Abstract
The thermodynamic, kinetic, and structural properties of Ln3+ complexes with the bifunctional DO3A-ACE4− ligand and its amide derivative DO3A-BACE4− (modelling the case where DO3A-ACE4− ligand binds to vector molecules) have been studied in order to confirm the usefulness of the corresponding Gd3+ complexes as relaxation labels of targeted MRI contrast agents. The stability constants of the Mg2+ and Ca2+ complexes of DO3A-ACE4− and DO3A-BACE4− complexes are lower than for DOTA4− and DO3A3−, while the Zn2+ and Cu2+ complexes have similar and higher stability than for DOTA4− and DO3A3− complexes. The stability constants of the Ln(DO3A-BACE)− complexes increase from Ce3+ to Gd3+ but remain practically constant for the late Ln3+ ions (represented by Yb3+). The stability constants of the Ln(DO3A-ACE)4− and Ln(DO3A-BACE)4− complexes are several orders of magnitude lower than those of the corresponding DOTA4− and DO3A3− complexes. The formation rate of Eu(DO3A-ACE)− is one order of magnitude slower than for Eu(DOTA)−, due to the presence of the protonated amine group, which destabilizes the protonated intermediate complex. This protonated group causes the Ln(DO3A-ACE)− complexes to dissociate several orders of magnitude faster than Ln(DOTA)− and its absence in the Ln(DO3A-BACE)− complexes results in inertness similar to Ln(DOTA)− (as judged by the rate constants of acid assisted dissociation). The 1H NMR spectra of the diamagnetic Y(DO3A-ACE)− and Y(DO3A-BACE)− reflect the slow dynamics at low temperatures of the intramolecular isomerization process between the SA pair of enantiomers, R-Λ(λλλλ) and S-Δ(δδδδ). The conformation of the Cα-substituted pendant arm is different in the two complexes, where the bulky substituent is further away from the macrocyclic ring in Y(DO3A-BACE)− than the amino group in Y(DO3A-ACE)− to minimize steric hindrance. The temperature dependence of the spectra reflects slower ring motions than pendant arms rearrangements in both complexes. Although losing some thermodynamic stability relative to Gd(DOTA)−, Gd(DO3A-BACE)− is still quite inert, indicating the usefulness of the bifunctional DO3A-ACE4− in the design of GBCAs and Ln3+-based tags for protein structural NMR analysis.
Highlights
The ultimate goal of modern diagnostic and molecular imaging techniques is the visualization of biological processes that occur at the cellular and molecular levels
In this work, we describe a detailed evaluation of the thermodynamic stability of the complexes of DO3A-N-(αaminopropionate) (DO3A-ACE4−, H4 DO3A-ACE = 1-(2-amino-carboxyethyl)-4,7,10-tris(caboxymethyl)-1,4,7,10-tetraazacyclododecane) and of its benzoylamide conjugate (DO3ABACE4−, H4 DO3A-BACE = 1-(2-benzylamido-carboxyethyl)-4,7,10-tris-(caboxymethyl)1,4,7,10-tetraazacyclodode cane) (Scheme 1) with essential metal ions (Mg2+, Ca2+, Cu2+, and Zn2+ ) and the lanthanide ions Ce3+, Gd3+, and Yb3+, as well as the formation kinetics of the Eu3+ complexes and the dissociation kinetics of the Ce3+ and Gd3+ complexes, using pH-potentiometry, 1 H relaxometry, and UV-Vis spectrophotometry
Ion characterized for several years in the search for the right bifunctional ligands (BFCs) capable of Ln3+ complexation [20,21,22,23,24]
Summary
The ultimate goal of modern diagnostic and molecular imaging techniques is the visualization of biological processes that occur at the cellular and molecular levels. The Gd3+ -based contrast agents (GBCAs) currently used in the clinics for T1 -weighed imaging are anionic or neutral Gd3+ chelates of linear (DTPA-type) or macrocyclic (DOTA-type) poly(aminocarboxylate) ligands. To ensure their safety, the GBCA complexes are endowed with high thermodynamic stability and kinetic inertness to prevent in vivo release of the highly toxic free metal ion. The recently recognized rare but severe medical condition known as nephrogenic systemic fibrosis (NSF) has been associated with the administration of GBCAs to patients with significant renal disease [4,5], leading to in vivo Gd3+ release which has been detected mostly as GdPO4 deposits by means of elemental bioimaging and speciation analysis [6].
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