[Quantitative analysis of 16 components in Cyclocarya paliurus leaf by UPLC-QE-Orbitrap-MS].

Modern research showed that components in the dried leaf of Cyclocarya paliurus. had various biological activities. The current quality control research was focused on content determination of polysaccharides and flavonoids, while there were less research on quantitative analysis of terpenes and phenolic acids. In this paper, the contents of 16 components of 3 kinds in C. paliurus leaf were determined by UPLC-QE-Orbitrap-MS. The results were as following: good linear relationship of 16 analytes existed within the studied concentration rages (R²>0.996), and RSDs were of <3.0% in the precision test and replicate test, with the average recovery rates 95.20%-104.4%, respectively. The results indicatod that the method is simple and accurate, which can be used for the comprehensive quality evaluation of C. paliurus leaf. The established method was applied to determine the contents of 12 batches of C. paliurus leaf from different areas, and the 16 analvtes contents in the samples could be different from several times to dozens times, which indicated that there might be significant quality difference in C. paliurus leaf from different areas.

[Analysis of HPLC and NIRS fingerprints of Chrysanthemum indicum of different processing methods].

This paper studied the HPLC and NIRS fingerprints of Chrysanthemum with different processing methods, including directly drying, drying after steamed, and drying after fried. The method of discriminant analysis of TQ software was used to analysis the NIRS fingerprint of Chrysanthemum with three different processing methods, and the results were consistent with HPLC fingerprint similarity analysis. NIRS and HPLC fingerprints were of different characteristics, and the combination of the two methods can quickly and accurately identify Chrysanthemum with different processing methods.

Tristetraprolin, a Potential Safeguard Against Carcinoma: Role in the Tumor Microenvironment.

Tristetraprolin (TTP), a well-known RNA-binding protein, primarily affects the expression of inflammation-related proteins by binding to the targeted AU-rich element in the 3' untranslated region after transcription and subsequently mediates messenger RNA decay. Recent studies have focused on the role of TTP in tumors and their related microenvironments, most of which have referred to TTP as a potential tumor suppressor involved in regulating cell proliferation, apoptosis, and metastasis of various cancers, as well as tumor immunity, inflammation, and metabolism of the microenvironment. Elevated TTP expression levels could aid the diagnosis and treatment of different cancers, improving the prognosis of patients. The aim of this review is to describe the role of TTP as a potential safeguard against carcinoma.