二阶导数同步荧光光谱法同时直接测定厚朴酚及和厚朴酚

研究了厚朴酚与和厚朴酚及其混合溶液的二阶导数同步荧光光谱,结果两者的二阶导数同步荧光光谱得到完全分离,消除了彼此间的干扰,据此建立了一种二阶导数同步荧光光谱法同时直接测定混合物中厚朴酚与和厚朴酚的新方法.厚朴酚与和厚朴酚的线性范围分别为2.8～500.0 μg/L和4.3～560.0 μg/L;检出限分别为0.84和1.30 μg/L,回收率分别为94.65%～105.58%和95.09%～104.51%; 相对标准偏差均低于4.08%.本方法用于同时直接测定厚朴药材及其提取物中厚朴酚与和厚朴酚含量,结果令人满意.     

高效液相色谱法同时测定血清和尿中厚朴酚与和厚朴酚

 建立了大鼠服用厚朴提取物后的血清中及尿中厚朴酚与和厚朴酚的高效液相色谱测定法。色谱柱填料为SpherisorbC18,流动相为甲醇-水-冰醋酸(体积比为70∶30∶1),UV检测波长为294nm,灵敏度0.005AUFS。样品用甲醇沉淀蛋白,上清液酸化后用乙酸乙酯-乙醚萃取,然后测定其中的药物浓度。血清和尿中的药物浓度与峰面积的线性关系良好,线性范围分别为0.05～2mg/L(厚朴酚)、0.025～1mg/L(和厚朴酚);精密度和重现性良好。血清中厚朴酚与和厚朴酚的平均加样回收率分别为95.6%(RSD=3.85%)和93.8%(RSD=3.95%),尿中分别为96.0%(RSD=3.83%)和94.9%(RSD=3.54%)。     

厚朴酚、和厚朴酚基态与激发态的电离常数及光谱性质差异的研究

通过对比厚朴酚、和厚朴酚的紫外光谱和荧光光谱在pH为-0.3 ～14.7时的变化情况,发现二者的光谱性质存在显著差异,从基态、激发态的电离平衡解释了其原因,探讨了取代基异构对厚朴酚与和厚朴酚基态、激发态电离平衡的影响.实验发现,厚朴酚具有较强的光酸性,水溶液中,当pH＞0时,厚朴酚只显示出1价阴离子HA-·的发射(λem=400 nm),采用荧光滴定法得到厚朴酚基态、激发态的电离常数分别为:pKa1·=0.57,pKa1=7.54、pKa2=14.38.而和厚朴酚的光酸性较厚朴酚小6个pK单位,其吸收和荧光光谱随pH的变化情况较厚朴酚复杂,采用荧光滴定法测定其pKa1·约为6.5.     

溶剂浮选-紫外分光光度法测定厚朴中总厚朴酚

建立了一种测定厚朴中总厚朴酚的新方法,即采用溶剂浮选法分离富集厚朴中的总厚朴酚,用紫外分光光度法测定其含量。考察了浮选溶剂、试液pH、氮气流速、浮选时间及电解质NaCl等因素对浮选效果的影响,优选出最佳浮选条件。采用所述方法对不同产地厚朴样品中总厚朴酚含量进行测定,样品加标回收率为94.9%-100.8%,RSD为2.8-4.1%。     

胶束增稳荧光法同时测定厚朴酚及和厚朴酚同分异构体

作者首次提出在十二烷基硫酸钠（ＳＤＳ）的醋酸－醋酸钠（ｐＨ＝４）缓冲溶液中,利用厚朴主和厚朴的荧光光谱差异性特征,建立了胶束增稳荧光法,可在二者同时存在下,不增加分离手续,达到同时测定的目的。该法具有灵敏度高、检测限低、线性范围宽等特点。本文 此新方法应用于兔血中痕量厚朴酚及和厚朴酚含量的２４ｈ检测,绘制了药时曲线,结果令人满意。     

高速逆流色谱分离制备厚朴的有效成分厚朴酚与和厚朴酚

建立了高速逆流色谱分离制备厚朴的有效成分厚朴酚与和厚朴酚的新方法,溶剂系统为石油醚-乙酸乙酯-甲醇-1％醋酸(5：5：7：3,V／V),上相为固定相,下相为流动相。从100mg厚朴粗提物制得和厚朴酚33．3mg,厚朴酚19．5mg,经高效液相色谱分析,纯度均大于99．5％,其化学结构由^1H NMR和^13C NMR鉴定。     

