Copper(II) 15-metallacrown-5 lanthanide(III) complexes derived from l-serine and l-threonine hydroxamic acids

Pacco, Antoine; Absillis, Gregory; Binnemans, Koen; Parac‐Vogt, Tatjana N.

doi:10.1016/j.jallcom.2007.04.053

Cited by 11 publications

(5 citation statements)

References 22 publications

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“…The ternary systems Eu 3+ or Gd 3+ /Cu 2+ /α-Alaha were initially studied by in-cell potentiometric titration, but a marked drift in the emf values was observed; thus, batch titrations were performed (see the Experimental Section). This inertness in the Ln 3+ 15-MC-5 formation in water was also recently put into evidence by Pacco and co-workers for ( S )-serine- and ( S )-threoninehydroxamic acids: their spectrophotometric study showed that the formation equilibrium was reached only 30 min after reactant mixing, although we have measured a drift in the emf readings within 12 h . In the present investigation, the titrations were limited to pH 6.5 because at higher pH the formation of an insoluble purple gelatinous material was observed.…”

Section: Resultssupporting

confidence: 80%

Thermodynamics of Self-Assembly of Copper(II) 15-Metallacrown-5 of Eu(III) or Gd(III) with (S)-α-Alaninehydroxamic Acid in Aqueous Solution

et al. 2010

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The equilibria of self-assembly of 15-metallacrown-5 (15-MC-5) complexes of Cu(2+) and (S)-alpha-alaninehydroxamic acid (alpha-Alaha, HL) with the lanthanide (Ln) ions Eu(3+) or Gd(3+) in aqueous solution are described. The binary Ln(3+)/alpha-Alaha systems were first studied by potentiometric and calorimetric in-cell titrations; the latter technique allowed us to define the most suitable speciation model. On the contrary, because the kinetics of formation of the Ln(3+) 15-MC-5 complexes is slow, their stability constants were determined by out-of-cell (batch) potentiometric titrations. Two 15-MC-5 complexes are formed with both Eu(3+) and Gd(3+), namely, {Ln[Cu(5)L(5)H(-5)]}(3+) and {Ln[Cu(5)L(5)H(-5)](OH)}(2+), with the latter being the hydroxo species of the former. The acidity of the former to give the hydroxo species is remarkably high (log K = 4.40-4.69). Moreover, our potentiometric and spectrophotometric investigations clearly indicate that the hydroxide ion is coordinated to the central Ln ion, as was reported for several 15-MC-5 in the solid state. The formation of {Ln[Cu(5)L(5)H(-5)]}(3+) starts at ca. pH 3.5, which converts at ca. pH 4.5 into the {Ln[Cu(5)L(5)H(-5)](OH)}(2+) species, which predominates up to pH 7, where a purple precipitate occurs. The coexistence of both 15-MC-5 species and the copper(II) 12-MC-4 species of alpha-Alaha ([Cu(5)L(4)H(-4)](2+)) was observed under appropriate experimental conditions (pH and ligand and metal concentrations). A complete ESI-MS investigation of the Ln(3+)/Cu(2+)/alpha-Alaha system at different pH's confirmed the formation of the two 15-MC-5 species. The 15-MC-5 stability constants were employed to quantitatively evaluate the solution behavior of Ln(III) MCs regarding their integrity, ligand substitution, and transmetalation processes. In particular, EDTA or DOTA, added in equimolar amounts, should not appreciably interfere with the MC integrity, as found in previous experimental investigations, although it is expected that at higher amounts of EDTA, the MC should be disrupted. Our results also demonstrate that an excess of alpha-aminohydroxamate does not interfere with the integrity of the MC, and the disappearance of the CD spectra upon addition of the R enantiomer to 15-MC-5 containing the S enantiomer is due to a very rapid ligand exchange with formation of all possible isomers with no selectivity. The stability of the 15-MC-5 complexes in the presence of transferrin, serum albumin, or an excess of Zn(2+) is also discussed. With regards to the latter metal ion, we found that the MCs are stable toward Gd(3+)/Zn(2+) transmetalation. although the presence of a phosphate buffer promotes the disruption of the MC scaffold by formation of stable Gd(3+)/phosphate species.

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Section: Resultssupporting

confidence: 80%

Thermodynamics of Self-Assembly of Copper(II) 15-Metallacrown-5 of Eu(III) or Gd(III) with (S)-α-Alaninehydroxamic Acid in Aqueous Solution

et al. 2010

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“…Nowadays, the popularity of water‐soluble polynuclear metallamacrocyclic Cu(II)‐Ln(III) complexes is largely due to their rich coordination chemistry, diverse properties and ease of synthesis . The remarkable feature of Cu(II)‐Ln(III) 15‐MC‐5 complexes is the deep color . It should be pointed out that the observed ligand‐field bands in visible region near 550 nm have provided the potential ability to obtain useful diagnostic information concerning the structures of transition metal ion‐peptide complexes .…”

