 1.

[0114] An antimicrobial test was conducted following the procedure described in USP 35 <51>, Antimicrobial Effectiveness Testing, on page 52, and all nanoemulsions prepared in this example passed the antimicrobial test. EXAMPLE 12: PREPARATION OF FRAGRANCE/ESSENTIAL OIL NANOEMULSIONS

[0115] The nanoemulsions were prepared following the procedure described below.

[0116] Preparation of the aqueous phase of nanoemulsions

[0117] A combination of 150 g of purified water, 150 g of urea, 40 g of propylene glycol was mixed with constant manual stirring in a beaker at 65-75 ° C to form the aqueous phase.

[0118] Preparation of the oil phase of nanoemulsions

[0119] A combination of 80 g lemon eucalyptus oil, 40 g citronella oil, 24 g lavender oil, 22 g eucalyptus oil, 15 g menthol, 15 g rosemary oil, 15 g of camphor, 15 g of menthol, 5 g of thyme, 10 g of beeswax, 10 g of lauric acid, 6 g of stearic acid, 14 g of sorbitan monostearati, 40 g of polyoxyethylene glycol stearate (40) and 40 g of PEG-40 hydrogenated castor oil was mixed by constant manual stirring in a 500 ml beaker at 65–75 °C to form the oily phase.

[0120] Preparation of nanoemulsions

[0121] 150 g of a w/o nanoemulsion composed of 60 g of the aqueous phase and 90 g of the oily phase was prepared following the procedure described in Example 2.

[0122] 100 g of an o/w nanoemulsion composed of 60 g of the aqueous phase and 40 g of the oil phase was prepared following the procedure described in Example 2.

[0123] Both nanoemulsions prepared were clear and stable at room temperature for at least 3 months. They exhibited the Tyndall effect of light refraction.

[0124] The type of each nanoemulsion prepared in this example was described following the procedure described in Example 1.

[0125] An antimicrobial test was conducted following the procedure described in USP 35 <51>, Antimicrobial Effectiveness Testing, on page 52, and the two nanoemulsions prepared in this example passed the antimicrobial test. EXAMPLE 13: PREPARATION OF MEDIUM-CHAIN OIL NANOEMULSIONS CONTAINING COQ10

[0126] The nanoemulsions were prepared following the procedure described below.

[0127] Preparation of the aqueous phase of nanoemulsions

[0128] A combination of 150 g of purified water, 100 g of glycerin, 80 g of xylitol, 20 g of mannitol and 30 g of methyl sulfonyl methane was mixed by constant manual stirring in a 500 ml beaker at 65- 75 °C to form the aqueous phase.

[0129] Preparation of the oil phase of nanoemulsions

[0130] A combination of 170 g of medium chain triglyceride oil, 16 g of stearic acid, 14 g of sorbitan monostearate, 30 g of polyethylene glycol sorbitan monostearate and 30 g of PEG-40 hydrogenated castor oil was mixed by through constant manual stirring in a 500 ml beaker at 65-75 °C to form the oily phase.

[0131] Preparation of nanoemulsions

[0132] 150 g of a w/o nanoemulsion composed of 50 g of the aqueous phase and 95 g of the oily phase dissolving 5 g of CoQ10 was prepared following the procedure described in Example 2.

[0133] 150 g of an o/w nanoemulsion composed of 90 g of the aqueous phase and 57 g of the oily phase dissolving 3 g of CoQ10 was prepared following the procedure described in Example 2.

[0134] 153 g of an o/w nanoemulsion composed of 120 g of the aqueous phase and 30 g of the oily phase dissolving 3 g of CoQ10 was prepared following the procedure described in Example 2.

[0135] All of the above nanoemulsions were clear and stable at room temperature for at least 3 months. They exhibited the Tyndall effect of light refraction.

[0136] The type of each nanoemulsion prepared in this example was described following the procedure described in Example 1.

[0137] An antimicrobial test was conducted following the procedure described in USP 35 <51>, Antimicrobial Effectiveness Testing, on page 52, and all nanoemulsions prepared in this example passed the antimicrobial test. EXAMPLE 14: PREPARATION OF MEDIUM CHAIN TRIGLYCERIDE NANOEMULSIONS

[0138] The nanoemulsions were prepared following the procedure described below.

[0139] Preparation of the aqueous phase of nanoemulsions

[0140] A combination of 100 g of purified water, 100 g of glycerin, 50 g of xylitol, 50 g of trehalose, 30 g of erythrol and 15 g of maltodextrin was mixed by constant manual stirring in a 500 ml beaker at 65-75 °C to form the aqueous phase.