新型厚朴酚2-甲亚胺衍生物的合成及其生物活性

以厚朴酚为原料,通过Reimer-Tiemann法,在其苯环羟基邻位引入甲酰基后,分别与甘氨酸、谷氨酸、精氨酸及对氨基苯磺酰胺反应合成了4个单取代、1个二取代新型厚朴酚2-甲亚胺衍生物(3a~3d和4),其结构经UV-Vis, ¹H NMR, IR, MS和元素分析表征。生物活性研究结果表明： 2-(N-甘氨酸)-厚朴酚甲亚胺(3a)对成肌细胞的毒性较大;2-［N-(4-氨磺酰苯基)］-厚朴酚甲亚胺(3d)浓度为64 μmol·L^-1时,对CYP2D6和CYP1A2的抑制率分别为42.9%和36.8%。     

厚朴酚-结晶紫-十二烷基硫酸钠体系的共振光散射光谱研究及分析应用

在pH=3.5的柠檬酸钠-盐酸缓冲介质中,阳离子染料结晶紫(CV)对厚朴酚/和厚朴酚与十二烷基硫酸钠( SDS)的共振光散射光谱有协同增强作用.在优化的实验条件下,在共振光散射波长为333 nm处,体系的共振光散射增加值与厚朴酚及和厚朴酚在0.02～5.33 μg/mL范围内呈良好的线性关系,检出限为1.88×10-4...     

流动注射与毛细管电泳联用在中药厚朴分析中的应用研究

对流动注射与毛细管电泳联用（ＦＩ－ＨＰＣＥ）技术在中药厚朴分析中的应用进行了研究。采用了一种新的联用接口，并运用单纯形法优化了缓冲液浓度、ｐＨ值及电压、甲醇含量以取得最佳分离效果，使中药厚朴中的有效成分厚朴酚及和厚朴酚与其他杂质得以基线分离。采用优化的条件对中药厚朴及其部分成药进行了分离分析。采样频率１０个样／ｈ，精密度为２．１％，回收率为９６％￣１０２．９％。     

大体积进样-逆电渗流堆积-毛细管区带电泳分离测定厚朴酚、绿原酸及咖啡酸

运用大体积进样-逆电渗流堆积-毛细管区带电泳分离测定了厚朴酚、绿原酸和咖啡酸。采用未涂层熔融石英毛细管(50 cm×50μm i.d.,有效柱长36 cm)分离;紫外检测波长为220 nm,运行缓冲液为40mmol/L四硼酸钠-20 mmol/L磷酸氢二钠(pH 9.0),分离电压16 kV,电动进样电压-12 kV,进样时间356s时达到最佳的分离效果。在优化条件下,上述3种化合物均在20 min内出峰,峰面积的RSD均小于4%。检出限分别为184.2、36.07、77.99 ng/L。将该法用于清肝利胆口服液中厚朴酚、绿原酸和咖啡酸的分离测定,结果满意。     

Simultaneous determination of honokiol and magnolol in Magnolia officinalis by liquid chromatography with tandem mass spectrometric detection

An optimized high-performance liquid chromatographic method coupled with tandem mass spectrometric detection (LC-MS/MS) was developed for the simultaneous determination of honokiol and magnolol in Magnolia officinalis. Honokiol and magnolol were separated from the extracts using a reversed-phase C(18) column with a mobile phase consisted of acetonitrile and water (75:25, v/v) at a flow-rate of 0.8 mL/min. Selected reaction monitoring (SRM) mode was used for all sample quantification by the precursor-ion/product ion pair m/z 265 --> m/z 224 for honokiol and m/z 265 --> m/z 247 for magnolol. Validation data showed that this method has good linearity (r(2) > 0.995) over the concentration range of 0.0025-0.5 microg/mL for honokiol and magnolol, and both intra- and inter-day variability were acceptable within 15% at the lowest concentrations for this method. This proposed method provides excellent specificity, higher sensitivity and shorter run time than conventional methods and was applied successfully to determine the contents of honokiol and magnolol in M. officinalis.     

