药品成分二维成像及活性分子的分布与渗透
如果您是一位化学家,您想要使用无标记方法观察某种化学成分在医药产品或复杂配方中的分布 ,Lightcore Technologies DC-SRS microscope 显微镜成像系统将为您提供简洁通用并可调节的化学成分成像平台,通过跟踪化学键的震动频率特征[350cm-1, 3800cm-1]观察不同化学成分的分布,以及跟踪氘代活性分子在活体内或活体外皮肤中的渗透。
对于微小样本,活体样本,或显微镜难以到达的样本区域,您可能需要可旋转弯曲的探针式成像镜头。 Lightcore Technologies M-FIP flexible endoscope 直径仅2毫米,探针镜头以光纤连接,可以用于相干拉曼散射成像(CARS),二次/三次谐波成像,以及双光子自荧光成像。
DC-SRS 显微镜: 化妆品活性物分子(红色) – 相干拉曼散射成像;人工培养皮肤(绿色)- 双光子子荧光成像
DC-SRS 显微镜: 体外涂抹后1小时10分钟,氘化甘油在人类活体皮肤中的深度渗透和浓度分布 – 相干拉曼散射成像
DC-SRS 显微镜: 在PMMA模拟皮肤基底上分布的表层活性分子的厚度(单位:微米;图像大小:1.4 mm x 1.1 mm)
M-FIP flexible endoscope 活体皮肤角质层细胞成像
参考文献:
- B. Sarri, R. Canonge, X. Audier, V. Lavastre, G. Pénarier, J. Alie, and H. Rigneault, “Discriminating polymorph distributions in pharmaceutical tablets using stimulated Raman scattering microscopy,” Journal of Raman Spectroscopy 50, 1896-1904 (2019). doi.org/10.1002/jrs.5743
- B. Sarri, X. Chen, R. Canonge, S. Grégoire, F. Formanek, J-B Galey, AnnePotter, T. Bornschlögl, and H. Rigneault, ‘In vivo quantitative molecular absorption of glycerol in human skin using coherent anti-Stokes Raman scattering (CARS) and two-photon auto-fluorescence’, J Controlled Release 308, 190-196 (2019) doi.org/10.1016/j.jconrel.2019.07.018
- X. Chen, P. Gasecka, F. Formanek, J. B. Galey, and H. Rigneault, ‘In vivo single human sweat gland activity monitoring using coherent anti-Stokes Raman scattering and two-photon excited auto-fluorescence microscopy’, British Journal of Dermatology 174, 803–812, (2016) doi.org/10.1111/bjd.14292
Highlighted in BJD: S. Osseiran, C. L. Evans, Sweating the small stuff, British J. Dermat. 174, 709 (2016) doi.org/10.1111/bjd.14504 - X. Chen, S. Grégoire, F. Formanek, J.-B. Galey, H. Rigneault, ‘Quantitative 3D molecular cutaneous absorption in human skin using label free nonlinear microscopy’, Journal of Controlled Release 200, 78-86 (2015) doi.org/10.1016/j.jconrel.2014.12.033