Refreshing DNA-Based Nanoprobes by Alcohol for Heavy Metal Detection: Toward Sustainable Sensing Nanomaterials

Increasing the applications of disposable nanomaterials yet with potential environmental risk and the resulting nanowastes have become a problem of public concern worldwide. However, efficient recovery of useful materials from nanowastes is currently limited by their tiny size, high physicochemical activity, and unpredictable aggregation. We have developed a conceptually new strategy for recycling nanoprobes by alcoholic solvent "refreshing". In specific, DNA-functionalized gold nanoparticles and nanorods are employed as colorimetric nanoprobes for Hg(II) and Ag(I) ions, respectively, both of which rely upon target-induced DNA terminal base pairing and the subsequent base pair stacking assembly of the nanoprobes. Upon the introduction of isopropanol to the "waste" aggregates, however, the DNAs are denaturalized to release heavy metal ions, leading to restoration of individual nanoprobes. The fine modulation of DNA hybridization not only affords sensitive detection but also addresses the recycling of the nanoprobes with high efficiency (>80%) while preserving the detection performance irrespective of the nanoprobe shape and surface-grafted DNA sequence. We further demonstrate the use of the recycled nanoprobes in the detection of Hg(II) species from salmon muscle tissue. With the generality of the recovering method and the combined features of the renewable nanoprobes, including high recycling efficiency and retained functionality, sustainable sensing nanomaterials are within reach.