Lanthanide(III) complexes of amide derivatives of DOTA exhibit an unusual variation in stability across the lanthanide series

Luminescence excitation spectroscopy of the ⁷F₀→⁵D₀ transition of the Eu(III) complex of 1,4,7,10-tetrakis(carbamoylmethyl)-1,4,7,10-tetraazacyclododecane (TCMC, an amide derivative of DOTA) is used to measure the stability constant of the complex (K). A log K value of 10.6 is obtained for [Eu(TCMC)]³⁺ at 25 °C and an ionic strength of 0.1 M. Competition experiments with eleven other members of the lanthanide(III) series give stability constants for their complexes with TCMC. An unusual variation in stability is observed for complexes of [Ln(TCMC)]³⁺ across the lanthanide series with a pronounced optimum for the Sm(III) complex. This variation is quite different from that observed for other Ln(III) macrocyclic complexes, suggesting that the TCMC ligand is uniquely sensitive to Ln(III) ion radius.     

Lanthanide chelate complexes of salicyloyl hydrazide-salicylaldehyde schiff base (SHSASB) and anthranilic acid-salicylaldehyde schiff base (AASASB)

New lanthanide complexes of salicylaldehyde- Schiff bases with salicyloyl hydrazide and anthranilic acid, were synthesized by a novel method consisting of refluxing the mixtures of Schiff base ligands and lanthanide trichloroacetate in acetone. Solid complexes of formulae Ln(SHSASB)₃·2H₂O and Ln₂(AASASB)₃·2H₂O where Ln = La---Yb and Y, were isolated. Pronto NMR and IR spectra for the complexes reveal the bidentate binding of both the Schiff base ligands to the lanthanide ion. Electronic spectra along with the conductance data for the complexes indicate a coordination number of six for the lanthanide ion in the complexes of both the Schiff bases.     

Molecular movements inside [1+1] asymmetric compartmental macrocycles: Formation of positional mononuclear and hetero-dinuclear lanthanide(III) isomers and related homo-dinuclear complexes

The mononuclear macrocyclic lanthanide(III) complexes, [Ln(H₂L)(H₂O)₄]Cl₃ (Ln = Y, La, Ce, Cu, Tb, Yb, Lu; H₂L = H₂L_A, H₂L_B, H₂L_C) were prepared by condensation 3,3′-(3,6-dioxaoctane-1,8-diyldioxy)bis(2-hydroxybenzaldehyde) or 3,3′-(3-oxapentane-1,5-diyldioxy)bis(2-hydroxybenzaldehyde) with 1,5-diamino-3-azamethylpentane or 1,7-diamino-3-azamethylheptane in the presence of LnCl₃ · nH₂O as templating agent. The asymmetric [1+1] ligands H₂L_A, H₂L_B and H₂L_C contain one smaller or larger N₃O₂ Schiff base site and one crown-ether like O₂O₄ or O₂O₃ site. The preference of the lanthanide ion to reside into the Schiff base or the crown-ether like chamber was investigated in the solid state and in methanol or dimethylsulfoxide solution. It was found that in the solid state or in methanol the lanthanide(III) ion coordinates into the O₂O_n site while in dimethylsulfoxide demetalation and partial metal ion migration from the O₂O_n into the N₃O₂ chamber occur. The mononuclear lanthanide(III) complexes [Ln(H₂L)(H₂O)₄]Cl₃ with the Ln³⁺ ion in the O₂O_n site have been used as ligands in the synthesis of the heterodinuclear complexes LnLn′(L)(Cl)₄ · 4H₂O by reaction with the appropriate Ln′(III) chloride in methanol and in the presence of base. The related homodinuclear complexes Ln₂(L)(Cl)₄ · 4H₂O have been prepared by the one-pot condensation of the appropriate precursors in the presence of base and of the lanthanide(III) ion as templating agent.The single-crystal X-ray structure of [Eu(H₂L_A)(H₂O)₄]Cl₃ · 5H₂O has been determined. The europium ion is nine-coordinated in the O₂O₃ ligand site and bonded to four water molecules and the coordination polyhedron can be described as a square monocapped antiprism.The site occupancy of the different lanthanide(III) ions and the physico-chemical properties arising from the different dinuclear aggregation and/or from the variation of the crown-ether shape have been investigated by IR and NMR spectroscopy, MS spectrometry and SEM-EDS microscopy. In particular, site migration and/or transmetalation reactions, together with demetalation reactions, have been monitored by NMR studies in methanol and dimethylsulfoxide. It was found that these processes strongly depend on the shape of the two coordination chambers, the solvent used and the radius of the lanthanide(III) ions. Thus, these molecular movements can be tuned by changing appropriately these parameters.     

