| 光谱学与光谱分析 |
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| Reflectance Spectroscopy Study of Low-Frequency Ultrasound and Glycerol on Skin Optical Clearing |
| ZHONG Hui-qing1,GUO Zhou-yi1,WEI Hua-jiang1*,ZHANG Zu-de1,YANG Hong-qin2,XIE Shu-sen2 |
1. Ministry of Education Key Laboratory of Laser Life Science and Institute of Laser Life Science, South China Normal University, Guangzhou 510631, China
2. Key Laboratory of Optoelectronic Science and Technology for Medicine of Ministry of Education, Fujian Normal University, Fuzhou 350007, China |
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Abstract In order to find a non-invasive way to improve the efficacy of skin optical clearing with topically applied optical clearing agents, the authors researched the changes of reflectance spectroscopy of skin tissues before and after being dealt by low-frequency ultrasound and osmotic active chemical agents within the wavelength range of 400-860 nm, and the degree of changes in reflectance spectroscopy of each group skin during 0-15 min and 15-30 min at 580 nm. The measurements were performed using a AvaSpec-2048 optical fiber spectrometer with integrating-sphere setup. The results of measurements showed that there were a few changes of the reflectance spectroscopy of skin tissues in the control group (Group 1) (The skin tissue was dealt with nothing.) during the whole observation; But in the Group 2 (The skin tissue was dealt with only low-frequency ultrasound), it was found that the reflectance of the skin tissue showed a significant increase comparing 15 min with 0 min, but the changes in reflectance of the tissues slowly restored the original form following the longer time since the ultrasound stopping; There was also a very fast changes in reflectance of the skins in the Group 3 (the skin were dealt with only 80% glycerol) compared with that in the Group 1. The authors also found that there was a very distinct decrease in the reflectance of skin tissues dealt with both low-frequency ultrasound and 80% glycerol group (Group 4), especially during the 0-15 min, and its speed was 4.0 times that of the Group 1 and 2.3 times that of Group 3 (During 0-15 min, the reflectance of skin tissues in the Group 1 decreased 1.896%; the reflectance of skin tissue in the Group 3 decreased 3.316%; the reflectance of skin tissues in the Group 4 decreased 7.551%). From the above results, it can be clearly seen that the low-frequency ultrasound and 80% glycerol not only have synergistic effect on optical clearing of skin tissue in vitro, but can change the optical clearing of the skin tissue in a short time.
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Received: 2009-03-23
Accepted: 2009-06-26
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Corresponding Authors:
WEI Hua-jiang
E-mail: weihj@scnu.edu.cn
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[1] DENG Yong, LUO Qing-ming, LU Qiang(邓 勇, 骆清铭, 鲁 强). Acta Optica Sinica(光学学报), 2006, 26(03): 419.
[2] WEI Hua-jiang, XING Da, HE Bo-hua, et al(魏华江, 邢 达, 何博华, 等). Spectroscopy and Spectral Analysis(光谱学与光谱分析), 2008, 28(1): 10.
[3] XIE Shu-sen, LI Hui, et al(谢树森, 李 晖, 等). Laser and Optoeletronics Progress(激光与光电子学进展), 2001, (9): 44.
[4] Bashkatov A N, Genina E A, Kochubey V I, et al. Optical Biopsy Ⅲ, 2000, 1(11): 256.
[5] Kassan D G, Lynch Am, et al. J. Am. Acad of Dermatology, 1996, 34(4): 657.
[6] Tuchin V V, Maksimova I L, Zimnyakov Dmitry A, et al. Mishin. J. Biomed. Opt., 1997, 2(4): 401.
[7] He Yonghong, Wang R K. J. Biomed. Opt., 2004, 9(1): 200.
[8] Moulton K, Lovell F, Williams E, et al. J. of Animal Science, 2005, 83: 246.
[9] Mcclure R A, Bui A, Chang J, et al. Lasers in Surgery and Medicine, 2008, Suppl 20: 6.
[10] Jiang J Y, Boese M, Turner P, et al. Journal of Biobmedical Optics, 2008, 13(2): 021105.
[11] Xu Xiangqun, Zhu Qiuhong. IEEE Transactions on Biomedical Engineering, 2008, 55(4): 1432.
[12] Huang C Y, Liu B, Brezinski M E. J. Opt. Soc. Am. A: Opt. Image. Sci. Vis., 2008, 25(4): 938.
[13] Mitragotri S, Kost J. Advanced Drug Delivery Reviews, 2004, 56(5): 589.
[14] Tezel A, Sens A, Mitragotri S. Pharmaceutical Research, 2002, 19(12): 1841.
[15] Samir Mitragotri, Daniel Blankschtein A R L. Pharmaceutical Research, 1996, 13(3): 411.
[16] Makoto Ogura, Sumit Paliwal S M. Advanced Drug Delivery Reviews, 2008, 60(10): 1218.
[17] Wang Ruikang, He Yonghong, Valery Tuchin. SPIE, 2004, 5316: 119.
[18] XU Xiang-qun, WU Liu(徐向群, 吴 柳). Chinese Journal of Lasers(中国激光), 2006, 33(7): 998.
[19] Mitragotri S, Ray D, Farrell J, et al. J. of Pharmaceutical Sciences, 2000, 89(7): 892.
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