[0141] Preparation of the oil phase of nanoemulsions

[0142] A combination of 170 g of medium chain triglyceride oil, 16 g of stearic acid, 14 g of sorbitan monostearate, 30 g of polyethylene glycol sorbitan monostearate and 30 g of PEG-40 hydrogenated castor oil were mixed by through constant manual stirring in a 500 ml beaker at 65-75 °C to form the oily phase.

[0143] Preparation of nanoemulsions

[0144] 180 g of a w/o nanoemulsion composed of 54 g of the aqueous phase and 120 g of the oil phase dissolving 6 g of lutein was prepared following the procedure described in Example 2.

[0145] 300 g of an o/w nanoemulsion composed of 174 g of the aqueous phase and 120 g of the oil phase dissolving 6 g of lutein was prepared following the procedure described in Example 2.

[0146] Both nanoemulsions prepared were clear and stable at room temperature for at least 3 months. They exhibited the Tyndall effect of light refraction.

[0147] The type of each nanoemulsion prepared in this example was described following the procedure described in Example 1.

[0148] An antimicrobial test was conducted following the procedure described in USP 35 <51>, Antimicrobial Effectiveness Testing, on page 52, and both nanoemulsions prepared in this example passed the antimicrobial test. EXAMPLE 15: PREPARATION OF MEDIUM CHAIN TRIGLYCERIDE OIL NANOEMULSIONS CONTAINING COQ10

[0149] The nanoemulsions were prepared following the procedure described below.

[0150] Preparation of the aqueous phase of nanoemulsions

[0151] A combination of 100 g of purified water, 100 g of glycerin, 50 g of xylitol, 50 g of trehalose, 35 g of erythrol and 15 g of maltodextrin was mixed by constant manual stirring in a 500 ml beaker at 65-75 °C to form the aqueous phase.

[0152] Preparation of the oil phase of nanoemulsions

[0153] A combination of 50 g of medium chain triglyceride oil, 50 g of fish oil, 10 g of stearic acid, 8 g of sorbitan monostearate, 20 g of polyethylene glycol sorbitan monostearate, and 20 g of Hydrogenated castor PEG-40 was mixed by constant manual stirring in a 500 ml beaker at 65-75 °C to form the oily phase.

[0154] Preparation of nanoemulsions

[0155] 125 g of a w/o nanoemulsion composed of 20 g of the aqueous phase and 100 g of the oil phase dissolving 5 g of CoQ10 was prepared following the procedure described in Example 2.

[0156] 100 g of an o/w nanoemulsion composed of 58 g of the aqueous phase and 40 g of the oily phase dissolving 2 g of CoQ10 was prepared following the procedure described in Example 2.

[0157] Both nanoemulsions prepared were clear and stable at room temperature for at least 3 months. They exhibited the Tyndall effect of light refraction.

[0158] The type of each nanoemulsion prepared in this example was described following the procedure described in Example 1.

[0159] An antimicrobial test was conducted following the procedure described in USP 35 <51>, Antimicrobial Effectiveness Testing, on page 52, and all nanoemulsions prepared in this example passed the antimicrobial test. EXAMPLE 16: PREPARATION OF SQUALENE/CAPRILIC CAPRYLIC TRIGLYCERIDE NANOEMULSIONS CONTAINING ISOSORBIDE DINITRATE OR FARMOTIDINE

[0160] The nanoemulsions were prepared following the procedure described below.

[0161] Preparation of the aqueous phase of nanoemulsions

[0162] A combination of 150 g of purified water, 150 g of urea, 40 g of propylene glycol was mixed with constant manual stirring in a beaker at 65-75 ° C to form the aqueous phase.

[0163] Preparation of the oil phase of nanoemulsions

[0164] A combination of 80 g of squalene, 80 g of caprylic capric triglyceride, 16 g of stearic acid, 14 g of sorbitan monostearate, 40 g of polyoxyethylene glycol stearate (40) and 40 g of PEG-hydrogenated castor oil 40 was mixed by constant manual stirring in a 500 ml beaker at 65-75 °C to form the oily phase.

[0165] Preparation of nanoemulsions

[0166] 150 g of a w/o nanoemulsion composed of 60 g of the aqueous phase and 90 g of the oily phase was prepared following the procedure described in Example 2.

[0167] 150 g of an o/w nanoemulsion composed of 90 g of the aqueous phase and 60 g of the oil phase was prepared following the procedure described in Example 2.

[0168] 150 g of an o/w nanoemulsion composed of 88.5 g of the aqueous phase and 60 g of the oily phase dissolving 1.5 g of isosorbide dinitrate was prepared following the procedure described in Example 2.