Phosphodiesterolytic activity of samarium(III) mixed ligand complexes containing crown ethers and α-amino acids

Phosphodiesterolytic activity of samarium complexes containing crown ethers and amino acids was systematically studied. Formation constants of mixed ligand Sm–crown ethers–amino acids complexes (crown ethers = 18-crown-6, 15-crown-5 and 12-crown-4 and amino acids = Gly and Arg) were determined at 37.0 °C and 0.50 M NMe₄Cl. Kinetics of the hydrolysis of BNPP (bis(4-nitrophenyl)phosphate) mediated by lanthanide(III)-mixed ligands complexes was studied under the same experimental conditions. The rate of BNPP cleavage is sensitive to metal ion concentration, pH, and ligand to metal molar ratio. Hydrolysis follows Michaelis–Menten-type saturation kinetics. High pH values markedly increase the observed activity. Potentiometric titrations results together with kinetic data of all these systems, under identical conditions, allowed us to identify the active species towards hydrolysis. Complexes with phosphodiesterolytic activity are monomeric hydroxylated cationic species. In general, a good phosphodiesterolytic activity is observed for these complexes under similar conditions to the physiological ones.     

Lanthanide ion catalysis of the trans-cis isomerization of trans-bis(oxalato)-diaquochromate(III) and trans-bis(malonato)diaquochromate(III) [1]

The lanthanide ion catalyzed trans-cis isomerizations of trans-bis(oxalato)diaquochromate(II) and trans-bis(malonato)diaquochromate(III) have been studied. A linear free energy relationship was found correlating the catalytic rate constants for the oxalate reaction with the corresponding formation constants of complexes formed between simple monocarboxylic acids and the light (LaGd) members of the lanthanide series. The results indicates that for this portion of the series, the reaction mechanism is related to the formation of monocarboxylate complex intermediates. When the ionic radius of the lanthanide ion decreases below a particular value (as in the latter half of the series), the metal ion remains coordinated to both carboxylates of the oxalate ion rather than simply binding to only one carboxylate. In either situation, isomerization to the cis product eventually occurs, and the lanthanide ion is released.The reaction rates associated with the trans-bis(malonato)diaquochromate(III) reaction were found to be significantly slower than those of the corresponding oxalate system. However, in the malonate system, no linear free energy relationship was found relating the catalytic rate constants with the corresponding formation constants of monocarboxylic acids. One does find a linear relationship between the catalytic rate constants for the malonate reaction and the log K₁ values for the corresponding lanthanide/malonate complexes. During the course of the trans-cis isomerization, the lanthanide ion chelates the dissociated malonate group of a pentavalent Cr(III) intermediate. In the mechanism the lanthanide ion does not aid in ring opening, and neither does it singly bond to the intermediate     

αvβ3-Integrin-targeting lanthanide complex: synthesis and evaluation as a tumor-homing luminescent probe

The application of lanthanide complexes in the time-resolved fluorescence imaging of living cells has emerged in the last few decades, providing high-contrast images of cells through detection of the delayed emission. In the present study, we synthesized novel trivalent lanthanide complexes containing the cyclic peptide c(RGDfK) to visualize the α_vβ₃-integrin-expressing tumor cells. Conjugation of c(RGDfK) with the macrocyclic bipyridine ligand had little effect on the fluorescence properties of the complex, indicating that the coordinated lanthanide ion was well isolated from the peptide. Bright luminescence images of α_vβ₃-integrin-expressing U87-MG cells were successfully obtained by employing the probes.     

