Laboratorio di Chimica Analitica, Dipartimento di Scienze e Tecnologie Biologiche e Ambientali (Di.S.Te.B.A.), Università del Salento, Via Monteroni, 73100 Lecce, Italy.
Dipartimento di Ingegneria dell'Informazione, Università di Pisa, Via G. Caruso 16, 56122 Pisa, Italy.
ACS Appl Mater Interfaces. 2024 Aug 21;16(33):43752-43761. doi: 10.1021/acsami.4c08860. Epub 2024 Aug 6.
Reconfiguration of chemical sensors, intended as the capacity of the sensor to adapt to novel operational scenarios, e.g., new target analytes, is potentially game changing and would enable rapid and cost-effective reaction to dynamic changes occurring at healthcare, environmental, and industrial levels. Yet, it is still a challenge, and rare examples of sensor reconfiguration have been reported to date. Here, we report on a reconfigurable label-free optical sensor leveraging the versatile immobilization of metal ions through a chelating agent on a nanostructured porous silica (PSiO) optical transducer for the detection of different biomolecules. First, we show the reversible grafting of different metal ions on the PSiO surface, namely, Ni, Cu, Zn, and Fe, which can mediate the interaction with different biomolecules and be switched under mild conditions. Then, we demonstrate reconfiguration of the sensor at two levels: 1) switching of the metal ions on the PSiO surface from Cu to Zn and testing the ability of Cu-functionalized and Zn-reconfigured devices for the sensing of the dipeptide carnosine (CAR), leveraging the well-known chelating ability of CAR toward divalent metal ions; and 2) reconfiguration of the Cu-functionalized PSiO sensor for a different target analyte, namely, the nucleotide adenosine triphosphate (ATP), switching Cu with Fe ions to exploit the interaction with ATP through phosphate groups. The Cu-functionalized and Zn-reconfigured sensors show effective sensing performance in CAR detection, also evaluated in tissue samples from murine brain, and so does the Fe-reconfigured sensor toward ATP, thus demonstrating effective reconfiguration of the sensor with the proposed surface chemistry.
化学传感器的重构,即传感器适应新的操作场景的能力,例如新的目标分析物,具有潜在的变革性,能够快速、经济有效地应对医疗、环境和工业等层面的动态变化。然而,这仍然是一个挑战,迄今为止,只有极少数传感器重构的例子被报道。在这里,我们报告了一种可重构的无标记光传感器,该传感器利用螯合剂在纳米结构化多孔硅(PSiO)光换能器上对金属离子进行多功能固定,用于检测不同的生物分子。首先,我们展示了不同金属离子(Ni、Cu、Zn 和 Fe)在 PSiO 表面的可逆接枝,这些金属离子可以介导与不同生物分子的相互作用,并在温和条件下进行切换。然后,我们在两个层面上展示了传感器的重构:1)将 PSiO 表面上的金属离子从 Cu 切换到 Zn,并测试 Cu 功能化和 Zn 重构器件对二肽肉碱(CAR)的传感能力,利用 CAR 对二价金属离子的众所周知的螯合能力;2)Cu 功能化 PSiO 传感器对不同目标分析物(即核苷酸三磷酸腺苷(ATP))的重构,通过磷酸基团将 Cu 与 Fe 离子进行交换,以利用与 ATP 的相互作用。Cu 功能化和 Zn 重构传感器在 CAR 检测中表现出有效的传感性能,在来自鼠脑的组织样本中也进行了评估,Fe 重构传感器对 ATP 也具有同样的效果,从而证明了所提出的表面化学方法对传感器的有效重构。
