12 results on '"Liu, Yaojiang"'
Search Results
2. Human telomerase reverse transcriptase (hTERT) synergistic with Sp1 upregulate Gli1 expression and increase gastric cancer invasion and metastasis
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Wu, Lingyi, Wang, Sumin, Tang, Bo, Tang, Li, Lei, Yuanyuan, Liu, Yaojiang, Yang, Min, Yang, Guodong, Zhang, Dan, and Liu, En
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- 2021
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3. Parabacteroides produces acetate to alleviate heparanase-exacerbated acute pancreatitis through reducing neutrophil infiltration
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Lei, Yuanyuan, Tang, Li, Liu, Shuang, Hu, Shiping, Wu, Lingyi, Liu, Yaojiang, Yang, Min, Huang, Shengjie, Tang, Xuefeng, Tang, Tao, Zhao, Xiaoyan, Vlodavsky, Israel, Zeng, Shuo, Tang, Bo, and Yang, Shiming
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- 2021
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4. Inhibition of MGMT-mediated autophagy suppression decreases cisplatin chemosensitivity in gastric cancer
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Lei, Yuanyuan, Tang, Li, Hu, Jiaxi, Wang, Sumin, Liu, Yaojiang, Yang, Min, Zhang, Jianwei, and Tang, Bo
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- 2020
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5. Additional file 1 of TLR4 regulates RORγt+ regulatory T-cell responses and susceptibility to colon inflammation through interaction with Akkermansia muciniphila
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Liu, Yaojiang, Yang, Min, Tang, Li, Wang, Fengchao, Huang, Shengjie, Liu, Shuang, Lei, Yuanyuan, Wang, Sumin, Xie, Zhuo, Wang, Wei, Zhao, Xiaoyan, Tang, Bo, and Yang, Shiming
- Abstract
Additional file 1: Figure S1. TLR4-/- mice develop severe DSS-induced colitis. Figure S2. Loss of TLR4 significantly alters gut microbiota taxonomic composition. Figure S3. FMT alleviates colon inflammation in TLR4-/- mice. Figure S4. Gut microbiota PCoA profile of Co-housing and FMT experiments. Figure S5. Gut microbiota taxonomic composition in FMT experiments. Figure S6. Gut microbiota taxonomic composition in Co-housing experiments. Figure S7. The intestinal innate immune responses evaluation between WT and TLR4-/- mice. Figure S8. The intestinal adaptive immune responses evaluation between WT and TLR4-/- mice. Figure S9. The cytokines profile of Treg and Th17 cells between WT and TLR4-/- mice. Figure S10. Correlation analysis between RORγt+ Treg cells and clinical parameters. Figure S11. Correlation analysis between differential flora and phenotypic indicators. Figure S12. Gut microbiota landscope of Co-housing and FMT experiments. Figure S13. The relative abundance of A. muciniphila is decreased in stool samples in patients with UC. Figure S14. The microbiome of UC patients are different from healthy participants. Figure S15. The microbiome of UC patients are different from healthy participants. Figure S16. The microbiome of UC patients are different from healthy participants. Figure S17. The microbiome of UC patients are different from healthy participants. Figure S18. A. muciniphila abundance discrepancy following single bacteria supplementation. Figure S19. Correlation analysis between transcription factor expression and A. muciniphila colonization. Figure S20. The intestinal innate immune responses evaluation between WT and TLR4-/- mice after A. muciniphila supplementation. Figure S21. Intestinal epithelial-derived TLR4 pathway participating in intestinal immune activation against colitis. Figure S22. A. muciniphila abundance discrepancy in BMT experiment following bacteria supplementation. Figure S23. TLR4 affects the intestinal colonization of A. muciniphila during homeostasis. Figure S24. The Interaction between TLR4 and Amuc-1100 mediated the intestinal colonization of A. muciniphila. Figure S25-S27. Top-ranked possible complex scenarios of TLR4 and Amuc-1100 based on ZDOCK prediction. Supplemental Methods. Faecal genomic DNA extraction and 16S-rRNA sequencing. Antibiotic cocktail treatment. Co-housing experiment. Faecal microbiota transplantation (FMT). Single-cell isolation. Flow cytometry. Gut microbiota qPCR quantification. Cultivation of A. muciniphila and Mouse Colonization with A. muciniphila. Meta-analysis of microbiome changes in patients with UC.
