Salirasib_COA_05699_MedChemExpress

DOI：10.19368/ki.2096-1782.2022.19.155布地奈德与复方异丙托溴铵雾化吸入用于小儿哮喘治疗中的临床研究陈炜，马泽南，邹公民苏州市吴中人民医院儿科，江苏苏州215000[摘要]目的探讨对小儿哮喘采用布地奈德联合复方异丙托溴胺雾化吸入的临床效果。

方法选择苏州市吴中人民医院2018年1月—2021年12月收治的小儿哮喘者80例，以随机数表法分为对照组（n=40，布地奈德联合沙丁胺醇治疗）与观察组（n=40，布地奈德联合复方异丙托溴铵治疗），比较两组临床疗效，典型症状改善时间与住院时间，并检测治疗前后第一秒用力呼气量（FEV1）、FEV1/用力肺活量（FVC）、呼气峰值流速（PEF）评估患儿肺功能，统计不良反应情况评估用药安全性。

结果观察组总有效率较对照组高（97.50% vs 80.00%），差异有统计学意义（χ2=4.507，P<0.05）。

治疗后，观察组咳痰咳嗽、肺哮鸣音、呼吸困难、肺啰音改善时间与住院时间分别为（4.51±1.74）、（3.59±1.36）、（2.75±1.27）、（2.65±1.15）、（4.60±1.52）d，均短于对照组，差异有统计学意义（t=3.789、5.404、6.664、7.356、4.623，P<0.05）。

观察组FEV1、FEV1/FVC、PEF水平分别为（1.72±0.16）L、（82.12±7.80）%、（4.20±0.58）L/s，均高于对照组，差异有统计学意义（t=6.633、3.891、5.811，P< 0.05）。

两组不良反应发生率（5.00% vs 10.00%）差异无统计学意义（χ2=0.180，P>0.05）。

结论对小儿哮喘予以布地奈德联合复方异丙溴铵进行雾化吸入可提升治疗效果，能加快哮喘症状的缓解，且可提高肺功能。

·临床研究·超声引导下微波消融联合贝伐珠单抗治疗晚期结肠癌伴肝转移的临床价值韩小军袁理郭道宁摘要目的探讨超声引导下微波消融联合贝伐珠单抗治疗晚期结肠癌伴肝转移的临床应用价值。

方法选取在我院就诊的102例晚期结肠癌伴肝转移患者，按随机数字表法分为观察组和对照组各51例，对照组采用贝伐珠单抗联合常规化疗治疗，观察组在此基础上采用超声引导下微波消融治疗；比较两组患者治疗后疗效、免疫功能、不良反应及预后情况。

结果治疗后，观察组客观缓解率（ORR）、疾病控制率（DCR）均高于对照组（均P<0.05）；两组CD3+、CD4+、CD8+均较治疗前下降，且观察组CD3+、CD4+、CD4+/CD8+均高于对照组，CD8+低于对照组，差异均有统计学意义（均P<0.05）。

治疗后，两组胃肠道反应、食欲减退、疲劳乏力等不良反应比较差异均无统计学意义；观察组累积无复发生存率及累积总生存率分别为78.77%、57.45%，均高于对照组（49.32%、34.23%），差异均有统计学意义（χ2=10.086、4.536，P=0.001、0.033）。

结论超声引导下微波消融联合贝伐珠单抗能提高晚期结肠癌伴肝转移患者的治疗效果，缓解免疫功能抑制，改善生存状况，具有较好的临床应用价值。

关键词超声引导；微波消融；结肠癌，晚期；肝转移；贝伐珠单抗［中图法分类号］R445.1［文献标识码］AClinical value of ultrasound-guided microwave ablation combined withbevacizumab in the treatment of advanced colonadenocarcinoma with liver metastasisHAN Xiaojun，YUAN Li，GUO DaoningDepartment of Ultrasound Medicine，Mianyang Hospital Affiliated to School of Medicine，University of Electronic Science andTechnology of China，Sichuan621000，ChinaABSTRACT Objective To explore the application clinical value of ultrasound-guided microwave ablation combined with bevacizumab in the treatment of advanced colon adenocarcinoma（COAD）with liver metastasis.Methods A total of102 patients with advanced COAD with liver metastasis treated in our hospital were selected，and divided into the observation group and the control group by random number table method，with51cases in each group.The control group was treated with bevacizumab combined with conventional chemotherapy.On this basis，the observation group was treated with ultrasound-guided microwave thermal ablation.The curative effect，immune function，adverse reactions and prognosis after treatment of the two groups were compared.Results After treatment，the objective remission rate（ORR）and disease control rate（DCR）in the observation group were higher than those in the control group（both P<0.05）.After treatment，the CD3+，CD4+and CD4/CD8+in the observation group were higher than those in the control group，and CD8+was lower than that in the control group，the differences were statistically significant（all P<0.05）.After treatment，there were no statistically significant difference in the incidence rates of adverse reactions such as gastrointestinal reactions，loss of appetite and fatigue between the two groups.The cumulative recurrence-free survival rate and cumulative overall survival rate in observation group were78.77%and57.45% respectively，which were significantly higher than those in control group（49.32%and34.23%），the differences were statistically significant（χ2=10.086，4.536，P=0.001，0.033）.Conclusion Ultrasound-guided microwave ablation combined with作者单位：621000四川省绵阳市，电子科技大学医学院附属绵阳医院绵阳市中心医院超声医学科（韩小军、郭道宁），肿瘤科（袁理）通讯作者：郭道宁，Email：******************结肠癌是常见的消化道肿瘤，近年来其发病率和死亡率均逐渐升高。

