Therapeutic potential of Dahuang Mudan Decoction for severe acute pancreatitis: targeting oxidative stress and MAPK pathways through network pharmacology and experimental verification

Abstract

ETHNOPHARMACOLOGICAL RELEVANCE: Acute pancreatitis (AP) is an inflammatory disease caused by the premature activation of digestive enzymes, leading to pancreatic self-digestion. In about 20 % of cases, AP progresses to severe acute pancreatitis (SAP), a life-threatening condition with high mortality. In traditional Chinese medicine (TCM), SAP corresponds to the "Yangming Fu-organ Excess Syndrome," attributed to internal damp-heat and toxin accumulation, Fu-organ qi obstruction, and blood stasis. Dahuang Mudan Decoction (DHMDD), a classic formula from Zhang Zhongjing's Eastern Han Dynasty text Synopsis of the Golden Chamber, can clear heat, detoxify, promote digestion, activate blood circulation, and resolve stasis. Despite its proven clinical efficacy, the molecular mechanisms of DHMDD remain unclear and require further investigation. AIM OF THE STUDY: This research sought to systematically elucidate the molecular mechanisms of DHMDD against SAP using an integrated approach that combines network pharmacology, transcriptome sequencing, and in vivo animal validation, and to identify its core bioactive components. MATERIALS AND METHODS: To investigate the effect of DHMDD on severe acute pancreatitis (SAP), we first established a mild-to-moderate acute pancreatitis (MAP) mouse model via caerulein injection to determine the optimal therapeutic dose of DHMDD. Subsequently, an SAP model was induced with L-arginine for mechanistic studies. We used liquid chromatography-mass spectrometry (LC-MS) to identify the blood-absorbed components of DHMDD in SAP mice. The potential mechanisms of DHMDD against SAP were screened by integrating network pharmacology (based on the absorbed components) with transcriptomic sequencing; intersection analysis was performed to identify core targets and pathways. Core bioactive components were pinpointed through molecular docking. Finally, in vivo validation was conducted: SAP mice were treated with DHMDD and its key component (rhein) at different doses to verify the therapeutic effects and regulation of the core pathways, thereby confirming DHMDD's anti-SAP efficacy and material basis. RESULTS: Initial experiments showed that all doses of DHMDD alleviated pancreatic injury and lowered serum lipase and amylase levels in MAP mice, with high-dose showing the greatest benefit. In SAP mice, high-dose DHMDD also markedly reduced pathological injury in pancreatic and lung tissues, decreased acinar cell apoptosis, and lowered inflammatory cell infiltration and cytokine levels. LC-MS identified the blood-absorbed components of DHMDD, and subsequent network pharmacology analysis, based on these components, pinpointed 366 potential therapeutic targets for SAP. Intersection analysis of these targets with transcriptomic differentially expressed genes (DEGs) from pancreatic tissues confirmed the core regulatory targets. KEGG enrichment analysis highlighted the involvement of inflammation-related MAPK signaling and oxidative stress-related pathways, a finding corroborated by transcriptomic data. Notably, animal experiments validated that the core bioactive component, rhein, at two tested doses, alleviated SAP-induced pancreatic and lung injury, reduced apoptosis and inflammation, mirroring the effects of DHMDD. Both DHMDD and rhein significantly suppressed MAPK pathway activation in macrophages while enhancing the antioxidant response in acinar cells via activation of the Nrf2/HO-1 signaling cascade. CONCLUSION: We have elucidated a dual mechanism for DHMDD in SAP: enhancing the Nrf2/HO-1 antioxidant axis in acinar cells and suppressing pro-inflammatory MAPK signaling in macrophages. The identified core component, rhein, mediates these effects, confirming its role as the key material basis. This work provides a scientific foundation for DHMDD's clinical use and positions rhein as a candidate for targeted drug development against SAP.

Key Findings

• Dahuang Mudan Decoction (DHMDD) exhibits therapeutic effects against severe acute pancreatitis (SAP) by targeting oxidative stress and MAPK signaling pathways.
• Network pharmacology combined with transcriptomic sequencing identified core bioactive components and molecular targets involved in DHMDD's action.
• In vivo validation in SAP mouse models confirmed that DHMDD and its key component rhein reduce pancreatic injury and oxidative damage.

Clinical Significance

Citation

Duan Lifang, Luo Ying, Shang Chenruet al.. Therapeutic potential of Dahuang Mudan Decoction for severe acute pancreatitis: targeting oxidative stress and MAPK pathways through network pharmacology and experimental verification Journal of ethnopharmacology. 2026-Apr-06.