麻黄中生物碱类有效成分的非水毛细管电泳含量测定

目的 利用非水毛细管电泳(NACE)法对麻黄中各生物碱类有效成分进行含量测定，并比较不同提取方法中各组份含量差异。方法 采用50mmol／L醋酸铵的甲醇溶液，未加入任何其他添加剂，检测波长为210nm。结果 各组份在8min内达基线分离。伪麻黄碱在9．8～147．0μg／mL，去甲基麻黄碱在6．8～102．0μg／mL，麻黄碱在9．4～141．0μg／mL，去甲基伪麻黄碱在4．8～72．0μg／mL，甲基麻黄碱在6．8～102．0μg／mL分别有良好的线性关系。各麻黄碱类回收率在95．0％～100．4％。结论 为麻黄中各生物碱类有效成分的含量测定提供了一种快速、准确和灵敏的测定方法。     

电泳法检测尿液中海洋硫酸多糖聚甘古酯原型物

目的 :建立检测尿液中海洋硫酸多糖类物质聚甘古酯 (911)的电泳方法 ,并用于药代动力学研究。方法 :以氯化十六烷基吡啶 (cetylpyridiniumchloride ,CPC)沉淀法提取尿液中 911,醋酸锌和醋酸钡两步电泳检测尿液中 911,同时测定回收率、电泳测定的检测限。结果 :实验证明该电泳法可以用于检测尿样中的 911原型物 ,911在尿液中的回收率约为 70 % ;水样中 911的检测限为 10 0 μg·L- 1,尿液中检测限为 2 5 0 μg·L- 1,超滤尿中检测限为 5 0 0 μg·L- 1,大鼠口服给药后可以从其尿液中检测到 911原型物。结论 :该电泳法是检测尿液中 911稳定、灵敏的方法     

咳特灵胶囊中马来酸氯苯那敏的高效毛细管电泳-电导法测定

建立了咳特灵胶囊中马来酸氯苯那敏含量的高效毛细管电泳 -电导测定法。采用未涂层弹性融硅石英毛细管柱 (4 0 cm× 75 μm) ,1× 10 -3 mol/L Na2 HPO4溶液为电泳介质 ,重力方式进样 ,室温下 15 k V恒压电泳分离 ,电导检测。马来酸氯苯那敏在 9.8～ 117.6μg/ml浓度范围内线性关系良好 ,平均回收率 96.8% ,RSD为 1.9%。     

菲啰啉对不同氧化剂和多柔比星所致CHL细胞DNA链断裂的影响

目的 为了研究菲啰啉对2种氧化剂和抗癌药多柔比星诱发细胞DNA损伤的影响, 并初步探讨其损伤机制。方法 用不同浓度菲啰啉预处理CHL细胞30 min, 再分别加入3种不同染毒受试物,共同培养一定时间(0.3 mmol·L^-1重铬酸钾：105 min； 0.5 μmol·L^-1多柔比星：5 min； 0.4 mmol·L^-1过氧化氢(H₂O₂)：25 min)后, 用碱性单细胞凝胶电泳方法(ASCGE)测定DNA链断裂情况, 并同时以菲啰啉与二甲亚砜(DMSO，0.33 mol·L^-1)比较对H₂O₂致DNA损伤中·OH的产生和清除。结果 3种染毒受试物均可明显引起CHL细胞DNA链断裂；而当3 μmol·L^-1菲啰啉预处理后, 可使重铬酸钾、H₂O₂所致DNA迁移长度和细胞拖尾率明显降低, 并超过DMSO降低H₂O₂的损伤作用, 当菲啰林浓度升至12 μmol·L^-1时, 可完全消除这两种因素所致的DNA链断裂损伤；10 μmol·L^-1菲啰啉可抑制多柔比星所致DNA损伤, 但浓度直至60 μmol·L^-1仍不能完全消除多柔比星的损伤作用。结论 菲啰啉对2种氧化剂和多柔比星所致DNA损伤均有不同程度的防护作用,同时提示重铬酸钾和H₂O₂所致的DNA损伤主要与需过渡金属离子参与的·OH产生有关, 而多柔比星所致损伤仅部分与此有关。     