血管外膜细胞钙化及其钙化机制研究谭小青,张旭升,樊小容,黄战军摘要 目的:研究经体外诱导钙化建立大鼠血管外膜细胞钙化模型,检测钙化过程中成骨相关指标及凋亡㊁自噬相关蛋白的表达变化,旨在为心血管疾病模型提供更精确的细胞模型,并初步探讨其钙化机制㊂方法:原代提取大鼠胸主动脉外膜纤维细胞,取3~6代细胞使用诱导培养基(高糖DMEM +10%胎牛血清+10mmol/L β-甘油磷酸+0.05mmol/L 抗坏血酸+100mmol/L 地塞米松)诱导钙化,诱导时间为3d ㊁6d ㊁9d ㊁12d ㊁15d ,筛选出诱导细胞钙化的最佳时间㊂对细胞采用茜素红S 染色㊁细胞内钙含量测定和碱性磷酸酶(ALP )活性检测,鉴定是否成功构建钙化模型㊂采用实时定量聚合酶链式反应(PT -PCR )检测成骨相关因子骨形态生成蛋白2(BMP2)和核心结合因子α1(Runx2)的mRNA 含量,蛋白免疫印迹法(Western Blot )检测凋亡蛋白Bax ㊁Bcl -2和自噬相关蛋白微血管相关蛋白(LC3)㊁Beclin -1的表达水平,找出血管外膜细胞钙化的潜在机制㊂结果:当诱导钙化时间为15d 时,血管外膜细胞中主要钙化指标胞内钙含量及ALP 活性上调(P <0.05),茜素红S 染色显示钙化组有明显钙盐沉积㊂血管外膜细胞经钙化诱导后,BMP2和Runx2的mRNA 水平上调,Bax 蛋白水平上调,Bcl -2和Beclin -1蛋白水平下调,LC3-Ⅱ/LC3-Ⅰ比值上调(P <0.05)㊂结论:钙化诱导培养基培养血管外膜细胞15d 可成功构建钙化细胞模型,血管外膜细胞钙化可能与细胞向成骨样表型转化有关,血管外膜细胞钙化过程涉及细胞自噬及凋亡调控㊂关键词 血管外膜细胞;钙化;成骨样表型转化;自噬与凋亡;实验研究d o i :10.12102/j.i s s n .1672-1349.2023.18.010 Calcification of Vascular Adventitial Cells and Its MechanismTAN Xiaoqing,ZHANG Xusheng,FAN Xiaorong,HUANG Zhanjun Longgang District People 's Hospital of Shenzhen,Shenzhen 518172,Guangdong,China Corresponding Author ZHANG Xusheng,E -mail:*****************Abstract Objective:To investigate the mananism of calcification of rat vascular adventitial cells,establish the calcification model of rat vascular adventitial cells,and detect the expression changes of osteogenesis -related indicators,apoptosis,and autophagy -related proteins during the calcification process.It aimed to provide more accurate cell models for cardiovascular disease and initially explore the mechanism of calcification.Methods:Rat thoracic aortic adventitial fibroblasts were extracted from the primary generation,and the 3rd to 6th generation cells were used for induction medium(high glucose DMEM +10%fetal bovine serum +10mmol/L β-glycerophosphate +0.05mmol/L ascorbic acid +100mmol/L dexamethasone)to induce calcification,the induction time was 3,6,9,12,and 15d,and the optimal time for inducing cell calcification was selected.The cells were stained with alizarin red S,detected by intracellular calcium content and alkaline phosphatase(ALP)to identify whether the calcification model was successfully constructed.Real -time quantitative reverse transcription polymerase chain reaction(RT -PCR)was used to detect the mRNA levels of osteogenesis -related factors bone morphogenetic protein(BMP2)and runt -related transcription factor 2(Runx2);Western Blot was used to detect the apoptosis proteins Bax,Bcl -2,the autophagy -related proteins LC -3,and Beclin -1expression level;then the potential mechanism of vascular adventitial cell calcification would be revealed.Results:When calcification was induced for 15days,the intracellular calcium content in the adventitial cells of the main calcification indicators and ALP activity were up -regulated(P <0.05).Alizarin red S staining showed obvious calcium deposits in the calcification group.After calcification was induced in adventitial cells,the mRNA levels of BMP2and Runx2up -regulated,the protein levels of Bax up -regulated,the protein levels of Bcl -2and Beclin -1down -regulated,and the ratio of LC3-Ⅱ/LC3-Ⅰdown -regulated(P <0.05).Conclusion:Adventitial cells cultured in the calcification -inducing medium for 15days could successfully construct a calcified cell model.calcification of adventitial cells might be related to the transformation of cells to an osteoblast -like phenotype.The Calcification process of adventitial cells involved autophagy and apoptosis regulation.Keywords adventitial cells;calcification;osteogenic phenotype transformation;autophagy and apoptosis;experimental study血管钙化常见于动脉粥样硬化㊁血脂异常㊁高血压㊁糖尿病㊁慢性肾病及衰老等人群[1],血管钙化引起血管硬度增加㊁顺应性降低,导致心肌缺血㊁心力衰竭㊁血栓形成等,增加脑卒中㊁心脏病㊁动脉粥样硬化斑块破裂等的风险,被认为是影响心血管疾病的重要因素之一[2-4]㊂目前关于血管内膜㊁中膜和心脏瓣膜钙化的关注和研究相对较多㊂临床工作中发现,血管外膜也可发生钙化,然而调查发现,现阶段对血管外膜钙化的作者单位 深圳市龙岗区人民医院(广东深圳518172)通讯作者 张旭升,E -mail :*****************引用信息 谭小青,张旭升,樊小容,等.