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- 2022
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6. Additional file 2 of Parabacteroides produces acetate to alleviate heparanase-exacerbated acute pancreatitis through reducing neutrophil infiltration
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Lei, Yuanyuan, Tang, Li, Liu, Shuang, Hu, Shiping, Wu, Lingyi, Liu, Yaojiang, Yang, Min, Huang, Shengjie, Tang, Xuefeng, Tang, Tao, Zhao, Xiaoyan, Vlodavsky, Israel, Zeng, Shuo, Tang, Bo, and Yang, Shiming
- Abstract
Additional file 1: Supplemental Figure 1. Confirmation of mouse and human Hpa encoding genes expressions across all experimental conditions. (a) Genotype identification of Hpa- Tg mice. Semiquantitative PCR amplification of DNA extracted from WT (n=1) and Hpa-Tg mice (n=10). Human Hpa specific primer was used to detect transgene vector sequences in the mouse genome. Total DNA was assessed by specific primer against a genomic sequence of the ribosomal protein L-19. The expression levels of mouse Hpa (b) and human Hpa (c) in WT+SW/WT+Cn/Hpa-Tg+SW/Hpa-Tg+Cn group were confirmed. The expression levels of mouse vs human Hpa in in Hpa-Tg SW/HpaTg+Cn groups were confirmed (d). (e) Before 16S rRNA sequencing of WT and HpaTg mice, the expression levels of mouse Hpa and human Hpa were confirmed. The expression levels of mouse or human Hpa, the expression levels of mouse vs human Hpa were also confirmed in ABX (f), FMT (g-i), cohousing (j), Parabacteroides administration (k-m) and acetate supplementation (n-p) experiments. Data were expressed as mean ± SEM. Significance between two groups was determined by unpaired, two-tailed t test or Mann-Whitney test depending on the sample distribution. Significance between multiple groups was determined through ordinary one-way ANOVA or Kruskal-Wallis test depending on the sample distribution. Exact p levels were all provided. ABX, antibiotic cocktail; Cn, caerulein; CoHo, cohoused; FMT, fecal microbiota transplantation; Hpa-Tg, heparanase-transgenic; P. distasonis, Parabacteroides distasonis; SiHo, housed singly; SW, sterile water; rRNA, ribosomal RNA; WT, wild-type. Supplemental Figure 2. Alpha-diversity, beta-diversity and bar plots of the phylum/class/order/family/genus taxonomic levels in WT and Hpa-Tg mice. (a) Alpha-diversity (Based on ACE, Observed features, Fisher alpha, Shannon and Faith pd). (b) PCoA of beta-diversity using Jaccard, Generalized Unifrac and Weighted Unifrac metric distance. (c) Quantification of dissimilarity values based on (b), presented as dissimilarity values (first (box bottom), third (box top) quartiles, the median (line inside box) and 2.5 interquartile range (line ends)). (d) Bar plots of the phylum taxonomic levels in WT and Hpa-Tg mice. Relative abundance is plotted for each group. The relative abundances of Firmicutes and Bacteroidetes were shown. (e) Bar plots of the class taxonomic levels in WT and Hpa-Tg mice. Relative abundance is plotted for each group. (f) Bar plots of the order taxonomic levels in WT and Hpa-Tg mice. Relative abundance is plotted for each group. Bacterial genera with relative abundance greater than 0.01% were analyzed. (g) Bar plots of the family taxonomic levels in WT and Hpa-Tg mice. Relative abundance is plotted for each group. Bacterial genera with relative abundance greater than 0.1% were analyzed. (h) Bar plots of the genus taxonomic levels in WT and Hpa-Tg mice. Relative abundance is plotted for each group. Bacterial genera with relative abundance greater than 1% were analyzed. Data were expressed as mean ± SEM. n=15 individuals/group. Significance between two groups was determined by unpaired, two-tailed t test or Mann-Whitney test depending on the sample distribution. For (b-c), differences of data were assessed by ANOSIM