Interactions between metal ions and carbohydrates. Syntheses and spectroscopic studies of several lanthanide nitrate–d-galactitol complexes

Two complexes of neutral d-galactitol (C₆H₁₄O₆, G) with terbium nitrate, TbGN(I) and TbGN(II), and one complex with samarium nitrate SmGN were synthesized and characterized. From IR, FIR, THz and luminescence spectra the possible coordinations were suggested, and the single-crystal X-ray diffraction results confirm the spectroscopic conclusions. In TbGN(I) (Tb(NO₃)₃·C₆H₁₄O₆·3H₂O), the Tb³⁺ is 9-coordinated with three water molecules and six OH groups from two d-galactitol molecules. Nitrate ions do not coordinate to metal ions, which is different from other reported lanthanide nitrate–d-galactitol complexes. In TbGN(II) and SmGN (Ln(NO₃)₃·C₆H₁₄O₆), Ln³⁺ is 10-coordinated with six OH groups from two d-galactitol molecules and four oxygen from two bidentate nitrate ions, and one nitrate ion is hydrogen bonded. No water exists in the structures. d-Galactitol molecules provide their 1-, 2- and 3-hydroxyl groups to coordinate with one metal ion and their 4-, 5- and 6-hydroxyl groups to coordinate with another metal ion in the three structures. There is still a new topological structure that can be observed for lanthanide–d-galactitol complexes, which indicates that the coordinations between hydroxyl groups and metal ions are complicated.     

Cd(II) and Cu(II) complexes of polydentate Schiff base ligands: synthesis, characterization, properties and biological activity

We report the synthesis of the Schiff base ligands, 4-[(4-bromo-phenylimino)-methyl]-benzene-1,2,3-triol (A₁), 4-[(3,5-di-tert-butyl-4-hydroxy-phenylimino)-methyl]-benzene-1,2,3-triol (A₂), 3-(p-tolylimino-methyl)-benzene-1,2-diol (A₃), 3-[(4-bromo-phenylimino)-methyl]-benzene-1,2-diol (A₄), and 4-[(3,5-di-tert-butyl-4-hydroxy-phenylimino)-methyl]-benzene-1,3-diol (A₅), and their Cd(II) and Cu(II) metal complexes, stability constants and potentiometric studies. The structure of the ligands and their complexes was investigated using elemental analysis, FT-IR, UV-Vis, ¹H and ¹³C NMR, mass spectra, magnetic susceptibility and conductance measurements. In the complexes, all the ligands behave as bidentate ligands, the oxygen in the ortho position and azomethine nitrogen atoms of the ligands coordinate to the metal ions. The keto-enol tautomeric forms of the Schiff base ligands A₁-A₅ have been investigated in polar and non-polar organic solvents. Antimicrobial activity of the ligands and metal complexes were tested using the disc diffusion method and the strains Bacillus megaterium and Candida tropicalis.Protonation constants of the triol and diol Schiff bases and stability constants of their Cu²⁺ and Cd²⁺ complexes were determined by potentiometric titration method in 50% DMSO-water media at 25.00 ± 0.02 °C under nitrogen atmosphere and ionic strength of 0.1 M sodium perchlorate. It has been observed that all the Schiff base ligands titrated here have two protonation constants. The variation of protonation constant of these compounds was interpreted on the basis of structural effects associated with the substituents. The divalent metal ions of Cu²⁺ and Cd²⁺ form stable 1:2 complexes with Schiff bases.The Schiff base complexes of cadmium inhibit the intense chemiluminescence reaction in dimethylsulfoxide (DMSO) solution between luminol and dioxygen in the presence of a strong base. This effect is significantly correlated with the stability constants K_CdL of the complexes and the protonation constants K_OH of the ligands; it also has a nonsignificant association with antibacterial activity.     