[0169] 150 g of an o/w nanoemulsion composed of 88.5 g of the aqueous phase and 60 g of the oily phase dissolving 1.5 g of famotidine was prepared following the procedure described in Example 2.

[0170] All of the above nanoemulsions were clear and stable at room temperature for at least 3 months. They exhibited the Tyndall effect of light refraction.

[0171] The type of each nanoemulsion prepared in this example was described following the procedure described in Example 1.

[0172] An antimicrobial test was conducted following the procedure described in USP 35 <51>, Antimicrobial Effectiveness Testing, on page 52, and all nanoemulsions prepared in this example passed the antimicrobial test. EXAMPLE 17: PREPARATION OF SYNTHETIC OIL NANOEMULSIONS CONTAINING CURCUMIN OR TESTOSTERONE

[0173] The nanoemulsions were prepared following the procedure described below.

[0174] Preparation of the aqueous phase of nanoemulsions

[0175] A combination of 150 g of purified water, 150 g of urea, 40 g of propylene glycol was mixed with constant manual stirring in a 500 ml beaker at 65-75 ° C to form the aqueous phase.

[0176] Preparation of the oil phase of a nanoemulsion

[0177] A combination of 80 g of capric caprylic triglyceride, 40 g of ethyl oleate, 40 g of sorbitan oleate, 8 g of beeswax, 8 g of lauric acid, 8 g of sorbitan monostearate, and 64 g of stearate of polyoxyethylene glycol (40) was mixed in a 400 ml beaker by constant manual stirring in a 400 ml beaker at 65-75 °C to form the oily phase.

[0178] Preparation of nanoemulsions

[0179] 135 g of a w/o nanoemulsion composed of 45 g of the aqueous phase and 90 g of the oil phase was prepared following the procedure described in Example 2.

[0180] 135 g of a w/o nanoemulsion composed of 45 g of the aqueous phase and 88.2 g of the oily phase dissolving 1.8 g of testosterone was prepared following the procedure described in Example 2.

[0181] 135 g of a w/o nanoemulsion composed of 45 g of the aqueous phase and 89.4 g of the oily phase dissolving 0.6 g of curcumin was prepared following the procedure described in Example 2.

[0182] All of the above nanoemulsions were clear and stable at room temperature for at least 3 months. They exhibited the Tyndall effect of light refraction.

[0183] The type of each nanoemulsion prepared in this example was described following the procedure described in Example 1.

[0184] An antimicrobial test was conducted following the procedure described in USP 35 <51>, Antimicrobial Effectiveness Testing, on page 52, and all nanoemulsions prepared in this example passed the antimicrobial test. EXAMPLE 18: PREPARATION OF A NANOEMULSION CONTAINING COQ10, VITAMIN A, VITAMIN E, AND VITAMIN D

[0185] The nanoemulsion was prepared following the procedure described below.

[0186] Preparation of the aqueous phase of the nanoemulsion

[0187] A combination of 280 g of purified water, 240 g of glycerin, 48 g of urea, and 32 g of trehalose was mixed by constant manual stirring in a 500 ml beaker at 65-75 ° C to form 600 g of the aqueous phase.

[0188] Preparation of the oil phase of the nanoemulsion

[0189] A combination of 2.4 g of CoQ10, 4.8 g of vitamin A, 1.2 g of vitamin D 1.2, 30 g of vitamin E, 85.6 g of paraffin oil, 140 g of cyclomethicone (DC-345), 32 g stearic acid, 24 g sorbitan monostearate, 80 g polyethylene glycol sorbitan monostearate was mixed by constant manual stirring in a 400 ml beaker at 65-75 °C to form 400 g of the oily phase.

[0190] Preparation of the nanoemulsion

[0191] 1000 g of a w/o nanoemulsion composed of 600 g of the aqueous phase and 400 g of the oil phase was prepared following the procedure described in Example 2.

[0192] The above nanoemulsion was a clear o/w nanoemulsion and stable at room temperature for at least 3 months. The nanoemulsion exhibited the Tyndall effect of light refraction.

[0193] The type of nanoemulsion was determined following the procedure described in Example 1.

[0194] An antimicrobial test was conducted following the procedure described in USP 35 <51>, Antimicrobial Effectiveness Testing, on page 52, and the nanoemulsion passed the antimicrobial test. EXAMPLE 19: PREPARATION OF A NANOEMULSION OF VITAMIN E/GRAPESEED OIL/COCONUT/MINK OIL/PARAFFIN OIL/CYCLOMETHICONE

[0195] The nanoemulsion was prepared following the procedure described below.

