Abstract The incidence of ulcerative colitis (UC) is on the rise globally. Shen-Zhu-Lian-Bai decoction (SZLBD) can relieve the clinical symptoms of UC. This study aimed to investigate the underlying molecular mechanism of SZLBD in the treatment of UC. The key treatment targets of SZLBD for UC were obtained based on the online database, and combined with the STRING database and Cytoscape 3.7.2 software, PPI network was constructed and visualized. The GEO database was utilized to validate the expression levels of core targets in UC. Metascape database GO functional annotation and KEGG pathway enrichment analysis. Molecular docking technology was used to verify the docking of core compounds with key targets. RT-qPCR and Western Blot were used to detect the expression of key targets in HCoEpiC cells for verification. After screening, 67 targets shared by SZLBD and UC were obtained. It is predicted that IL-6, IL-1B, and AKT1 might be the key targets of SZLBD in the treatment of UC. Quercetin was the main active ingredient. GEO results showed that the expression levels of IL-6, IL-1B and AKT1 were higher in the UC group compared to the control group. GO and KEGG analyses showed that these targets were related to apoptosis and inflammation. The results of molecular docking demonstrated that the AKT1 gene, a key target of quercetin, had the highest affinity of -9.2 kcal/mol. Cell experiments found that quercetin could affect the expression of IL-6, IL-1B, and AKT1. This study preliminarily explored and verified the mechanism of action of SZLBD in the treatment of UC, which provides a theoretical basis for subsequent in vivo mechanism studies. Keywords: Ulcerative colitis, Shen-Zhu-Lian-Bai decoction (SZLBD), Network pharmacological, Molecular docking, Cell experiments Subject terms: Clinical pharmacology, Pharmacogenetics Introduction Ulcerative colitis (UC) is a chronic inflammatory disease of the colon that typically presents with abdominal pain, diarrhea, and blood in the stool^[26]1. It is characterized by recurrence and remission of mucosal inflammation that begins in the rectum and extends near the colon. Endoscopic biopsy is the only way to diagnose UC^[27]2. Currently, the incidence of UC is on the rise globally^[28]2. Although the exact pathogenesis of UC is unknown, several factors, such as defects in the colonic epithelium, the mucus barrier, and the epithelial barrier^[29]3 have been identified to affect UC development. Medications for UC include 5-aminosalicylic acid drugs (5-ASA), steroids, and immunosuppressant. Although Western medicine can achieve certain an effect, the effect is not ideal^[30]4. Many herbs have shown significant advantages in treating UC^[31]5. The commonly used traditional Chinese medicines (TCM) formulas for the treatment of UC include Ge-Gen-Qin-Lian decoction (GGQLD)^[32]6 and Shen-Ling-Bai-Zhu-San (SLBZS)^[33]7. Based on these two formulas, we combined clinical conditions to develop the TCM formula Shen-Zhu-Lian-Bai decoction (SZLBD). SZLBD is composed of Coptis chinensis Franch. (Huanglian), Phellodendron chinense Schneid. (Huangbai), Atractylodes macrocephala Koidz. (Baizhu), Portulacae oleracea L. (Machixian), Citrus reticulata Blanco (Chenpi), Codonopsis pilosula (Franch.) Nannf. (Dangshen), Paeonia lactiflora Pall. (Baishao). Huanglian and its active ingredient berberine have been proved to treat UC^[34]8. The ingredient of Huangbai can treat UC^[35]9. Baizhu Shaoyao San (BSS) composed of Baizhu, Baishao and Chenpi, so on, which can be used to treat UC^[36]10. Dangshen combined with astragalus polysaccharide (APS) can improve colitis in mice^[37]11. The above research indicates that the components of SZLBD play a role in treating UC. Therefore, we believe that SZLBD may have a good therapeutic effect on UC, but its related mechanism of action is still unclear. In this study, TCM formula SZLBD was used as the research object, and network pharmacology and molecular docking methods were applied to