血管外膜细胞钙化及其钙化机制研究[J ].中西医结合心脑血管病杂志,2023,21(18):3347-3350.关注较少,因此,需要更多的研究来阐明血管钙化的致病机制㊂最初血管钙化被认为是被动和退行性病变,标志着血管老化,但是越来越多研究表明血管钙化是类似于胚胎骨形成的病理生物学过程[5-6]㊂Bostr öm 等[7-8]研究发现,钙化过程中大鼠血管中膜细胞由原有收缩表型转变成为成骨样细胞表型,原有的收缩标志物如平滑肌肌动蛋白α(α-SMA )等表达减少,并表达核心结合因子α1(Runx2)㊁骨形态生成蛋白2(BMP2)等多种成骨样标志物,从而介导骨基质在血管中沉积㊂细胞凋亡与自噬为2种细胞死亡的方式,与血管钙化息息相关,研究表明,血管中膜细胞在细胞凋亡过程中释放凋亡小体,促进细胞钙化,而细胞自噬通过多种机制调控细胞钙化[9-10]㊂本研究对大鼠血管外膜细胞进行体外诱导钙化,建立大鼠血管外膜细胞钙化模型,并检测钙化过程中成骨相关指标及凋亡㊁自噬相关蛋白的表达变化,旨在为心血管疾病模型提供更精确的细胞模型,并初步探讨其钙化机制㊂1材料与方法1.1试剂胎牛血清(FBS,Gibco),青霉素,链霉素(Gibco,美国),茜素红S溶液,β-甘油磷酸,抗坏血酸,地塞米松(Sigma,美国),抗GAPDH抗体(Bioworld),抗Bcl-2, Bax,Bcelin1和微血管相关蛋白(LC3)抗体(CST),碱性磷酸酶检测试剂盒㊁钙(Ca)检测试剂盒(南京建城生物工程研究所)㊂1.2大鼠血管外膜细胞分离与培养取10只4~6周龄雄性Wistar-Kyoto大鼠(体质量120~180g)胸主动脉分离血管外膜,采用组织黏附法培养㊂使用添加10%胎牛血清的高糖DMEM培养基(Gibco dmem)在37ħ㊁5%二氧化碳条件下培养细胞㊂当细胞增殖至80%~90%融合时,用0.25%胰酶消化传代㊂使用第3代至第6代的细胞进行后续实验㊂1.3体外钙化模型的建立钙化诱导培养基为含10%胎牛血清,10mmol/L β-甘油磷酸钠,0.05mmol/L抗坏血酸和100mmol/L 地塞米松的高糖DMEM培养液㊂将第3代至第6代细胞分为对照组和钙化组,待细胞长至50%融合时,使用钙化诱导培养基培养,每3d更换1次培养基,连续培养15d㊂1.4碱性磷酸酶(ALP)酶活测定细胞钙化诱导后,弃去培养基,1ˑ磷酸缓冲盐溶液(PBS)洗细胞3次,加入裂解液500μL(1%T ritonX-100),冰上裂解40min后,离心,取上清液㊂使用上清液根据试剂盒说明书检测ALP活性及总蛋白含量㊂1.5细胞内钙含量检测细胞钙化诱导后,弃去培养基,1ˑPBS洗细胞3次,每孔加入500μL0.6mol/L的盐酸4ħ脱钙过夜,取上清,根据钙测试试剂盒说明书检测钙含量㊂将脱钙后的细胞用4ħPBS洗3次,每孔加入500μL NaOH/0.1%SDS裂解细胞,取上清,用二喹啉甲酸法(BCA)测定细胞蛋白含量㊂1.6茜素红S染色细胞钙化诱导15d,弃去培养基,1ˑPBS洗细胞3次,加入0.5mL4%多聚甲醛室温固定15min,用双蒸水洗3次,加入1mL0.1%茜素红室温孵育15min,吸去染液,双蒸水洗3次,在倒置显微镜下观察㊂1.7实时定量聚合酶链式反应(RT-PCR)检测细胞钙化诱导后,弃去培养基,1ˑPBS洗细胞3次,使用TaKaRa MiniBEST Universal RNA Extraction Kit提取总RNA,使用PrimeScrip TM RT reagent Kit将所提取的RNA逆转录合成cDNA,以cDNA为模板,通过SYBR Green I嵌合荧光定量RT-PCR检测BMP-2㊁Runx2和GAPDH的表达量㊂引物序列见表1㊂表1引物序列基因方向序列Runx2正向5'-TGGCTTTGGTTTCAGGTTAGG-3'反向5'-TGGAGATGTTGCTCTGTTCG-3' BMP-2正向5'-TGAGGATTAGCAGGTCTTTGC-3'反向5'-TCTCGTTTGTGGAGTGGATG-3' GAPDH正向5'-GGCTGCCCAGAACATCAT-3'反向5'-CGGACACATTGGGGGTAG-3'1.8蛋白免疫印迹法(Western Blot)检测细胞钙化诱导15d,弃去培养基,1ˑPBS洗细胞3次,提取细胞总蛋白㊂使用12%SDS-PAGE胶电泳分离,并转移到聚偏二氟乙烯膜(PVDF)上,封闭后,加入一抗(Bax1ʒ1000,Bcl-21ʒ1000,Beclin11ʒ1000, LC31ʒ1000,GAPDH1:1000)稀释液,4ħ孵育过夜;加入二抗稀释液(1ʒ10000)室温孵育1h后,使用ECL发光试剂盒显影并计算灰度值㊂1.9统计学处理应用SPSS19.0软件进行统计处理,符合正态分布的定量资料以均数ʃ标准差(xʃs)表示,比较采用t检验,以P<0.05为差异有统计学意义㊂2结果2.1大鼠血管外膜细胞可在体外被诱导钙化为验证高磷是否能诱导大鼠血管外膜细胞钙化,使用钙化诱导培养基培养细胞,在不同时间点检测ALP活性和胞内钙含量㊂随着培养时间延长,ALP活性逐渐上升,在培养第12天达到峰值,与对照组比较差异有统计学意义(P<0.05);诱导第3天开始所测得的胞内钙含量与对照组比较升高(P<0.05),ALP 活性和钙含量升高具有时间依赖性㊂详见图1㊁图2㊂诱导15d所测得钙含量最高,因此,后续实验选择的诱导时间为15d㊂对钙化诱导15d的细胞进行茜素红S染色,结果显示,对照组细胞呈长梭形,而钙化组细胞变成菱形㊂茜素红S染色后,钙化组可观察到大量的橘红色钙结节(见图3),而对照组完全没有㊂这也证明大鼠血管外膜细胞可在体外被钙化培养基诱导钙化㊂图1钙化诱导培养基诱导外膜细胞后ALP含量(与0d时比较,*P<0.05)图2钙化诱导培养基诱导外膜细胞后胞内钙含量(与0d时比较,*P<0.05)图3培养15d时细胞经茜素S红染色切片图(ˑ100)2.2血管外膜细胞钙化与细胞向成骨样表型转化有关血管钙化的增加与成骨细胞特异性标志物如BMP2㊁和Runx2的增加有关[11]㊂RT-PCR结果显示,与对照组比较,钙化组的成骨细胞特异性标志物BMP2和Runx2mRNA表达量增加,与对照组比较差异有统计学意义(P<0.05)㊂详见图4㊂图4外膜细胞钙化过程中BMP2和Runx2mRNA表达量(与对照组比较,*P<0.05)2.3血管外膜细胞钙化过程涉及细胞自噬及凋亡调控通过Western Blot检测凋亡和自噬相关蛋白的表达量变化㊂与对照组比较,钙化组促凋亡蛋白Bax表达上调,抑凋亡蛋白Bcl-2表达下调(P<0.05)㊂详见图5㊂钙化组自噬相关蛋白Beclin1表达上调,LC3-Ⅱ/ LC3-Ⅰ比例上调(P<0.05),说明钙化诱导培养后细胞内凋亡水平上调㊁自噬水平升高㊂详见图6㊂图5诱导钙化后促凋亡蛋白及抑凋亡蛋白表达变化图6诱导钙化后凋亡及自噬蛋白Beclin1等表达变化3讨论血管钙化作为心血管疾病病人的并发症之一,其发病率与严重程度逐年增高及加重,是导致心血管疾病病人高死亡率的重要因素㊂血管钙化缺乏有效的治疗药物㊂因此,探究血管钙化发病机制,在分子水平寻找有效的诊断和防治靶点是急需开展的基础研究工作㊂本研究证明,使用10mmol/Lβ-甘油磷酸+0.05 mmol/L抗坏血酸+100mmol/L地塞米松培养外膜细胞即可诱导大鼠血管外膜细胞在体外发生钙化,这是通过茜素红S染色㊁ALP活性检测及胞内钙含量检测结果得以确定的㊂血管钙化过程中,血管中膜细胞向成骨样细胞表型转变并表达相关成骨标志物,从而引起骨基质的沉积,是血管钙化的重要特点及机制[5]㊂本实验所用的血管外膜细胞钙化条件与血管中膜细胞钙化条件一致,说明血管外膜细胞钙化的机制可能与中膜细胞钙化的机制部分一致㊂血管中膜细胞钙化过程中,细胞表达成骨相关的转录因子如Runx2等,进而促进下游表达骨相关蛋白如骨形态发生蛋白BMP2等的表达,从而促使细胞向成骨样细胞主动分化[12-13],本研究也观察到类似的机制㊂通过PT-PCR检测,发现钙化培养基培养大鼠血管外膜细胞15d后,BMP2和Runx2的mRNA表达水平升高㊂本研究通过对钙盐沉积与成骨样细胞表型转变2个维度的探讨,证明血管外膜细胞可在体外被诱导钙化,丰富了血管钙化的分型㊂血管钙化的发生机制复杂,涉及多种信号通路,如细胞自噬和凋亡㊁Wnt/β-catenin信号通路激活㊁内质网应激等均参与调控血管钙化的过程㊂自噬作为一种细胞应激的适应性反应,在维持血管结构与功能中十分关键㊂研究表明,血管钙化过程中自噬水平增高[14-15]㊂在体外实验中,高磷可提高大鼠血管中膜细胞的自噬水平,增加细胞内自噬体数量,从而抑制凋亡与钙化[16]㊂还有研究表明,自噬可通过抑制大鼠血管中膜细胞氧化应激,抑制血管内皮细胞的炎症反应,对三酰甘油等脂代谢进行调控,从而减轻血管钙化[17-18]㊂LC3和Beclin1是2种典型的自噬标志物,Western