Coordinatively Unsaturated Lanthanide(III) Helicates: Luminescence Sensors for Adenosine Monophosphate in Aqueous Media

Sahoo, Jashobanta; Arunachalam, Rajendran; Subramanian, P.; Suresh, Eringathodi; Valkonen, Arto; Rissanen, Kari; Albrecht, Markus

doi:10.1002/anie.201604093

Cited by 88 publications

(62 citation statements)

References 66 publications

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“…In general the affinity order, determined by the charge of the phosphate moiety, is usually found to be ATP>ADP>AMP, and a different order of selectivity between these species remains a challenge. With this in mind, Albrecht [29] has studied a coordinatively unsaturated double--stranded helical dinuclear europium complex [Eu.12] that causes a significant 64--fold increase of luminescence intensity upon binding AMP molecules with selectivity over ATP and ADP, as well as other biologically relevant ions. Two strands of bis(tridentate) diamide ligands encapsulate two Eu 3+ ions, whose coordination spheres are saturated with water molecules and nitrate ions.…”

Section: Sensing Of Biologically Relevant Anionsmentioning

confidence: 99%

Responsive, Water‐Soluble Europium(III) Luminescent Probes

Shuvaev

Starck

Parker

2017

Chemistry A European J

110

103

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Use policyThe full-text may be used and/or reproduced, and given to third parties in any format or medium, without prior permission or charge, for personal research or study, educational, or not-for-prot purposes provided that:• a full bibliographic reference is made to the original source • a link is made to the metadata record in DRO • the full-text is not changed in any way The full-text must not be sold in any format or medium without the formal permission of the copyright holders.Please consult the full DRO policy for further details. E-mail: david.parker@dur.ac.uk; sergey.shuvaev@dur.ac.uk Abstract: The design principles, mechanism of action and performance of europium(III) complexes that serve as strongly emissive and responsive molecular probes in water are critically discussed. Examples of systems designed to assess pH, selected metal ions and anions, including chiral species, as well as selected small molecules and biopolymers are considered, and prospects evaluated for improved performance in more complex biological media such as in bio--fluids and within living cells. Modulation of the emission spectral form, lifetime and degree of circular polarisation can be used to quantify the spectral response and permit calibration. IntroductionThe genesis of lanthanide bio--imaging probes can be traced to two discoveries: the observation of the red emission of europium by Crookes in 1885 and the report of its sensitised emission made by Weissman in 1942 [1] . Each discovery epitomises the advantageous optical features of lanthanide complexes - narrow bands in emission with energies only slightly affected by the nature of the ligand, and a large separation (a "pseudo--Stokes' shift") between the absorbing (ligand--antenna) and emitting (lanthanide ion) photon energies. These favourable optical properties create a myriad of opportunities to devise responsive systems by judicious ligand design. Europium(III) complexes have particular advantages over other lanthanide complexes in biologically relevant applications: the higher transparency of biological tissue towards the red region of the visible spectrum; their high inherent brightness and low sensitivity to quenching by oxygen; the presence of three excited states ( 5 D2, 5 D1 and 5 D0) spanning the range 17500--21000 cm --1 that are lower in energy than the triplet levels of many different types of ligands; the presence of an environmentally insensitive magnetic--dipole transition 5 D0 to 7 F1 in the luminescence spectrum, (Figure 1), that can be used as an internal reference to the hypersensitive transition bands around 620 ( 5 D0 --7 F2) and 700 nm ( 5 D0 to 7 F4), and the high emission anisotropy factors, gem, in circularly polarised luminescence (CPL) spectra.

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Section: Sensing Of Biologically Relevant Anionsmentioning

confidence: 99%

Responsive, Water‐Soluble Europium(III) Luminescent Probes

Shuvaev

Starck

Parker

2017

Chemistry A European J

110

103

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“…2b, the emission peaks at 579, 593, 614, 651, and 698 nm correspond to the 5 D 0 / 7 F J (J ¼ 0-4) transitions of the Eu 3+ cations. 35 Notably, the emission spectrum of 2 is mainly dominated by the 5 D 0 / 7 F 2 transition, which is more intense than others, leading to intense red luminescence. 36 The bright colors also demonstrate that HL 7À acts as an excellent "antenna" linker in the effectively transfer energies to Tb 3+ and Eu 3+ metals.…”

Section: Luminescent Propertiesmentioning

confidence: 98%

Three resorcin[4]arene-based lanthanide-coordination polymers with multifunctional photoluminescence sensing properties

et al. 2019

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“…[3] Am ore recent example of al uminescent probe capable of monitoring the ADP/ATP ratio on the basis of small molecules was reported by Butler and co-workers,who used ae uropium complex with a1 ,4,7,10-tetraazacyclododecane-1,7-diacetic acid (DO2A)-based ligand bearing two quinolone-derived chromophores to stabilise nucleotide molecules through hydrogen bonding. [5,6] Different strategies to modulate selectivity and binding affinities have been employed, including steric complementarity, [7] variation of the overall charge, [8] and introduction of stabilising and orienting weak interactions,such as hydrogen bonding, [9] p-p stacking, [10] or boroncarbohydrate interactions. [5,6] Different strategies to modulate selectivity and binding affinities have been employed, including steric complementarity, [7] variation of the overall charge, [8] and introduction of stabilising and orienting weak interactions,such as hydrogen bonding, [9] p-p stacking, [10] or boroncarbohydrate interactions.…”

mentioning

confidence: 99%

“…[4] Europium complexes have been used extensively for selective anion binding,o ften generating ar atiometric response in emission. [5,6] Different strategies to modulate selectivity and binding affinities have been employed, including steric complementarity, [7] variation of the overall charge, [8] and introduction of stabilising and orienting weak interactions,such as hydrogen bonding, [9] p-p stacking, [10] or boroncarbohydrate interactions. [11] Furthermore,t he high rotatory strength [12] of certain magnetic-dipole allowed transitions in Eu 3+ complexes can give rise to as trong circularly polarised luminescence (CPL) signal, with adissymmetry factor (g em )of up to 1.4.…”

mentioning

confidence: 99%

Monitoring of the ADP/ATP Ratio by Induced Circularly Polarised Europium Luminescence

2018

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As eries of three europium complexes bearing picolyl amine moieties was found to possess differing binding affinities towards Zn 2+ and three nucleotides:AMP,ADP,and ATP. Al arge increase in the total emission intensity was observed upon binding Zn 2+ ,followed by signal amplification upon the addition of nucleotides.T he resulting adducts possessed strong induced circularly polarised emission, with ADP and ATPsignals of opposite sign. Model DFT geometries of the adducts suggest the D diastereoisomer is preferred for ATPa nd the L isomer for ADP/AMP.T his change in sign allows the ADP/ATP (or AMP/ATP) ratio to be assessed by monitoring changes in the emission dissymmetry factor,g em .Supportinginformation and the ORCID identification number(s) for the author(s) of this article can be found under: https://doi.

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Coordinatively Unsaturated Lanthanide(III) Helicates: Luminescence Sensors for Adenosine Monophosphate in Aqueous Media

Cited by 88 publications

References 66 publications

Responsive, Water‐Soluble Europium(III) Luminescent Probes

Responsive, Water‐Soluble Europium(III) Luminescent Probes

Three resorcin[4]arene-based lanthanide-coordination polymers with multifunctional photoluminescence sensing properties

Monitoring of the ADP/ATP Ratio by Induced Circularly Polarised Europium Luminescence

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