• Journal of Dairy Science and Biotechnology
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• v.24 no.1
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• pp.53-63
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• 2006

Nano and micro capsulation (NM capsulation) involve the incorporation for nanofood materials, enzymes, cells or other materials in small capsules. Since Kim D. M. (2001) showed that a new type of food called firstly the name of nanofood, which means nanotechnology for food, and the encapsulated materials can be protected from moisture, heat or other extreme conditions, thus enhancing their stability and maintaining viability applications for this nanofood technique have increased in the food. NM capsules for nanofood is also utilized to mask odours or tastes. Various techniques are employed to form the capsules, including spray drying, spray chilling or spray cooling, extrusion coating, fluidized bed coating, liposome entrapment, coacervation, inclusion complexation, centrifugal extrusion and rotational suspension separation. Each of these techniques is discussed in this review. A wide variety of nanofood is NM capsulated - flavouring agents, acids, bases, artificial sweeteners, colourants, preservatives, leavening agents, antioxidants, agents with undesirable flavours, odours and nutrients, among others. The use of NM capsulation for sweeteners such as aspartame and flavors in chewing gum is well known. Fats, starches, dextrins, alginates, protein and lipid materials can be employed as encapsulating materials. Various methods exist to release the ingredients from the capsules. Release can be site-specific, stage-specific or signaled by changes in pH, temperature, irradiation or osmotic shock. NM capsulation for the nanofood, the most common method is by solvent-activated release. The addition of water to dry beverages or cake mixes is an example. Liposomes have been applied in cheese-making, and its use in the preparation of nanofood emulsions such as spreads, margarine and mayonnaise is a developing area. Most recent developments include the NM capsulation for nanofood in the areas of controlled release, carrier materials, preparation methods and sweetener immobilization. New markets are being developed and current research is underway to reduce the high production costs and lack of food-grade materials.

• Applied Chemistry for Engineering
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• v.19 no.6
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• pp.604-608
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• 2008

In this work, the basic research for nano-capsulation of L-ascorbic acid (Vitamin C) in nonaqueous system was carried out. 500 nm-sized nano-capsules were prepared in nonaqueous system, and the emulsified capsule had mean size of 410 nm. The stability test on the temperature and the storage periods was performed at 4, 20, and $30^{\circ}C$ for 30 days. After 5 days, L-ascorbic acid was extricated 5.1, 9.3, and 12.5% at each temperature, but only 1~2 % was extricated after the time span. Likewise, the results of the skin susceptibility on women and men, each 10 persons, revealed that the very thin allergy was shown from only a woman after 2 days, but it was not shown from the others.

• Journal of the Society of Cosmetic Scientists of Korea
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• v.46 no.2
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• pp.133-145
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• 2020

This study utilized nano-liposomes for the purpose of stabilizing and increasing the solubility of biotin, a water-soluble active material with low solubility. The particle size, zeta potential, and polydispersity index were confirmed with a nano zetasizer. It was possible to manufacture nano liposomes at 100 to 250 nm of particle size and -80 to -30 mV of zeta potential. Dialysis membrane method (DMM) was used to measure the capsulation efficiency of biotin in biotin nano-liposomes, and results showed that pH increased biotin nano-liposomes had higher capsulation efficiency than normal biotin nano-liposome. Through this experiment, it was confirmed that the pH has a great influence on the stability of biotin nano-liposomes. In vitro franz diffusion cell method was used to measure in vitro skin absorption rate of biotin nano-liposomes. The shape of the formulation and biotin solubility in nano-liposome was observed by cryogenic transmission electron microscopy (cryo-TEM). Through this study, we confirmed that biotin, which is introduced as closely related to hair health, can be incorporated into a nano-liposome drug delivery system, to make biotin nano-liposome with improved solubility and precipitation problems.

