Multiple pathways for lanthanide sensitization in self-assembled aqueous complexes
Metadata
Show full item recordAuthor
Navarro, Amparo; Ruiz-Arias, Alvaro; Fueyo-Gonzalez, Francisco; Izquierdo-Garcia, Carolina; Peña-Ruiz, Tomás; Gutierrez-Rodriguez, Marta; Herranz, Rosario; Cuerva, Juan M.; González-Vera, Juan A.; Orte Gutiérrez, ÁngelEditorial
Elsevier
Materia
Lanthanides Density functional calculations Luminescence
Date
2024-08-03Referencia bibliográfica
Navarro, A. et. al. 323 (2024 ) 124926. [https://doi.org/10.1016/j.saa.2024.124926]
Sponsorship
PID2020-114256RB-I00 and PID2022-137214OB-C22 funded by Agencia Estatal de Investigacion (Spain) AEI/10.13039/501100011033; P21_00212, A-FQM-386- UGR20 and 2021/00627/001-FEDER_UJA_2020 funded by FEDER/ Junta de Andalucía-Consejería de Universidad, Investigación e Innovación (Andalucía regional government, Spain); diaRNAgnosis project funded by the European Union’s Horizon 2020 research and innovation programme under the Marie Sklodowska-Curie grant agreement No 101007934, CSIC (Spain) grant 202180E073, and PAIDIFQM- 337, Universidad de Jaén (Spain); Universidad de Granada / CBUAAbstract
Lanthanide photoluminescence (PL) emission has attracted much attention for technological and bioimaging
applications because of its particularly interesting features, such as narrow emission bands and very long PL
lifetimes. However, this emission process necessitates a preceding step of energy transfer from suitable antennas.
While biocompatible applications require luminophores that are stable in aqueous media, most lanthanide-based
emitters are quenched by water molecules. Previously, we described a small luminophore, 8-methoxy-2-oxo-
1,2,4,5-tetrahydrocyclopenta[de]quinoline-3-phosphonic acid (PAnt), which is capable of dynamically coordinating
with Tb(III) and Eu(III), and its exchangeable behavior improved their performance in PL lifetime imaging
microscopy (PLIM) compared with conventional lanthanide cryptate imaging agents. Herein, we report an indepth
photophysical and time-dependent density functional theory (TD–DFT) computational study that reveals
different sensitization mechanisms for Eu(III) and Tb(III) in stable complexes formed in water. Understanding this unique behavior in aqueous media enables the exploration of different applications in bioimaging or novel
emitting materials.