Phosphodiesterolytic activity of lanthanide (III) complexes with α-amino acids

Kinetics of the hydrolysis of BNPP (bis(4-nitrophenyl)phosphate) mediated by lanthanide - samarium (III) and ytterbium (III) - alone and in the presence of various alfa amino acids has been systematically studied at 37.0 °C and I = 0.15 M in NaClO₄, in the pH interval of 7-9. The rate of BNPP cleavage is sensitive to metal ion concentration, pH, and ligand to metal molar ratio. Hydrolysis follows Michaelis-Menten-type saturation kinetics. For both metals, high pH values markedly increase the observed activity. Besides, potentiometric titrations of all these systems under identical conditions allowed us to identify the active coordination compounds towards hydrolysis. The results show that complexes with phosphodiesterolytic activity are monomeric cationic species such as [Ln(aa)₃(OH)]²⁺ or [Ln(aa)₂(OH)₂]⁺. Since phosphodiesterolytic activity is evident above pH 7 and it is increased with increasing pH, hydrolytic reactions of the metals are competitive processes that could lead to their precipitation as Ln(OH)₃(s). In this sense, ligand excess (for example, ligand to metal molar ratio equal to 30) was employed. Furthermore, due to its more extended hydrolysis, ytterbium shows, in general, less activity than samarium under the studied conditions. In general, a good phosphodiesterolytic activity is observed for these complexes under similar conditions to the physiological ones. Amino acids could be easily derivatized without changing their coordinating ability, leading to lanthanide complexes possibly capable of efficiently hydrolyzing the phosphodiester linkages of nucleic acids.     

Complexes of aluminium with peptide ligands: A fourier transform IR spectroscopic study

Aluminium has been recognized to be a neurotoxic agent and a risk factor in Alzheimer's disease and other neuronal dysfunctions. CD spectroscopic studies on two synthetic fragments of the human neurofilament protein midsized subunit (NF-M), and their alanine-for-serine-substituled and /or serine-phosphorylated derivatives showed the formation of stable, citric acid resistant complexes of Al³⁺with peptide ligands [M. Hollósi, Z.M. Shen, A. Perczel, and G.D. Fasman (1994) Proc. Natl. Acad. Sci. USA, vol. 9 , pp.4902-4906]. In the case of Ser-phosphorylated fragments, aβ-sheet inducing effect of Ca²⁺ and Al³⁺ ions was observed. However, the serine-containing parent peptides, NF-M 13 (KSPVPKSPVEEKG) and NF-M 17 (EEKGKSPVPKSPVEEKG), failed to show CD spectral changes reflecting β-sheet formation upon addition of Al³⁺ ions. On the basis of the amide I region of the Fourier transform ir spectra, in triftuoroethanol, the peptide backbone of NF-M17 and NF-M17 (A⁶A¹¹) shows marked changes in the presence ofAl³⁺. The most significant spectral differences are seen in the car-boxyl region (> 1700 cm^?l). The high-frequency component bands above 1760 cm^?1 in both spectra belong to the C? O of undissociated CF₃COOH. Another strong band at 1710 cm^?1 which appears only in the spectrum of NF-Ml 7 (A⁶A¹¹)(NF-M17 with Ser⁶ andSer¹¹ replaced by Ala) can be assigned to the side chain or C-terminal COOH groups. The differential proton-ation state of the carboxyl groups in the two peptides suggests the format ion ofAl³⁺ complexes of different structure and stability. The Al³⁺ complex ofNF-Ml 7 (A⁶A¹¹) is likely less stable, or one or more of the carboxylates are not coordinated to the Al³⁺ and thus can serve as a base to bind the liberated protons. In NF-M17 the OH groups of serines facilitate the formation of type [Al-pep(H_-1)] complexes with the involvement of all carboxylategroups in the molecule. The relevance of intramolecular and intermolecular Al³⁺ binding to the controversial biological role of aluminium is also discussed. © 1995 John Wiley & Sons, Inc.     

