Chen Joseph, Chao Darrian, Tran Uyen Phuong, Billingsley Kelvin L
Department of Chemistry and Biochemistry, Loyola University Chicago, Chicago, IL 60660, USA.
Department of Chemistry and Biochemistry, California State University Fullerton, Fullerton, CA 92831, USA.
Synthesis (Stuttg). 2024 Sep;56(18):2909-2917. doi: 10.1055/a-2335-8736. Epub 2024 Jun 12.
Hyperpolarized C magnetic resonance spectroscopy can provide unique insights into metabolic activity . Despite the advantages of this technology, certain metabolic pathways such as the tricarboxylic acid (TCA) cycle are more challenging to examine due to the limitations associated with currently available hyperpolarized C probes. In this report, we systematically employ computational analyses, synthetic techniques, and studies to facilitate the design of new chemical probes for the TCA cycle. This platform allows for the rapid identification of probe scaffolds that are amenable to hyperpolarized C experimentation. Using these results, we have developed two C-labeled chemical probes, [1,4-C]-dipropyl succinate and [1,4-C]-diallyl succinate, which are employed in hyperpolarized C metabolic studies.
超极化碳磁共振波谱能够为代谢活性提供独特的见解。尽管这项技术具有诸多优势,但由于现有超极化碳探针存在局限性,某些代谢途径,如三羧酸(TCA)循环,更具研究挑战性。在本报告中,我们系统地运用计算分析、合成技术及研究,以推动用于TCA循环的新型化学探针的设计。该平台能够快速识别适用于超极化碳实验的探针支架。利用这些结果,我们开发了两种碳标记的化学探针,[1,4-C]-二丙基琥珀酸酯和[1,4-C]-二烯丙基琥珀酸酯,并将其用于超极化碳代谢研究。