predict the effective compounds, key targets and signaling pathways of SZLBD in the treatment of UC, which were verified by cell experiments. The specific flow chart is shown in Fig. [38]1. Figure 1. [39]Figure 1 [40]Open in a new tab Flow chart of SZLBD against UC. Materials and methods Screening of active compounds in SZLBD The active compounds of 7 TCM in SZLBD were searched in the Traditional Chinese Medicine Systems Pharmacology (TCMSP) database ([41]http://tcmspw.com/), and each compounds was screened according to the criteria of by the oral bioavailability (OB) ≥ 30% and drug likeness (DL) ≥ 0.18. Screening of common targets of SZLBD and UC The active compounds of SZLBD and their target information were retrieved from the TCMSP database, and the targets were converted into the corresponding human gene names using the STRING database ([42]https://string-db.org/). UC-associated targets were obtained from the GeneCards database ([43]https://www.genecards.org/) and the NCBI database by entering the keyword “ulcerative colitis”. All targets were limited to Homo sapiens. Next, the common targets of GeneCards and NCBI databases were retained as UC-related targets. Finally, the intersection targets of SZLBD-related targets and UC-related targets were considered as potential therapeutic target for SZLBD in the treatment of UC. Protein–protein interaction (PPI) networks construction The common targets of SZLBD and UC were entered into the STRING database ([44]https://string-db.org/) for PPI network construction. The nodes and edges of the network represent proteins and protein–protein associations, respectively. PPI networks were visualized using Cytoscape 3.7.2 software, and topological features were analyzed to screen core targets. GEO verification We validated the expression levels of these core targets in UC using an external dataset from the Gene Expression Omnibus (GEO). We utilized the "limma" package in R language to obtain the expression levels of core genes in both the normal and UC groups. We then generated box plots using the Sangerbox online platform ([45]http://sangerbox.com/home.html). GO functional annotation and KEGG signaling pathway enrichment analysis In order to understand the biological functions and related signaling pathways involved in the common targets of SZLBD and UC, GO functional annotation (including biological process (BP), cell ingredient (CC) and molecular function (MF)) and KEGG signaling pathway enrichment analysis were performed for the common targets using Metascape database ([46]https://metascape.org/). In the end, there are only p-values < 0.01, count > 3, enrichment factor (enrichment factor is the ratio between observed counts and counts expected by chance) > 1.5 is considered a significant enrichment result^[47]12,[48]13. Molecular docking The molecular structure of the core active compounds were downloaded from the PubChem database ([49]https://pubchem.ncbi.nlm.nih.gov/). The protein crystal structure of the key targets were obtained from the RCSB PDB database (PDB, [50]https://www.rcsb.org/). The structure of compounds and proteins were processed by AutoDockTools (version 1.5.6). Optimal combinations of docking score were visualized by PyMOL. Experimental verification Cell culture and quercetin administration Human colonic epithelial cells (HCoEpiC) were purchased from Saibaikang Company (Shanghai, China). HCoEpiC cells were cultured at 37 °C under 5% CO[2]-humidified air in DMEM supplemented with 10% fetal bovine serum (FBS), 100 U/mL penicillin and 100 μg/mL streptomycin^[51]14. Screening of LPS concentration HCoEpiC was made into 5 × 10^4 cells/mL suspension, inoculated in culture plates or culture flasks, and cultured in a 37 °C incubator with 5% CO[2] for 24 h. Cells were treated with different concentrations of LPS (5, 10, 15 μg/mL). After 24 h, cell viability was assessed using the CCK-8 assay by measuring absorbance in each well to calculate cell survival rates. Quercetin cytotoxicity