• 한국수산과학회지
• /
• 제35권3호
• /
• pp.231-236
• /
• 2002

국내산 송이의 특징인 송이 향을 효과적으로 보존할 수 있는 방법을 개발하기 위하여 알긴산으로 송이 향의 주된 성분인 1-oc-ten-3-ol을 캡슐화 공정과 송이 향의 잔존량에 영향을 미치는 요인을 조사한 결과는 다음과 같다. 분무건조를 위한 alginates의 점도는 350cp 이하가 되어야 하므로, alginates 용액의 점도를 낮추기 위하여 첨가한 citric acid 량이 증가할수록 점도는 낮아졌으며, 또한 $0.1\%의 농도에서 150cp 이하의 점도를 나타내었다. 1-octen-3-ol과 유화제를 첨가하여 에멀젼시킨 alginates 용액의 점도는 에멀젼시키기 전의 점도보다 높았지만 150cp 이하를 나타내 분무 건조 공정에는 영향이 없었다. alginates 용액의 점도가 낮을수록 용액의 EAI는 증가하였으나 ESI는 감소하였고 캡슐의 1-octen-3-of의 잔존량이 감소하였다. alginates 용액의 점도를 낮추는 공정에서 citric acid 첨가 후 가열시간이 길어질수록 점도는 급격히 감소하였고 에멀전 전후의 점도는 큰 차이 없었다 생송이를 알긴 산용액으로 캡슐화할 때 첨가되는 대두유의 량이 많을수록 1-oc-ten-3-ol의 잔존량이 많았다. 생송이를 alginates용액으로 캡슐화한 후 진공동결건조한 캡슐이 풍건한 것보다 1-octen-3-ol의 잔존량이 많았다.

• 한국수산과학회지
• /
• 제48권5호
• /
• pp.589-595
• /
• 2015

Alginates are used to encapsulate various materials, including food, cosmetics, and pharmaceuticals. This study examined the properties and oxidation stability of fish oil capsules manufactured with calcium alginate gels. The fish oil capsules were manufactured by dropping sodium alginate solution and fish oil into a calcium chloride solution through nozzles. The membrane thickness, sphericity, rupture strength and deformation depth of the fish oil capsules were determined. The peroxide value of the fish oil was assayed to determine the oxidation stability of the capsules. The capsules measured approximately 3 mm with a membrane thickness of 90 μm independent of the amount of fish oil added. As the amount of fish oil encapsulated increased, the sphericity, rupture strength and deformation depth of the capsules decreased. The encapsulation efficiency increased until the amount of fish oil was 30%. The oxidation stability of fish oil in capsules was dependent on the type of nozzle, e.g., the oxidation stability of fish oil in capsules made using a double nozzle was greater than with a single nozzle. These results should lead to industrial application of fish oils including eicosapentaenoic (EPA) and docosahexaenoic (DHA) acids, as nutraceuticals.

• 한국농업기계학회:학술대회논문집
• /
• 한국농업기계학회 2017년도 춘계공동학술대회
• /
• pp.27-27
• /
• 2017

Biocompatible capsules have recently been highlighted as novel delivery platforms of any "materials" (e.g., drug, food, agriculture pesticide) to address current problems of living systems such as humans, animals, and plats in academia and industry for agriculture, biological, biomedical, environmental, food applications. For example, biocompatible alginate capsules were proposed as a delivery platform of biocontrol agents (e.g., bacterial antagonists) for an alternative to antibiotics, which will be a potential strategy in future agriculture. Here, we proposed a new platform based on biocompatible alginate capsules that can control the movements as an active target delivery strategy for various applications including agriculture and biological engineering. We designed and fabricated large scale biocompatible capsules using alginates and custom-made nozzles as well as gelling solutions. To develop the active target delivery platforms, we incorporated the iron oxide nanoparticles in the large scale alginate capsules. It was found that the sizes of large scale alginate capsules could be controlled via various working conditions such as concentrations of alginate solutions and iron oxide nanoparticles. As a proof of concept work, we showed that the iron oxide particles-incorporated large scale alginate capsules could be moved actively by the magnetic fields, which would be a strategy as active target delivery platforms for agriculture and biological engineering (e.g., controlled delivery of agriculture pesticides and biocontrol agents).

• Journal of Dairy Science and Biotechnology
• /
• 제24권1호
• /
• pp.53-63
• /
• 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.