test. Exact p levels were all provided. ANOSIM, analysis of similarities Hpa-Tg, heparanase-transgenic; WT, wild-type. Supplemental Figure 3. Exacerbated acute pancreatitis in Hpa-Tg mice depended on gut microbiota. (a) ABX experimental design, WT and Hpa-Tg littermates were put on a course of intragastrically antibiotic cocktail administration for 5 days for gut microbiota depletion After that, 16S rRNA sequencing analysis and AP induction were performed. (b) Pancreas (g)/body (g) weight x 1‰. (c) Serum amylase. (d) Serum lipase. (e) Representative images of pancreatic H&E staining. (f) Histologic score. (g) Serum TNF-α measured by ELISA. (h) Serum IL-6 measured by ELISA. (a-h) n=5 individuals/group. Data were expressed as mean ± SEM. Differences of data were assessed by assessed by unpaired, two-tailed t test or Mann-Whitney test depending on the sample distribution. Exact p levels were all provided. Scale bars, 500 and 200 μm, respectively. ABX, antibiotic cocktail; AP, acute pancreatitis; Cn, caerulein; Hpa-Tg, heparanase-transgenic; rRNA, ribosomal RNA; WT, wild-type. Supplemental Figure 4. Beta-diversity among ABX experimental groups. 16S rRNA sequencing analysis in fecal bacterial DNA from ABX WT mice (n=5) and Hpa Tg mice (n=3) was performed. PCoA of beta-diversity using Bray-Curtis (a), Jaccard (b), Generalized Unifrac (c) and Weighted Unifrac (d) metric distance. Differences of data were assessed by ANOSIM test. Exact p levels were all provided. ABX, antibiotic cocktail; ANOSIM, analysis of similarities; Hpa-Tg, heparanase-transgenic; PCoA, principal coordinate analysis; rRNA, ribosomal RNA; WT, wild-type. Supplemental Figure 5. Beta-diversity among FMT experimental groups. 16S rRNA sequencing analysis in fecal bacterial DNA from FMT groups was performed. n=7 individuals/group. PCoA of beta-diversity using Bray-Curtis (a), Jaccard (b), Generalized Unifrac (c) and Weighted Unifrac (d) metric distance. Differences of data were assessed by ANOSIM test. Exact p levels were all provided. ANOSIM, analysis of similarities; Hpa-Tg, heparanase-transgenic; PCoA, principal coordinate analysis FMT, fecal microbiota transplantation; rRNA, ribosomal RNA; WT, wild-type. Supplemental Figure 6. Beta-diversity among CoHo WT and CoHo Hpa-Tg groups. 16S rRNA sequencing analysis in fecal bacterial DNA from CoHo WT and CoHo Hpa-Tg groups was performed. n=7 individuals/group. PCoA of beta-diversity using Bray-Curtis (a), Jaccard (b), Generalized Unifrac (c) and Weighted Unifrac (d) metric distance. Differences of data were assessed by ANOSIM test. Exact p levels were all provided. ANOSIM, analysis of similarities; CoHo, cohoused; Hpa-Tg, heparanase-transgenic; PCoA, principal coordinate analysis; rRNA, ribosomal RNA; WT, wild-type. Supplemental Figure 7. Parabacteroides was the most important biomarker to distinguish WT and Hpa-Tg mice. (a) VIP score of OPLS-DA. VIP score (calculated based on 16S rRNA sequencing data of Fig. 2) was used to rank the ability of different taxa to discriminate between WT and Hpa-Tg mice. A taxon with VIP score >1.5 was considered important in the discrimination. n=15 individuals/group. (b) In ABX experiment, Parabacteroides abundance was confirmed by 16S rRNA sequencing (n=5/3 in ABX WT/ABX Hpa-Tg group, respectively) and qRT-PCR (using specific primers of P. distasonis, n=5 individuals/group). (c) In FMT experiment, Parabacteroides abundance was confirmed by 16S rRNA sequencing and qRT-PCR (using specific primers of P. distasonis). n=7 individuals/group. (d) In Cohousing experiment, Parabacteroides abundance was confirmed by 16S rRNA sequencing and qRT-PCR (using specific primers of P. distasonis). n=7 individuals/group. (e-j) The correlations between severity indicators of AP and Parabacteroides abundance were analyzed using Spearman’s correlations. 