人参皂苷的仿生提取研究

通过体外模拟胃肠道环境,建立一种提取人参皂苷的仿生方法.考察了提取条件对配制的仿生胃液和仿生肠液提取人参皂苷浓度的影响.基于高效液相色谱-三重四极杆质谱的多反应监测模式建立定量分析Re,Rg1,20(S)-Rf,Rb1,Ro,Rc,Rb2,Rd等8种人参皂苷的方法,并比较了仿生和超声两种提取方法的人参皂苷提取效率.结果...     

液质联用测定人参与五灵脂、莱菔子配伍的人参皂苷

采用液质联用(HPLC-ESI-MSn)技术,对不同比例的人参、五灵脂和人参、莱菔子的水煎液、沉淀和药渣进行研究,共鉴定了10种人参皂苷,并对这10种人参皂苷配伍前后的变化进行了系统的研究。实验结果表明,在共煎液中,除Ro外,其它皂苷的含量都有所下降。五灵脂或莱菔子的加入对人参皂苷的影响不同,莱菔子影响人参皂苷的溶出,而与五灵脂配伍,部分人参皂苷生成沉淀。     

液质联用中接口离子化新技术

液相色谱-质谱联用(简称液质联用,LC-MS)将色谱的高分离效能与质谱强大的结构测定功能结合,不仅实现了对复杂混合物更准确的定性定量分析,而且简化了样品的前处理过程,使样品分析更简便,在药物分析、食品与环境分析以及生物样品检测等众多领域得到了广泛的应用。作为LC-MS的核心组成部分,液质接口的作用是将LC的液体引入,发生电离,并将生成的离子传输进MS。因此,接口离子化技术的改进直接影响了LC-MS的发展和应用。为了获得更高的灵敏度和更广泛的适用性,研究人员一直致力于离子化技术的研究,以促进分析物的解吸,提高其电离和传输效率,减少基质效应的干扰。本文针对近年来LC-MS接口离子化技术的改进和发展,从离子化原理出发,对接口离子源的构造、影响电离的因素、以及相关的应用进行综述,探讨其优缺点,并对LC-MS接口离子化技术的发展趋势进行了展望。     

液质联用技术分析西洋参花化学成分及H9c2心肌细胞损伤保护作用

高温高压转化前后西洋参花醇提液经正己烷、氯仿、乙酸乙酯和正丁醇分级萃取后共得10种不同极性组分,通过H9c2心肌细胞损伤模型筛选最佳活性组分,并对其进行抗氧化活性的测定以及化学组成分析,利用液质联用技术检测其处理前后的化学成分。结果表明,提取的10种活性组分中,高温高压转化后西洋参花乙酸乙酯萃取层(PEE)能够有效保护H9c2心肌细胞损伤,显著提高细胞存活率并降低细胞ROS水平,与高温高压转化处理前西洋参花乙酸乙酯层(OEE)相较,二者总体皂苷含量相近且均具有较强的抗氧化活性。通过液质分析,初步确定了PEE中所含高温高压转化裂解生成的Rk₁与Rg₅更具良好的心肌细胞损伤保护作用。     

人参二醇类皂苷的生物转化动态及人参稀有皂苷C-K或F2的制备

为了低成本有效制备人参稀有皂苷C-K或F₂, 将A. niger g.848菌酶用于转化含有人参皂苷(质量分数)分别为49.6% Rb₁, 25.9% Rd, 19.3% Rc和5.23% Rb₂的西洋参二醇混合皂苷. 霉菌发酵时, 采用人参二醇皂苷诱导物比人参提取液诱导物的产酶总活力提高10%~15%. 所产的2种诱导酶均能水解人参二醇皂苷的3-O-和20-O-多种糖基, 均为人参皂苷酶Ⅰ型; 但是人参二醇皂苷诱导物所产酶几乎全部转化人参二醇皂苷为C-K, 而人参提取液诱导物所产酶则残留中间产物. 使用黑曲霉人参二醇皂苷诱导所产酶, 在转化西洋参二醇皂苷的动态研究中发现, 酶反应1.5~2.5 h, 主要为产物F₂; 酶反应12 h后, 主要产物为C-K皂苷. 基于此, 40 g人参二醇类皂苷在45 ℃粗酶反应24 h, 经处理得到含C-K质量分数为87%的23 g酶反应产物, C-K转化率达85%(摩尔分数). 用40 g西洋参二醇皂苷在45 ℃粗酶反应2.5 h, 经处理得到含有质量分数为58%的F₂和27%的C-K的26 g酶反应产物, F₂转化率为50.4%, C-K转化率为29.5%. 通过人参二醇皂苷诱导的黑曲霉粗酶转化人参二醇类皂苷动态研究, 建立了C-K转化率为85%, F₂转化率为50%的制备方法, 为大批量制备提供了基础依据.     