test Quercetin was purchased from MCE Company. The cells were randomly divided into 7 groups, i.e., the normal group, the model group, and the quercetin-added group (0, 20, 40, 60, and 80 μM). Except the normal group, all groups were given LPS with a final concentration of 10 μg/mL to create an inflammatory injury model. In addition to the normal group and the model group, each group was added with the corresponding test drug and incubated at 37 °C with 5% CO[2] for 24 h. Cell viability was assessed using the CCK-8 assay by measuring absorbance in each well to calculate cell survival rates. Real-time quantitative PCR (RT-qPCR) Total cellular RNA was extracted using TRIzol reagent (Invitrogen, Carlsbad, CA, USA) according to the manufacturer’s instructions. Subsequently, cDNA was synthesized using a PrimeScript RT reagent kit (Takara Biotechnology, Dalian, China). Real-time PCR was then performed using an ABI 7500 Sequence Detection System (Applied Biosystems, Foster City, CA, USA). The primer sequences are shown in Table [52]1. Table 1. Primer Sequence. Gene Primer sequence AKT1-F TGGACTACCTGCACTCGGAGAA AKT1-R GTGCCGCAAAAGGCTTTCATGG IL-6-F CTCCTTCTCCACAAGCGCC IL-6-R GATGCCGTCGAGGATGTACC IL-1B-F GCCAGTGAAATGATGGCTTATT IL-1B-R AGGAGCACTTCATCTGTTTAGG GAPDH-F GGAGCGAGATCCCTCCAAAAT GAPDH-R GGCTGTTGTCATACTTCTCATGG [53]Open in a new tab F forward, R reverse. Western blot analysis The cells were lysed using RIPA lysis buffer after treatment. After centrifugation at 4 °C and 3000 rpm for 10 min, the supernatant was collected. Subsequently, protein lysates were separated and electrophoresed on PVDF membranes using 10% SDS-PAGE. The PVDF membranes were then incubated in 5% skim milk TBST solution for 2 h, followed by washing with TBST solution without skim milk three times for 10 min each. Afterwards, the membranes were incubated overnight at 4 °C with IL-6, IL-1B, and AKT1 rabbit polyclonal antibodies (sourced respectively from ZEN BIO, proteintech, and ZEN BIO). The membranes were moistened with TBST solution three times for 10 min each, followed by incubation at room temperature for 1.5 h in HRP-labeled goat anti-rabbit IgG solution (dilution ratio: 1/20,000). Finally, the membranes were washed with TBST solution three times for 10 min each, and then tested using a Tanon chemiluminescence imager. The images were quantitatively analyzed using ImageJ software. Results Screening results of active compounds in SZLBD A total of 90 active compounds of SZLBD were obtained based on the TCMSP database and the screening criteria of OB ≥ 30% and DL ≥ 0.18 (Table [54]2). Combined with the TCMSP database, 185 SZLBD related targets were obtained, and the ingredients—compounds -target network was shown in Fig. [55]2. As a result, the main active compounds of SZLBD included quercetin and kaempferol, among others, each of which regulated multiple targets. Table 2. Information for Potential active ingredients of SZLBD. Mol ID Molecule name Herb Pinyin OB (%) DL MOL000622 Magnograndiolide Huanglian, Huangbai 63.709 0.188 MOL008647 Moupinamide Huanglian 86.712 0.265 MOL000098 Quercetin Huanglian, Huangbai, Machixian 46.433 0.275 MOL000785 Palmatine Huanglian, Huangbai 64.601 0.645 MOL000762 Palmidin A Huanglian, Huangbai 35.358 0.650 MOL002894 Berberrubine Huanglian, Huangbai 35.736 0.727 MOL013352 Obacunone Huanglian, Huangbai 43.286 0.767 MOL002903 (R)-Canadine Huanglian 55.367 0.775 MOL002907 Corchoroside A_qt Huanglian 104.954 0.776 MOL002897 Epiberberine Huanglian 43.092 0.776 MOL001454 Berberine Huanglian, Huangbai 36.861 0.777 MOL002904 Berlambine Huanglian 36.681 0.816 MOL001458 Coptisine Huanglian, Huangbai 30.672 0.856 MOL002668 Worenine Huanglian, Huangbai 45.833 0.866 MOL002659 Kihadanin A Huangbai 31.605 0.702 MOL002671 Candletoxin A Huangbai 31.811 0.688 MOL002666 Chelerythrine Huangbai 34.184 0.780 MOL002636 Kihadalactone A Huangbai 34.209 0.817 MOL006413 Phellochin Huangbai 35.412 0.815 MOL002670 Cavidine Huangbai 35.642 0.805 MOL000790 