Lanthanide complex coordination polyhedron geometry prediction accuracies of ab initio effective core potential calculations

The ability to efficiently and accurately predict solid-state geometries of lanthanide coordination compounds efficiently and accurately is central for the design of new ligands capable of forming stable and highly luminescent complexes. Accordingly, we present in this paper a report on the capability of various ab initio effective core potential calculations in reproducing the coordination polyhedron geometries of lanthanide complexes. Starting with all combinations of HF, B3LYP and MP2(Full) with STO-3G, 3-21G, 6-31G, 6-31G* and 6-31+G basis sets for [Eu(H₂O)₉]³⁺ and closing with more manageable calculations for the larger complexes, we computed the fully predicted ab initio geometries for a total of 80 calculations on 52 complexes of Sm(III), Eu(III), Gd(III), Tb(III), Dy(III), Ho(III), Er(III) and Tm(III), the largest containing 164 atoms. Our results indicate that RHF/STO-3G/ECP appears to be the most efficient model chemistry in terms of coordination polyhedron crystallographic geometry predictions from isolated lanthanide complex ion calculations. Moreover, both augmenting the basis set and/or including electron correlation generally enlarged the deviations and aggravated the quality of the predicted coordination polyhedron crystallographic geometry. Our results further indicate that Cosentino et al.’s suggestion of using RHF/3-21G/ECP geometries appears to be indeed a more robust, but not necessarily, more accurate recommendation to be adopted for the general lanthanide complex case. Figure Graphical visualization of unsigned mean errors, UME(Eu-L)s, involving only the interatomic distances between the europium central ion and the oxygen atoms of the coordination polyhedron of the cation nona-aqua-europium(III) for various model chemistries, all compared to the “Cambridge Structural Database 2004” crystallographic geometry     

The complexation between holothurian triterpene glycosides and Chl as the basis for lipid-saponin carriers of subunit protein antigens

The ability of holothurian triterpene glycosides (cucumarioside A₂-2 from Cucumaria japonica, cucumarioside G₁ from C. fraudatrix, frondoside A from C. frondosa, and holotoxin A₁ from Apostichopus japonicus) to form supramolecular lipid-saponin complexes was studied. TEM demonstrated that all the studied compounds form supramolecular cholesterol-saponin complexes (nanoparticles) in aqueous medium. The complexes formed by cucumarioside A₂-2, holotoxin A₁, and frondoside A had a tubular structure and fundamentally differed in the structure from the particles produced by cucumarioside G₁. The morphology of the nanoparticles formed by cucumarioside A₂-2, holotoxin A₁, and cucumarioside G₁ changed depending on the fraction of cholesterol in the lipid-saponin system; however, this pattern was not observed for frondoside A. At the same molar fraction of cholesterol in the lipid-saponin system, cucumarioside A₂-2 formed the particles with the most pronounced tubular structure; the cholesterol-saponin complexes of holotoxin A₁ had a less pronounced tubular structure, whereas the structure of frondoside A particles was extremely heterogeneous. Comparative analysis of the morphology of the described supramolecular complexes and specific structural features of the glycosides demonstrated that the structure of the corresponding nanoparticles depended on the degree of branching of the carbohydrate moiety in the glycoside molecule and the complexation with cholesterol was determined by the specific features of aglycone structure. Thus, the feasibility of producing new generation antigen carriers using the complexes in question was proved.     

Chiroptical Spectra of Tetrakis (+)‐3‐Heptafluorobutylrylcamphorate Ln(III) Complexes with an Encapsulated Alkali Metal Ion: Solution Structures as Revealed by Chiroptical Spectra

The preparation of tetrakis((+)‐hfbc) lanthanide(III) complexes with an encapsulated alkali metal and ammonium ions M[Ln((+)‐hfbc)₄] (hereafter abbreviated as M‐Ln : (+)‐hfbc, (+)‐heptafluorobutyrylcamphorate; M, ammonium or benzyl ammonium ions as well as alkali metal ions) was reported and discussed. The electronic circular dichroism (CD) spectra in the intraligand π?π* transition of M–Ln were examined in view of the solvent effect. Here, the concentration, alkali metal, and ammonium ion dependences are compared with the solid CD, ⁵D₀ ← ⁷F₀(Eu(III)) excitation spectra, circularly polarized luminescence, and vibrational circular dichroism. It has been revealed that the dodecahedral eight coordinate DD‐8‐M‐Ln complexes in crystals are equilibrated between the diastereoselectively formed square antiprism eight coordinate SAPR‐8‐M‐Ln and [Ln((+)‐hfbc)₃] in EtOH and CH₃CN solutions or between the SAPR‐8‐M‐Ln and DD‐D_2d(mmmm)‐8‐M‐Ln complexes in CHCl₃ solution. The observed CD couplets are found to reflect the exciton CD couplets which are useful to determine the four‐bladed SAPR‐(llll) absolute configuration around the lanthanide(III) ion. Chirality 24:1055–1062, 2012. © 2012 Wiley Periodicals, Inc.     

