A Starburst-Shaped Heterometallic Compound Incorporating Six Densely Packed Gd3+ Ions

The heterotritopic ligand [bpy(DTTA)2]8- has two diethylenediamine-tetraacetate units for selective lanthanide(III) coordination and one bipyridine function for selective FeII coordination. In aqueous solution and in the presence of these metals, the ligand is capable of self-assembly to form a rigid supramolecular metallostar structure, {Fe[Gd2bpy(DTTA)2(H2O)4]3}4-. We report here the physicochemical characterization of the dinuclear complex [Gd2bpy(DTTA)2(H2O)4]2- and the metallostar {Fe[Gd2bpy(DTTA)2(H2O)4]3}4- with regard to potential MRI contrast agent applications. A combination of pH potentiometry and 1H NMR spectroscopy has been used to determine protonation constants for the ligand [bpy(DTTA)2]8- and for the complexes [Fe{bpy(DTTA)2}3]2- and [Y2bpy(DTTA)2]2-. In addition, stability constants have been measured for the dinuclear chelates [M2bpy(DTTA)2]n- formed with M = Gd3+ and Zn2+ (log KGdL = 18.2; log KZnL = 18.0; log KZnHL = 3.4). A multiple field, variable-temperature 17O NMR and proton relaxivity study on [Gd2bpy(DTTA)2(H2O)4]2- and {Fe[Gd2bpy(DTTA)2(H2O)4]3}4- yielded the parameters for water exchange and the rotational dynamics. The 17O chemical shifts are indicative of bishydration of the lanthanide ion. The exchange rates of the two inner-sphere water molecules are very similar in the dinuclear [Gd2bpy(DTTA)2(H2O)4]2- and in the metallostar (kex298 = 8.1+/-0.3 x 10^6 and 7.4+/-0.2 x 10^6 s-1, respectively), and are comparable to kex298 for similar GdIII poly(amino carboxylates). The rotational dynamics of the metallostar has been described by means of the Lipari-Szabo approach, which involves separating global and local motions. The difference between the local and global rotational correlation times, lO298 = 190�15 ps and gO298 = 930+/-50 ps, respectively, shows that the metallostar is not completely rigid. However, the relatively high value of S2 = 0.60+/-0.04, describing the restriction of the local motions with regard to the global one, points to a limited flexibility compared with previously reported macromolecules such as dendrimers. As a result of the two inner-sphere water molecules, with their near-optimal exchange rate, and the limited flexibility, the metallostar has a remarkable molar proton relaxivity, particularly at high magnetic fields (r1 = 33.2 and 16.4 mM-1 s-1 at 60 and 200 MHz, respectively, at 25 �C). It packs six efficiently relaxing GdIII ions into a small molecular space, which leads, to the best of our knowledge, to the highest relaxivity per molecular mass ever reported for a GdIII complex. The [bpy(DTTA)2]8- ligand is also a prime candidate as a terminal ligand for constructing larger sized, FeII (or RuII)-based metallostars or metallodendrimers loaded with GdIII on the surface.

6-Phosphoryl Picolinic Acids as Europium and Terbium Sensitizers

Julien Alexandre Andres, Anne-Sophie Chauvin

Three 6-phosphoryl picolinic acid (6PPA) derivatives were synthesized and used as europium and terbium sensitizers. Two of the three ligands (6-diethoxyphosphoryl picolinic acid (Hdeppa) and 6-monoethoxyphosphoryl picofinic acid (H(2)meppa)) are water-soluble, once complexed to lanthanide ions, while the third (6-dihydroxyphosphoryl picolinic acid (H(3)dhppa)) forms a precipitate. The stability constants of the phosphoryl-based complexes were found to be higher than the carboxylate analogue (dipicolinic acid, H(2)dpa). The main species are the [LnL(3)] complexes under strict stoichiometric conditions, confirmed by P-31 NMR spectroscopy, mass spectrometry and lifetime analyses. The photophysical measurements reveal that the emission intensity of [Eu(deppa)(3)] is maximal at pH 4.8, whereas for Eu(meppa)(3), the optimum pH is observed at 9.0. The lifetimes are all in the millisecond range and have confirmed the absence of water molecules in the first coordination sphere. The emissions of the terbium are always brighter than the corresponding europium within this phosphoryl series. The quantum yields of the phosphoryl containing complexes are lower than the carboxylate analogue (Ln(dpa)(3)), except for [Tb(deppa)(3)], which exhibits an interesting quantum yield of 40% in aqueous solution.

2011

Multifrequency EPR studies of zero field splitting of Gd(III) based MRI contrast agents in solids and liquids

Magnetic Resonance Imaging (MRI) offers an amazing number of ways to probe the human body. It is a wonderful symbiosis of engineering, science and medicine. The power of MRI is its ability to probe a variety of physical mechanisms that can then not only reveal delicate anatomical structures but also discover important information about the physiology of tissue function in normal and diseased states. Paramagnetic metal ions, as a result of their unpaired electrons, act as potent MRI contrast agents. They decrease the T1 and T2 relaxation times of nearby water protons. The mechanism of T1 relaxation is generally a through space dipole-dipole interaction. This interaction is between the unpaired electrons of a paramagnetic ion, such as Gd(III) and the water molecules that are in fast exchange within the ion's inner-coordination sphere. The lanthanide ion Gd(III) is by far the most frequently chosen metal centre in MRI contrast agent, because it has a very high magnetic moment (S = 7/2) and a symmetric electronic ground state, 8S7/2. As it is generally highly toxic, acyclic and macrocyclic polyaminocarboxylates ligands have been synthesized forming thermodynamically and kinetically stable complexes with Gd(III). The coupling of the seven unpaired electrons of the Gd(III) ion with the surrounding water proton spins observed in MRI is crucial for the contrast agent effectiveness, expressed as relaxivity. Therefore, understanding the behavior of the electron spin system can provide valuable information for the development of new compounds. Since this ion has S >1, its spin Hamiltonian includes a significant Zero Field Splitting (ZFS) contribution. This work was devoted to the determination by Electron Paramagnetic Resonance (EPR) spectroscopy of parameters governing the strength of ZFS of Gd(III)-based MRI contrast agents in aqueous solution, frozen solution, and powders. The analysis of multiple frequency and temperature EPR data has been conducted on selected commercial and potential MRI contrast agents. The studied complexes have been designed in the aim to optimise other important parameters which influence the relaxivity, like the rotational diffusion of the complexes and the water residence time in the first coordination shell. This work provides a survey of electron spin relaxation through the determination of the ZFS parameters for Gd(III)-based contrast agents (1) in solution where a rigorous derivation of the relaxation rates was applied to the analysis of the full EPR line shape at multiple frequencies, and (2) in glasses and powders where a direct and straightforward determination of ZFS parameters allowed, for the first time, to establish a correlation between the sign of the axial ZFS parameter and the nature of the chelating ligand in Gd(III) complexes.

EPFL2006

Multifrequency EPR studies of zero field splitting of Gd(III) based MRI contrast agents in solids and liquids

EPFL2006