Blot实验结果表明,用钙化培养基诱导大鼠血管外膜细胞15d,LC3-Ⅱ/LC3-Ⅰ比率升高,Beclin1蛋白水平表达升高,说明细胞内自噬水平升高㊂多项研究表明,细胞凋亡参与促进血管钙化的发生,抑制细胞凋亡和抑制钙化[16-17]㊂在对大鼠的体内研究发现,成纤维细胞生长因子21通过内质网应激调控Caspase-12信号通路来减少血管内中膜细胞凋亡,从而抑制血管钙化[18]㊂另外,提高培养基中的Pi 或Ca2+浓度,可诱导细胞质膜形成并释放基质囊泡(如凋亡小体),从而导致细胞外基质钙化,这种基质钙化可能成为血管钙化的成核位点[19]㊂Bax和Bcl-2是2种典型的凋亡和抑制凋亡蛋白,本实验结果证明,利用钙化培养基对血管外膜细胞诱导钙化过程中,细胞内凋亡水平升高㊂同时细胞内自噬水平也升高,这可能是细胞自我调控以对抗钙化的结果㊂本研究证实血管外膜细胞可在体外被诱导钙化,且外膜钙化过程与骨组织钙化过程类似,为主动可调控的过程㊂血管钙化是一个复杂的过程,涉及细胞凋亡和自噬等调控通路,仍需进一步研究㊂参考文献:[1]梁英权,段亚君,韩际宏.血管钙化分子机制研究进展[J].中国动脉硬化杂志,2020,28(11):921-929.[2]NICOLL R,HENEIN M Y.The predictive value of arterial andvalvular calcification for mortality and cardiovascular events[J].Int J Cardiol Heart Vessel,2014,3:1-5.[3]JOHNSON R C,LEOPOLD J A,LOSCALZO J.Vascularcalcification:pathobiological mechanisms and clinical implications[J].Circulation Research,2006,99(10):1044-1059.[4]YAMADA S,GIACHELLI C M.Vascular calcification in CKD-MBD:roles for phosphate,FGF23,and Klotho[J].Bone,2017,100:87-93.[5]LIN M E,CHEN T M,WALLINGFORD M C,et al.Runx2deletion insmooth muscle cells inhibits vascular osteochondrogenesis andcalcification but not atherosclerotic lesion formation[J].Cardiovascular Research,2016,112(2):606-616.[6]DURHAM A L,SPEER M Y,SCATENA M,et al.Role of smoothmuscle cells in vascular calcification:implications in atherosclerosis andarterial stiffness[J].Cardiovascular Research,2018,114(4):590-600.[7]BOSTRÖM K I,RAJAMANNAN N M,TOWLER D A.The regulationof valvular and vascular sclerosis by osteogenic morphogens[J].Circulation Research,2011,109(5):564-577.[8]SPEER M Y,YANG H Y,BRABB T,et al.Smooth muscle cells giverise to osteochondrogenic precursors and chondrocytes incalcifying arteries[J].Circulation Research,2009,104(6):733-741.[9]PROUDFOOT D,SKEPPER J N,HEGYI L,et al.Apoptosisregulates human vascular calcification in vitro:evidence forinitiation of vascular calcification by apoptotic bodies[J].Circulation Research,2000,87(11):1055-1062.[10]AN S J,BOYD R,ZHU M,et al.NADPH oxidase mediatesangiotensin 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[12]LEOPOLD J A.Vascular calcification:mechanisms of vascularsmooth muscle cell calcification[J].Trends in CardiovascularMedicine,2015,25(4):267-274.[13]刘聿秀.高尿酸诱导血管钙化的机制研究[D].青岛:青岛大学,2015.[14]LIU Q,LUO Y,ZHAO Y,et al.Nano-hydroxyapatite acceleratesvascular calcification via lysosome impairment and autophagydysfunction in smooth muscle cells[J].Bioact Mater,2022,8:478-493.[15]LIANG J,HUANG J,HE W,et al.β-Hydroxybutyric Inhibits vascularcalcification via autophagy enhancement in models induced byhigh phosphate[J].Front Cardiovasc Med,2021,8:685748. [16]CICERI P,ELLI F,CAPPELLETTI L,et al.A new in vitro model todelay high phosphate-induced vascular calcification progression[J].Mol Cell Biochem,2015,410(1/2):197-206.[17]BYON C H,JAVED A,DAI Q,et al.Oxidative stress inducesvascular calcification through modulation of the osteogenictranscription factor Runx2by AKT signaling[J].The Journal ofBiological Chemistry,2008,283(22):15319-15327.[18]OUIMET M,FRANKLIN V,MAK E,et al.Autophagy regulatescholesterol efflux from macrophage foam cells via lysosomal acidlipase[J].Cell Metabolism,2011,13(6):655-667.[19]REYNOLDS J L,JOANNIDES A J,SKEPPER J N,et al.Humanvascular smooth muscle cells undergo vesicle-mediatedcalcification in response to changes in extracellular calcium andphosphate concentrations:a potential mechanism for acceleratedvascular calcification in ESRD[J].Journal of the AmericanSociety of Nephrology,2004,15(11):2857-2867.(收稿日期:2022-03-30)(本文编辑王雅洁)。