DFT modeling on the suitable crown ether architecture for complexation with Cs<Superscript>+</Superscript> and Sr<Superscript>2+</Superscript> metal ions

Crown ether architectures were explored for the inclusion of Cs⁺ and Sr²⁺ ions within nano-cavity of macrocyclic crown ethers using density functional theory (DFT) modeling. The modeling was undertaken to gain insight into the mechanism of the complexation of Cs⁺ and Sr²⁺ ion with this ligand experimentally. The selectivity of Cs⁺ and Sr²⁺ ions for a particular size of crown ether has been explained based on the fitting and binding interaction of the guest ions in the narrow cavity of crown ethers. Although, Di-Benzo-18-Crown-6 (DB18C6) and Di-Benzo-21-Crown-7 (DB21C7) provide suitable host architecture for Sr²⁺ and Cs⁺ ions respectively as the ion size match with the cavity of the host, but consideration of binding interaction along with the cavity matching both DB18C6 and DB21C7 prefers Sr²⁺ ion. The calculated values of binding enthalpy of Cs metal ion with the crown ethers were found to be in good agreement with the experimental results. The gas phase binding enthalpy for Sr²⁺ ion with crown ether was higher than Cs metal ion. The ion exchange reaction between Sr and Cs always favors the selection of Sr metal ion both in the gas and in micro-solvated systems. The gas phase selectivity remains unchanged in micro-solvated phase. We have demonstrated the effect of micro-solvation on the binding interaction between the metal ions (Cs⁺ and Sr²⁺) and the macrocyclic crown ethers by considering micro-solvated metal ions up to eight water molecules directly attached to the metal ion and also by considering two water molecules attached to metal-ion-crown ether complexes. A metal ion exchange reaction involving the replacement of strontium ion in metal ion-crown ether complexes with cesium ion contained within a metal ion-water cluster serves as the basis for modeling binding preferences in solution. The calculated O-H stretching frequency of H₂O molecule in micro-solvated metal ion-crown complexes is more red-shifted in comparison to hydrated metal ions. The calculated IR spectra can be compared with an experimental spectrum to determine the presence of micro-solvated metal ion–crown ether complexes in extractant phase.     

New complexes of La(III), Ce(III), Pr(III), Nd(III), Sm(III), Eu(III) and Gd(III) ions with morin

New solid complex compounds of La(III), Ce(III), Pr(III), Nd(III), Sm(III), Eu(III) and Gd(III) ions with morin were synthesized. The molecular formula of the complexes is Ln(C₁₅H₉O₇)₃ · nH₂O, where Ln is the cation of lanthanide and n = 6 for La(III), Sm(III), Gd(III) or n = 8 for Ce(III), Pr(III), Nd(III) and Eu(III). Thermogravimetric studies and the values of dehydration enthalpy indicate that water occurring in the compounds is not present in the inner coordination sphere of the complex. The structure of the complexes was determined on the basis of UV-visible, IR, MS, ¹H NMR and ¹³C NMR analyses. It was found that in binding the lanthanide ions the following groups of morin take part: 3OH and 4CO in the case of complexes of La, Pr, Nd, Sm and Eu, or 5OH and 4CO in the case of complexes of Ce and Gd. The complexes are five- and six-membered chelate compounds.     

