We created an immunosensing platform for the detection of proteins in a buffer solution. Our sensing platform relies on graphene oxide (GO) nanosheets conjugated with antibodies to provide quantitative binding sites for analyte proteins. When analyte proteins and standard fluorescein-labelled proteins are competing for the binding sites, the assay exhibits quantitative fluorescence quenching by GO for the fluorescein-labelled proteins as determined by the analyte protein concentration. Because of this mechanism, measured fluorescence intensity from unquenched fluorescein-labelled protein was shown to increase with an increasing analyte protein concentration. As an alternative to the conventional enzyme-linked immunosorbent assay (ELISA), our method does not require an enzyme-linked second antibody for protein recognition and the enzyme for optical signal measurement. Thus, it is beneficial with its low cost and fewer systematic errors caused by the series of antigen-antibody recognition steps in ELISA. Immune globulin G (IgG) was introduced as a model protein to test our method and our results showed that the limit of detection for IgG was 4.67 pmol mL−1 in the buffer solution. This sensing mechanism could be developed into a promising biosensor for the detection of proteins, which would broaden the spectrum of GO applications in both analytical biochemistry and clinical diagnosis.
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机译:我们创建了一个用于检测缓冲溶液中蛋白质的免疫传感平台。我们的传感平台依靠与抗体偶联的氧化石墨烯(GO)纳米片,为分析物蛋白质提供定量结合位点。当分析物蛋白和标准的荧光素标记蛋白竞争结合位点时,该测定法会显示出通过GO对荧光素标记的蛋白进行定量荧光猝灭,这由分析物蛋白浓度确定。由于这种机理,未分析的荧光素标记蛋白的荧光强度随分析物蛋白浓度的增加而增加。作为常规酶联免疫吸附测定(ELISA)的替代方法,我们的方法不需要用于蛋白识别的酶联二抗和用于光信号测量的酶。因此,它具有低成本和由ELISA中一系列抗原-抗体识别步骤引起的系统错误少的优点。引入免疫球蛋白G(IgG)作为模型蛋白来测试我们的方法,我们的结果表明,在缓冲液中,IgG的检出限为4.67 pmol mL -1 。这种传感机制可以发展成为一种有前途的生物传感器来检测蛋白质,这将扩大GO在分析生物化学和临床诊断中的应用范围。
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