Process and system for reducing sizes of emulsion droplets and emulsions having reduced droplet sizes
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
A01N-025/00
A61K-047/00
B01F-003/22
B01F-003/08
출원번호
US-0997996
(2009-06-17)
등록번호
US-9000053
(2015-04-07)
국제출원번호
PCT/US2009/047676
(2009-06-17)
§371/§102 date
20101214
(20101214)
국제공개번호
WO2009/155353
(2009-12-23)
발명자
/ 주소
Mason, Thomas G.
Fryd, Michael M.
출원인 / 주소
The Regents of the University of California
대리인 / 주소
Venable LLP
인용정보
피인용 횟수 :
0인용 특허 :
7
초록▼
A method of producing an emulsion includes preparing a droplet solution comprising first and second molecular species, the droplet solution being in a fluid phase, wherein the first molecular species is soluble in the second molecular species; forming a plurality of droplets from the droplet solutio
A method of producing an emulsion includes preparing a droplet solution comprising first and second molecular species, the droplet solution being in a fluid phase, wherein the first molecular species is soluble in the second molecular species; forming a plurality of droplets from the droplet solution in a bulk fluid to create a first emulsion, the plurality of droplets having a first ensemble average radius in the bulk fluid, wherein the first molecular species of the droplet solution is at least partially soluble in the bulk fluid and the droplet solution is at least partially immiscible in the bulk fluid; and allowing molecules of the first molecular species to migrate from the plurality of fluid droplets to the bulk fluid due to a higher concentration of the first molecular species in the droplet solution than the bulk fluid to result in the plurality of droplets having a second ensemble average radius that is smaller than the first ensemble average radius. An emulsion includes a bulk fluid and a plurality of droplets dispersed in the bulk fluid. The plurality of droplets have an ensemble average radius less than about 25 nm and greater than about 5 nm.
대표청구항▼
1. A method of producing a nanoemulsion, comprising: preparing a droplet solution comprising first and second molecular species, said droplet solution being in a fluid phase, wherein said first molecular species is soluble in said second molecular species;forming a first plurality of fluid droplets
1. A method of producing a nanoemulsion, comprising: preparing a droplet solution comprising first and second molecular species, said droplet solution being in a fluid phase, wherein said first molecular species is soluble in said second molecular species;forming a first plurality of fluid droplets from said droplet solution in a bulk fluid to provide a first emulsion, said first plurality of fluid droplets having a first ensemble average radius that is greater than about 100 nanometers in said bulk fluid, wherein said first molecular species of said fluid droplet solution is at least partially soluble in said bulk fluid and said droplet solution is at least partially immiscible in said bulk fluid;performing an extreme emulsification of said first emulsion to provide a first nanoemulsion comprising a second plurality of fluid droplets having a second ensemble average radius that is less than about 100 nanometers in said bulk fluid;subjecting said first nanoemulsion to an environment to provide a second nanoemulsion comprising a third plurality of fluid droplets having a third ensemble average radius that is less than said second ensemble average radius due to said first molecular species migrating out of said second plurality of fluid droplets to said bulk fluid; andcollecting said third plurality of fluid droplets having said third ensemble average radius to provide said nanoemulsion having reduced fluid droplet sizes. 2. A method of producing a nanoemulsion according to claim 1, further comprising reducing a concentration of said first molecular species in said bulk fluid to provide a condition favorable for further migration of molecules of said first molecular species from said third plurality of fluid droplets to said bulk fluid to provide a fourth nanoemulsion having a fourth ensemble average radius that is smaller than said third nanoensemble average radius. 3. A method of producing a nanoemulsion according to claim 1, wherein said forming a first plurality of fluid droplets from said droplet solution in a bulk fluid to provide a first emulsion comprises a multi-stage process for creating said first emulsion. 4. A method of producing a nanoemulsion according to claim 1, further comprising adding a stabilizer to at least one of said bulk fluid and said droplet solution to help prevent coalescence of said first plurality of fluid droplets. 5. A method of producing a nanoemulsion according to claim 1, wherein said first plurality of fluid droplets comprise at least one of a viscous liquid, a viscoelastic liquid, a yield-stress material, a shear-thinning material, a shear-thickening material, a thixotropic material, a multi-phase material, and a viscoplastic material. 