益生菌对阿尔茨海默病作用的研究进展发布时间：2021-12-14T06:08:15.523Z 来源：《中国结合医学杂志》2021年12期作者：宋鑫萍1,2，李盛钰2，金清1[导读] 阿尔茨海默病已成为威胁全球老年人生命健康的主要疾病之一，患者数量逐年攀升，其护理的经济成本高，给全球经济造成重大挑战。

近年来研究显示，益生菌在适量使用时作为有益于宿主健康的微生物，在防治阿尔茨海默病方面具有积极影响，其作用机制可能通过调节肠道菌群，影响神经免疫系统，调控神经活性物质以及代谢产物，通过肠-脑轴影响该病发生和发展。

宋鑫萍1,2，李盛钰2，金清11.延边大学农学院，吉林延吉 1330022.吉林省农业科学院农产品加工研究所，吉林长春 130033摘要：阿尔茨海默病已成为威胁全球老年人生命健康的主要疾病之一，患者数量逐年攀升，其护理的经济成本高，给全球经济造成重大挑战。

近年来研究显示，益生菌在适量使用时作为有益于宿主健康的微生物，在防治阿尔茨海默病方面具有积极影响，其作用机制可能通过调节肠道菌群，影响神经免疫系统，调控神经活性物质以及代谢产物，通过肠-脑轴影响该病发生和发展。

本文综述了近几年来国内外益生菌对阿尔茨海默病的作用进展，以及其预防和治疗阿尔茨海默病的潜在作用机制。

关键词：益生菌；阿尔茨海默病；肠道菌群；机制Recent Progress in Research on Probiotics Effect on Alzheimer’s DiseaseSONG Xinping1,2，LI Shengyu2，JI Qing1*(1.College of Agricultural, Yanbian University, Yanji 133002，China)(2.Institute of Agro-food Technology, Jilin Academy of Agricultural Sciences, Chanchun 130033, China)Abstract：Alzheimer’s disease has become one of the major diseases threatening the life and health of the global elderly. The number of patients is increasing year by year, and the economic cost of nursing is high, which poses a major challenge to the global economy. In recent years, studies have shown that probiotics, as microorganisms beneficial to the health of the host, have a positive impact on the prevention and treatment of Alzheimer’s disease. Its mechanism may be through regulating intestinal flora, affecting the nervous immune system, regulating the neuroactive substances and metabolites, and affecting the occurrence and development of the disease through thegut- brain axis. This paper reviews the progress of probiotics on Alzheimer’s disease at home and abroad in recent years, as well as its potential mechanism of prevention and treatment.Key words：probiotics; Alzheimer’s disease; gut microbiota; mechanism阿尔茨海默病（Alzheimer’s disease, AD），系中枢神经系统退行性疾病，属于老年期痴呆常见类型，临床特征主要包括：记忆力减退、认知功能障碍、行为改变、焦虑和抑郁等。

