HPLC测定大鼠肠道菌群中辛伐他汀及其代谢物的方法学研究

目的:建立HPLC测定大鼠肠道菌群中辛伐他汀及辛伐他汀酸浓度的方法。方法:取含辛伐他汀或辛伐他汀酸的大鼠肠道菌群孵育液加入含有内标物(异替格瑞洛,浓度为:1×103ng·mL-1)的蛋白沉淀剂沉淀,离心后取上清液进行HPLC分析。色谱条件:Amethyst C18-H色谱柱(4.6 mm×250 mm, 5μm);流动相甲醇(A)-0.1%磷酸溶液(B)(80∶20)。检测波长237 nm,流速0.8 mL·min-1,柱温30℃,进样量50μL。结果:采用甲醇溶液作为蛋白沉淀剂,含药菌液与甲醇溶液比例为1∶2时,在4℃下离心力为15 250 g离心,对辛伐他汀及辛伐他汀酸提取率最高。结论:该方法专属性强、提取率高、精密度好、操作简便,可应用于辛伐他汀相关的药动学研究。

大鼠肠道菌群对ilexsaponin A_(1)体外代谢转化的影响

目的考察大鼠肠道菌群对毛冬青三萜皂苷ilexsaponin A_(1)体外代谢转化的影响。方法采用HPLC-ESI-QTOF-MS/MS法检测ilexsaponin A_(1)体外肠道菌孵育样品,条件为Kromasil 100-5 C_(18)色谱柱(250 mm×4.6 mm,5μm);流动相乙腈(含0.1%甲酸)-0.1%甲酸,梯度洗脱;体积流量1.0 mL/min;柱温30℃;电喷雾离子源(ESI);负离子模式。对代谢产物进行筛查鉴定,结合二级质谱图,推测代谢产物及其可能的生物转化途径。结果鉴定出14个代谢产物(M1~M14),ilexsaponin A_(1)发生了去糖基化、氧化、还原等代谢反应(M1~M2、M4~M5、M7~M8),其脱糖生成的苷元ilexgenin A进一步发生氧化、羟甲基化、还原等生物转化反应(M3、M6、M9~M11、M13~M14)。结论ilexsaponin A_(1)在大鼠肠道菌群中发生代谢转化,该成分在体内发挥药效并不完全以原型物吸收入血,其苷元ilexgenin A或脱糖后的代谢转化物为其可能的药效物质。

大鼠肠道菌群对长梗冬青苷体外代谢的影响

目的:探究体外孵育的大鼠肠道菌群对长梗冬青苷的代谢转化规律。方法:将长梗冬青苷与大鼠肠道菌群在厌氧条件下共孵育,分别于0,4,8,12,24,48 h时取样,经乙酸乙酯萃取后采用HPLC法进行定性和定量分析。结果:在与大鼠肠道菌群共孵育48 h后,90.8%的长梗冬青苷被代谢转化为M_2,M_2与铁冬青酸对照品通过HPLC分析时色谱行为一致,故确定M_2为铁冬青酸。结论:长梗冬青苷可以被体外孵育的大鼠肠道菌群代谢转化为铁冬青酸。

离体大鼠肠道菌群对淫羊藿苷的代谢研究

目的：考察大鼠肠道茵群对淫羊藿苷和淫羊藿次苷Ⅱ的代谢情况。为研究淫羊藿苷的口服吸收机理打下基础。方法：将待测药物与新配制的大鼠肠内容物混悬液在37℃孵化,采用高效液相色谱法同时测定孵化前后溶液中淫羊藿苷和淫羊藿次苷Ⅱ的浓度。结果：淫羊藿苷被肠道菌群迅速代谢成淫羊藿次苷Ⅱ,而淫羊藿次苷Ⅱ不被代谢。结论：研究淫羊藿次苷Ⅱ的吸收和代谢机理对于研究淫羊藿苷的口服吸收机理非常有必要。

苦荞饮食对自发性高血压大鼠肠道菌群的影响

[目的]研究苦荞饮食对自发性高血压大鼠肠道菌群的影响。[方法]将10只自发性高血压大鼠(Spontaneously Hypertensive Rats,SHR)随机分成常规饮食对照组和苦荞饮食组,对照SHR(SHR-C)正常饮食,苦荞饮食组SHR(SHR-TBW)全荞麦饮食,第3、6和12周无菌收集SHR粪便样本,16S rDNA V3-V4区扩增,Hiseq高通量测序后进行比对和分类。[结果]SHR-C和SHR-TBW大鼠肠道菌群结构及组成多样性有显著性的差异。随时间厚壁菌门/拟杆菌门(Firmicutes/Bacteriodetes,F/B)值从0.22增加到1.89;未知不可分类的菌群从16.52%增加到50.65%;Allobaculum、丁酸弧菌属、毛螺菌属和变形菌菌属是SHR-TBW饮食的优势菌群。[结论]苦荞饮食能重构高血压肠道菌群,饮食干预可有效改善血压。