• Journal of the Society of Cosmetic Scientists of Korea
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• v.30 no.3 s.47
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• pp.419-426
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• 2004

The nano-ceramide capsulation is a technique that capsulates ceramide III and tocopheryl linoleate at the mono-vesicle to act on the horny layer in skin. In this technique, $0.5{\~}5.0\;wt\%$ of hydrogenated lecithin and $0.01{\~}2.00\;wt\%$ of lysolecithin are used as the membrane-strengthen agents of the mono-vesicle and $5.0{\~}10.0\;wt\%$ of propylene glycol and $5.0{\~}10.0\;wt\%$ of ethyl alcohol are used as solvents. Active ingredients such ceramide III and tocopheryl linoleate are utilized to enhance the moisturizing efficacy and treat atopy skin. These materials do not contain synthetic emulsifiers. The optimal conditions or nano-ceramide capsulation are such that particles pass Microfludizdizer 3 times at 1,000 bar and $60{\~}70^{\circ}C$ and pH of nano capsules is $5.8{\pm}0.5.$ The average size of particles is $63.1{\pm}7.34\;nm$ showing lucid state like water by the laser light scattering. A zeta potential value is $-55.1\pm0.84\;mV.$ Through clinical tests, the moisturizing effect (in-vivo, n=8, p-value<0.05) showed $21.15\%$ of improvement comparison to comparison-samples and $36.31\%$ of improvement compared to the state before treatment. Moreover, the effectiveness of atopy skin showed positive reaction from 10 volunteers.

• Proceedings of the SCSK Conference
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• 2003.09b
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• pp.268-279
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• 2003

The nano capsulation of the ceramide was a technique that capsulated ceramide III and tocopheryl linoleate at the mono-vesicle, so as to act the horny layer in skin. It was used 0.5-5.0 wt% of hydrogenated lecithin and 0.01~2.00 wt% of lysolecithin as the membrane-strengthen agents of the mono-vesicle, 5.0~10 wt% of propylene glycol and 5.0~10.0 wt% of ethyl alcohol made by high-pressure Microfluidizer. To enhance the moisturizing efficacy and treat an atopy skin, used ceramide III and tocopheryl linoleate as the active ingredients, and it was made the nano-capsule that synthetic emulsifiers were free. The optimal condition of capsulation of nano ceramide was as follows. The conditions were 3 times at 1,000bar and 60-7$0^{\circ}C$. The particle size showed 63.1$\pm$7.34 nm such as the transparence water as the results for measuring by the laser light scattering. A zeta potential value was -55.1$\pm$0.84 ㎷. The result of the clinical test, the moisturizing effect (in-vivo, n=8, p-value<0.05) was improved 21.15% compared to control, as well as it was improved 36.31 % before the treatment. Moreover, the effectiveness of atopy skin indicated positive reaction that patients were 10 volunteers.

• Journal of the Korean Applied Science and Technology
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• v.17 no.4
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• pp.248-256
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• 2000

We investigated the property of formation of mono-vesicle(designated nano-some) with using of the combined co-emulsifiers and phospholipid. Nano-some was prepared with hydrogenated lecithin(HL) and diethanolamine cetyl phosphate(DEA-CP) by swelling reaction. Kojic acid and kojic dipalmitate could be made stabilization by nano-some system using microfluidizer(MF). Nano-some has a good affinity to skin by means of this system. The composition was compounded by 2% of hydrogenated lecithin (phosphatidyl choline contained with 75%, 0.5% of DEA-CP and 0.5% of diglyceryl dioleate (DGDO). To make nano-some, several conditions of MF have to be considered as follows. The optimum pH was 6.0. The pressure was 10,000psi and passage temperature was at $306^{\circ}C$. The nano-some base was passed to homogenize continually 3 times through MF. The Particle size distributions of the vesicles were with in $57{\sim}75.7nm$(mean 66nm) by measuring the Zetasizer-3000. Zeta potential of vesicles with 3 times passage through MF was -24.8mV. Formations for nano-some vesicle certificated photograph by scanning electric magnification (SEM). Stability of nano-some was very good for 6months. The turbidity was very good transparency compared nano-some with liposome. It was formed the mono vesicle in the opposite direction to be formed the multi-lamellar vesicle of liposome.

• Carbon letters
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• v.27
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• pp.18-25
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• 2018

In this study, graphene oxide(GO) was used as drug carriers to amorphize poorly watersoluble drugs via a co-spray drying process. Two poorly water-soluble drugs, fenofibrate and ibuprofen, were investigated. It was found that the drug molecules could be in the graphene nanosheets in amorphous or nano crystalline forms and thus have a significantly enhanced dissolution rate compared with the counterpart crystalline form. In addition, the dissolution of the amorphous drug enwrapped with the graphene oxide was higher than that of the amorphous drug in activated carbon (AC) even though the AC possessed a larger specific surface area than that of the graphene oxide. The amorphous formulations also remained stable under accelerated storage conditions ($40^{\circ}C$ and 75% relative humidity) for a study period of 14 months. Therefore, graphene oxide could be a potential drug carrier and amorphization agent for poorly water-soluble drugs to enhance their bioavailability.