6 mice each in WT and Hpa-Tg mice were included in the statistics. (k) In Parabacteroides administration experiment, Parabacteroides abundance was confirmed by 16S rRNA sequencing. n=5 individuals/group. Data were expressed as mean ± SEM. Differences of data in two groups were assessed by assessed by unpaired, two-tailed t test or Mann-Whitney test depending on the sample distribution. Differences of data in more than two groups were assessed by ordinary one-way ANOVA or Kruskal-Wallis test depending on the sample distribution. Exact p levels were all provided. ABX, antibiotic cocktail; AP, acute pancreatitis; FMT, fecal microbiota transplantation; Hpa-Tg, heparanase-transgenic; OPLS-DA, orthogonal partial least squares discrimination analysis; P. distasonis, Parabacteroides. distasonis; qRT-PCR, Quantitative RT-PCR; rRNA, ribosomal RNA; VIP, valuable influence on projection; WT, wild-type. Supplemental Figure 8. Acetate concentration in ABX, FMT and cohousing experiments. (a) The whole annotation of microbial gene function of WT and Hpa-Tg mice on KEGG pathway analysis. Analysis of 16S rRNA sequencing data from Figure 2. n = 15 individuals/group. (b) Relative fold change of acetate concentration from cecal content in ABX experiment. n=5 individuals/group. (c) Relative fold change of acetate concentration from cecal content in FMT experiment. n=7 individuals/group. (d) Relative fold change of acetate concentration from cecal content in CoHo WT and CoHo Hpa-Tg mice. n=7 individuals/group. Data were expressed as mean ± SEM. Differences of data in two groups were assessed by assessed by Mann-Whitney test. Differences of data in FMT experiment was assessed by ordinary one-way ANOVA. Exact p levels were all provided. ABX, antibiotic cocktail; CoHo, cohoused; FMT, fecal microbiota transplantation; Hpa-Tg, heparanase-transgenic; rRNA, ribosomal RNA; KEGG, kyoto encyclopedia of genes and genomes; WT, wild-type. Supplemental Figure 9. Confirmation of acetate enrichment in acetate supplementation experiment. Relative fold change of acetate concentration from cecal content in acetate supplementation experiment. n=9 individuals/group. Data were expressed as mean ± SEM. Differences of data were assessed by ordinary one-way ANOVA. Exact p levels were all provided. WT, wild-type; Hpa-Tg, heparanase transgenic. Supplemental Figure 10. Neutrophil infiltration depended on gut microbiota in heparanase-exacerbated acute pancreatitis. WT and Hpa-Tg mice were treated with/without Cn. Representative plots of immunohistochemistry and bar plots of neutrophils in pancreas were shown in (a) and (b), respectively. Representative plots of immunohistochemistry and bar plots of neutrophils in pancreas of ABX experiment were shown in (c) and (d), respectively. Representative plots of immunohistochemistry and bar plots of neutrophils in pancreas of FMT experiment were shown in (e) and (f), respectively. Representative plots of immunohistochemistry and bar plots of neutrophils in pancreas of cohousing experiment were shown in (g) and (h), respectively. Differences of data in two groups were assessed by unpaired, two-tailed t test. Differences of data in more than two groups were assessed by ordinary one-way ANOVA. Exact p levels were all provided. Scale bars, 200 and 50 μm, respectively. ABX, antibiotic cocktail; FMT, fecal microbiota transplantation; Hpa-Tg, heparanase- X transgenic; Cn, caerulein; CoHo, cohoused. SiHo, housed singly; SW, sterile water; WT, wild-type. Supplemental Figure 11. Alpha rarefaction curves of all 16S rRNA sequencing analyses. Alpha rarefaction curves (Faith pd) in WT and Hpa-Tg groups (a), ABX experiment (b), CoHo WT and CoHo Hpa-Tg groups (c), FMT experiment (d) and the administration of Parabacteroides experiment (e). ABX, antibiotic cocktail; CoHo, cohoused; FMT, fecal microbiota transplantation; Hpa-Tg, heparanase-transgenic; P. distasonis, Parabacteroides distasonis; WT, wild-type. Supplemental Table 1. Schmidt's score system of pancreatic histopathology. Supplemental Table 2. Primers for qRT-PCR detection (SYBR Green). Supplemental Table 3. Primers for qRT-PCR detection (Taqman).
