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Hyper-CEST NMR of metal organic polyhedral cages reveals hidden diastereomers with diverse guest exchange kinetics

Jabadurai Jayapaul, Sanna Komulainen, Владимир В. Живонитко, Jiří Mareš, Chandan Giri, Kari Rissanen, Perttu Lantto, Ville‐Veikko Telkki, Leif Schröder

2022Nature Communications36 citationsDOIOpen Access PDF

Abstract

Abstract Guest capture and release are important properties of self-assembling nanostructures. Over time, a significant fraction of guests might engage in short-lived states with different symmetry and stereoselectivity and transit frequently between multiple environments, thereby escaping common spectroscopy techniques. Here, we investigate the cavity of an iron-based metal organic polyhedron (Fe-MOP) using spin-hyperpolarized 129 Xe Chemical Exchange Saturation Transfer (hyper-CEST) NMR. We report strong signals unknown from previous studies that persist under different perturbations. On-the-fly delivery of hyperpolarized gas yields CEST signatures that reflect different Xe exchange kinetics from multiple environments. Dilute pools with ~ 10 4 -fold lower spin numbers than reported for directly detected hyperpolarized nuclei are readily detected due to efficient guest turnover. The system is further probed by instantaneous and medium timescale perturbations. Computational modeling indicates that these signals originate likely from Xe bound to three Fe-MOP diastereomers ( T , C 3 , S 4 ). The symmetry thus induces steric effects with aperture size changes that tunes selective spin manipulation as it is employed in CEST MRI agents and, potentially, impacts other processes occurring on the millisecond time scale.

Topics & Concepts

DiastereomerChemistryKineticsMagnetization transferSteric effectsNuclear magnetic resonance spectroscopyChemical physicsSaturation (graph theory)MetalNuclear magnetic resonancePhysicsStereochemistryMagnetic resonance imagingMedicineRadiologyQuantum mechanicsMathematicsOrganic chemistryCombinatoricsAdvanced NMR Techniques and ApplicationsAtomic and Subatomic Physics ResearchMagnetism in coordination complexes