• Journal of the Society of Cosmetic Scientists of Korea
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• v.34 no.1
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• pp.15-23
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• 2008

This study is on encapsulation of a new whitening agent, LA-PEG using solid lipid nanoparticle(SLN) method, one of nanoparticle preparation method. Classical method has high capsulation efficiency for hydrophobic compounds but has demerit of low capsulation efficiency($2{\sim}3%$) for hydrophilic compounds. Purpose of this study is preparation of SLN that has higher skin penetration effect compared with general liposome, and also has higher encapsulation efficiency of hydrophilic compounds. For SLN preparation, coconut oil, macadamia oil, and jojoba oil were used. As a result, SLN preparation using coconut oil(include LA-PEG) has the most high encapsulation efficiency and also has the smallest average particle size(270 nm). SLN prepared with macadamia oil and 1% of Tween 60 has the largest particle size. Base made with coconut oil and 2% of Tween 60 showed the fastest release and base made with macadamia oil and 2% of Tween 20 showed the latest release.

• Journal of the Korean Applied Science and Technology
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• v.37 no.4
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• pp.1041-1051
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• 2020

The technology of microbubbles and nanobubbles originated in Japan and Europe is applicable to various applications and its effects are diverse, attracting attention not only from many researchers but also from industry experts. In particular, nanobubbles have the advantage that they can be applied to products in the form of liquids, such as cosmetics, from the study that they can exist for more than several months in water. In this study, it was carried out the production of nanobubbles using bubble encapsulation technique and the experiment of skin permeability enhancement of active substances in cosmetics using nanobubble techniquethree. Nanobubbles were confirmed to affect the skin permeability increase of active substances, and up to 250% increase in skin permeability compared to non-bubbles-free materials(Caffeic acid, at 8 hour). It is expected that research results and industrial ripple effects can be expected not only in the cosmetic field, but also in fields applicable to the improvement of permeability by nanobubble techniques, such as areas related to drug delivery system.

• Journal of the Korean Applied Science and Technology
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• v.36 no.2
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• pp.592-599
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• 2019

This study is to stabilize insoluble and unstable active ingredient which is Idebenone (INCI name: hydroxydecyl ubiquinone) in a multi-lamellar vesicle (MLV) and to stabilize it in the skin care cosmetics. Idebenone is good effective raw material in the treatment of Alzheimer's disease in the medical field and a powerful antioxidant in dermatology. It is well known as a substance that inhibits the formation of melanin and cleans the skin pigment. However, it did not dissolve in any solvent and it was difficult to apply in cosmetic applications. Niosome vesicle was able to develop a nano-particle by making a multi-layer of idebenone encapsulated with a nonionic surfactant, hydrogenated lecithin and glycine soja (soybean) sterols and passing it through a high pressure microfluidizer. Idebenone niosome vesicle (INV) has been developed to have the ability to dissolve transparently in water and to promote transdermal penetration. The appearance of the INV was a yellowish liquid having specific odor, and the particle size distribution of INV was about 10~80 nm. The pH was 5~8 (mean=6.8). This capsulation with idebenone was stored in a $45^{\circ}C$ incubator for 3 months and its stability was observed and quantitatively measured by HPLC. As a result, the stability of the sample encapsulated in the niosome vesicle (97.5%) was about 66.3% higher than that of the non-capsule sample of 32.5%. Idebenone 1% INV was used for the efficacy test and clinical trial evaluation as follows. The anti-oxidative activity of INV was 38.2%, which was superior to that of 12.8% tocopherol (control). The melanin-reducing effect of B16 melanoma cells was better than INV (17.4%) and Albutin (control) (9.6%). Pro-collagen synthesis rate was 128.2% for INV and 89.3% for tocopherol (control). The skin moisturizing effect was 15.5% better than the placebo sample. The elasticity effect was 9.7% better than the placebo sample. As an application field, INV containing 1% of idebenone is expected to be able to develop various functional cosmetic formulations such as skin toner, ampoule essence, cream, eye cream and sunblock cream. In addition, it is expected that this encapsulated material will be widely applicable to emulsifying agents for skin use in the pharmaceutical industry as well as the cosmetics industry.