摘要
The assembling of a coating of time-resolved fluorescent chelator BSPDA ( abbreviated for 4, 7-bis ( sulfhydrylphenyl)-1, 10-phenanthroline-2, 9-dicarboxylic acid) onto a nano-gold layer was demonstrated. First, BSPDA was synthesized by simple procedures, and then an approach was developed to immobilize BSPDA onto the nano-gold layer deposited on a silane modified glass substrate, whereby europium ion (Ⅲ, Eu^3+ ) was captured and released owing to the interactive process of complexation and dissociation between BSPDA functionalized coating and Eu^3+ solution. The fluorescence spectra and related lifetimes were determined. Also, the BSPDA functionalized coating's specific complexation with Eu^3+ on the BSPDA assembly layer and the nonspecific adsorption of Eu^3+ on the nano-gold layer were compared. These results allowed a selective complexation of Eu^3+ by assembling a BSPDA chelating layer on the nano-gold layer; thus, a tunable time-resolved fluorescent layer was covalently attached, The results of the nanoparticle assembling and probing (or labeling) processes to specific bio-systems were very interesting and had significant implications to time-resolved-fluorescence-based detection on biosensor surfaces such as DNA chip and to arrayed light display devices.
The assembling of a coating of time-resolved fluorescent chelator BSPDA ( abbreviated for 4, 7-bis ( sulfhydrylphenyl)-1, 10-phenanthroline-2, 9-dicarboxylic acid) onto a nano-gold layer was demonstrated. First, BSPDA was synthesized by simple procedures, and then an approach was developed to immobilize BSPDA onto the nano-gold layer deposited on a silane modified glass substrate, whereby europium ion (Ⅲ, Eu^3+ ) was captured and released owing to the interactive process of complexation and dissociation between BSPDA functionalized coating and Eu^3+ solution. The fluorescence spectra and related lifetimes were determined. Also, the BSPDA functionalized coating's specific complexation with Eu^3+ on the BSPDA assembly layer and the nonspecific adsorption of Eu^3+ on the nano-gold layer were compared. These results allowed a selective complexation of Eu^3+ by assembling a BSPDA chelating layer on the nano-gold layer; thus, a tunable time-resolved fluorescent layer was covalently attached, The results of the nanoparticle assembling and probing (or labeling) processes to specific bio-systems were very interesting and had significant implications to time-resolved-fluorescence-based detection on biosensor surfaces such as DNA chip and to arrayed light display devices.
基金
Project supported by the National Natural Science Foundation of China (20505020)
the Natural Science Foundation ofGuangdong Province (06300086)
China Postdoctoral Science Foundation (20060390202)
Scientific Research Fund ofHunan Provincial Education Department (05C508)
Skeleton Youth Faculty Programof Hunan Higher Educational School