[0196] Preparation of the aqueous phase of the nanoemulsion

[0197] A combination of 168 g of purified water, 115 g of urea, 77 g of glycerin, 20 g of propylene glycol, 20 g of sodium pyrrolidine carbobixalate, and 20 g of trehalose was mixed by constant manual stirring. in a 500 ml beaker at 65-75 °C to form 420 g of the aqueous phase.

[0198] Preparation of the oil phase of the nanoemulsion

[0199] A combination of 30 g of vitamin E, 30 g of grape seed oil, 40 g of coconut oil, 8 g of mink oil, 24 g of paraffin oil, 60 g of cyclomethicone (DC -345), 16 g of beeswax, 8 g of glyceryl monostearate, 19 g of stearic acid, 17 g of sorbitan monostearate, 50 g of PEG-40 hydrogenated castor oil and 28 g of polyoxyethylene glycol stearate (40 ) was mixed by constant manual stirring in a 400 ml beaker at 65-75 °C to form 330 g of the oily phase.

[0200] Nanoemulsion preparation

[0201] 750 g of a nanoemulsion composed of 420 g of the aqueous phase and 330 g of the oil phase was prepared following the procedure described in Example 2.

[0202] The above nanoemulsion was a clear o/w nanoemulsion and stable at room temperature for at least 3 months. The nanoemulsion exhibited the Tyndall effect of light refraction.

[0203] The type of nanoemulsion was determined following the procedure described in Example 1.

[0204] An antimicrobial test was conducted following the procedure described in USP 35 <51>, Antimicrobial Effectiveness Testing, on page 52, and the nanoemulsion passed the antimicrobial test. EXAMPLE 20: PREPARATION OF A NANOEMULSION OF VITAMIN E/GRAPESEED OIL/COCONUT/MINK OIL/PARAFFIN OIL/CYCLOMETHICONE

[0205] The nanoemulsion was prepared following the procedure described below.

[0206] Preparation of the aqueous phase of the nanoemulsion

[0207] A combination of 168 g of purified water, 115 g of urea, 77 g of glycerin, 20 g of propylene glycol, 20 g of sodium pyrrolidine carbobixalate, and 20 g of trehalose was mixed by constant manual stirring in a 500 ml beaker at 65-75 °C to form 420 g of the aqueous phase.

[0208] Preparation of the oil phase of the nanoemulsion

[0209] A combination of 30 g of vitamin E, 30 g of grape seed oil, 40 g of coconut oil, 8 g of mink oil, 24 g of paraffin oil, 60 g of cyclomethicone (DC -345), 16 g of beeswax, 8 g of glyceryl monostearate, 19 g of stearic acid, 17 g of sorbitan monostearate, 50 g of PEG-40 hydrogenated castor oil and 28 g of polyethylene glycol stearate (40 ) was mixed by constant manual stirring in a 400 ml beaker at 65-75 ° C to form 330 g of the oily phase.

[0210] Nanoemulsion preparation

[0211] 750 g of a nanoemulsion composed of 420 g of the aqueous phase and 330 g of the oil phase was prepared following the procedure described in Example 2.

[0212] The above nanoemulsion was a clear o/w nanoemulsion and stable at room temperature for at least 3 months. The nanoemulsion exhibited the Tyndall effect of light refraction.

[0213] The type of nanoemulsion was determined following the procedure described in Example 1.

[0214] An antimicrobial test was conducted following the procedure described in USP 35 <51>, Antimicrobial Effectiveness Testing, on page 52, and the nanoemulsion passed the antimicrobial test. EXAMPLE 21: PREPARATION OF A NANOEMULSION OF VITAMIN E/GRAPESEED OIL/COCONUT/MINK OIL/PARAFFIN OIL/CYCLOMETHICONE

[0215] The nanoemulsion was prepared following the procedure described below.

[0216] Preparation of the aqueous phase of the nanoemulsion

[0217] A combination of 168 g of purified water, 115 g of urea, 77 g of glycerin, 20 g of propylene glycol, 20 g of sodium pyrrolidine carbobixalate, and 20 g of trehalose was mixed by constant manual stirring in a 500 ml beaker at 65-75 °C to form 420 g of the aqueous phase.

[0218] Preparation of the oil phase of the nanoemulsion

[0219] A combination of 30 g of vitamin E, 30 g of grape seed oil, 40 g of coconut oil, 8 g of mink oil, 24 g of paraffin oil, 60 g of cyclomethicone (DC -345), 16 g of beeswax, 8 g of glyceryl monostearate, 19 g of stearic acid, 17 g of sorbitan monostearate, 50 g of PEG-40 hydrogenated castor oil and 28 g of polyoxyethylene glycol stearate was mixed by constant manual stirring in a 400 ml beaker at 65-75 °C to form 330 g of the oily phase.