Mild,efficient and rapid O-debenzylation of ortho -substituted phenols with trifluoroacetic acidSteven Fletcher *,Patrick T.Gunning *Department of Chemistry,University of Toronto,Mississauga,ON L5L 1C6,Canadaa r t i c l e i n f o Article history:Received 21May 2008Revised 2June 2008Accepted 4June 2008Available online 10June 2008a b s t r a c tThe mild and efficient deblocking of aryl benzyl ethers with TFA is reported.Cleavage was fastest with ortho -electron-withdrawing groups on the phenolic ring,which we have attributed to a proton chelation effect,furnishing the deprotected phenols in excellent yields.The corresponding para -methoxybenzyl,allyl and iso -propyl ethers were also cleanly removed under these conditions.In addition,the selective aryl benzyl ether debenzylation in the presence of benzyl ester,Cbz carbamate and Boc carbamate func-tionalities was also observed.Crown Copyright Ó2008Published by Elsevier Ltd.All rights reserved.Phosphotyrosines feature in the design of inhibitors of several protein targets,including protein tyrosine phosphatase 1B (PTP1B).1However,these moieties suffer from hydrolytic lability to cellular phosphatases and poor cell penetration due to the asso-ciated dianionic charge.1To address these issues,salicylic acid derivatives (and closely-related analogues)have become popular mimetics of phosphotyrosine in small molecule inhibitors.1–5Turk-son et al.have recently reported on NSC74859(1),a potent,sali-cylic acid-based inhibitor of the oncogenic protein Stat3.6As part of our structure–activity relationship (SAR)studies on NSC74859(1),we sought to debenzylate both the phenol ether and benzoate ester in 2without reducing the aryl-bromide bond,a common undesired side reaction that occurs with hydrogen gas and Pd/C catalyst.7O -Benzyl-protected phenols are known to undergo debenzyla-tion with trifluoroacetic acid (TFA)8by an initial protonation of the weakly basic phenol oxygen,although additives such as strongorganic acids (e.g.,trifluoromethanesulfonic acid 9)or a large excess of nucleophilic scavenger (e.g.,thioanisole,which accelerates the reaction by a ‘push–pull’mechanism 10)are typically required.Re-cent work by Ploypradith et al.describes the mild deprotection of aromatic ethers with sub-stoichiometric para -toluenesulfonic acid on solid support.11In a special case,O -benzyl-protected ortho -nitrophenol was cleaved rapidly (<5min)with neat TFA,12which we considered was due to the ability of the substrate to chelate a proton since the structurally-similar ortho -hydroxybenzoates (salicylates)are well-known to chelate copper ions and iron ions.We reasoned that 2(and indeed 3)may similarly undergo acceler-ated debenzylation with TFA.In fact,as shown in Scheme 1,treat-ment of 2(or 3)with a 1:1mixture of TFA/toluene led to rapid debenzylation (5min for 2;1h for 3)in 91%yield for 2(or 85%yield for 3).In this Letter,we will explore the structural require-ments of the phenol component that increase the lability of the O -benzyl phenol ether bond in the presence of TFA.In addition,0040-4039/$-see front matter Crown Copyright Ó2008Published by Elsevier Ltd.All rights reserved.*Tel.:+19058285354;fax:+19058285425(P.T.G.).E-mail addresses:steven.fletcher@utoronto.ca (S.Fletcher),patrick.gunning@utoronto.ca (P.T.Gunning).Tetrahedron Letters 49(2008)4817–4819Contents lists available at ScienceDirectTetrahedron Lettersj o ur na l h om e pa ge :w w w.e ls e v ie r.c o m/lo c at e/t et l e twe will explore the selectivity of this mild debenzylation tech-nique with respect to other aromatic ethers and examine the sta-bility of other benzyl-based protecting groups to these reaction conditions.A series of 12O -benzyl-protected phenols was prepared by standard procedures in near quantitative yields.Each of these ethers was then deprotected with a 1:1mixture of TFA/toluene;our observations are summarized in Table 1.In certain cases,O ?C benzyl migration (Friedel–Crafts reaction)by-products (610%)were occasionally inseparable from the product by silica gel flash column chromatography.Thus,several benzyl cation cap-tors were investigated for their abilities to improve yields and puri-ties of the debenzylation reactions.Three to ten equivalents of p -cresol,anisole and triethylsilane were employed,but these exerted little effects on reducing by-product formation.Conversely,we dis-covered that including the more nucleophilic scavenger thioanisole as an additive to the co-solvent toluene typically,after silica gel flash column chromatography,furnished products in P 95%puri-ties (and higher yields),as judged by 1H NMR.Nevertheless,we envisaged any Friedel–Crafts impurities would be more readily separable on slightly more complex aryl benzyl ethers,as we ob-served with the substrates shown in Scheme 1and Tables 3and 4(>99%purities (1H NMR)in each case).Whilst likely leading to even higher yields and purities,large excesses of thioanisole (50equiv)are also known to accelerate TFA-mediated debenzyla-tion.10However,in our hands just 3equiv of thioanisole had little effect on the rate of debenzylation,allowing us to attribute the deprotection rates solely to the structure of the phenol.Electron-rich phenols are good scavengers of benzyl cations,13and since preliminary experiments with electron-rich phenols generated complex mixtures of Friedel–Crafts by-products under these deb-enzylation conditions,we chose to investigate only electron-poor phenols in this study.O -Benzyl-protected phenols with p -ortho -electron-withdraw-ing groups (6a ,6b ,6d ,6f )were swiftly (several in less than 3h cf.24h for unsubstituted phenol 6l )and cleanly debenzylated,with less than 5%of the undesired C-benzylated phenol by-prod-ucts.In contrast,meta -and para -electron-withdrawing groups slo-wed down the debenzylation (e.g.,entries 6g and 6h ),relative to the control compound 6l ,which itself could only be obtained in moderate purity by this method.The r -withdrawing (and p -donating)bromophenols 6i –k were insufficiently deactivated to benzyl cation scavenging and were contaminated with several by-products.Importantly,n -butyl benzyl ether 8was unaffected by TFA under the reaction conditions,indicating this procedure is selective for aryl benzyl ethers.In addition,the results in Table 1suggest that this procedure is suitable only for phenols substituted with p -electron-withdrawing groups.Since the debenzylation mechanism with TFA proceeds via an initial protonation of the phenol ether oxygen,the more available the ether oxygen lone pairs are,the faster the reaction will be.Hence,the slower reaction times for the phenols bearing meta -and para -electron-withdrawing groups make sense,although this is not true for the ortho -functionalized aryl benzyl ethers.As hypothesized for the bis-benzyl salicylate derivative 2earlier,we considered these ortho -substituted phenols were capable of chelat-ing the acidic hydrogen atom from TFA which therein facilitated the acid-mediated debenzylation via a six-membered cyclic inter-mediate,as proposed in Scheme 2.A similar chelation intermediate has been put forward by Baldwin and Haraldsson to account for the Lewis acid MgBr 2-mediated debenzylation of aromatic benzyl ethers ortho to an aldehyde group.14Accordingly,to test this hypothesis we expanded this series of ortho -substituted aryl benzyl ethers,and the results from their deb-enzylation reactions with TFA are summarized in Table 2.These substrates have been listed in order of increasing approximateTable 1TFA-mediated debenzylation of O -benzyl-protected phenols aTFAtolueneOBnROHR67Substrate RTime (h)b Yield c (%)6a o -CO 2Me,m d -NHAc 5min 936b o -CO 2Me 5min 946c p -CO 2Me 36e 63(85f )6d o -CO 2Bn 5min 936e p -CO 2Bn 36e 58(79f )6f o -NO 23976g m -NO 236e 75(98f )6h p -NO 236e 66(98f )6i o -Br 16—g 6j m -Br 30—g 6k p -Br 36—g 6lH 24—gn -BuOBn (8)—24No reactionaThe reaction was carried out with 