• 대한화장품학회지
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• 제47권2호
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• pp.163-170
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• 2021

본 연구는 인체 친화적인 소재로 여드름균을 제거하는 기술을 만들기 위해서 진행하였다. 먼저 여드름균을 운모 디스크에 흡착시켜 생장시킨 후 원자현미경을 통해 바이오필름이 제대로 성장하였는지를 확인하였다. 이미지 상으로 형태가 둥글게 변하였고 사이즈도 평균 17% 정도 길어졌으며 물질을 구분하는 공명주파수의 위상 값이 단일값으로 관찰된 것을 볼 때 세균막이 운모디스크 전체를 덮어서 자란 바이오필름을 확인할 수 있었다. 이렇게 바이오필름을 생성시킨 여드름균에 여러 가지 아미노산 50 mM을 각각 처리하여 관찰한 결과 valine, serine, argine, leucine을 처리하였을 때 여드름균의 농도가 감소한 것을 발견하였다. 나노인덴터와 AFM 컨택모드로 스캔을 한 결과 valine (Val)을 처리한 여드름균 바이오필름의 강도가 증가해 있는 것을 확인하였다. 이것은 균을 보호하는 외곽의 세균막이 형성 억제됨으로써 세균막보다 더 높은 강도일 수 있는 균을 측정했기 때문일 수 있다. 여드름균과 Val을 처리한 여드름균에 균과 바이오필름 내부의 세균막을 볼 수 있는 형광물질을 각각 태깅하고 형광 이미지를 관찰한 결과 저농도 Val을 처리한 여드름균에서는 세균막이 관찰되었으나 10 mM 이상의 Val을 처리할 때부터 여드름균의 세균막이 형성 억제됨을 알 수 있었다. 뿐만 아니라 Val 10 mM 이상의 농도에서는 여드름균 전체의 농도도 감소하는 것을 알 수 있었다. 즉, 세균막이 형성 억제됨으로써 약화된 여드름균의 결합력에 의해서 여드름 균의 농도가 감소한 것으로 볼 수 있다. 마침내 Val의 투입은 세균막 생성을 억제함으로써 여드름균을 제거하는 효능이 있음을 확인하였다.

• 한국진공학회:학술대회논문집
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• 한국진공학회 2013년도 제45회 하계 정기학술대회 초록집
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• pp.88-89
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• 2013

A variety of influenza A viruses from animal hosts are continuously prevalent throughout the world which cause human epidemics resulting millions of human infections and enormous industrial and economic damages. Thus, early diagnosis of such pathogen is of paramount importance for biomedical examination and public healthcare screening. To approach this issue, here we propose a fully integrated Rotary genetic analysis system, called Rotary Genetic Analyzer, for on-site detection of influenza A viruses with high speed. The Rotary Genetic Analyzer is made up of four parts including a disposable microchip, a servo motor for precise and high rate spinning of the chip, thermal blocks for temperature control, and a miniaturized optical fluorescence detector as shown Fig. 1. A thermal block made from duralumin is integrated with a film heater at the bottom and a resistance temperature detector (RTD) in the middle. For the efficient performance of RT-PCR, three thermal blocks are placed on the Rotary stage and the temperature of each block is corresponded to the thermal cycling, namely $95^{\circ}C$ (denature), $58^{\circ}C$ (annealing), and $72^{\circ}C$ (extension). Rotary RT-PCR was performed to amplify the target gene which was monitored by an optical fluorescent detector above the extension block. A disposable microdevice (10 cm diameter) consists of a solid-phase extraction based sample pretreatment unit, bead chamber, and 4 ${\mu}L$ of the PCR chamber as shown Fig. 2. The microchip is fabricated using a patterned polycarbonate (PC) sheet with 1 mm thickness and a PC film with 130 ${\mu}m$ thickness, which layers are thermally bonded at $138^{\circ}C$ using acetone vapour. Silicatreated microglass beads with 150~212 ${\mu}L$ diameter are introduced into the sample pretreatment chambers and held in place by weir structure for construction of solid-phase extraction system. Fig. 3 shows strobed images of sequential loading of three samples. Three samples were loaded into the reservoir simultaneously (Fig. 3A), then the influenza A H3N2 viral RNA sample was loaded at 5000 RPM for 10 sec (Fig. 3B). Washing buffer was followed at 5000 RPM for 5 min (Fig. 3C), and angular frequency was decreased to 100 RPM for siphon priming of PCR cocktail to the channel as shown in Figure 3D. Finally the PCR cocktail was loaded to the bead chamber at 2000 RPM for 10 sec, and then RPM was increased up to 5000 RPM for 1 min to obtain the as much as PCR cocktail containing the RNA template (Fig. 3E). In this system, the wastes from RNA samples and washing buffer were transported to the waste chamber, which is fully filled to the chamber with precise optimization. Then, the PCR cocktail was able to transport to the PCR chamber. Fig. 3F shows the final image of the sample pretreatment. PCR cocktail containing RNA template is successfully isolated from waste. To detect the influenza A H3N2 virus, the purified RNA with PCR cocktail in the PCR chamber was amplified by using performed the RNA capture on the proposed microdevice. The fluorescence images were described in Figure 4A at the 0, 40 cycles. The fluorescence signal (40 cycle) was drastically increased confirming the influenza A H3N2 virus. The real-time profiles were successfully obtained using the optical fluorescence detector as shown in Figure 4B. The Rotary PCR and off-chip PCR were compared with same amount of influenza A H3N2 virus. The Ct value of Rotary PCR was smaller than the off-chip PCR without contamination. The whole process of the sample pretreatment and RT-PCR could be accomplished in 30 min on the fully integrated Rotary Genetic Analyzer system. We have demonstrated a fully integrated and portable Rotary Genetic Analyzer for detection of the gene expression of influenza A virus, which has 'Sample-in-answer-out' capability including sample pretreatment, rotary amplification, and optical detection. Target gene amplification was real-time monitored using the integrated Rotary Genetic Analyzer system.