[0220] Nanoemulsion preparation

[0221] 750 g of a nanoemulsion composed of 420 g of the aqueous phase and 330 g of the oil phase was prepared following the procedure described in Example 2.

[0222] The above nanoemulsion was a clear o/w nanoemulsion and stable at room temperature for at least 3 months. The nanoemulsion exhibited the Tyndall effect of light refraction.

[0223] The type of nanoemulsion was determined following the procedure described in Example 1.

[0224] An antimicrobial test was conducted following the procedure described in USP 35 <51>, Antimicrobial Effectiveness Testing, on page 52, and the nanoemulsion passed the antimicrobial test. EXAMPLE 22: PREPARATION OF A NANOEMULSION OF VITAMIN E/GRAPESEED OIL/COCONUT/MINK OIL/PARAFFIN OIL/CYCLOMETHICONE

[0225] The nanoemulsion was prepared following the procedure described below.

[0226] Preparation of the aqueous phase of the nanoemulsion

[0227] A combination of 150 g of purified water, 150 g of urea, 40 g of propylene glycol was mixed with constant manual stirring in a beaker at 65-75 ° C to form 340 g of the aqueous phase.

[0228] Preparation of the oil phase of the nanoemulsion

[0229] A combination of 30 g of vitamin E, 30 g of grape seed oil, 40 g of coconut oil, 8 g of mink oil, 24 g of paraffin oil, 60 g of cyclomethicone (DC-345 ), 16 g of beeswax, 8 g of glyceryl monostearate, 19 g of stearic acid, 17 g of sorbitan monostearate, 50 g of PEG-40 hydrogenated castor oil and 28 g of polyoxyethylene glycol stearate (40) was mixed by constant manual stirring in a 400 ml beaker at 65-75 °C to form 330 g of the oily phase.

[0230] Nanoemulsion preparation

[0231] 750 g of a nanoemulsion composed of 420 g of the aqueous phase and 330 g of the oil phase was prepared following the procedure described in Example 2.

[0232] The above nanoemulsion was a clear o/w nanoemulsion and stable at room temperature for at least 3 months. The nanoemulsion exhibited the Tyndall effect of light refraction.

[0233] The type of nanoemulsion was determined following the procedure described in Example 1.

[0234] An antimicrobial test was conducted following the procedure described in USP 35 <51>, Antimicrobial Effectiveness Testing, on page 52, and the nanoemulsion passed the antimicrobial test. EXAMPLE 23: PREPARATION OF ESSENTIAL OIL NANOEMULSIONS CONTAINING ONLY A HYDROPHILIC SURFACTANT

[0235] The nanoemulsions were prepared following the procedure described below.

[0236] Preparation of the aqueous phase of nanoemulsions

[0237] A combination of 200 g of purified water, 100 g of glycerin, 50 g of glucosamine and 50 g of methyl sulfonyl methane was mixed by constant manual stirring in a 500 ml beaker at 65-75 ° C to form the aqueous phase.

[0238] Preparation of the oil phase of nanoemulsions

[0239] A combination of 30 g of vitamin E, 30 g of grape seed oil, 40 g of coconut oil, 8 g of mink oil, 24 g of paraffin oil, 60 g of cyclomethicone (DC-345 ), 16 g of beeswax, 8 g of glyceryl monostearate, 19 g of stearic acid, 17 g of sorbitan monostearate and 68 g of PEG-40 hydrogenated castor oil was mixed by constant manual stirring in a 400 ml beaker at 65-75 °C to form the oily phase.

[0240] Preparation of nanoemulsions

[0241] 150 g of a w/o nanoemulsion composed of 60 g of the aqueous phase and 90 g of the oily phase was prepared following the procedure described in Example 2.

[0242] 150 g of an o/w nanoemulsion composed of 90 g of the aqueous phase and 60 g of the oily phase was prepared following the procedure described in Example 2.

[0243] The above nanoemulsions were clear and stable at room temperature for at least 3 months. They exhibited the Tyndall effect of light refraction.

[0244] The type of each nanoemulsion prepared in this example was described following the procedure described in Example 1.

[0245] An antimicrobial test was conducted following the procedure described in USP 35 <51>, Antimicrobial Effectiveness Testing, on page 52, and the two nanoemulsions prepared in this example passed the antimicrobial test.

OTHER ACHIEVEMENTS

[0246] All characteristics disclosed in this specification can be combined in any combination. Each resource disclosed in this specification may be replaced by an alternative resource serving a similar, equivalent or the same purpose. Therefore, unless expressly stated otherwise, each feature disclosed is only one example of a generic series of equivalent or similar features.