Isocorypalmine Huangbai 35.768 0.592 MOL002641 Phellavin_qt Huangbai 35.860 0.442 MOL002673 Hispidone Huangbai 36.181 0.830 MOL002656 Dihydroniloticin Huangbai 36.426 0.815 MOL006392 Dihydroniloticin Huangbai 36.426 0.815 MOL000358 Beta-sitosterol Huangbai, Machixian, Baishao 36.914 0.751 MOL001771 Poriferast-5-en-3beta-ol Huangbai 36.914 0.750 MOL002643 Delta 7-stigmastenol Huangbai 37.423 0.751 MOL005438 Campesterol Huangbai 37.577 0.715 MOL002672 Hericenone H Huangbai 38.997 0.634 MOL002663 Skimmianin Huangbai 40.137 0.196 MOL002644 Phellopterin Huangbai 40.186 0.279 MOL002662 Rutaecarpine Huangbai 40.300 0.598 MOL006401 Melianone Huangbai 40.529 0.778 MOL002660 Niloticin Huangbai 41.414 0.818 MOL002651 Dehydrotanshinone II A Huangbai 43.762 0.400 MOL000449 Stigmasterol Huangbai, Dangshen 43.830 0.757 MOL006422 Thalifendine Huangbai 44.411 0.726 MOL001455 (S)-Canadine Huangbai 53.834 0.775 MOL002652 Delta7-Dehydrosophoramine Huangbai 54.450 0.253 MOL001131 Phellamurin_qt Huangbai 56.597 0.393 MOL000787 Fumarine Huangbai 59.263 0.827 MOL000020 12-senecioyl-2E,8E,10E-atractylentriol Baizhu 62.396 0.223 MOL000021 14-acetyl-12-senecioyl-2E,8E,10E-atractylentriol Baizhu 60.313 0.305 MOL000022 14-acetyl-12-senecioyl-2E,8Z,10E-atractylentriol Baizhu 63.371 0.300 MOL000028 α-Amyrin Baizhu 39.512 0.763 MOL000033 (3S,8S,9S,10R,13R,14S,17R)-10,13-dimethyl-17-[(2R,5S)-5-propan-2-ylocta n-2-yl]-2,3,4,7,8,9,11,12,14,15,16,17-dodecahydro-1H-cyclopenta[a]phena nthren-3-ol Baizhu 36.228 0.783 MOL000049 3β-acetoxyatractylone Baizhu 54.067 0.219 MOL000072 8β-ethoxy atractylenolide III Baizhu 35.951 0.211 MOL001439 Arachidonic acid Machixian 45.573 0.204 MOL003578 Cycloartenol Machixian 38.686 0.781 MOL002773 Beta-carotene Machixian 37.184 0.584 MOL000422 Kaempferol Machixian, Baishao 41.882 0.241 MOL005100 5,7-dihydroxy-2-(3-hydroxy-4-methoxyphenyl)chroman-4-one Machixian, Chenpi 47.736 0.272 MOL000006 Luteolin Machixian, Dangshen 36.163 0.246 MOL006657 Isobetanidin Machixian 59.731 0.521 MOL006662 Isobetanin_qt Machixian 30.162 0.521 MOL000359 Sitosterol Chenpi, Baishao 36.914 0.751 MOL004328 Naringenin Chenpi 59.294 0.211 MOL005815 Citromitin Chenpi 86.904 0.514 MOL005828 Nobiletin Chenpi 61.669 0.517 MOL001006 Poriferasta-7,22E-dien-3beta-ol Dangshen 42.979 0.756 MOL002140 Perlolyrine Dangshen 65.948 0.275 MOL002879 Diop Dangshen 43.593 0.392 MOL003036 ZINC03978781 Dangshen 43.830 0.756 MOL003896 7-Methoxy-2-methyl isoflavone Dangshen 42.565 0.199 MOL004355 Spinasterol Dangshen 42.979 0.755 MOL004492 Chrysanthemaxanthin Dangshen 38.724 0.584 MOL005321 Frutinone A Dangshen 65.904 0.342 MOL006554 Taraxerol Dangshen 38.403 0.767 MOL006774 Stigmast-7-enol Dangshen 37.423 0.751 MOL007059 3-beta-Hydroxymethyllenetanshiquinone Dangshen 32.161 0.409 MOL007514 Methyl icosa-11,14-dienoate Dangshen 39.667 0.229 MOL008391 5alpha-Stigmastan-3,6-dione Dangshen 33.115 0.790 MOL008393 7-(beta-Xylosyl)cephalomannine_qt Dangshen 38.327 0.286 MOL008397 Daturilin Dangshen 50.365 0.768 MOL008400 Glycitein Dangshen 50.479 0.238 MOL008406 Spinoside A Dangshen 39.967 0.403 MOL008407 (8S,9S,10R,13R,14S,17R)-17-[(E,2R,5S)-5-ethyl-6-methylhept-3-en-2-yl]-1 0,13-dimethyl-1,2,4,7,8,9,11,12,14,15,16,17-dodecahydrocyclopenta[a]phe nanthren-3-one Dangshen 45.405 0.762 MOL008411 11-Hydroxyrankinidine Dangshen 40.003 0.662 MOL001910 11alpha,12alpha-epoxy-3beta-23-dihydroxy-30-norolean-20-en-28,12beta-ol ide Baishao 64.774 0.376 MOL001918 Paeoniflorgenone Baishao 87.593 0.367 MOL001919 (3S,5R,8R,9R,10S,14S)-3,17-dihydroxy-4,4,8,10,14-pentamethyl-2,3,5,6,7, 9-hexahydro-1H-cyclopenta[a]phenanthrene-15,16-dione Baishao 43.556 0.533 MOL001921 Lactiflorin Baishao 49.121 0.797 MOL001924 Paeoniflorin Baishao 53.870 0.787 MOL001925 Paeoniflorin_qt Baishao 68.176 0.395 MOL001928 Albiflorin_qt Baishao 66.641 0.326 MOL001930 Benzoyl paeoniflorin Baishao 31.274 0.746 MOL000211 Mairin Baishao 55.377 0.776 MOL000492 ( +)-catechin Baishao 54.826 0.242 [56]Open in a new tab SZLBD Shen-Zhu-Lian-Bai