Efficient polarization redistribution in hyperpolarized 1-D-propane produced via pairwise parahydrogen addition

IF 2.624
Nuwandi M. Ariyasingha , Shiraz Nantogma , Anna Samoilenko , Oleg G. Salnikov , Nikita V. Chukanov , Larisa M. Kovtunova , Igor V. Koptyug , Eduard Y. Chekmenev
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引用次数: 0

Abstract

Parahydrogen-Induced Polarization (PHIP) is NMR hyperpolarization technique that has matured from fundamental science to a biomedical tool for production of hyperpolarized MRI contrast agents. The spin order of nascent parahydrogen-derived protons can be employed directly for enhancement of their NMR signals or for polarization transfer to other nuclei in the hydrogenation product. In this work, we study the process of pairwise parahydrogen addition to propylene, which results in symmetric propane molecule with substantially enhanced methyl and methylene NMR signals. Specifically, we have synthesized site-selectively isotopically labeled 3-d-propylene molecule to study polarization dynamics in the resulting monodeuterated propane after pairwise parahydrogen addition. The deuterium presence in the hyperpolarized propane product results in a minute isotope chemical shift effect allowing to distinguish the proton resonances of CH3 and CH2D groups at 600 MHz. Pairwise parahydrogen 1,2-addition to 3-d-propylene was first confirmed by performing the reaction inside a 600 MHz NMR spectrometer, i.e., in the weakly-coupled regime at 14 T, where proton polarization dynamics is restricted to the molecular sites of parahydrogen addition. However, when the pairwise parahydrogen addition is performed in the strongly-coupled regime, i.e., at the Earth's magnetic field, efficient polarization transfer to CH2D protons is readily observed, leading to polarization redistribution between the three inequivalent sites. This finding is important as it sheds light on polarization dynamics in the strongly coupled symmetric spin systems such as propane studied here—the presented results are expected to be applicable to other spin systems such as butane.

Abstract Image

通过对氢加成制备的超极化一维丙烷的高效极化重分布
对氢诱导极化(PHIP)是核磁共振超极化技术,已经从基础科学发展成为生产超极化MRI造影剂的生物医学工具。新生的对氢衍生质子的自旋顺序可以直接用于增强其核磁共振信号或用于极化转移到氢化产物中的其他原子核。在这项工作中,我们研究了丙烯的成对对氢加成过程,该过程导致丙烷分子对称,甲基和亚甲基核磁共振信号显著增强。具体来说,我们合成了位置选择性同位素标记的三维丙烯分子,以研究成对对氢加成后所得一氘化丙烷的极化动力学。氘在超极化丙烷产物中的存在导致了微小的同位素化学位移效应,使得在600 MHz时可以区分CH3和CH2D基团的质子共振。在600 MHz核磁共振波谱仪内进行反应,即在14t弱耦合状态下,质子极化动力学仅限于对氢加成的分子位点,首次证实了对氢1,2加成到3-丙烯的反应。然而,当在强耦合条件下,即在地球磁场下进行成对对氢加成时,很容易观察到CH2D质子的有效极化转移,导致三个不相等位点之间的极化重新分布。这一发现很重要,因为它揭示了强耦合对称自旋系统(如丙烷)的极化动力学,所提出的结果有望适用于其他自旋系统(如丁烷)。
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CiteScore
1.90
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