[0247] From the above description, one skilled in the art can easily determine the essential characteristics of the present invention, and without departing from the spirit and scope thereof, can make various changes and modifications to the invention to adapt it for various uses and conditions . Thus, other embodiments are also within the scope of the following claims.

Claims (22)

1. NANOEMULSION, characterized by comprising: (1) an aqueous phase including: (1) water or an aqueous solution, and (2) one or more water-soluble organic nanostructure stabilizer, in which the water or aqueous solution has a content less than 75% by weight of the aqueous phase, each of the water-soluble organic nanostructure stabilizers has a content of less than 99% by weight of the aqueous phase, and at least one of the water-soluble organic nanostructure stabilizers is urea, xylitol or glucosamine, and (8) an oily phase including: (9) an oil or an oily solution, (10) an organic gel thickener, and (11) a hydrophilic surfactant having a hydrophilic-lipophilic balance value greater than 8.0 , in which the oil or oily solution has a content of less than 80% by weight of the oily phase, the organic gel thickener has a content of less than 60% by weight of the oil phase, and the hydrophilic surfactant has a content of less than 60% by weight of the oil phase, wherein the water or aqueous solution constitutes 2.5% by weight or more of the nanoemulsion, a weight ratio of the aqueous phase to the oil phase of 1:40-100:1, and the aqueous phase is dispersed as nanosized droplets in the oil phase or the oil phase is dispersed as nanosized droplets in the aqueous phase, and the nanoemulsion is self-preserving in the absence of an antimicrobial preservative and has reversible continuous and dispersed phases. 2. NANOEMULSION, according to claim 1, characterized in that the oil phase is dispersed as nanosized droplets in the aqueous phase. 3. NANOEMULSION, according to claim 1, characterized in that the aqueous phase is dispersed as nanosized droplets in the oil phase. 4. NANOEMULSION, according to claim 2, characterized in that the hydrophilic-lipophilic balance value is greater than 10. 5. NANOEMULSION, according to claim 4, characterized in that the hydrophilic-lipophilic balance value is greater than 13. 6. NANOEMULSION, according to claim 3, characterized in that the hydrophilic-lipophilic balance value is greater than 10. 7. NANOEMULSION, according to claim 6, characterized in that the hydrophilic-lipophilic balance value is greater than 13. 8. NANOEMULSION according to claim 4, characterized in that the water-soluble organic nanostructure stabilizer is a water-soluble vitamin, water-soluble peptide, a water-soluble oligopeptide, a polyol, a water-soluble saccharide, a water-soluble oligosaccharide in water, a disaccharide, a monosaccharide, a hydrogenated carbohydrate, an amino acid, amino sugar or a combination thereof; the oil is a vegetable oil, a silicone oil, a synthetic oil, a mineral oil, an animal oil, an essential oil or a combination of these; and the organic gel thickener is saturated fatty acid, fatty acid alcohol, a fatty acid derivative having a melting point above 45°C or a combination thereof. 9. NANOEMULSION, according to claim 4, characterized in that the water-soluble organic nanostructure stabilizer is also any one of methylsulfonylmethane, hydroxyethyl, urea, mannitol, sorbitol, lactose, fructose, dextrose, ribose, trehalose, raffinose, maltitol, isomalt , lactitol, erythritol, inositol, taurine, glycerin, propylene glycol, dipropylene glycol, butylene glycol, hexylene glycol, polyethylene glycol, ethoxydiglycol, carnitine, arginine, sodium pyrolidine carboxylic acid and hydrolyzed collagen, or a combination thereof; the oil is coconut oil, palm oil, grape seed oil, olive oil, avocado oil, evening primrose oil, tea tree essential oil, eucalyptus oil, lavender oil, rosemary oil, horse fat, fish, lanolin oil, cyclomethicone, cyclopentasiloxane, phenyl trimethicone, caprylic or capric triglyceride, isopropyl myristate, isostearyl isostearate, decyl oleate, ethylhexyl isononate, isohexadecane, octyldodecanol, paraffin oil, polydecene, polyisobutene, menthol, or a combination of these; organic gel thickener is stearic acid, lauric acid, glycerol monostearate, PEG 6000 distearate, monoglyceride, diglyceride, saccharide fatty acid ester, propylene glycol fatty acid ester, glycol fatty acid ester decylhexyl fatty acid ester, fatty acid alcohol, cetylesterate, ascorbyl fatty esters, glyceryl fatty esters, hexyldecyl fatty esters or a combination thereof; and the hydrophilic surfactant is polyoxyethylene sorbitan fatty acid ester, polyoxyethylene sorbitol fatty acid ester, polyoxyethylene fatty acid ester, polyoxyethylene alcohol ester, nonylphenol alkoxylates, alkyl alkoxylates, poly(ethylene glycol)-poly copolymer ( propylene glycol)-poly(ethylene glycol), PEG dimethicone, polyoxyethylene fatty acid ester (40), polyoxyethylene saccharide fatty acid ester (20), glyceryl fatty acid ester PEG-15, hydrogenated castor oil PEG-35, PEG-40 hydrogenated castor oil, polyglycerol fatty acid ester, fatty amino derivatives, or a combination thereof. 