6(0.5mmol)in a 1:1mixture of TFA/toluene (5ml)at rt,with 3equiv of thioanisole.bTime taken for all starting material to be consumed.cIsolated yield after silica gel flash column chromatography.dmeta to phenol oxygen AND para to ester.eReaction was slow and incomplete after 3days.fYield based on recovered starting material.gComplex mixture of products.Table 2TFA-mediated debenzylation of O -benzyl-protected,ortho -substituted phenols aTFA tolueneOBnOH67RRSubstrate R p K aH b Time c (h)Yield d (%)Relative rate 6m CO 2NH 2À2248316n CHO À7 3.594e 6.96o CO 2H À8191246b CO 2Me À8.55min 942886d CO 2Bn À8.55min 932886p CN À10>4851(95f )—6f NO 2À1239786i Br —16—g 1.56lH—24—g1aThe reaction was carried out with 6(0.5mmol)in a 1:1mixture of TFA/toluene (5ml)at rt,with 3equiv of thioanisole.bApproximate p K aH of conjugate acid of R group.15cTime taken for all starting material to be consumed.dIsolated yield after silica gel flash column chromatography.eIncluding thioanisole in the deprotection of 6n led to further by-products,thus no scavenger was used and compound 7n could be obtained in only 90%purity.fYield based on recovered starting material.gComplex mixture of products.4818S.Fletcher,P.T.Gunning /Tetrahedron Letters 49(2008)4817–4819acidity of the conjugate acid (decreasing p K aH )of the ortho -elec-tron-withdrawing substituent.15There appears to be an optimal p K aH of around À8.5,that is exhibited by carboxylic esters,which lead to the fastest rate of debenzylation with TFA.In an approxi-mate bell-shaped distribution of reaction rate versus ortho -substi-tuent p K aH —that was interrupted only by ortho -cyanophenol 6p —protonatable groups with p K aH ’s <À8.5or >À8.5were less effective at accelerating the TFA-mediated debenzylation.These data concur with our chelation hypothesis:groups that are too ba-sic bind more strongly to the TFA proton making it less available for sharing with,and ultimately releasing to,the phenol ether oxygen;groups that are weakly basic do not bind the TFA proton as well,leading to reduced chelation and hence less rate enhancement.The anomalous result for ortho -cyanophenol 6p was anticipated since this compound was selected as a negative control.Phenol 6p is geometrically incapable of chelating a proton,because the lin-ear,sp -hybridized nitrile functionality directs its basic nitrogen atom (p K aH %À10)away from the phenol oxygen.As predicted,there was no rate enhancement for the TFA-mediated debenzyla-tion of 6p relative to phenol 6l .In fact,6p was only slowly deben-zylated,at a rate that was comparable with the m -nitro and p -nitro derivatives 6g and 6h ,respectively.We next wanted to investigate the selectivity for the deprotec-tion of the benzyl group over other phenol protecting groups.Accordingly,the benzyl group in salicylate derivative 9a was varied with para -methoxybenzyl (PMB;9b ),methyl (9c ),allyl (9d )and iso -propyl (i -Pr;9e ).These substrates were then debenzylated with a 1:1mixture of TFA/toluene;our findings are reported in Table 3.Any impurities this time were minor and readily separable from the products,eliminating the need for the additive thioanisole.The relative rates at which these protecting groups were removed was para -methoxybenzyl >benzyl >allyl >iso -propyl )methyl,which reflects the stability of the carbocations.These data suggest that in salicylates such as 9,the benzyl phenol protecting group (R =Bn)can be removed with TFA in the presence of the corres-ponding allyl,iso -propyl and methyl ethers.Finally,we explored the selectivity of this mild debenzylation technique over other benzyl-based protecting groups,as shown in Table 4.As the results demonstrate,it was possible to deblock the O -benzyl ether in the presence of a benzyl ester (6d )and in the presence of a benzyl carbamate (11b ),thereby increasing the orthogonality of O -benzyl phenol ethers of salicylate derivatives.Interestingly,it was even possible to cleave the benzyl group in 11c with TFA in the presence of an N -Boc-protected aniline.In summary,we have presented the mild,efficient and rapid deblocking of ortho -substituted aryl benzyl ethers with TFA.Deb-enzylation was fastest when the ortho group was a carboxylic ester,which we have attributed to a proton chelation effect.Other ortho groups that accelerated the TFA-mediated debenzylation included carboxylic acid,aldehyde and nitro.In addition,we have shown that in such ortho -functionalized phenols,benzyl could be removed in the presence of the corresponding iso -propyl,allyl and methyl ethers.Moreover,the benzyl ether could be selectively cleaved in the presence of benzyl ester,Cbz carbamate and Boc carbamate functionalities.AcknowledgementsThe authors gratefully acknowledge financial support for this work from the Canadian Foundation of Innovation and the Univer-sity of Toronto (Connaught Foundation).References and notes1.Zhang,S.;Zhang,Z.-Y.Drug Discov.Today 2007,12,373–381.2.(a)Pei,Z.;Li,X.;Liu,G.;Abad-Zapatero,C.;Lubben,T.;Zhang,T.;Ballaron,S.J.;Hutchins,C.W.;Trevillyana,J.M.;Jirouseka,M.R.Bioorg.Med.Chem.Lett.2003,13,3129–3132;(b)Xin,Z.;Liu,G.;Abad-Zapatero,C.;Pei,Z.;Szczepankiewicz,B.G.;Li,X.;Zhang,T.;Hutchins,C.W.;Hajduk,P.J.;Ballaron,S.J.;Stashko,M.A.;Lubben,T.H.;Trevillyana,J.M.;Jirouseka,M.R.Bioorg.Med.Chem.Lett.2003,13,3947–3950.3.Tautz,L.;Bruckner,S.;Sareth,S.;Alonso,A.;Bogetz,J.;Bottini,N.;Pellecchia,M.;Mustelin,T.J.Biol.Chem.2005,280,9400–9408.4.Shrestha,S.;Bhattarai,B.R.;Chang,K.J.;Leea,K.-H.;Choa,H.Bioorg.Med.Chem.Lett.2007,17,2760–2764.5.Liljebris,C.;Larsen,S.D.;Ogg,D.;Palazuk,B.J.;Bleasdale,J.E.J.Med.Chem.2002,45,1785–1798.6.Siddiquee,K.;Zhang,S.;Guida,W.C.;Blaskovich,M.A.;Greedy,B.;Lawrence,H.R.;Yip,M.L.R.;Jove,R.;Laughlin,M.M.;Lawrence,N.J.;Sebti,S.M.;Turkson,J.Proc.Natl.Acad.Sci.U.S.A.2007,104,7391–7396.7.Pandey,P.N.;Purkayastha,M.L.Synthesis 1982,876–878.8.(a)Greene,T.W.;Wuts,P.G.M.Protective Groups in Organic Synthesis ,3rd ed.;John Wiley &Sons:New York,1999;(b)Kocienski,P.J.Protecting Groups ,3rd ed.;Georg Thieme:Stuttgart,Germany,2003.9.Kiso,Y.;Isawa,H.;Kitagawa,K.;Akita,T.Chem.Pharm.Bull.1978,26,2562–2564.10.Kiso,Y.;Ukawa,K.;Nakamura,S.;Ito,K.;Akita,T.Chem.Pharm.Bull.1980,28,673–676.11.Ploypradith,P.;Cheryklin,P.;Niyomtham,N.;Bertoni,D.R.;Ruchirawat,.Lett.2007,9,2637–2640.12.Marsh,J.P.,Jr.;Goodman,.Chem.1965,30,2491–2492.13.(a)Eberle,A.N.J.Chem.Soc.,Perkin Trans.11986,361–367;(b)Bodanszky,M.;Tolle,J.C.;Deshmane,S.S.;Bodanszky,A.Int.J.Pept.Protein Res.1978,12,57–68.14.Haraldsson,G.G.;Baldwin,J.E.Tetrahedron 1997,53,215–224.15.(a)Ionization Constants of Organic Acids in Solution ;Serjeant,E.P.,Dempsey,B.,Eds.IUPAC Chemical Data Series No.23;Pergamon Press:Oxford,UK,1979;(b)see also:/labs/evans/pdf/evans_pKa_table.pdf .Table 3TFA-mediated deprotection of O-blocked phenol ether derivatives of methyl 4-acetamidosalicylate aTFAtolueneNHAcNHAcORO OMeOH OMeO 910Substrate R Time b (h)Yield c (%)9a Bn 5min 919b PMB 2min 909c Me 480d 9d Allyl 20919ei -Pr3692aThe reaction was carried out with 9(0.5mmol)in a 1:1mixture of TFA/toluene (5ml)at rt.bTime taken for all starting material to be consumed.cIsolated yield after silica gel flash column chromatography.dOnly starting material remained after 48h,at which point the reaction was aborted.Table 4Selectivity investigation into the TFA-mediated debenzylation of aryl benzyl ethers aTFA tolueneOBnOH2Bn2Bn1112RRSubstrate R Yield b (%)6d c H 9311a NHAc 9211b NHCbz 9311c dNHBoc54aThe reaction was carried out with 11(0.5mmol)in a 1:1mixture of TFA/toluene (5ml)at rt for 5min,then all solvents were evaporated.bIsolated yield after silica gel flash column chromatography.cFor compound 6d ,3equiv of thioanisole were also used.dAfter 5min,the reaction mixture was diluted with CH 2Cl 2and then immedi-ately neutralized with 1M NaOH.The organic layer was then separated and evaporated.S.Fletcher,P.T.Gunning /Tetrahedron Letters 49(2008)4817–48194819。

