Lanthanide‐Based T2ex and CEST Complexes Provide Insights into the Design of pH Sensitive MRI Agents

The CEST and T₁ /T₂ relaxation properties of a series of Eu³⁺ and Dy³⁺ DOTA‐tetraamide complexes with four appended primary amine groups are measured as a function of pH. The CEST signals in the Eu³⁺ complexes show a strong CEST signal after the pH was reduced from 8 to 5. The opposite trend was observed for the Dy³⁺ complexes where the r_2ex of bulk water protons increased dramatically from ca. 1.5 mm ⁻¹ s⁻¹ to 13 mm ⁻¹ s⁻¹ between pH 5 and 9 while r₁ remained unchanged. A fit of the CEST data (Eu³⁺ complexes) to Bloch theory and the T_2ex data (Dy³⁺ complexes) to Swift–Connick theory provided the proton‐exchange rates as a function of pH. These data showed that the four amine groups contribute significantly to proton‐catalyzed exchange of the Ln³⁺‐bound water protons even though their pK _a’s are much higher than the observed CEST or T_2ex effects. This demonstrated the utility of using appended acidic/basic groups to catalyze prototropic exchange for imaging tissue pH by MRI.     

Intermolecular C?H Bond Activation by a Cationic Iridium(III) Dichloride Phenanthroline Complex

It is demonstrated that a cationic iridium(III) dichloride phenanthroline complex is capable of C H activation and H/D exchange. It can cleave benzylic and unactivated secondary C H bonds, but exhibits unique selectivity when compared to similar systems that have been studied in the condensed phase. Gas‐phase rate constants and kinetic isotope effects are reported for a variety of substrates and the analysis is supported by DFT calculations at the M06/QZVP level.     

Cross‐Peaks in Simple Two‐Dimensional NMR Experiments from Chemical Exchange of Transverse Magnetisation

Two‐dimensional correlation measurements such as COSY, NOESY, HMQC, and HSQC experiments are central to small‐molecule and biomolecular NMR spectroscopy, and commonly form the basis of more complex experiments designed to study chemical exchange occurring during additional mixing periods. However, exchange occurring during chemical shift evolution periods can also influence the appearance of such spectra. While this is often exploited through one‐dimensional lineshape analysis (“dynamic NMR”), the analysis of exchange across multiple chemical shift evolution periods has received less attention. Here we report that chemical exchange‐induced cross‐peaks can arise in even the simplest two‐dimensional NMR experiments. These cross‐peaks can have highly distorted phases that contain rich information about the underlying exchange process. The quantitative analysis of such peaks, from a single 2D spectrum, can provide a highly accurate characterisation of underlying exchange processes.