重氮甲烷作为潜在的分子成像标签:探究高效和长寿命 SABRE 诱导的极化所需的条件。
Diazirines as Potential Molecular Imaging Tags: Probing the Requirements for Efficient and Long-Lived SABRE-Induced Hyperpolarization.
机构信息
Department of Chemistry, Duke University, French Family Science Center, 124 Science Drive, Durham, NC, 27708, USA.
Department of Physics, Duke University, USA.
出版信息
Angew Chem Int Ed Engl. 2017 Sep 25;56(40):12112-12116. doi: 10.1002/anie.201704970. Epub 2017 Jul 24.
Abstract
Diazirines are an attractive class of potential molecular tags for magnetic resonance imaging owing to their biocompatibility and ease of incorporation into a large variety of molecules. As recently reported, N -diazirine can be hyperpolarized by the SABRE-SHEATH method, sustaining both singlet and magnetization states, thus offering a path to long-lived polarization storage. Herein, we show the generality of this approach by illustrating that the diazirine tag alone is sufficient for achieving excellent signal enhancements with long-lasting polarization. Our investigations reveal the critical role of Lewis basic additives, including water, on achieving SABRE-promoted hyperpolarization. The application of this strategy to a N -diazirine-containing choline derivative demonstrates the potential of N -diazirines as molecular imaging tags for biomedical applications.
摘要
叠氮化合物因其生物相容性和易于与各种分子结合而成为磁共振成像中一种有吸引力的潜在分子标记物。最近有报道称,N-叠氮化物可以通过 SABRE-SHEATH 方法进行超极化,维持单重态和磁化状态,从而为长时间的极化存储提供了途径。在此,我们通过证明叠氮化物标签本身足以实现具有持久极化的优异信号增强,展示了这种方法的通用性。我们的研究揭示了路易斯碱添加剂(包括水)在实现 SABRE 促进的超极化方面的关键作用。该策略在含 N-叠氮化物的胆碱衍生物中的应用证明了 N-叠氮化物作为生物医学应用的分子成像标记物的潜力。
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