Faculty of Chemistry, Institute of Biological Chemistry, University Vienna, Währinger Str. 38, 1090 Vienna, Austria.
Athinoula A. Martinos Center for Biomedical Imaging, Department of Radiology, Massachusetts General Hospital, Charlestown, Massachusetts 02129, United States.
J Phys Chem B. 2022 Jun 23;126(24):4599-4610. doi: 10.1021/acs.jpcb.2c03375. Epub 2022 Jun 8.
Dissolution dynamic nuclear polarization (DDNP) is a versatile tool to boost signal amplitudes in solution-state nuclear magnetic resonance (NMR) spectroscopy. For DDNP, nuclei are spin-hyperpolarized "" in a dedicated DNP device and then transferred to an NMR spectrometer for detection. Dramatic signal enhancements can be achieved, enabling shorter acquisition times, real-time monitoring of fast reactions, and reduced sample concentrations. Here, we show how the sample transfer in DDNP experiments can affect NMR spectra through cross-correlated cross-relaxation (CCR), especially in the case of low-field passages. Such processes can selectively invert signals of C spins in proton-carrying moieties. For their investigations, we use schemes for simultaneous or "parallel" detection of hyperpolarized H and C nuclei. We find that H → C CCR can invert signals of C spins if the proton polarization is close to 100%. We deduce that low-field passage in a DDNP experiment, a common occurrence due to the introduction of so-called "ultra-shielded" magnets, accelerates these effects due to field-dependent paramagnetic relaxation enhancements that can influence CCR. The reported effects are demonstrated for various molecules, laboratory layouts, and DDNP systems. As coupled C-H spin systems are ubiquitous, we expect similar effects to be observed in various DDNP experiments. This might be exploited for selective spectroscopic labeling of hydrocarbons.
溶解动态核极化(DDNP)是一种在溶液核磁共振(NMR)光谱中增强信号幅度的多功能工具。在 DDNP 中,核自旋在专用的 DNP 设备中被“超极化”,然后转移到 NMR 光谱仪中进行检测。通过 DDNP 可以实现显著的信号增强,从而缩短采集时间、实时监测快速反应以及降低样品浓度。在这里,我们展示了样品转移在 DDNP 实验中如何通过交叉相关交叉弛豫(CCR)影响 NMR 光谱,特别是在低场通过的情况下。这些过程可以选择性地反转质子携带部分中 C 核的信号。对于它们的研究,我们使用同时或“平行”检测超极化 H 和 C 核的方案。我们发现,如果质子极化接近 100%,则 H→C CCR 可以反转 C 核的信号。我们推断,由于引入了所谓的“超屏蔽”磁铁,在 DDNP 实验中经常发生的低场通过会由于磁场依赖性顺磁弛豫增强而加速这些效应,这些效应会影响 CCR。我们报告了各种分子、实验室布局和 DDNP 系统的实验结果。由于耦合的 C-H 自旋系统无处不在,我们预计在各种 DDNP 实验中都会观察到类似的效应。这可能被用于烃类的选择性光谱标记。
