Qu Xiaochao, Wang Jing, Zhang Zhenxi, Koop Norbert, Rahmanzadeh Ramtin, Hüttmann Gereon
Xi'an Jiaotong University, The Key Laboratory of Biomedical Information Engineering of the Ministry of Education, Institute of Biomedical Analytical Technology and Instrumentation, School of Life Science and Technology, Xi'an 710049, China.
J Biomed Opt. 2008 May-Jun;13(3):031217. doi: 10.1117/1.2942373.
Due to their unique optical properties, optical probes, including metal nanoparticles (NPs) and fluorescent dyes, are increasingly used as labeling tools in biological imaging. Using multiphoton microscopy and fluorescence lifetime imaging (FLIM) at 750-nm excitation, we recorded intensity and FLIM images from gold NPs (30 nm) and the fluorescent dye Alexa 488 (A488) conjugated with monoclonal ACT-1 antibodies as well as Hoechst 33258 (H258) after incubation with the lymphoma cell line (Karpas-299). From the FLIM images, we can easily discriminate the imaging difference between cells and optical probes according to their distinct fluorescence lifetimes (cellular autofluorescence: 1 to 2 ns; gold NPs: <0.02 ns; A488: 3.5 ns; H258: 2.5 ns). The NP-ACT-1 and A488-ACT-1 conjugates were bound homogeneously on the surface of cells, whereas H258 stained the cell nucleus. We demonstrate that the emission intensity of gold NPs is about ten times stronger than that of the autofluorescence of Karpas-299 cells at the same excitation power. Compared with fluorescent dyes, stronger emission is also observed from gold NPs. Together with their high photostability, these observations suggest that gold NPs are a viable alternative to fluorescent dyes for cellular imaging and cancer diagnosis.
由于其独特的光学性质,包括金属纳米颗粒(NPs)和荧光染料在内的光学探针越来越多地被用作生物成像中的标记工具。使用750纳米激发下的多光子显微镜和荧光寿命成像(FLIM),我们记录了与单克隆ACT-1抗体偶联的金纳米颗粒(30纳米)、荧光染料Alexa 488(A488)以及与淋巴瘤细胞系(Karpas-299)孵育后的Hoechst 33258(H258)的强度和FLIM图像。从FLIM图像中,我们可以根据细胞和光学探针不同的荧光寿命(细胞自发荧光:1至2纳秒;金纳米颗粒:<0.02纳秒;A488:3.5纳秒;H258:2.5纳秒)轻松区分成像差异。NP-ACT-1和A488-ACT-1偶联物均匀地结合在细胞表面,而H258则对细胞核进行染色。我们证明,在相同激发功率下,金纳米颗粒的发射强度比Karpas-299细胞的自发荧光强度强约十倍。与荧光染料相比,金纳米颗粒也观察到更强的发射。连同它们的高光稳定性,这些观察结果表明金纳米颗粒是用于细胞成像和癌症诊断的荧光染料的可行替代品。
