Identification of the metabolites of n-butylidenephthalide in rat and human liver microsomes by liquid chromatography-high-resolution mass spectrometry

Design, synthesis and bioactivity of a new class of antifungal amino acid-directed phthalide compounds

BACKGROUND

Peanut southern blight disease, caused by Sclerotium rolfsii, is a destructive soil-borne fungal disease. The current control measures, which mainly employ succinate dehydrogenase inhibitors, are prone to resistance and toxicity to non-target organisms. As a result, it is necessary to explore the potential of eco-friendly fungicides for this disease.

RESULTS

Fourteen novel phthalide compounds incorporating amino acid moieties were designed and synthesized. The in vitro activity of analog A1 [half maximal effective concentration (EC50 ) = 332.21 mg L-1 ] was slightly lower than that of polyoxin (EC50  = 284.32 mg L-1 ). It was observed that on the seventh day, the curative activity of A1 at a concentration of 600.00 mg L-1 was 57.75%, while the curative activity of polyoxin at a concentration of 300.00 mg L-1 was 42.55%. These results suggested that our compound exhibited in vivo activity. Peanut plants treated with A1 showed significant agronomic improvements compared to the untreated control. Several compounds in this series exhibited superior root absorption and conduction in comparison to the endothermic fungicide thifluzamide. The growth promotion and absorption-conduction experiments demonstrated the reason for the superior in vivo activity of the target compound. Cytotoxic assays have demonstrated that this series of targeted compounds exhibit low toxicity levels toward human lo2 liver cells.

CONCLUSION

Our results provide a new strategy for the design and synthesis of novel green compounds. Furthermore, the target compound A1 can serve as a lead for further development of green fungicides. © 2024 Society of Chemical Industry.

A high-resolution mass spectrometric method for identification and characterization of the in vitro metabolites of senkyunolide H

RATIONALE

Ligusticum chuanxiong Hort is a well-known herb medicine that has been widely prescribed to treat cardiovascular diseases in China for hundreds of years. Senkyunolide H (SNH) is one of the major bioactive ingredients extracted from L. chuanxiong, and it displayed neuroprotective effects. To fully understand its mechanism of action, the metabolism needs to be investigated.

METHODS

In vitro studies were conducted by incubating SNH with rat and human hepatocytes, and the metabolites were identified and characterized using liquid chromatography in combination with hybrid quadrupole Orbitrap mass spectrometry (LC-Orbitrap-MS). The structures of the metabolites were proposed by accurate mass analysis of respective precursor ions, indicative product ions, and elemental compositions.

RESULTS

Under the current conditions, a total of 10 metabolites were identified, and among these metabolites, M3 and M4 were the most abundant metabolites both in rat and human hepatocytes. Our results demonstrated that hydroxylation, hydration, glucuronidation, and GSH conjugation were the primary metabolic pathways of SNH.

CONCLUSIONS

The present study provides new information on the metabolism of SNH, which would help prospects of the disposition of SNH.

Characterization of diterpene metabolism in rats with ingestion of seed products from Euphorbia lathyris L. (Semen Euphorbiae and Semen Euphorbiae Pulveratum) using UHPLC-Q-Exactive MS

Previous pharmacological studies have indicated that diterpenoids are the primary effective chemical cluster in the seeds of Euphorbia lathyris L. The seed products are used in traditional Chinese medicine in the forms of Semen Euphorbiae (SE) and Semen Euphorbiae Pulveratum (SEP). However, the metabolism of the plant's diterpenoids has not well elucidated, which means that the in vivo metabolites products have not been identified. In the current study, the physiological metabolites of six diterpenes (Euphorbia factor L₁ (L1), L₂ (L2), L₃ (L3), L_7a (L7a), L_7b (L7b), and L₈ (L8) were screened in feces and urine of rats after oral administration of SE and SEP, using UHPLC-Q-Exactive MS. A total of 22 metabolites were detected in feces and eight in urine, indicating that the major elimination route of diterpenoids is via the colon. Hydrolysis, methylation and glucuronidation served as be the primary metabolic pathways of these diterpenoids. To sum up, this study contributed toward the elucidated of new metabolites and metabolic pathways of SE and SEP, and the new chemical identities can be used to guide further pharmacokinetic studies.