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- 2022
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7. Lithium carbonate alleviates colon inflammation through modulating gut microbiota and Treg cells in a GPR43-dependent manner
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Huang, Shengjie, primary, Hu, Shiping, additional, Liu, Shuang, additional, Tang, Bo, additional, Liu, Yaojiang, additional, Tang, Li, additional, Lei, Yuanyuan, additional, Zhong, Li, additional, Yang, Shiming, additional, and He, Song, additional
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- 2022
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8. Helicobacter pylori-Induced Heparanase Promotes H. pylori Colonization and Gastritis
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Tang, Li, primary, Tang, Bo, additional, Lei, Yuanyuan, additional, Yang, Min, additional, Wang, Sumin, additional, Hu, Shiping, additional, Xie, Zhuo, additional, Liu, Yaojiang, additional, Vlodavsky, Israel, additional, and Yang, Shiming, additional
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- 2021
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9. TLR4 regulates RORγt+ regulatory T-cell responses and susceptibility to colon inflammation through interaction with Akkermansia muciniphila.
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Liu, Yaojiang, Yang, Min, Tang, Li, Wang, Fengchao, Huang, Shengjie, Liu, Shuang, Lei, Yuanyuan, Wang, Sumin, Xie, Zhuo, Wang, Wei, Zhao, Xiaoyan, Tang, Bo, and Yang, Shiming
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INFLAMMATORY bowel diseases ,TOLL-like receptors ,FECAL microbiota transplantation ,MICROBIAL ecology ,BONE marrow transplantation ,INTESTINAL mucosa ,HOMEOSTASIS - Abstract
Background: Well-balanced interactions between gut microbiota and the immune system are essential to prevent chronic intestinal inflammation, as observed in inflammatory bowel diseases (IBD). Toll-like receptor 4 (TLR4) functions as a sensor mediating the crosstalk between the intestinal commensal microbiome and host immunity, but the influence of TLR4 on the shaping of intestinal microbiota and immune responses during colon inflammation remains poorly characterized. We investigated whether the different susceptibilities to colitis between wild-type (WT) and TLR4
−/− mice were gut microbiota-dependent and aimed to identify the potential immunity modulation mechanism. Methods: We performed antibiotic depletion of the microbiota, cohousing experiments, and faecal microbiota transplantation (FMT) in WT and TLR4−/− mice to assess the influence of TLR4 on intestinal microbial ecology. 16S rRNA sequencing was performed to dissect microbial discrepancies, and dysbiosis-associated immune perturbation was investigated by flow cytometry. Akkermansia muciniphila (A. muciniphila)-mediated immune modulation was confirmed through the T-cell transfer colitis model and bone marrow chimaera construction. Results: TLR4−/− mice experienced enhanced susceptibility to DSS-induced colitis. 