decoction. Figure 2. [57]Figure 2 [58]Open in a new tab Key active compounds of SZLBD-target network. The teal represents traditional Chinese medicines (HL, Huanglian; CP, Chenpi; BZ, Baizhu; HB, Huangbai; MCX, Machixian; BS, Baishao; DS, Dangshen), the pink represents active ingredients, and the blue represents the targets of SZLBD. Common targets of SZLBD and UC According to GeneCards and NCBI databases, 547 UC-related genes were obtained. A total of 67 common targets of SZLBD-UC were obtained by intersecting SZLBD-related targets and UC-related targets. The UC-herb-ingredient-target network is displayed in Fig. [59]3. Figure 3. [60]Figure 3 [61]Open in a new tab Common targets of SZLBD and UC. The red represents UC (ulcerative colitis), the teal represents traditional Chinese medicine (HL, Huanglian; CP, Chenpi; BZ, Baizhu; HB, Huangbai; MCX, Machixian; BS, Baishao; DS, Dangshen), the pink represents active ingredients, and the blue represents the targets of SZLBD acting on UC. PPI network of SZLBD-UC A PPI network with 67 nodes and 912 edges was constructed by using the STRING database and visualized through Cytoscape software (Fig. [62]4). Based on the topological analysis results of PPI network, we found that IL-6, IL-1B and AKT1 had high degree values, so we speculated that the above targets may be the key targets for SZLBD treatment of UC. Figure 4. [63]Figure 4 [64]Open in a new tab PPI network. GEO verification Based on the [65]GSE75214 dataset (which includes 11 control samples and 97 UC patient samples), we analyzed the expression levels of IL-6, IL-1B, and AKT1 between the control and UC groups. The results showed that compared to the control group, the expression levels of IL-6, IL-1B, and AKT1 were higher in the UC group (Fig. [66]5). Figure 5. [67]Figure 5 [68]Open in a new tab Expression of IL-6, IL-1B and AKT1 between normal and UC samples. **p < 0.01,****p < 0.001. GO functional annotation and KEGG signaling pathway enrichment analysis A total of 1186 items were obtained from GO functional annotation analysis, and the significant enrichment results are shown in Fig. [69]6. Among them, there were 1072 BP entries (Fig. [70]6A), mainly involving inflammatory response, positive regulation of cell death and regulation of inflammatory response, etc. There were 34 CC entries (Fig. [71]6B), mainly involving membrane raft, transcription regulator complex and extracellular matrix, etc. There were 80 MF entries (Fig. [72]6C), involving cytokine activity, RNA polymerase II-specific DNA-binding transcription factor binding and protein homodimerization activity, etc. Figure 6. [73]Figure 6 [74]Open in a new tab GO functional annotation and KEGG signaling pathway enrichment analysis results. (A) BP enrichment analysis; (B) CC enrichment analysis; (C) MF enrichment analysis (D) KEGG enrichment analysis. A total of 138 pathways were obtained from KEGG signaling pathway enrichment analysis, and the significant results are shown in Fig. [75]5D. Signaling pathways associated with UC therapy mainly include IL-17 signaling pathway, PI3K-Akt signaling pathway and inflammatory bowel disease, etc. Molecular docking In this study, the main active ingredient quercetin was selected as the ligand molecule and the key targets IL-6, IL-1B and AKT1 were selected as receptor molecules for molecular docking, and the results showed that quercetin had a strong affinity with IL-6, IL-1B and AKT1 (Fig. [76]7). Quercetin and IL-6 formed stable complexes by interacting with amino acid GLU127, ARG141, GLU137 and GLN130 (Fig. [77]7A). Quercetin mainly interacted with amino acid residues ASN92, LYS148, CLU149, PRO176 and TYR175 of IL-1B (Fig. [78]7B). In addition, quercetin mainly interacted with AKT1 residues LEU52, GLU49, ARG48, CLY327, ARG328, TYR326, ALA329 and GLY393 (Fig. [79]7C). The molecular docking scores of quercetin with IL-6, IL-1B and AKT1 proteins were − 7.2 kcal/mol, − 7.0 kcal/mol and − 9.2 kcal/mol, respectively. Based on molecular