10. NANOEMULSION, according to claim 9, characterized in that the hydrophilic-lipophilic balance value is greater than 13; the water or aqueous solution has a content of less than 60% by weight of the aqueous phase and the water-soluble organic nanostructure stabilizer has a content of less than 50% by weight of the aqueous phase; the oil or oily solution has a content of 45-65% by weight of the oily phase, the organic gel thickener has a content of less than 25% by weight of the oily phase, and the hydrophilic surfactant has a content of less than 35% by weight from the oily phase; water or aqueous solution constitutes 30% by weight or less of the nanoemulsion and a weight ratio of the aqueous phase to the oil phase of 1:2-3:1; and the nanoemulsion has a pH of 311 and is transparent or translucent. 11. NANOEMULSION according to claim 6, characterized in that the water-soluble organic nanostructure stabilizer is a water-soluble vitamin, water-soluble peptide, a water-soluble oligopeptide, a polyol, a water-soluble saccharide, a water-soluble oligosaccharide in water, a disaccharide, a monosaccharide, a hydrogenated carbohydrate, an amino acid, amino sugar, or a combination thereof; the oil is a vegetable oil, a silicone oil, a synthetic oil, a mineral oil, an oil of animal origin, an essential oil, or a combination of these; and the organic gel thickener is saturated fatty acid, fatty acid alcohol, a fatty acid derivative having a melting point above 45°C, or a combination thereof. 12. NANOEMULSION, according to claim 6, characterized in that the water-soluble organic nanostructure stabilizer is also any one of methylsulfonylmethane, hydroxyethyl urea, mannitol, sorbitol, lactose, fructose, dextrose, ribose, trehalose, raffinose, maltitol, isomalt, lactitol, erythritol, inositol, taurine, glycerin, propylene glycol, dipropylene glycol, butylene glycol, hexylene glycol, polyethylene glycol, ethoxydiglycol, carnitine, arginine, sodium pyrolidine carboxylic acid and hydrolyzed collagen, or a combination thereof; the oil is coconut oil, palm oil, grape seed oil, grapefruit seed oil, olive oil, avocado oil, evening primrose oil, tea tree essential oil, eucalyptus oil, lavender oil, rosemary oil, horse fat, fish oils, squalene, lanolin oil, cyclomethicone, cyclopentasiloxane, phenyl trimethicone, caprylic or capric triglyceride, isopropyl myristate, isostearyl isostearate, decyl oleate, ethylhexyl isononate, isohexadecane, octyldodecanol, paraffin oil, polydecene, polyisobutene, menthol or a combination thereof; organic gel thickener is stearic acid, lauric acid, glycerol monostearate, PEG 6000 distearate, monoglyceride, diglyceride, saccharide fatty acid ester, propylene glycol fatty acid ester, glycol fatty acid ester decylhexyl fatty acid ester, fatty acid alcohol, cetylesterate, ascorbyl fatty esters, glyceryl fatty esters, hexyldecyl fatty esters or a combination thereof; and the hydrophilic surfactant is polyoxyethylene sorbitan fatty acid ester, polyoxyethylene sorbitol fatty acid ester, polyoxyethylene fatty acid ester, polyoxyethylene alcohol ester, nonylphenol alkoxylates, alkyl alkoxylates, poly(ethylene glycol)-poly( propylene glycol)- poly(ethylene glycol), PEG dimethicone, polyoxyethylene fatty acid ester (40), polyoxyethylene saccharide fatty acid ester (20), glyceryl fatty acid ester PEG-15, hydrogenated castor oil PEG-35, PEG-40 hydrogenated castor oil, polyglycerol fatty acid ester, fatty amino derivatives, or a combination thereof. 13. NANOEMULSION, according to claim 12, characterized in that the hydrophilic-lipophilic balance value is greater than 13; the water or aqueous solution has a content of less than 60% by weight of the aqueous phase and the water-soluble organic nanostructure stabilizer has a content of less than 50% by weight of the aqueous phase; the oil or oily solution has a content of 45-65% by weight of the oily phase, the organic gel thickener has a content of less than 25% by weight of the oily phase, and the hydrophilic surfactant has a content of less than 35% by weight from the oily phase; water or aqueous solution constitutes 30% by weight or less of the nanoemulsion and a weight ratio of the aqueous phase to the oil phase of 1:2-3:1; and the nanoemulsion has a pH of 311 and is transparent or translucent. 