Most of cosmetics are emulsion products that contain the source of nutrition vegetable oil, mineral oil, natural extract and carbohydrate etc. There are many possibilities to be contaminated by microbials. We investigated the effect of antimicrobial and minimum inhibitory concentration(MIC) with thiamine dilauryl sulfate(TDS), which was prepared to use cosmetic lotion formulation. Staphylococcus aureus(S. aureus) and Escherichia col(E. coli) were used as test organism. MIC value of TDS was determined aganist microorganism for the growth inhibition by concentration of TDS. From the MIC results, antimicrobial effect of TDS was generally more effective to gram positive than gram negative. Antimicrobial effect with pH value against some microorganism appeared in the following order : pH 5 > pH 6 > pH 7. It showed strong antimicrobial activities against S. aureus, and weak antimicrobial activities against E. coli. If it was possible to determine the formulations with TDS, it would be effective to reduce the artificial preservatives.

본 연구는 레시틴으로 나노입자화 시킨 티아민 디라우릴 설페이트의 향장활성 증진에 관한 것이다. TDS를 포집시킨 나노입자는 150 ~ 200 nm의 크기를 나타내는 구형이며, 또한 제타포텐셜을 측정하여 여러 pH범위에서 안정한 것을 확인하였다. TDS 나노입자는 인간 섬유아세포(CCD-986sk)에 높은 농도를 처리하여도85%의 세포생존률을 보였다. 자유라디칼소거활성 실험을 진행한 결과 나노입자화하지 않은 TDS 희석액(1.0mg/mL)은 81.6%의 활성을 나타내었고, 나노입자화한 TDS 용액은 이보다 더 높은 88.1%의 높은 라디칼 소거활성을 보였다. TDS 나노입자는 자외선을 조사시킨 CCD-986sk에서 MMP-1의 발현을 41.4% 감소시켰다.TDS 용액과 TDS 나노입자를 가지고 salmonella typhimurium, listeria monocytogenes에 대하여 항균활성을 측정하였다. TDS 나노입자의 경우 양성대조군의 항균활성과 비슷한 결과를 나타내었다. 이러한 결과들로TDS 나노입자가 항산화, 미백, 주름개선 효능같은 향장 소재로서의 적용이 가능할 것이라 생각된다.

Conventional Thiamine Dilauryl Sulfate (TDS) powder has a low stability. In order to solve this problem, this study was performed to improve the solubility of TDS. The process for enhance solubility of TDS was nano grinding mill and ultrasonic dispersion process. TDS paticle was manufactured to nano size through nano grinding mill process. The size of TDS nanoparticle was measured as average 220 nm by DLS. And The TDS nanoparticle in water solution manufactured through ultrasonic dispersion process. The TDS nanoparticle in water solution was showed the highest solubility with 40% ethanol. These results was increased the concentration of TDS from 200 ppm to 240 ppm in water solution. The TDS nanoparticle in water solution showed diameter of Colletotrichum gloeosporioides growth with smaller than about 1.56 cm compared to the TDS paticle in water solution at same concentration. Also, TDS nanoparticle in water solution showed growth inhibition activity as 59.2% with higher than about 10% compared to the TDS paticle water solution in same concentration. Finally, TDS nanoparticle in water solution was increased solubility through nano grinding mill and ultrasonic dispersion process. Also, the increase of concentration in TDS nanopaticle in water solution according to solubility enhancement lead to an result enhancement of antifungal activity. Consequently, we suggested that the TDS nanoparticle in water solution was more effective than TDS particle in water solution owing to the sub-cellular particle size, ability to persistence and targeting to cell membrane of Colletotrichum gloeosporioides. Furthermore we expected the applicating possibility with bio pesticide.