Highly Efficient Determination of Complex NMR Multiplet Structures in Inhomogeneous Magnetic Fields.
Haolin ZhanYu-Qing HuangXinchang WangTien-Mo ShihZhong ChenPublished in: Analytical chemistry (2021)
Proton-proton scalar (J) coupling plays an important role in disentangling molecular structures and spatial conformations. But it is challenging to extract J coupling networks from congested 1H NMR spectra, especially in inhomogeneous magnetic fields. Herein, we propose a general liquid NMR protocol, named HR-G-SERF, to implement highly efficient determination of individual J couplings and corresponding coupling networks via simultaneously suppressing effects of spectral congestions and magnetic field inhomogeneity. This method records full-resolved 2D absorption-mode spectra to deliver great convenience for multipet analyses on complex samples. More meaningfully, it is capable of disentangling multiplet structures of biological samples, that is, grape sarcocarp, despite of its heterogeneous semisolid state and extensive compositions. In addition, a modification, named AH-G-SERF, is developed to compress experimental acquisition and subsequently improve unit-time SNR, while maintaining satisfactory spectral performance. This accelerated variant may further boost the applicability for rapid NMR detections and afford the possibility of adopting hyperpolarized substances to enhance the overall sensitivity. Therefore, this study provides a promising tool for molecular structure elucidations and composition analyses in chemistry, biochemistry, and metabonomics among others.
Keyphrases
- highly efficient
- high resolution
- magnetic resonance
- molecularly imprinted
- solid state
- optical coherence tomography
- room temperature
- solid phase extraction
- electron transfer
- mass spectrometry
- randomized controlled trial
- density functional theory
- signaling pathway
- single molecule
- dual energy
- contrast enhanced
- molecular dynamics
- drug discovery