Determination of Magnolol and Honokiol by Non-aqueous Capillary Electrophoresis

Introduction Capillaryelectrophoresis(CE),ahighefficiency separationtechnique,hasrapidlydevelopedsince1981[1].Notonlyhavedifferentmodesbeenrepor ted[1—3],butalsosomenon aqueouselectrophoresis media[4]havebeenapplied.Theimportantproperties ofnonaqueousmed…     

Determination of honokiol and magnolol by micro HPLC with electrochemical detection and its application to the distribution analysis in branches and leaves of Magnolia obovata

A simple and sensitive method has been developed for determining honokiol and magnolol in fresh Magnolia obovata (M. obovata) by micro high-performance liquid chromatography with electrochemical detection (microHPLC-ECD). Chromatography was performed using a Capcell Pak C-18 UG 120 microbore octadecylsilica (ODS) column, methanol-water-phosphoric acid (65 : 35 : 0.5, v/v/v), as a mobile phase and applied potential at +0.8 V vs. Ag/AgCl. Peak heights were found linearly related to the amounts of honokiol and magnolol injected from 0.67 pg to 2.0 ng (r>0.999). The detection limits (S/N=3) were 0.13 pg, respectively. Honokiol and magnolol of 0.27 ng were detected with relative standard deviation (RSD) of 0.73 and 1.17% (n=5), respectively. Honokiol and magnolol in Magnolia Bark of the Japanese Pharmacopoeia were extracted with 70% methanol, diluted with a mobile phase, and injected into the microHPLC-ECD for determination. Recoveries of honokiol and magnolol in Magnolia Bark exceeded 98.7% with RSD, less than 0.93% (n=5). Determination of the distributions of honokiol and magnolol in bark, phloem, wood, leaf blades, and petioles of fresh M. obovata were made using weight samples of 40-238 mg. This method is useful to determine honokiol and magnolol in M. obovata, which is a candidate for crude magnolia bark for traditional Japanese herbal medicines.     

High-performance liquid chromatographic method for simultaneous determination of honokiol and magnolol in rat plasma

A high-performance liquid chromatographic (HPLC) method is described for the simultaneous determination of honokiol and magnolol in rat plasma. The plasma was deproteinized with acetonitrile which contained an internal standard (diphenyl) and was separated from the aqueous layer by adding sodium chloride. Honokiol and magnolol are extracted into the acetonitrile layer with high yield, and determined by reversed-phase HPLC and ultraviolet detection. The limits of quantitation for honokiol and magnolol were 13 and 25 ng ml⁻¹ in plasma, respectively, and recovery of both analytes was greater than 93%. The assay was linear from 20 to 200 ng ml⁻¹ for honokiol and from 40 to 400 ng ml⁻¹ for magnolol. Variation over the range of the standard curve was less than 15%. The method was used to determine the concentration-time profiles of honokiol and magnolol in the plasma following rectal administration of Houpo extract at a dose of 245 mg kg⁻¹, equivalent to 13.5, 24.4 mg kg⁻¹ of honokiol and magnolol, respectively.     

Liquid chromatographic determination of honokiol and magnolol in hou po (Magnolia officinalis) as the raw herb and dried aqueous extract

A validated analytical method is described for the determination of honokiol and magnolol in Hou Po (Magnolia officinalis) as the dried raw herb and the commercially prepared dried aqueous extract. The samples were extracted with methanol by the Soxhlet method, and the extract was analyzed by liquid chromatography with photodiode array (LC/PDA) detection with confirmation of analyte identity by negative-ion electrospray ionization tandem mass spectrometry (ESI-MS/MS). A C18 column was used with a menthanol--0.1% aqueous acetic acid gradient mobile phase. Honokiol and magnolol were quantified at 288 nm. With the MS detector, the honokiol precursor ion at m/z 265 was shown to produce ions at m/z 222 and 224. For magnolol, the precursor ion at m/z 265 produced the ions at m/z 247 and 245. Comparable results were obtained for the LC/PDA and LC/ESI-MS/MS methods of quantitation. Six commercially prepared dried aqueous extracts were analyzed. The levels of honokiol and magnolol found in the raw herb were 17.0 and 21.3 mg/g, respectively. The limits of detection for honokiol and magnolol in the raw herb were 0.45 and 0.58 mg/g, respectively, and in the dried aqueous extract, 0.04 and 0.30 mg/g, respectively.     