Section: Introductionmentioning

confidence: 99%

pH‐Responsive Switching Properties of a Water‐Soluble Metallamacrocyclic Phenylalaninehydroximate La(III)–Cu(II) Complex: Insight into Tuning Protonation Ligand States

et al. 2019

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The water-soluble copper(II)-lanthanum(III) complex based on phenylalaninehydroximate ligands La(H 2 O) 4 -[15-MC CuPhalaha -5](Cl) 3 (1) has been synthesized and characterized structurally and spectroscopically. The X-ray structure of 1 demonstrated that the ring copper ions are placed in distorted square pyramidal geometries with various axial coordination ligands. UV/Vis absorption spectra reveal halochromic behavior of 1 in the aqueous solution which represents reversible color changes from blue to colorless in response to pH variations. This effect has been described as pH-induced "on-off-on" switch through protonation and deprotonation of the phenylalanine-[a] G. A. Razuvaev

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“…The structural information gleaned from the pseudo-contact shifts can confirm or refute if the solid-state structure is retained in solution or if a series of molecules made with the same ligand set but different lanthanide ions are isostructural in solution. − Almost all studies that have investigated a series of lanthanide complexes rely on complexes that contain one Ln III ion with a diamagnetic, organic ligand. Thus, little is known regarding the 1 H NMR behavior, and, in particular, the pseudo-contact shift properties of Ln III ions in the presence of paramagnetic 3 d transition metals. − Metallacrowns (MC) are a class of molecules that offer a window into such investigations, which may result in unpredicted properties.…”

Section: Introductionmentioning

confidence: 99%

Elucidation of¹H NMR Paramagnetic Features of Heterotrimetallic Lanthanide(III)/Manganese(III) 12-MC-4 Complexes

et al. 2017

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The paramagnetic one-dimensional H NMR spectra of twelve LnNa(OAc)[12-MC-4] complexes, where Ln is Pr-Yb (except Pm) and Y, are reported. Their solid-state isostructural nature is confirmed in methanol-d solution, as a similar pattern in the H NMR spectra is observed along the series. Notably, a relatively well-resolved spectrum is reported for the Gd complex. The chemical shift data are analyzed using the "all lanthanides" method, and the Fermi contact and pseudo-contact contributions are calculated for the lanthanide-induced shift (LIS). For the Tb-Yb complexes, the pseudo-contact contributions are typically 1 order of magnitude higher than the Fermi contact contributions; however, for the Gd complex, the Fermi contact is the main contribution to the paramagnetic chemical shift. For the methyl protons of the axial acetate (OAc) ligands, the LIS is opposite in sign, with respect to that of the aromatic salicylhydroximate (shi) protons, because of structural rearrangements that occur upon dissociation of the Na cation in solution. The calculated crystal field parameters (B) for the Tb (360 cm), Dy (250 cm), Ho (380 cm), Er (410 cm), Tm (620 cm), and Yb (380 cm) complexes are not constant, likely as a consequence of the inaccuracy of the Bleaney's constants and, to a smaller extent, the small structural changes that occur in solution. Overall, the metallacrown scaffold retains structural integrity and similarity in solution for the entire series; however, small structural features, which do not affect the overall similarity, do likely occur.

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Copper(II) 15-metallacrown-5 lanthanide(III) complexes derived from l-serine and l-threonine hydroxamic acids

Cited by 11 publications

References 22 publications

Thermodynamics of Self-Assembly of Copper(II) 15-Metallacrown-5 of Eu(III) or Gd(III) with (S)-α-Alaninehydroxamic Acid in Aqueous Solution

Thermodynamics of Self-Assembly of Copper(II) 15-Metallacrown-5 of Eu(III) or Gd(III) with (S)-α-Alaninehydroxamic Acid in Aqueous Solution

pH‐Responsive Switching Properties of a Water‐Soluble Metallamacrocyclic Phenylalaninehydroximate La(III)–Cu(II) Complex: Insight into Tuning Protonation Ligand States

Elucidation of¹H NMR Paramagnetic Features of Heterotrimetallic Lanthanide(III)/Manganese(III) 12-MC-4 Complexes

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Copper(II) 15-metallacrown-5 lanthanide(III) complexes derived from l-serine and l-threonine hydroxamic acids

Cited by 11 publications

References 22 publications

Thermodynamics of Self-Assembly of Copper(II) 15-Metallacrown-5 of Eu(III) or Gd(III) with (S)-α-Alaninehydroxamic Acid in Aqueous Solution

Thermodynamics of Self-Assembly of Copper(II) 15-Metallacrown-5 of Eu(III) or Gd(III) with (S)-α-Alaninehydroxamic Acid in Aqueous Solution

pH‐Responsive Switching Properties of a Water‐Soluble Metallamacrocyclic Phenylalaninehydroximate La(III)–Cu(II) Complex: Insight into Tuning Protonation Ligand States

Elucidation of1H NMR Paramagnetic Features of Heterotrimetallic Lanthanide(III)/Manganese(III) 12-MC-4 Complexes

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Elucidation of¹H NMR Paramagnetic Features of Heterotrimetallic Lanthanide(III)/Manganese(III) 12-MC-4 Complexes