Triarylamine Rhodanine Derivatives as Red Emissive Sensor for Discriminative Detection of Ag⁺ and Hg²⁺ ions in Buffer-Free Aqueous Solutions

Abstract: A completely water-soluble, red emitting, multibranched sensor based on the electron-rich triphenylamine and electron-deficient rhodanine-3-acetic acid has been developed. The sensors mRA, dRA, and tRA, respectively, have one, two, and three rhodanine-3-acetic acid groups, responsible for the interaction with the metal ions as well as the solubility of the probe in water. mRA, dRA, and tRA senses Ag+ and Hg2+ ions in a buffer-free aqueous solution with the lowest detection level of 0.06 and 0.02 ppm, respectiv… Show more

“…[13][14][15] On this firm basis, we advocate the use of bridged triarylamines, known as N-heterotriangulenes (N-HTAs), in the role of chromophoric aromatic lids, in order to achieve redox-active nanosized cavities [16][17][18][19][20] for larger chiral guests, aiming at setting foot on the realm of enantioselective discrimination. [21][22][23] Precedents of sensing examples involving triarylamines range from the detection of metallic cations, [24] to toxic anions [25] or anions present in chemical weapons, [26] nitroaromatic explosives, [27] biological metabolites, [28] toxic gases, [29,30] and pH determination. [31] Regarding the implementation of triarylamines in both macrocyclic and cage structures, few examples can be tracked down in literature, [32][33][34][35][36][37][38][39] and even scarcer examples are found for their bridged analogues, N-HTAs, whose presence in complexing and sensing processes is limited.…”

“…Precedents of sensing examples involving triarylamines range from the detection of metallic cations, [24] to toxic anions [25] or anions present in chemical weapons, [26] nitroaromatic explosives, [27] biological metabolites, [28] toxic gases,[ 29 , 30 ] and pH determination. [31] Regarding the implementation of triarylamines in both macrocyclic and cage structures, few examples can be tracked down in literature,[ 32 , 33 , 34 , 35 , 36 , 37 , 38 , 39 ] and even scarcer examples are found for their bridged analogues, N ‐HTAs, whose presence in complexing and sensing processes is limited.…”

A Chiral Molecular Cage Comprising Diethynylallenes and N‐Heterotriangulenes for Enantioselective Recognition

“…[13][14][15] On this firm basis, we advocate the use of bridged triarylamines, known as N-heterotriangulenes (N-HTAs), in the role of chromophoric aromatic lids, in order to achieve redox-active nanosized cavities [16][17][18][19][20] for larger chiral guests, aiming at setting foot on the realm of enantioselective discrimination. [21][22][23] Precedents of sensing examples involving triarylamines range from the detection of metallic cations, [24] to toxic anions [25] or anions present in chemical weapons, [26] nitroaromatic explosives, [27] biological metabolites, [28] toxic gases, [29,30] and pH determination. [31] Regarding the implementation of triarylamines in both macrocyclic and cage structures, few examples can be tracked down in literature, [32][33][34][35][36][37][38][39] and even scarcer examples are found for their bridged analogues, N-HTAs, whose presence in complexing and sensing processes is limited.…”

“…Precedents of sensing examples involving triarylamines range from the detection of metallic cations, [24] to toxic anions [25] or anions present in chemical weapons, [26] nitroaromatic explosives, [27] biological metabolites, [28] toxic gases,[ 29 , 30 ] and pH determination. [31] Regarding the implementation of triarylamines in both macrocyclic and cage structures, few examples can be tracked down in literature,[ 32 , 33 , 34 , 35 , 36 , 37 , 38 , 39 ] and even scarcer examples are found for their bridged analogues, N ‐HTAs, whose presence in complexing and sensing processes is limited.…”

A Chiral Molecular Cage Comprising Diethynylallenes and N‐Heterotriangulenes for Enantioselective Recognition

“…Easwaramoorthi et al designed and synthesized three probes 58–60 based on triphenylamine and rhodanine-3-acetic acid for the dual detection of Ag + and Hg 2+ in buffer-free aqueous solutions. 92 All the three chemosensors showed distinct colour changes for Ag + and Hg 2+ by the naked eye. Probe 58 in solution showed a change in color from yellow to purple or colorless in the presence of Ag + and Hg 2+ , respectively.…”

Triphenylamine-based small-molecule fluorescent probes

“…Indeed, only a few probes are soluble in purely aqueous solutions. [16][17][18][19][20][21][22][23] Another issue when developing a Ag + -responsive probe for biological application is the selectivity with respect to Cu + . The similarity in coordination properties of these two cations may cause a similar response for both.…”

Bioinspired Luminescent Europium-Based Probe Capable of Discrimination between Ag⁺ and Cu⁺