docking, it was preliminarily verified that quercetin had good binding ability to IL-6, IL-1B and AKT1, which further proved the reliability of the prediction results of the network pharmacology. Figure 7. [80]Figure 7 [81]Open in a new tab Molecular docking of quercetin (MOL000098) with its targets. (A) IL-6 protein-quercetin; (B) IL-1B protein-quercetin; (C) AKT1 protein-quercetin. Experimental verification In order to verify that quercetin can interact with IL-6, IL-1B and AKT1 to participate in the treatment of UC by SZLBD, cellular validation was performed in this study. Firstly, an inflammatory cell model was constructed by treating with DMEM containing different concentrations of LPS (5, 10, 15 μg/mL) for 24 h. Cell viability was determined, and the optimal concentration was determined to be 10 μg/mL (Fig. [82]8A). After treating with LPS (10 μg/mL) for 24 h, cells were treated with different concentrations of quercetin (0, 20, 40, 60, and 80 μM) for 24 h, and cell viability was measured to determine the optimal concentration, which was found to be 40 μg/mL (Fig. [83]8B). We examined the effect of quercetin on inflammatory factors in HCoEpiC cells. Compared with the control group, the mRNA and protein expression levels of IL-6, IL-1B, and AKT1 were significantly increased in the model group. Compared with the model group, the mRNA and protein expression levels of IL-6, IL-1B, and AKT1were significantly decreased in the quercetin-treated group (Fig. [84]8C–I). Figure 8. [85]Figure 8 [86]Open in a new tab Quercetin improves LPS-induced inflammatory damage of HCoEpiC cells. (A) The choice of LPS safety and effective concentration; (B) The choice of quercetin safety and effective concentration; (C) Levels of mRNA expression of IL-6; (D) Levels of mRNA expression of IL-1B; (E) Levels of mRNA expression of AKT1; (F–I) Expression of IL-6, IL-1B and AKT1 proteins. *p < 0.05,**p < 0.01,***p < 0.001. Discussion Literature has reported that Huanglian significantly inhibits the level of proinflammatory cytokines (IL-17) in the treatment of UC^[87]15. It has been found that Huangbai can improve chronic inflammatory injury caused by endothelial dysfunction by regulating the PI3K-Akt-mTOR signaling pathway^[88]16. Baizhu and Chenpi are the main ingredients of Baizhu Shaoyao San, another Chinese medicine for the treatment of UC, which can regulate inflammatory factors and intestinal flora^[89]17. Machixian has anti-ulcer and anti-inflammatory effects. Studies have shown that Machixian can reduce the symptoms of colitis^[90]18. Dangshen and Baishao are herbs from TCM formulas Zhen-Wu-Bu-Qi Decoction for the treatment of UC^[91]19, which exhibit anti-inflammatory properties by modulating the PI3K-AKT, MAPK signaling pathway, and NF-κB signaling pathway. In our study, 90 active compounds and 185 targets of SZLBD were identified from the TCMSP database. The compounds-targets network diagram shows the potential synergies between multiple ingredients and their targets. Quercetin, the main active ingredient, comes from Huanglian, Huangbai and Machixian. In conclusion, these three herbs of SZLBD can treat and improve UC by acting on the IL-17 and PI3K-Akt signaling pathways, which is consistent with and more complete than previous studies. Quercetin (3, 5, 7, 3’, 4’-pentahydroxyflavonoid) is one of the main representatives of flavonoids. In plants, it exists mainly in the form of glycosides. In addition, quercetin has a wide range of biological effects, including antioxidant, anticancer, anti-inflammatory, antidiabetic and antibacterial effects^[92]20. It exerts its anti-inflammatory effect mainly by inhibiting the release of cytokines, reducing the production of COX and LOX, and maintaining the stability of mast cells^[93]21. A study of pulpitis has reported that quercetin reduces the production of pro-inflammatory cytokines IL-6 and IL-17^[94]22. Besides, quercetin-induced miR-369-3p modulates inflammatory cascades in chronic inflammatory responses