6. A method of producing a nanoemulsion according to claim 1, wherein a solubility of said second molecular species in said bulk fluid is less than a solubility of said first molecular species in said bulk fluid. 7. A method of producing a nanoemulsion according to claim 2, wherein said reducing a concentration of said first molecular species in said bulk fluid comprises providing a selected temperature and pressure environment so that molecules of said first molecular species will evaporate from said bulk fluid. 8. A method of producing a nanoemulsion according to claim 7, further comprising recovering at least some of said evaporated molecules of said first molecular species for reuse in producing emulsions. 9. A method of producing a nanoemulsion according to claim 2, wherein said reducing a concentration of said first molecular species in said bulk fluid comprises adding a liquid to said bulk fluid that is free of molecules of said first molecular species. 10. A method of producing a nanoemulsion according to claim 2, wherein said reducing a concentration of said first molecular species in said bulk fluid comprises a dialysis process to remove molecules of said first molecular species from said bulk fluid. 11. A method of producing a nanoemulsion according to claim 1, further comprising adding a material to said bulk fluid that interacts with molecules of said first molecular species to remove said molecules of said first molecular species from at least free motion within said bulk fluid. 12. A method of producing a nanoemulsion according to claim 2, wherein said allowing molecules of said first molecular species to migrate from said third plurality of fluid droplets to said bulk fluid and said reducing a concentration of said first molecular species in said bulk fluid are repeated until said nanoemulsion comprises fluid droplets having an ensemble average radius of less than about 100 nm and greater than about 3 nm. 13. A method of producing a nanoemulsion according to claim 2, wherein said allowing molecules of said first molecular species to migrate from said third plurality of fluid droplets to said bulk fluid and said reducing a concentration of said first molecular species in said bulk fluid are repeated until said nanoemulsion comprises fluid droplets having an ensemble average radius of less than about 25 nm and greater than about 5 nm. 14. A method of producing a nanoemulsion according to claim 1, wherein said droplet solution is immiscible with said bulk fluid over a range of temperature and pressure conditions after said forming a first plurality of fluid droplets. 15. A method of producing a nanoemulsion according to claim 1, further comprising mixing an additive with at least one of said droplet solution and said bulk fluid, wherein said additive comprises at least one of ultraviolet-light-blocking molecules, moisturizing molecules, exfoliant molecules, anti-microbial molecules, anti-fungal molecules, anti-acne molecules, anti-wrinkle molecules, anti-septic molecules, insect-repellent molecules, dyes, pigments, particulates, nanoparticulates, clays, lipids, proteins, lipoproteins, vitamins, polypeptides, block copolypeptides, biopolymers, fragrances, pH modifiers, or water repellency molecules. 16. A method of producing a nanoemulsion according to claim 1, further comprising mixing an additive with at least one of said droplet solution and said bulk fluid, wherein said additive comprises at least one of a biologically active material, a fluorescent material, a magnetically responsive material, a magnetized material, a ferromagnetic material, a ferroelectric material, an isotopically labeled material, a radioactive material, an optically absorbing material, a biodegradable material, a thermally conductive material, a thermally insulating material, a viscoelastic material, a viscoplastic material, a disordered material, an ordered material, a toxic material, a non-toxic material, a plant-derived material, an animal-derived material, a polymeric material, a phase-separated polymeric material, a diblock polymeric material, a biopolymeric material, a genetic material, a protein material, a poly-(amino acid) material, a polyelectrolyte material, a multi-phase material, a nanoparticle dispersion material, an imaging contrast-enhancing material, a birefringent material, a chiral material, an achiral material, a reactive material, an explosive material, a catalytic material, an acidic-pH material, a basic-pH material, a neutral-pH material, a glass-forming material, a glassy material, a photoreactive material, a liquid-crystalline material, a thermotropic liquid crystalline material, a lyotropic liquid crystalline material, a racemic material, a non-racemic material, a crosslinkable material, a graphenic material, an electrically semiconductive material, an electrically insulating material, or an electrically conductive material.
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