离体大鼠肠道菌群对射干饮片异黄酮苷转化的影响

目的:考查离体大鼠肠道菌群对射干饮片中异黄酮苷代谢转化的影响。方法:将射干饮片与离体大鼠肠道菌群在厌氧条件下孵育24 h,孵育后饮片用水清洗干净并干燥至干,采用HPLC法对射干饮片中射干苷和野鸢尾苷及代谢产物鸢尾黄素和野鸢尾黄素进行定量分析。结果:大鼠肠道菌群对射干饮片中射干苷和野鸢尾苷有显著的代谢转化作用,孵育24 h时有79%射干苷和70%野鸢尾苷被转化,代谢产物分别为鸢尾黄素和野鸢尾黄素。结论:离体大鼠肠道菌群对射干饮片中的异黄酮苷类成分有代谢转化作用,而这种作用显著提高了射干饮片异黄酮苷元的含量。

大鼠肠道菌群对苦丁茶冬青皂苷D体外代谢的影响

目的观察大鼠离体肠道菌群对苦丁茶冬青叶中苦丁茶冬青皂苷D厌氧代谢的影响。方法健康SD大鼠新鲜粪便制备的肠道菌群混悬液与苦丁茶冬青皂苷D体外厌氧培养后,收集代谢产物,采用ACQUITY UPLC BEH C_(18)(2.1 mm×100 mm,1.7μm)色谱柱;流动相水(含0.1%甲酸)-甲醇(含0.1%甲酸),梯度洗脱。应用LTQ-Orbitrap质谱正离子模式分析苦丁茶冬青皂苷D的代谢产物。结果根据精确相对分子质量数据和特征离子碎片,从肠道菌群培养液中检测出4个代谢产物,主要代谢途径是脱糖反应。结论离体培养的大鼠肠道菌群可对苦丁茶冬青皂苷D进行代谢,为进一步研究其体内代谢过程提供了科学依据。

离体大鼠肠道菌对6种皂苷类成分代谢研究

为考察离体大鼠肠道菌群对6种皂苷类成分代谢转化的情况,将6种皂苷类成分单体(三七皂苷R_1,人参皂苷Rg_1,人参皂苷Rg_2,人参皂苷Re,人参皂苷Rd和人参皂苷Rb_1)分别与离体大鼠肠道菌群在厌氧条件下孵育8,24 h,通过乙腈沉淀蛋白和乙酸乙酯萃取处理后,采用LC-Q-TOF-MS/MS对代谢产物进行定性分析。通过比较空白对照样品和加药孵育样品的总离子流以及各个色谱峰的准分子离子和多级碎片离子,分析各皂苷类成分在大鼠粪便中可能的代谢产物。结果发现,大鼠肠道菌群对6种皂苷类成分具有显著的代谢转化作用,三七皂苷R_1主要被代谢为5个产物,代谢途径为三七皂苷R_1→人参皂苷Rg_1→人参皂苷Rh_1和人参皂苷F_1→原人参三醇→脱氢原人参三醇;人参皂苷Rg_1主要被代谢为4个产物,代谢途径为人参皂苷Rg_1→人参皂苷Rh_1和人参皂苷F_1→原人参三醇→脱氢原人参三醇;人参皂苷Rg_2主要被代谢为2个产物,代谢途径为人参皂苷Rg_2→原人参三醇→脱氢原人参三醇;人参皂苷Re主要被代谢为4个产物,代谢途径为人参皂苷Re→人参皂苷Rg_2→人参皂苷F_1→原人参三醇→脱氢原人参三醇;人参皂苷Rd主要被代谢为4个产物,代谢途径为人参皂苷Rd→人参皂苷Rg_3和人参皂苷F_2→人参皂苷Rh_2→原人参二醇;人参皂苷Rb_1主要被代谢为5个产物,分别为人参皂苷Rb_1→人参皂苷Rd→人参皂苷Rg_3和人参皂苷F_2→人参皂苷Rh_2→原人参二醇。综上所述,6种皂苷类单体均能够被离体大鼠肠道菌群代谢,主要的代谢途径为脱糖基和脱氢。