Thermodynamic and kinetic parameters of an oligonucleotide hairpin helix

The thermodynamics of the hairpin helix-single strand transition of A₆C₆U₆ has been analyzed by a staggering zipper model with consideration of single strand stacking. This analysis yields an enthalpy change of +11 kcal/mole for the formation of a first, isolated base pair. The stability constant of a first (intramolecular) base pair in A₆C₆U₆ is around 2 × 1O^?5 at 25°C, whereas a first (intermoleciilar) base pair in an A₆ · U₆ helix is characterised by a stability constant of about 4 × 10^?3M^?1 (25°C, extrapolated from A_n · V_n oligomer measurements). These data indicate a destabilizing effect of the C₆ loop.The rate constant of hairpin helix formation is 2 to 3 × 10⁴ sec^?1 associated with an activation enthalpy of +2.5 kcal/mote. The rate of helix dissociation of the A₆C₆U₆ hairpin is in the range of 10³ to lO⁵ sec^?1 with an activation enthalpy of 21 $\text{kcal}\text{mole}$. A comparison with the kinetic parameters obtained for A · U oligomer helices shows a specific influence of the C₆ loop due to the stacking tendency of the cytosine residues. This intluence is preferentially reflected in the relatively low value of the rate constant of helix formation.     

Coordination compounds of divalent lanthanides with crown ethers

New complexes LnI₂·18-crown-6 (Ln-Sm, Tm, Dy, Nd) and LnJ₂·dibenzo-18-crown-6 (Ln-Sm, Tm) were synthesized using the solutions of LnI₂ in THF. The compounds obtained oxidize quickly in air, but are relatively stable in an inert atmosphere. The Tm²⁺ complex is decomposed by light. The compounds obtained are poorly soluble in THF, the Sm²⁺ and Tm²⁺ compounds are soluble in CH₃CN, forming solutions with a period of half oxidation of 170 h and 6 min, respectively. Iodide ions of the complexes can be substituted for Cl^? during treatment of the compounds by solution of LiCl in THF. The reflection spectra of the compounds synthesized are similar to the absorption spectra of Ln²⁺ in THF, although a shift of bands towards the short wave region is observed.The study of the Ln²⁺ oxidation kinetics in H₂O, CH₃CN, THF in the presence of crown ethers has shown that their stability is influenced not only by the type of solvent, relative solubility and stability of complexes Ln²⁺ and Ln³⁺, but also by phenyl groups, and by decreasing stability of Dy²⁺ and Nd²⁺.     

Magnetic and luminescence characteristics of dinuclear complexes of lanthanides and a phenolic schiff base macrocyclic ligand

The magnetic and luminescence characteristics of trimorphic homodinuclear macrocyclic complexes of lanthanides and a 2:2 phenolate Schiff's base L, derived from 2,6-diformyl-p-cresol and triethylenetetramine were determined. The complexes of Pr³⁺ exhibit non-Curie-Weiss temperature dependent magnetic susceptibilities for which satisfactory fits to an axial relationship depends on crystal field splitting and a weak binuclear Pr³⁺Pr³⁺ antiferromagnetic interaction. The exchange interaction parameters are zJ′ = −2.2, −4.4 and −7.0 cm ⁻¹ for ‘off-white’ Pr₂L(NO₃)₄·2H₂O, ‘yellow’ Pr₂L(NO₃)₄, and ‘orange’ Pr₂L(NO₃)₂(OH)₂, respectively. In contrast, magnetic susceptibilities of the Ln₂L(NO₃)₃(OH) complexes (Ln = Dy, Ho) follow Curie-Weiss behavior over the entire temperature range (6 K to 300 K). The complexes of closed shell ions La³⁺, Lu³⁺, Y³⁺ and those of the half filled shell ion Gd³⁺ exhibit a strong ligand fluorescence in the 450 nm to 650 nm range with decay times at 77 K of 5–8 ns for Ln≠Gd or 2–4 ns for Ln = Gd. The complexes of Gd³⁺ also exhibit a phosphorescence at 600 nm (decay time ∼ 200 μs). The complexes containing Ce³⁺, Eu³⁺, Tb³⁺ and Er³⁺ show very weak ligand luminescence indicative of effective quenching processes. Sensitized emission from the lanthanide ion is observed only with the Eu³⁺ complexes (⁵D_o → ⁷F_j transitions). The emission lifetimes are on the order of 250 μs in the pure Eu³⁺ complexes. The emission decay curves from dilute samples of Eu³⁺ in ‘off-white’ La₂L(NO₃)_4nH₂O show a noticeable rise time as well as a biphasic decay (fast component ∼ 400 μs; slow component ∼ 2500 μs). The luminescing states of L and Eu³⁺ have a common excitation spectrum which is similar to the electronic absorption spectrum of L indicating that ligand-to-metal ion energy transfer processes are dominant. Overall the result if this study suggest that the spectral properties of the complexes are determined by the coordination mode of the lanthanide ions to the Schiff base portion of macrocyclic ligand.     