N-乙酰氨基葡萄糖水溶液变旋过程的液质联用和旋光研究

研究N-乙酰氨基葡萄糖在水溶液中的变旋行为.通过液质联用及比旋度分析,监测N-乙酰氨基葡萄糖水溶液的变旋情况.得到基于APCI离子源的N-乙酰氨基葡萄糖的多级质谱图,确认其水溶液变旋稳定时间及稳定状态下的差向异构体组成比例,并对N-乙酰氨基葡萄糖HPLC图中的差向异构体色谱峰进行指认.为存在变旋行为的糖及糖苷类化合物的研究提供了准确可行的方法.     

密闭式微波降解法促进常见人参皂苷向稀有人参皂苷转化的规律

采用密闭微波技术对7种常见人参皂苷单体(Rb1,Rb2,Rb3,Rc,Rd,Re和Rg1)进行降解,通过高效液相色谱(HPLC)分析并与相同条件下非微波降解物对比,研究了密闭微波降解人参皂苷的产物在化学结构及组成上的变化规律,以期快速、高效地制备生物活性高的稀有人参皂苷.结果表明,密闭式微波降解法能够使常见人参皂苷基本降解完全,而相同条件下非微波降解法则基本不发生降解.原人参二醇型人参皂苷易水解掉C20位糖,并发生C20位构型变化,生成20(R)-Rg3和20(S)-Rg3,其中20-(R)为优势构型,C20位羟基进一步脱水产生稀有人参皂苷Rk1和Rg5.同时,20(S/R)-Rg3失去C3位的1分子葡萄糖转化为20(S/R)-Rh2,C20位羟基再进一步脱水生成了Rk2和Rh3.此外,人参皂苷C20位所连的糖种类与构型影响了降解产物中各稀有皂苷的组成与比例,但7种原人参二醇型人参皂苷密闭式微波降解产物中Rg5含量均为最高.密闭式微波降解对原三醇型人参皂苷的转化作用与原二醇型人参皂苷具有相似的规律,人参皂苷Re和Rg1的密闭式微波降解产物中Rh4含量均为最高.本文结果进一步说明在相同的降解条件下,密闭式微波降解法的降解效率远高于高温高压非微波降解法,密闭式微波降解可明显促进常见人参皂苷向稀有人参皂苷转化,因此采用密闭微波技术对常见人参皂苷进行降解可以大量获得稀有人参皂苷.     

人参中皂苷类化合物的HPLC-ESI MS研究

利用高效液相色谱与电喷雾质谱联用技术分析鉴定了人参粗提物中人参皂苷类化合物。实验采用反相C18色谱柱,二元线性梯度洗脱（0．2％的醋酸水溶液和乙腈）,分离并检测了人参中的皂苷类化合物：通过与电喷雾质谱的联用和质谱的源内CID技术获得了其中主要色谱峰相对应化合物的相对分子质量和结构信息。     

液质联用仪器分析实验的开发和教学实践

把科研成果引入到仪器分析实验教学中,以二硫甲脒盐酸盐的水解反应为例,介绍了液质联用(HPLC-MS)仪器分析实验的开发。将分离与鉴定结合,通过数据分析与理论结合,使学生运用分析化学的手段解决化学中的问题,不仅培养了学生的综合分析实验能力,同时也激发了学生对科学研究的兴趣。     

人参皂苷与环糊精包合物的研究进展

人参皂苷是从人参、西洋参和三七中提取的主要活性成分,其药效价值相当高,但因其在水中几乎不溶,生物利用度极低,因此极大的限制了其在临床上的应用.环糊精具有独特的性质,其"腔内疏水、腔外亲水",可以选择性的包合人参皂苷等客体分子.环糊精与人参皂苷形成包合物后可以改变客体分子的某些物理化学性能,如水溶性、稳定性以及光学性质等,以此来提高其生物利用度.     