and increases IL-6 production^[95]23. Quercetin can also inhibit inflammation by regulating the PI3K-AKT signaling pathway, thus reducing oxidative stress damage in GES-1 cells^[96]24. In mice with DSS-induced colitis, quercetin can significantly improve moderate DSS- induced colitis and reduce intestinal inflammation^[97]25. Additionally, in the study of Huai Hua San for treating UC, quercetin has also been found to play an important role in exerting anti-inflammatory effects^[98]26. In our study, both the prediction of active compounds and cell verification experiments indicated that quercetin was a key ingredient of SZLBD and played a vital role in the treatment of UC by regulating inflammation-related processes. It is well known that IL-1B and IL-6 are pro-inflammatory factors. In a past study, administration of a water-soluble artemisinin analog (SM934) was found to improve UC by reducing DSS-induced mRNA and protein levels of IL-1 B and IL-6^[99]27. Protein kinase B (AKT) is a member of the human serine-threonine kinase and the AGC family of protein kinases. Samples of human patients with UC showed severe down regulation of AKT1 function, accompanied by decreased AKT1 activity and increased inflammation^[100]28. More drugs for the treatment of UC work through the pathway where AKT1 is located. Dihydroartemisinin can alleviate DSS-induced colitis via the PI3K-AKT signaling pathway^[101]29. Huangqin decoction ameliorates DSS-induced colitis by inhibiting the Ras-PI3K-Akt-HIF-1α pathway^[102]30. Quercetin can alleviate inflammation by reducing the levels of TNF-α, IL-1β, IL-6, and IL-10, thus treating DSS-induced colitis in mice^[103]31. The results of network pharmacology analysis and cell experiments in this study showed that quercetin, the main ingredient of SZLBD, targeted IL-6, IL-1B and AKT1 in the treatment of UC. We speculated that quercetin might improve UC by reducing the expression of pro-inflammatory factors and the PI3K-Akt signaling pathway. Overall, this study suggested that quercetin might be the main active ingredient in SZLBD. IL-6, IL-1B, and AKT1 were potential therapeutic targets of SZLBD in the treatment of UC. In addition, the role of SZLBD in UC might be achieved by modulating the balance of cytokines in the immune system and inflammation-related pathways, such as the IL-17 and PI3K-AKT pathways. These findings confirm that network pharmacology is an important method for predicting active compounds and targets. This study provides a theoretical basis for SZLBD in the treatment of UC and a comprehensive approach for finding more Chinese medicines to treat UC. However, our study still has some limitations. First, most targets in the databases are verified, and unverified or undocumented ones may be overlooked. Second, quercetin, although identified as the main active ingredient of SZLBD, cannot completely replace SZLBD. Third, network pharmacology analysis ignores the absorption pathways, effective sites, active compounds, and metabolic forms of bioactive substances. Additionally, we have not yet explored the roles of other key ingredients within the decoction. Finally, we have not yet conducted animal studies to validate the efficacy of the SZLBD. Therefore, we need more in vitro and in vivo research to further explore the underlying molecular mechanisms by which SZLBD treats UC. Conclusion In this study, we combined network pharmacology, molecular docking, and in vitro experiments to explore and verify the mechanism by which SZLBD targets and their main bioactive constituents effectively exert anti-UC effects. We found that SZLBD acted on multiple targets of multiple signaling pathways, and intervened in the PI3K-Akt and IL-17 pathways to delay the progression in UC. In the follow-up study, we plan to design in vivo and in vitro animal pharmacological experiments to deeply investigate the mechanism of action of SZLBD in the treatment of UC, so as to provide more references for its clinical application and