Integrated Nanoextraction and Colorimetric Reactions in Surface Nanodroplets for Combinative Analysis
A combinative approach for chemical analysis makes it possible to distinguish a mixture of a large number of compounds from other mixtures in a single step. This work demonstrates a combinative analysis approach using surface nanodroplets for integrating nanoextraction and colorimetric reactions for...
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| Veröffentlicht in: | Analytical chemistry (Washington) 2020-09, Vol.92 (18), p.12442-12450 |
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| creator | Wei, Zixiang Li, Miaosi Zeng, Hongbo Zhang, Xuehua |
| description | A combinative approach for chemical analysis makes it possible to distinguish a mixture of a large number of compounds from other mixtures in a single step. This work demonstrates a combinative analysis approach using surface nanodroplets for integrating nanoextraction and colorimetric reactions for the identification of multicomponent mixtures. The model analytes are acidic compounds dissolved in an oil that are extracted into aqueous droplets on a solid substrate. The proton from acid dissociation reacts with the halochromic chemical compounds inside the droplets, leading to the color change of the droplets. The rate of the colorimetric reaction exhibits certain specificity for the acid type, distinguishing acid mixtures with the same pH value. The underlying principle is that the acid transport rate is associated with the partition coefficient and the dissociation constant of the acid, as well as to the concentration in the oil. As a demonstration, we showed that droplet-based combinative analysis can be applied for anti-counterfeiting of various alcoholic spirits by comparing the decoloration time of organic acid mixtures in the spirits. The readout can be done by a common hand-hold mobile phone. |
| doi_str_mv | 10.1021/acs.analchem.0c02239 |
| format | Article |
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This work demonstrates a combinative analysis approach using surface nanodroplets for integrating nanoextraction and colorimetric reactions for the identification of multicomponent mixtures. The model analytes are acidic compounds dissolved in an oil that are extracted into aqueous droplets on a solid substrate. The proton from acid dissociation reacts with the halochromic chemical compounds inside the droplets, leading to the color change of the droplets. The rate of the colorimetric reaction exhibits certain specificity for the acid type, distinguishing acid mixtures with the same pH value. The underlying principle is that the acid transport rate is associated with the partition coefficient and the dissociation constant of the acid, as well as to the concentration in the oil. As a demonstration, we showed that droplet-based combinative analysis can be applied for anti-counterfeiting of various alcoholic spirits by comparing the decoloration time of organic acid mixtures in the spirits. 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As a demonstration, we showed that droplet-based combinative analysis can be applied for anti-counterfeiting of various alcoholic spirits by comparing the decoloration time of organic acid mixtures in the spirits. 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| source | American Chemical Society Journals |
| subjects | Acids Chemical analysis Chemical compounds Chemical reactions Colorimetry Decoloring Droplets Halochromism Organic acids Spirits Substrates Transport rate |
| title | Integrated Nanoextraction and Colorimetric Reactions in Surface Nanodroplets for Combinative Analysis |
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