Formation of Humic Colloids in Aqueous Solutions at Different pH Values

Russian Journal of Physical Chemistry A - The effect the mechanochemical modification of humic acids has on their surface-active and acid–base properties is studied. The dependence of the...     

The Effect of Crown Ethers on the Oxidation of Triethylamine by Ferricyanide Ion in Aqueous Solutions at Different pH Values

The effect of benzo-15-crown-5,15-crown-5 and 12-crown-4 on the oxidation of triethylamine by aqueous ferricyanide ion has been studied at pH 4, 7 and 11. The crown ethers retard the normal oxidation process at all pH values, the effect depending on the crown ether concentration. The three crown ethers show the same retardation effect at pH 4 and 7, while at pH 11 the retardation decreases in the order B15C5 > 12C4 > 15C5.     

Determination of Seven Major Ginsenosides in Different Parts of Panax quinquefolius L.(American Ginseng) with Different Ages

Ginsenosides Rg1,Re,Rb1,Rc,Rb2,Rb3,and Rd in different parts of the American ginseng plant were investigated.The extraction process was a pressurized microwave-assisted extraction(PMAE).The seven ginsenosides were separated and determined by high-performance liquid chromatography(HPLC) with a ultraviolet(UV) detector,at 203 nm.The experiment results showed significant variations in the individual ginsenoside contents of the American ginseng in different parts and ages of the plant.The results demonstrated that the leaves,root hairs,and rhizomes of Panax quinquefolius L.contained higher ginsenoside contents,followed by the main roots and stems.The leaves contained dramatically higher levels of ginsenoside Rg1,Rb3,and Rd than the other four parts.Higher contents of Rb1 and Re were present in the main roots,root hairs,and rhizomes.The amount of ginsenoside content in the stems was the lowest.The total content of the seven ginsenosides in main roots,root hairs and rhizomes increased with the age of the plant.In contrast,the ginsenoside contents in the leaves and stems decreased with a year of growth.     

pH值对亮黄水溶液及CTAB胶束溶液共振Raman光谱的影响

我们曾研究了黑皂膜的界面性质,为深入了解pH对偶氮苯类化合物在水溶液中及胶束表面上结构变化的影响,本文选用亮黄(BY)为谱学探针,仔细考察了其水溶液及溴化十六烷基三甲铵(CTAB)胶束溶液的共振Raman光谱,根据谱带指认,描述了由酸碱性导致的BY分子的结构变化,其中包括共振体间平衡和酸碱平衡。     

Determination of Seven Major Ginsenosides in Different Parts of Panax quinquefolius L.（American Ginseng） with Different Ages

Ginsenosides Rgl, Re, Rb1, Rc, Rb2, Rb3, and Rd in different parts of the American ginseng plant were investigated. The extraction process was a pressurized microwave-assisted extraction（PMAE）. The seven ginsenosides were separated and determined by high-performance liquid chromatography（HPLC） with a ultraviolet（UV） detector, at 203 nm. The experiment results showed significant variations in the individual ginsenoside contents of the American ginseng in different parts and ages of the plant. The results demonstrated that the leaves, root hairs, and rhizomes of Panax quinquefolius L. contained higher ginsenoside contents, followed by the main roots and stems. The leaves contained dramatically higher levels of ginsenoside Rg1 Rb3, and Rd than the other four parts. Higher contents of Rb1 and Re were present in the main roots, root hairs, and rhizomes. The amount of ginsenoside content in the stems was the lowest. The total content of the seven ginsenosides in main roots, root hairs and rhizomes increased with the age of the plant. In contrast, the ginsenoside contents in the leaves and stems decreased with a year of growth.     