上海应用技术学院研究生课程《高等天然产物化学》试卷2014 / 2015 学年第1 学期课程代码：NX0702013论文题目：乙酰胆碱酯酶抑制剂的研究进展姓名：芮银146061414康满满146061409专业：制药工程学院：化工学院乙酰胆碱酯酶抑制剂的研究进展芮银，陈祎桐，康满满摘要：本文阐述了乙酰胆碱酯酶抑制剂(AChEI)的研究进展，介绍了用于药物治疗的乙酰胆碱酯酶抑制剂的各种来源如植物、微生物等，及其抑制乙酰胆碱的活性物质。

在此基础上，总结了几种现代分析技术，对AChEIs进行筛选，大大加快AD药物资源的开发利用进程。

这些方法主要有基于比色法的Ellman's法及相关的改进方法、薄层显色法、荧光显色法、电喷雾质谱法等。

但是，到目前为止，现代分析技术在AD药物资源中的应用还处在起步阶段。

关键词：乙酰胆碱酯酶抑制剂，筛选方法，薄层显色法，荧光显色法The progress of acetylcholinesteraseinhibitorsRui Yin, Chen Yitong, Kang ManmanAbstract：In this artical, the research elaborates progress of acetylcholinesterase inhibitors (AChEI), and introduces a variety of sources for drug treatment acetylcholinesterase inhibitors such as plants, microorganisms, and its active ingredients. On this basis, the review summarizes several modern analytic techniques such as Ellman's method which based on the colorimetric method, TLC chromogenic method, fluorescent color method, Electrospray ionization mass spectrometry and so on. However, at present, the application of modern analytic techniques in AD drug resources is still in infancy.Key word: Acetylcholinesterase inhibitors, Screening Methods, TLC chromogenic method, Fluorescent color method目录摘要.................................................................................................错误!未定义书签。

专利名称：科罗索酸在制备抗肿瘤药物中的应用专利类型：发明专利
发明人：凌昌全,辛海量,徐燕丰,苏永华,盛佳钰申请号：CN200910057252.7
申请日：20090513
公开号：CN101884636A
公开日：
20101117
专利内容由知识产权出版社提供
摘要：本发明涉及医药技术领域，具体涉及科罗索酸在制备抗肿瘤药物中的应用，辅以药学上可接受的辅料，可制备成各种口服、注射、外用制剂，具有较好的开发应用前景。

本发明人在发现其具有较强的抗肿瘤作用的基础上，还进一步阐明其抗肿瘤作用的机理为由阻滞肿瘤细胞于S期及诱导细胞凋亡介导。

申请人：中国人民解放军第二军医大学
地址：200433 上海市杨浦区翔殷路800号
国籍：CN
代理机构：上海浦一知识产权代理有限公司
代理人：潘诗孟
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专利名称：乌索酸在制备调控肿瘤细胞分裂周期药物中的用途专利类型：发明专利
发明人：陆云华
申请号：CN200810136606.2
申请日：20081224
公开号：CN101444516A
公开日：
20090603
专利内容由知识产权出版社提供
摘要：本发明属于药物化学技术领域。

本发明公开了乌索酸在制备调控肿瘤细胞分裂周期药物中的用途，通过实验表明乌索酸可以改变肺癌、胃癌、肝癌、乳腺癌、白血病细胞的分裂周期，显著抑制肺癌、胃癌、肝癌、乳腺癌、白血病细胞的细胞分裂。

乌索酸可以制备抑制肿瘤细胞分裂的药物。

申请人：宜春学院
地址：336000 江西省宜春市袁州区学府路576号宜春学院
国籍：CN
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专利名称：一种用于治疗胃癌的肿瘤疫苗及其制备方法专利类型：发明专利
发明人：崔长友
申请号：CN201510711700.6
申请日：20151028
公开号：CN105169379A
公开日：
20151223
专利内容由知识产权出版社提供
摘要：本发明公开了一种用于治疗胃癌的肿瘤疫苗及其制备方法，该胃癌疫苗包括胃癌细胞分泌的exosomes小体，所述的胃癌细胞是经过Salpichrolide？U和SAHA联合加药处理
的，Salpichrolide？U和SAHA的摩尔浓度之比为0.8～1.2:1。

本发明创造性地使用Salpichrolide？U和SAHA加药处理胃癌细胞，结果表明，处理后的胃癌细胞分泌的exosomes及其可溶性免疫分子则能显著改善前述的抑制作用。

本发明显著提高了exosomes肿瘤疫苗治疗效果，具有重要的临床应用价值。

申请人：崔长友
地址：210046 江苏省南京市栖霞区仙林大道163号南京大学生命科学学院
国籍：CN
代理机构：长沙星耀专利事务所
代理人：许伯严
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专利名称：一种螺杂环类化合物、其制备方法及应用
专利类型：发明专利
发明人：王倩,张冰宾,石辰,舒思杰,霍国永,向志军,夏广新,吴国胜,梁涛,赵永新,李令文,柯樱
申请号：CN202111305935.7
申请日：20211105
公开号：CN114437096A
公开日：
20220506
专利内容由知识产权出版社提供
摘要：本发明提供了一种螺杂环类化合物、其制备方法及应用。

本发明的螺杂环类化合物如式I所示。

该类化合物对RORγt具有抑制活性，可有效抑制RORγt蛋白受体，从而调控Th17细胞的分化，抑制IL‑17的产生，进而治疗RORγt介导的相关自身免疫类疾病。

申请人：上海医药集团股份有限公司
地址：201203 上海市浦东新区张江路92号
国籍：CN
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