14. NANOEMULSION, according to claim 8, characterized in that the water or aqueous solution of the nanoemulsion has a content of less than 60% by weight of the aqueous phase and the water-soluble organic nanostructure stabilizer has a content of less than 70% by weight of the aqueous phase; the oil or oily solution has a content of 30-70% by weight of the oily phase, the organic gel thickener has a content of less than 45% by weight of the oily phase, and the hydrophilic surfactant has a content of less than 45% by weight from the oily phase; and the water or aqueous solution constitutes 38% by weight or less of the nanoemulsion and a weight ratio of the aqueous phase to the oil phase of 1:3-4:1. 15. NANOEMULSION, according to claim 14, characterized in that the water or aqueous solution of the nanoemulsion has a content of less than 45% by weight of the aqueous phase and the water-soluble organic nanostructure stabilizer has a content of less than 50% by weight of the aqueous phase; the oil or oily solution has a content of 45-65% by weight of the oily phase, the organic gel thickener has a content of less than 25% by weight of the oily phase, and the hydrophilic surfactant has a content of less than 35% by weight from the oily phase; and the water or aqueous solution constitutes 30% by weight or less of the nanoemulsion and a weight ratio of the aqueous phase to the oil phase of 1:2-3:1. 16. NANOEMULSION, according to claim 11, characterized in that the water or aqueous solution of the nanoemulsion has a content of less than 60% by weight of the aqueous phase and the water-soluble organic nanostructure stabilizer has a content of less than 70% by weight of the aqueous phase; the oil or oily solution has a content of 30-70% by weight of the oily phase, the organic gel thickener has a content of less than 45% by weight of the oily phase, and the hydrophilic surfactant has a content of less than 45% by weight from the oily phase; and the water or aqueous solution constitutes 38% by weight or less of the nanoemulsion and a weight ratio of the aqueous phase to the oil phase of 1:3-4:1. 17. NANOEMULSION, according to claim 16, characterized in that the water or aqueous solution of the nanoemulsion has a content of less than 45% by weight of the aqueous phase and the water-soluble organic nanostructure stabilizer has a content of less than 50% by weight of the aqueous phase; the oil or oily solution has a content of 45-65% by weight of the oily phase, the organic gel thickener has a content of less than 25% by weight of the oily phase, and the hydrophilic surfactant has a content of less than 35% by weight from the oily phase; and the water or aqueous solution constitutes 30% by weight or less of the nanoemulsion and a weight ratio of the aqueous phase to the oil phase of 1:2-3:1. 18. NANOEMULSION, according to claim 15, characterized in that the nanoemulsion has a pH of 3-11 and is transparent or translucent. 19. NANOEMULSION, according to claim 17, characterized in that the nanoemulsion has a pH of 3-11 and is transparent or translucent. 20. NANOEMULSION, according to claim 1, characterized in that the nanoemulsion has a pH of 3-11 and is transparent or translucent. 21. NANOEMULSION, according to claim 1, characterized in that the nanoemulsion is a cosmetic product, a pharmaceutical product, a food product, a household chemical product, an agricultural product, a printing product, a dye product, a veterinary product, or a diagnostic product. 22. METHOD FOR PREPARING THE NANOEMULSION, as defined in claim 1, the method being characterized by comprising: (1) mixing water or aqueous solution and one or more soluble organic nanostructure stabilizers to form an aqueous phase, in which the water or aqueous solution has a content of less than 75% by weight of the aqueous phase, and each of the water-soluble organic nanostructure stabilizers has a content of less than 99% by weight of the aqueous phase, and at least one of the soluble organic nanostructure stabilizers is urea, xylitol or glucosamine; (2) mixing an oil or aqueous solution, an organic thickener, and a hydrophilic surfactant having a hydrophilic-lipophilic balance value greater than 8.0 to form an oily phase, in which the oil or oily solution has a content less than 80% by weight of the oil phase, the organic gel thickener has a content of less than 60% by weight of the oil phase, and the hydrophilic surfactant has a content of less than 60% by weight of the oil phase; and (3) mixing the aqueous phase and the oil phase, a weight ratio of the aqueous phase to the oil phase being 1:40100:1, to form a nanoemulsion, wherein the water or aqueous solution constitutes 74% by weight or less nanoemulsion; wherein the aqueous phase is dispersed as nanosized droplets in the oil phase or the oil phase is dispersed as nanosized droplets in the aqueous phase.