Wu Qi, Chen Yuan, Wang Yan-Li, Song Ji-Ying, Lv Hai-Tao, Sun Ya-Ming
College of Chemistry and Pharmaceutical Sciences, Qingdao Agricultural University, Qingdao, 266109, China.
College of Chemistry and Pharmaceutical Sciences, Qingdao Agricultural University, Qingdao, 266109, China.
Anal Chim Acta. 2025 Jan 15;1334:343414. doi: 10.1016/j.aca.2024.343414. Epub 2024 Nov 13.
Chirality is an essential property of nature. Chiral recognition is of great significance to life sciences, pharmaceutical industry, food analysis, and so on. Chiral carbon dots (CCDs), as green nanomaterials, have great prospects in chiral sensing. However, CCDs with enantioselectivity for tryptophan (Trp) enantiomers are scarce. Moreover, most chiral sensing platforms depend on the difference of fluorescence intensity at the same emission wavelength to identify enantiomers, it is still a challenge to distinguish enantiomers by the positions of fluorescent emission peaks.
Novel CCDs with specific chiral recognition ability for Trp enantiomers are synthesized using l-lysine and l-cysteine as precursors. The CCDs have two fluorescent emission peaks at 390 nm and 450 nm. Interestingly, the fluorescence intensity of CCDs at 390 nm enhances obviously on the addition of L-Trp, while it enhances slightly at 450 nm in the presence of D-Trp. This chiral sensing system not only can identify Trp enantiomers according to fluorescence intensity, but also achieves the distinguishment depending on emission wavelength. The enantioselectivity (I/I) reaches 4.5 when the concentration of Trp enantiomer is 1 mM. This chiral sensing platform not only can be used for quantitative analysis of D-Trp and L-Trp, but also can be used for determining the enantiomeric excess of racemates. The chiral recognition mechanism is investigated by molecular simulation. It is found that L-Trp has higher binding energy with CCDs.
This work presents a novel kind of CCDs with special chiral recognition performance for Trp enantiomers, and opens the door to identify chiral isomers according to wavelength difference, which has profound significance for the development of chiral sensing platforms, and may provide inspirations for the design of novel CCDs with excellent chiral recognition performance.
手性是自然界的一种基本属性。手性识别在生命科学、制药工业、食品分析等领域具有重要意义。手性碳点(CCDs)作为绿色纳米材料,在手性传感方面具有广阔前景。然而,对色氨酸(Trp)对映体具有对映选择性的CCDs却很稀少。此外,大多数手性传感平台依赖于同一发射波长下荧光强度的差异来识别对映体,通过荧光发射峰的位置区分对映体仍然是一个挑战。
以L-赖氨酸和L-半胱氨酸为前驱体合成了对Trp对映体具有特定手性识别能力的新型CCDs。这些CCDs在390nm和450nm处有两个荧光发射峰。有趣的是,加入L-Trp时,CCDs在390nm处的荧光强度明显增强,而在D-Trp存在下,其在450nm处的荧光强度略有增强。这种手性传感系统不仅可以根据荧光强度识别Trp对映体,还能根据发射波长实现区分。当Trp对映体浓度为1mM时,对映选择性(I/I)达到4.5。这种手性传感平台不仅可用于D-Trp和L-Trp的定量分析,还可用于测定外消旋体的对映体过量。通过分子模拟研究了手性识别机制。发现L-Trp与CCDs具有更高的结合能。
这项工作展示了一种对Trp对映体具有特殊手性识别性能的新型CCDs,并为根据波长差异识别手性异构体打开了大门,这对手性传感平台的发展具有深远意义,可能为设计具有优异手性识别性能的新型CCDs提供启示。