不同植物蛋白质对大鼠肠道菌群的影响

目的:以酪蛋白为参照,观察麦绿素、大豆蛋白和花生蛋白等3种植物蛋白质对生长期大鼠肠道菌群结构的影响。方法:生长期雄性SD大鼠36只,随机分为4组,分别饲喂含20%酪蛋白(酪蛋白组)、14%酪蛋白加6%麦绿素(麦绿素组)、20%大豆蛋白(大豆蛋白组)和20%花生蛋白(花生蛋白组)的人工半合成饲料,28d时连续收集7d的粪便,测干、湿质量,35d后经直肠取粪检测5种肠道常见菌群的数量。结果:3种植物蛋白组平均日排出粪便量均显著高于对照组;花生蛋白组日排出粪便湿重、粪便干重和粪便含水率均显著高于其它3组;花生蛋白组双歧杆菌数量显著增加,肠杆菌和产气荚膜梭菌数量显著减少,B/E值大幅上升。大豆蛋白组肠杆菌和肠球菌数量显著增加,B/E值显著降低。麦绿素组大鼠肠道菌群结构与酪蛋白组无显著差异,不同来源的蛋白质对乳杆菌数量影响不大。结论:花生蛋白对双歧杆菌有增殖效果,对大鼠肠道菌群有很好的调节作用。

环烯醚萜类化合物在阿霉素肾病大鼠肠道菌中的代谢差异研究

目的 以梓醇、京尼平苷、车叶草苷、龙胆苦苷和莫诺苷为代表化合物,考察环烯醚萜类化合物在阿霉素肾病大鼠肠道菌群的代谢产物及代谢途径。方法 通过构建阿霉素肾病模型,在厌氧条件下将5种环烯醚萜单体分别与离体大鼠肠道菌群孵育8,24 h,采用高效液相色谱-四级杆飞行时间质谱(HPLC-Q-TOF-MS)对代谢产物进行定性分析。通过对照品对照、准确分子量、裂解方式等手段,分析推测这5种环烯醚萜在肠道菌的作用下均可发生I相代谢反应,包括水解、氧化、还原、甲基化反应。结果 孵育24 h后,京尼平苷和莫诺苷,其苷元水平相应较高;而梓醇、车叶草苷、龙胆苦苷的原型和苷元均相应较低。京尼平苷、车叶草苷、龙胆苦苷和莫诺苷均检测到含N代谢产物,其水平和孵育时间有关。在该体系中未发现Ⅱ相代谢产物。结论 该结果揭示了5种环烯醚萜类化合物在阿霉素肾病大鼠肠道菌中的代谢差异,为其体内研究及进一步开发提供了依据。

基于肠道菌群代谢的知母皂苷BⅡ体外代谢转化研究

目的通过大鼠肠道菌群体外实验,观察大鼠肠道菌群对知母皂苷BⅡ的代谢转化情况。方法收集大鼠新鲜粪便,将大鼠肠道菌加入厌氧培养液得到肠道菌孵育液,加入知母皂苷BⅡ,在厌氧环境中37℃温孵24 h,经沉淀离心,取上清液,采用高效液相色谱和薄层色谱方法对知母皂苷BⅡ降解情况和代谢成分进行分析。结果知母皂苷BⅡ在大鼠粪便孵育液中很快发生代谢转化,24 h后孵育液中已检测不到知母皂苷BⅡ,能检测出较高浓度的代谢产物。代谢产物经检测为知母皂苷AⅢ。结论离体培养的大鼠肠道菌可对知母皂苷BⅡ进行代谢,初步确定代谢产物为知母皂苷AⅢ。

肠道菌群法研究延胡索、白芷配伍对延胡索乙素代谢的影响

目的:考察大鼠肠道菌群对延胡索总碱(TA)中延胡索乙素(tetrahydropalmatine,TET)的代谢情况及白芷香豆素(coumarin,Cou)和白芷挥发油(volatile oil,VO)两种提取物与TA配伍对延胡索乙素在大鼠体内代谢的影响,探讨元胡、白芷有效组分配伍规律。方法:分别将TA,TA-Cou,TA-VO,TA-Cou-VO 4组药物与新鲜配制的大鼠肠内容物混悬液在37℃孵化,采用HPLC-FLD测定孵化不同时间大鼠肠内容物混悬液中TET的浓度。结果:TA-Cou组明显减缓了TET的降解速度。结论:从代谢的角度证实了元胡白芷配伍的合理性。