The action of lipases on chloroplast membranes. III. The effect of lipid hydrolysis on chlorophyll-protein complexes in thylakoid membranes

Bean thylakoid membranes treated with various lipolytic enzymes (bean galactolipase, phospholipases A₂, C, D) showed marked changes in their acyl lipid composition. As a consequence of acyl lipids hydrolysis, destruction of some chlorophyll a-protein complexes (CP1a, CP1, CPa) or monomerization of the oligomeric of light harvesting chlorophyll a/b protein complex (LHCP) was observed. It is concluded that galactolipids and phosphatidylcholine are responsible for the stability of CP1a, CP1 and CPa, respectively. Phosphatidylglycerol and to some extent monogalactosyldiacylglycerol are essential for the stabilization of oligomeric structures of light harvesting chlorophyll a/b protein complex.Abbreviations chl chlorophyll - CP1a, CP1 chl a-protein complexes, of PSI - CPa chl a-protein complex of PSII - DGDG diagalactosyldiacylglycerol - FC free chl - GL galactolipase - LHCP^1–3 light harvesting chl a/b protein complex - MGDG monogalactosyldiacylglycerol - PAGE polyacrylamide gel electrophoresis - PC phosphatidylcholine - PG phosphatidylglycerol - PLA₂ phospholipase A₂ - PL phospholipase C - PLD phospholipase D - PSI photosystem I - PSII photosystem II - SDS sodium dodecyl sulphate - SQDG sulfoquinovosyl-diacylglycerol - TCA trichloroacetic acid - Tricine N-tris-(hydroxymethyl)-methylglycine - Tris Tris-(hydroxymethyl)-aminomethan     

Comparison of crystal field dependent and independent methods to analyse lanthanide induced NMR shifts in axially symmetric complexes. Part I. Systems with a C3 symmetry axis

A critical analysis of the lanthanide induced paramagnetic shift (LIS) data for several series of Ln³⁺ complexes of C₃ symmetry in terms of structural changes, crystal-field effects and/or variation of hyperfine constants along the lanthanide series was undertaken using a combination of the two-nuclei and three-nuclei techniques together with the classical one-nucleus technique. The crystal-field independent two-nuclei technique to study the isostructurality of a series of lanthanide complexes, is usefully complemented by the three nuclei shift ratio method, which is based exclusively on the experimental shift data, requiring no knowledge of B₀², 〈S_z〉 or C_j values. However, this later method cannot provide quantitative values for F_i and G_i. The combined use of the three methods was found to be a powerful analytical tool of the solution structure of lanthanide complexes. Isostructurality of whole series of complexes, either with no change of the F_i, G_i and B₀² parameters (L⁵ and L⁶), or with changes of the F_i and B₀² parameters (L⁷ and L⁸), is clearly defined by the combination of the two first methods. In these cases, the three-nuclei method sometimes fully supports such an isostructurality (L⁶, L⁸), but in other cases, due to the high structural sensitivity of its α and β parameters, it is able to detect small, unnoticed, structural changes in the complexes of L⁵ and L⁷. Clear structural changes, involving the F_i, G_i and B₀² parameters, are observed for the series of complexes of (L⁹), where the three methods agree, involving hydration and carboxylate coordination changes. More subtle structural changes, involving the internal dynamics of the bound ligands, are proposed in other cases (L¹-L⁴). These could also result from a magnification, by the present graphical analysis, of the breaks expected from the gradual structural changes along the series due to the lanthanide contraction.