Identification and Evaluation of a Panel of Ginsenosides from Different Red Ginseng Extracts with Nootropic Effect

Red ginseng has been gradually discovered to have pharmacological and physiological effects. It is well known that the most important bioactive components of ginseng are ginsenosides. The nootropic effect of ginsenosides from nine different red ginseng extracts was evaluated here. Nine groups of mice were perfused with different concentrations of nine red ginseng extracts, respectively, and two groups of mice with distilled water. The nootropic effect of ginsenosides on mice was evaluated with behavior tests and a biochemical indicator study. The extracts were identified by rapid resolution liquid chromatography coupled with quadrupole-time-of-flight mass spectrometry(RRLC-Q-TOF-MS). Furthermore, principal component analysis(PCA) was used to analyze the contribution of chemical components from different ginseng groups. The extracts with the most and the weakest effective nootropic were found. It is notable that extract processing is a very important factor to decide pharmacological functions of ginseng extracts. As a conclusion, the most effective extract method for ginsenosides has been found. A panel of 13 ginsenosides has been screened out as chemical markers with nootropic effect, which include high level ginsenosides Ra0, Rb1, Rc, Rb2, Rb3, Re, Rd, and Rg1 and low level ginsenosides mRb1, mRc, mRb2, mRd, and F2. Low level ginsenosides were first time to be discovered as possible nootropic compounds. This method may shed light on fast discovery of bioactive compounds of medicinal plants with low level compounds.     

Determination of Thiophosphamide in Aqueous Solutions by Cathodic Stripping Voltammetry at a Silver Electrode

It was demonstrated that thiophosphamide can be determined in aqueous solutions by cathodic stripping voltammetry at a silver electrode. The determination conditions were found. The detection limit for thiophosphamide in the Britton buffer solution (pH 11.2) was 5 × 10^–4M (relative standard deviation 5%), and the upper boundary of the analytical range was 3 × 10^–3M (relative standard deviation 1.5%) for a time of electroaccumulation of 5 min.     

Identification of Ginsenosides in Panax quinquefolium by LC-MS

An HPLC-APCI-MS method for the identification of ginsenosides in Panax quinquefolium has been developed. HPLC-APCI-MS could effectively identify ocotillol, protopanaxadiol, protopanaxatriol and oleanane-type ginsenosides in a single MS experiment since [M-H]⁻ ions and characteristic thermal degradation ions of ginsenosides could be simultaneously observed under negative and positive ionization conditions. Nine ocotillol-type ginsenosides including 24(R)-pseudoginsenoside F₁₁ were firstly identified and a total of 30 ginsenosides were identified in Panax quinquefolium. The ginsenoside profile differences between Chinese and American P. quinquefolium were investigated by HPLC-APCI-MS.     

Electrical Conductance Studies in Aqueous Solutions with Glutamic Ions

Conductivity measurements in dilute aqueous solutions of L-glutamic acid, DL-glutamic acid, sodium-L-glutamate and magnesium-L-glutamate, were performed in the 288.15 to 323.15 K temperature range. The limiting molar conductivities of glutamic anions, λ ^o(HGlu⁻,T) and the dissociation constants of glutamic acid, K ₂(T) were derived by the use of the Debye–Hückel equation for the activity coefficients and the Onsager, and Quint and Viallard conductivity equations.     

Electrical Conductance Studies in Aqueous Solutions with Aspartic Ions

Conductivity measurements of dilute aqueous solutions of DL-aspartic acid, potassium-DL-aspartate and magnesium-DL-aspartate were performed in the 288.15 to 323.15 K temperature range. The limiting molar conductances of aspartate anions, λ ⁰(HAsp⁻,T) and the dissociation constants of aspartic acid, K ₂(T) were derived by use of the Debye-Hückel equation for the activity coefficients and the Onsager, and Quint and Viallard conductivity equations.