A simple taurocholate-induced model of severe acute pancreatitis in rats

AIM: To investigate gut barrier damage and intestinal bacteria translocation in severe acute pancreatitis (SAP), a simple rat model of SAP was induced and studied.METHODS: Pancreatitis was induced by uniformly distributed injection of 3.8% Na taurocholate (1 mL/kg) beneath the pancreatic capsule. Rats in the control group were injected with normal saline in the identical location. RESULTS: Serum amylase, plasma endotoxin, intestinal permeability, and pancreatitis pathology scores were all markedly higher in the pancreatitis group than in the control group (P < 0.01). The bacterial infection rate was signif icantly higher in the SAP group than in the control group (P < 0.01), observed in parallel by both bacterial culture and real-time polymerase chain reaction. Acute damage of the pancreas was observed histologically in SAP rats, showing interstitial edema, leukocyte infiltration, acinar cell necrosis and hemorrhage. The microstructure of the intestinal mucosa of SAP ratsappeared to be destroyed with loose, shortened microvilli and rupture of the intercellular junction, as shown by electron microscopy. CONCLUSION: Significant gut barrier damage and intestinal bacterial translocation were def initely observed with few potential study confounders in this SAP rat model, suggesting that it may be an appropriate animal model for study of gut barrier damage and bacterial translocation in SAP.

Moxibustion inhibits interleukin-12 and tumor necrosis factor alpha and modulates intestinal flora in rat with ulcerative colitis

AIM: To investigate the effect of moxibustion on intestinal flora and release of interleukin-12 (IL-12) and tumor necrosis factor-α (TNF-α) from the colon in rat with ulcerative colitis (UC). METHODS: A rat model of UC was established by local stimulation of the intestine with supernatant from colonic contents harvested from human UC patients. A total of 40 male Sprague-Dawley rats were randomly divided into the following groups: normal (sham), model (UC), herb-partition moxibustion (HPM-treated), and positive control sulfasalazine (SA-treated). Rats treated with HPM received HPM at acupuncture points ST25 and RN6, once a day for 15 min, for a total of 8 d. Rats in the SA group were perfused with SA twice a day for 8 d. The colonic histopathology was observed by hematoxylin-eosin. The levels of intestinal flora, including Bifidobacterium, Lactobacillus, Escherichia coli (E. coli), and Bacteroides fragilis (B. fragilis), were tested by real-time quantitative polymerase chain reaction to detect bacterial 16S rRNA/DNA in order to determine DNA copy numbers of each specific species. Immunohistochemical assays were used to observe the expression of TNF-α and IL-12 in the rat colons. RESULTS: HPM treatment inhibited immunopathology in colonic tissues of UC rats; the general morphological score and the immunopathological score were significantly decreased in the HPM and SA groups compared with the model group [3.5 (2.0-4.0), 3.0 (1.5-3.5) vs 6.0 (5.5-7.0), P < 0.05 for the general morphological score, and 3.00 (2.00-3.50), 3.00 (2.50-3.50) vs 5.00 (4.50-5.50), P < 0.01 for the immunopathological score]. As measured by DNA copy number, we found that Bifidobacterium and Lactobacillus, which are associated with a healthy colon, were significantly higher in the HPM and SA groups than in the model group (1.395 ± 1.339, 1.461 ± 1.152 vs 0.045 ± 0.036, P < 0.01 for Bifidobacterium, and 0.395 ± 0.325, 0.851 ± 0.651 vs 0.0015 ± 0.0014, P < 0.01 for Lactobacillus). On the other hand, E. coli and B. fragilis, which are associated with an inflamed colon, were significantly lower in the HPM and SA groups than in the model group (0.244 ± 0.107, 0.628 ± 0.257 vs 1.691 ± 0.683, P < 0.01 for E. coli, and 0.351 ± 0.181, 0.416 ± 0.329 vs 1.285 ± 1.039, P < 0.01 for B. fragilis). The expression of TNF-α and IL-12 was decreased after HPM and SA treatment as compared to UC model alone (4970.81 ± 959.78, 6635.45 ± 1135.16 vs 12333.81 ± 680.79, P < 0.01 for TNF-α, and 5528.75 ± 1245.72, 7477.38 ± 1259.16 vs 12550.29 ± 1973.30, P < 0.01 for IL-12). CONCLUSION: HPM treatment can regulate intestinal flora and inhibit the expression of TNF-α and IL-12 in the colon tissues of UC rats, indicating that HPM can improve colonic immune response.