16S rRNA sequencing showed notable discrepancy in the gut microbiota between WT and TLR4−/− mice. In particular, A. muciniphila contributed most to distinguishing the two groups. The T-cell transfer colitis model and bone marrow transplantation (BMT) consistently demonstrated that A. muciniphila ameliorated colitis by upregulating RORγt+ Treg cell-mediated immune responses. Mucosal biopsies from human manifested parallel outcomes with colon tissue from WT mice, as evidenced by the positive correlation between TLR4 expression and intestinal A. muciniphila colonization during homeostasis. Conclusions: Our results demonstrate a novel protective role of TLR4 against intestinal inflammation, wherein it can modulate A. muciniphila-associated immune responses. These findings provide a new perspective on host-commensal symbiosis, which may be beneficial for developing potential therapeutic strategies. CehHU1DpMuC43wfy6GXbFM Video abstract. [ABSTRACT FROM AUTHOR]- Published
- 2022
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10. Feasibility of Endoscopic Submucosal Dissection for Early Esophageal Squamous Cell Carcinoma with Relative Indications
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Liu, Yaojiang, primary, Qian, Dan, additional, Tang, Bo, additional, Fan, Chaoqiang, additional, Yu, Jin, additional, Lin, Hui, additional, Bai, Jianying, additional, and Zhao, Xiaoyan, additional
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- 2020
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11. Lithium Carbonate Treatment Alleviates Gut Inflammation Through Activating Treg Cell Responses in a Microbiota-Dependent Manner
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Huang, Shengjie, primary, Tang, Bo, additional, Tang, Li, additional, Liu, Yaojiang, additional, Liu, Shuang, additional, Lei, Yuanyuan, additional, Hu, Shiping, additional, Zhong, Li, additional, Yang, Shiming, additional, and He, Song, additional
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- 2020
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12. Feasibility of Endoscopic Submucosal Dissection for Early Esophageal Squamous Cell Carcinoma with Relative Indications.
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Liu, Yaojiang, Qian, Dan, Tang, Bo, Fan, Chaoqiang, Yu, Jin, Lin, Hui, Bai, Jianying, and Zhao, Xiaoyan
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SQUAMOUS cell carcinoma , *TREATMENT effectiveness , *DISSECTION , *NECK dissection - Abstract
Backgrounds: Endoscopic submucosal dissection (ESD) has been widely performed in the treatment of early esophageal squamous cell carcinoma (ESCC). Few studies have compared the long-term outcomes of esophageal ESD based on absolute indications and relative indications. The aim of the current study was to investigate the safety and efficacy of ESD for early ESCC with relative indications. Methods: 297 patients with early ESCC who underwent ESD were retrospectively analyzed. They were divided into 3 groups: group A, the absolute indications group; group B, the relative indications without additional treatment after ESD group; and group C, the relative indications with additional treatment after ESD group. The baseline characteristics, therapeutic efficacy, complications, prognosis outcomes, and follow-up data were evaluated. Results: During the median follow-up period of 51.0 months (range 6–101 months), the incidence of local recurrence in groups A, B, and C was 1.63% (3/184), 4.23% (3/71), and 0 (0/42), respectively (p = 0.253). The 5-year overall survival rates were 97.83% (95% CI: 95.69–99.95%) in group A, 95.77% (95% CI: 90.95–100.00%) in group B, and 97.62% (95% CI: 92.81–100.00%) in group C with no significant differences among these 3 groups. Conclusions: ESD is a feasible and effective treatment for early ESCC with relative indications. Under the premise of sufficient preoperative assessment and scheduled postoperative endoscopic surveillance, additional treatment might not be necessary for patients with relative indications after ESD procedures. [ABSTRACT FROM AUTHOR]
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- 2021
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