Study of the mechanism underlying the anti-inflammatory effect of Miao medicine comprising raw and processed Radix Wikstroemia indica using the "sweat soaking method".

ETHNOPHARMACOLOGICAL RELEVANCE: To explore the differences in the anti-inflammatory efficacy and mechanisms of the Miao medicine, both raw and after processing, using the "sweat soaking method" of Radix Wikstroemia indica (RWI). AIM OF THE STUDY: The purpose of this study was to explore the differences in the anti-inflammatory efficacy and mechanism of action before and after the processing of the Miao medicine (RWI) using the "sweat soaking method." MATERIALS AND METHODS: Network pharmacology technology was used to construct the "drug-component target-pathway-disease" network, and the main anti-inflammatory pathways of RWI were identified. Rat models of collagen-induced arthritis were established. The changes in body weight, swelling rate of the foot pad and ankle joint, arthritis index, thymus index, spleen index, pathological changes of the ankle joint, and the content of inflammatory cytokines (IL-1ß, IL-2, IL-6, IL-10, TNF-α, and NO) were used as indices to evaluate the effect of RWI on rats with collagen-induced arthritis before and after its processing. Plasma and urine samples were collected from the rats, and the potential biomarkers of, and metabolic pathways underlying the anti-inflammatory effects of RWI before and after processing were identified using 1H-Nuclear magnetic resonance metabolomics combined with a multivariate statistical analysis. RESULTS: Eleven key anti-inflammatory targets of IL6, IL-1ß, TNF, ALB, AKT1, IFNG, INS, STAT3, EGFR, TP53, and SRC were identified by network pharmacology. The PI3K-Akt signaling pathway, steroid hormone biosynthesis, arginine biosynthesis, arginine and proline metabolism, tryptophan metabolism, and other pathways were mainly involved in these effects. Pharmacodynamic studies found that both raw and processed RWI products downregulated inflammatory factors in rats with collagen-induced arthritis and alleviated the pathological changes. A total of 41 potential pathways for the anti-inflammatory effects of raw RWI products and 36 potential pathways for the anti-inflammatory effects of processed RWI products were identified by plasma and urine metabolomics. The common pathways of network pharmacology and metabolomics were steroid hormone biosynthesis, arginine biosynthesis, arginine and proline metabolism, and tryptophan metabolism. CONCLUSIONS: The anti-inflammatory effect of RWI was mainly related to the regulation of steroid hormone biosynthesis, arginine biosynthesis, arginine and proline metabolism, and tryptophan metabolism. Finally, the "sweat soaking method" enhanced the anti-inflammatory effect of RWI.

Spatiotemporal evolution of seismicity during the cyclic operation of the Hutubi underground gas storage, Xinjiang, China.

Underground gas storages (UGSs) are important large-scale industrial facilities used to bridge the gap between natural gas consumption and supply. The cyclic operation of the UGS may alter the subsurface stresses and local seismicity. We examined seismicity around the Hutubi UGS from 2011 to 2019 using the matched filter technique (MFT) and double-difference location methods. More than 1300 earthquakes were detected with seismicity around the UGS showing a remarkable increase since the start of its operation and showing a clear correlation to seasonal gas production. About 684 detected earthquakes were located, most of them occurred within 6 km of the reservoir. The events can be grouped into two clusters. Both clusters initiated around the gas pressure boundary. The first cluster extinct after the first injection period. While the second cluster diffused upward along a pre-existing fault. We speculate that strain localization caused by non-uniform gas injection contributes to the initiation of seismicity clusters around the UGS, and the trapped crude oil/gas played an important role in the migration of the second surge. The revealed seismicity pattern contributes to a better understanding of the mechanism of induced seismic events and emphasizes the importance of seismic monitoring in the UGS region.

Dual response to pH and chiral microenvironments for the release of a flurbiprofen-loaded chiral self-assembled mesoporous silica drug delivery system.

This study examined the effects of pH and chirality on the release of flurbiprofen (FP)-loaded chiral (L/D) self-assembled mesoporous silica nanoparticles (CSA-L/D-MSNs), which were synthesized using cationic cetyltrimethyl ammonium bromide (CTAB) as a template and chiral modified using L/D-tartaric acids. The morphology and physicochemical properties of the CSA-L/D-MSNs were systemically determined and compared with those of non-functionalized mesoporous silica nanoparticles (MSN). The results showed that the CSA-L/D-MSNs were spherical nanoparticles, and the chirality in the L/D-tartaric acids was successfully imparted to the CSA-L/D-MSNs. FP could be loaded into the CSA-L/D-MSNs and was effectively transformed from the crystalline state to an amorphous state after drug loading due to the finite size effect. The release of FP@CSA-L/D-MSNs was faster than that of FP in a pH 1.2 medium and slower in a pH 6.8 medium, and it was better than that of FP@MSNs in both release mediums. Meanwhile, the FP@CSA-L/D-MSNs exhibited a clearly enhanced pH response because the negatively charged carboxyl groups on their surface induced stronger electrostatic repulsion between FP and CSA-L/D-MSNs. Moreover, the effect of the chiral environment on the release of FP@CSA-L/D-MSNs was further studied by introducing small-molecule chiral additives (L/D-alanine). It was found that the release of FP was inhibited in a chiral environment. Particularly, the CSA-L/D-MSNs began to exert the chiral recognition function, in which the CSA-L-MSN responded to chiral stimuli and enhanced the cumulative release amount from 84.25 %-89.11 % in a pH 6.8-L medium, while the CSA-D-MSN showed a suppressed release in the pH 6.8-L medium. Notably, the CSA-L/D-MSNs exhibited intelligent drug release by both chirality response and pH response, and will provide valuable guidance for the design of drug delivery systems.