Intracellular reactive oxygen species(ROS) produced in a various pathologic state was known to intermediate many cellular response such as inflammation. Recently, low level light irradiation by HeNe laser used in many clinical field could improve inflammatory state by scavenging intracellular ROS through photo-detachment/dissociation process. The purpose of this study is to investigate the differential effects of blue and red light irradiation on ROS scavenging effects. Immortalized human oral keratinocyte HaCat cells were used. Phorbol 12-myristate 13-acetate(PMA) was treated for inflammation. Red(635nm) and blue(470nm) light irradiation was carried out. To asses the intracellular ROS by light irradiation, confocal microscopic and flow cytometric assay with DCF fluorescence for total ROS and ESR spectrometry of DMPO-O2 - for superoxide anion were caried out. And microarray was performed for mRNA expression level. Released intracellular total ROS in PMA treated HaCat cell lines was dissociated efficiently by red light irradiation, while blue light irradiation did not. Rather, blue light irradiation increased ROS formation. For superoxide anion generated the first synthetic form of ROS, red light irradiation reduced its amount but blue light irradiation did not. In the mRNA expression in line with cyclooxygenase(COX) pathway, prostagrandin endoperoxide synthase 1(PTGS 1), prostagrandin endoperoxide synthase 2(PTGS 2) and phospholipase A2(PLA2) were increased by both light irradiation and they were decreased as time flows. And genes associated with ROS releasing, mRNA expressions of tumor necrosis factor receptor (TNFR) and interleukin 1beta(IL1B) were increased by 1 hour red light irradiation but did not by blue light irradiation. As a result, red and blue light irradiation showed different response in affecting the level of ROS. These findings indicate that red light rather than blue light is more useful for anti-inflammation in clinical field

I. INTRODUCTION
 II. MATERIALS AND METHODS
  1. Primary cell culture and chemicals
  2. Light source and irradiation
  3. Enzyme-linked immunoassay for PGE2
  4. Flow cytometer and laser scanning confocalmicroscope analysis for detectionof ROS formation
  5. Electron spin resonance(ESR) spin trappingdetermination of superoxide anion(O2-)
  6. Total RNA isolation
  7. Analysis of mRNA expression by microarraychip
  8. Statistical Data Analysis
 III. RESULTS
  1. PGE2 release and ROS detection
  2. Microarray analysis
 IV. DISCUSSION
 V. CONCLUSIONS
 VI. REFERENCES

• 한세우(전남대학교 치의학전문대학원 구강병리학교실 및 치의학연구소) | Sei Woo Han
• 고영종(전남대학교 치의학전문대학원 구강병리학교실 및 치의학연구소) | Young Jong Ko
• 정진안(전남대학교 치의학전문대학원 구강병리학교실 및 치의학연구소) | Jin An Jeong
• 김지은(전남대학교 치의학전문대학원 구강병리학교실 및 치의학연구소) | Ji Eun Kim
• 김인애(전남대학교 치의학전문대학원 구강병리학교실 및 치의학연구소) | In Ae Kim
• 임원봉(전남대학교 치의학전문대학원 구강병리학교실 및 치의학연구소) | Won Bong Lim
• 임회순(전남대학교 치의학전문대학원 구강병리학교실 및 치의학연구소) | Hoi Soon Lim
• 박지일(광주보건대학 치위생과) | Ji Il Park
• 김미숙(전남보건환경연구원) | Mi Sook Kim
• 김서연(송원대학 치위생과) | Seo Yune Kim
• 김옥준(전남대학교 치의학전문대학원 구강병리학교실 및 치의학연구소) | Ok Joon Kim
• 최홍란(전남대학교 치의학전문대학원 구강병리학교실 및 치의학연구소) | Hong Ran Choi correspondence