Evaluation and differentiation of the Betulaceae birch bark species and their bioactive triterpene content using analytical FT-vibrational spectroscopy and GC-MS

A new simple, rapid and sensitive reversed-phase liquid chromatographic method was developed and validated for the simultaneous determination of sulpiride (SUL) and mebeverine Hydrochloride (MEB) in the presence of their impurities and degradation products. The separation of these compounds was achieved within 6 min on a 250 mm, 4.6 mm i.d., 5 m particle size Waters^?-C18 column using isocractic mobile phase containing a mixture of acetonitrile and 0.01 M dihydrogenphosphate buffer (45:55) at pH = 4.0. The analysis was performed at a flow rate of 1.0 mL/min with fluorescence-detection at excitation 300 nm and emission at 365 nm. The concentration-response relationship was linear over a concentration range of 10- 100 ng/mL for both MEB and SUL with a limit of detection 0.73 ng/mL and 0.85 ng/mL for MEB and SUL respectively. The proposed method was successfully applied for the analysis of both MEB and SUL in bulk with average recoveries of 100.22 ± 0.757% and 99.96 ± 0.625% respectively, and in commercial tablets with average recoveries of 100.04 ± 0.93% and 100.03 ± 0.376% for MEB and SUL respectively. The proposed method was successfully applied to the determination of MEB metabolite (veratic acid) in real plasma simultaneously with SUL. The mean% recoveries (n = 3) for both MEB metabolite (veratic acid) and SUL were 100.36 ± 2.92 and 99.06 ± 2.11 for spiked human plasma respectively. For real human plasma, the mean% recoveries (n = 3) were and respectively.     

Isolation and purification of honokiol and magnolol from cortex Magnoliae officinalis by high-speed counter-current chromatography

High-speed counter-current chromatography was used to isolate and purify honokiol and magnolol from cortex Magnoliae Officinalis (Magnolia officinalis Rehd. et Wils.), a plant used in the traditional Chinese medicine. A crude sample, 150 mg, was successfully separated with a two-phase solvent system composed of n-hexane-ethyl acetate-methanol-water (1:0.4:1:0.4, v/v), and the fractions were analyzed by high-performance liquid chromatography. The separation produced 80 and 45 mg of honokiol and magnolol with purities of 99.2 and 98.2%, respectively, in 2.5 h.     

Multiwalled‐carbon‐nanotubes‐based matrix solid‐phase dispersion extraction coupled with high‐performance liquid chromatography for the determination of honokiol and magnolol in Magnoliae Cortex

In this paper, multiwalled‐carbon‐nanotube‐based matrix solid‐phase dispersion coupled to HPLC with diode array detection was used to extract and determine honokiol and magnolol from Magnoliae Cortex. The extraction efficiency of the multiwalled‐carbon‐nanotube‐based matrix solid‐phase dispersion was studied and optimized as a function of the amount of dispersing sorbent, volume of elution solvent, and flow rate of elution solvent, with the aid of response surface methodology. An amount of 0.06 g of carboxyl‐modified multiwalled carbon nanotubes and 1.5 mL of methanol at a flow rate of 1.1 mL/min were selected. The method obtained good linearity (r² > 0.9992) and precision (RSD < 4.7%) for honokiol and magnolol, with limits of detection of 0.045 and 0.087 μg/mL, respectively. The recoveries obtained from analyzing in triplicate spiked samples were determined to be from 90.23 to 101.10% and the RSDs from 3.5 to 4.8%. The proposed method that required less samples and reagents was simpler and faster than Soxhlet and maceration extraction methods. The optimized method was applied for analyzing five real samples collected from different cultivated areas.     

Separation and determination of honokiol and magnolol in Chinese traditional medicines by capillary electrophoresis with the application of response surface methodology and radial basis function neural network

A method for the separation and determination of honokiol and magnolol in Magnolia officinalis and its medicinal preparation is developed by capillary zone electrophoresis and response surface methodology. The concentration of borate, content of organic modifier, and applied voltage are selected as variables. The optimized conditions (i.e., 16 mmol/L sodium tetraborate at pH 10.0, 11% methanol, applied voltage of 25 kV and UV detection at 210 nm) are obtained and successfully applied to the analysis of honokiol and magnolol in Magnolia officinalis and Huoxiang Zhengqi Liquid. Good separation is achieved within 6 min. The limits of detection are 1.67 μg/mL for honokiol and 0.83 μg/mL for magnolol, respectively. In addition, an artificial neural network with "3-7-1" structure based on the ratio of peak resolution to the migration time of the later component (R(s)/t) given by Box-Behnken design is also reported, and the predicted results are in good agreement with the values given by the mathematic software and the experimental results.