磺胺类药物的毛细管高效液相色谱与电色谱研究

目的 研究毛细管高效液相色谱(μ-HPLC)和毛细管电色谱(CEC)分离磺胺类药物,建立药物微分离分析方法。方法 用ODS柱为固定相,甲醇和2 mmol·L^-1磷酸缓冲液（pH 3.0～7.0）为流动相,电压为0～-15 kV,流速为10 μL·min^-1,紫外检测波长254 nm。结果μ-HPLC在甲醇-2 mmol·L^-1磷酸缓冲液（30∶70）,pH 3.0时5种磺胺类药物实现基线分离;CEC在电压为-5 kV,甲醇-2 mmol·L^-1磷酸缓冲液（30∶70）,pH 5.0时5种磺胺类药物实现基线分离。结论电渗流随甲醇含量、缓冲液浓度增加而下降,随pH值、电压的增加而增加;溶质的保留值（k）随甲醇含量、缓冲液浓度、电压的增加而下降,随电压增加下降明显的是TMP,随pH值变化较复杂。在相同条件下对5种磺胺类药物的分离,μ-HPLC需67 min,CEC只需25 min,后者更适合于磺胺类药物的快速分离分析。     

水和非水毛细管电泳-电导检测法分离测定水杨酸类药物

目的建立水和非水毛细管电泳-电导法分离水杨酸类药物。方法用未涂层石英毛细管柱(55 cm×50 μm),以10 mmol·L^-1 Tris-30 mmol·L^-1 H₃BO₃(pH 8.0)为运行缓冲液,分离电压为24 kV,进样时间10 s,电导检测法。结果在非水实验条件下,水杨酸(SA)、乙酰水杨酸(ASA)和磺基水杨酸(SSA)得到很好的分离。SA,ASA和SSA的线性范围分别为0.05～100 mg·L^-1,5.0～250 mg·L^-1,0.08～100 mg·L^-1,r均大于0.995。结论应用于阿斯匹林制剂中水杨酸和乙酰水杨酸含量的测定,结果令人满意。与水介质相比,乙醇介质具有更高的灵敏度和分离效率。     

高效毛细管电泳测定血管紧张素转化酶抑制剂captopril的活性

目的建立高效毛细管电泳测定血管紧张素转化酶抑制剂captopril抑制活性的方法。方法用紫外分光光度计确定了马尿酸的特征吸收波长为228 nm。高效毛细管电泳的条件：熔融石英毛细柱，电泳缓冲液为pH 8.3的50 mmol·L^-1磷酸缓冲液，进样压力4.8 kPa，进样时间3 s，分离电压20 kV，检测波长228 nm。结果在7 min内使反应物和生成物完全分离，标定了captopril的IC₅₀值为0.019　μmol·L^-1，经过酶反应动力学判断captopril为竞争性抑制剂。结论该方法准确、简便、快速，可用于captopril抑制活性的分析。     

The CEC behaviour of several synthetic peptides related to the activin βA–βD subunits

Abstract: The resolution of several structurally related synthetic peptides, derived from the loop 3 region of the activin β_A–β_D subunits, has been studied using capillary electrochromatography (CEC) with Hypersil n‐octadecylsilica as the sorbent. The results confirm that the CEC migration of these peptides can be varied in a charge‐state‐specific manner as the properties of the background electrolyte, such as pH, salt concentration and content of organic modifier, or temperature are systematically changed. Acidic peptides followed similar trends in retention behaviour, which was distinctly different to that shown by more basic peptides. The CEC separation of these peptides with the Hypersil n‐octadecyl‐silica involved distinguishable contributions from both electrophoretic mobility and chromatographic retention. Temperature effects were reflected as variations in both the electro‐osmotic flow and the electrophoretic mobility of the peptides. When the separation forces acting on the peptides were synergistic with the electro‐osmotic flow, as, for example, with the positively charged peptides at a particular pH and buffer electrolyte composition, their retention coefficient, κ_cec, decreased with increasing capillary temperature, whereas when the separation forces worked in opposite directions, as for example with negatively charged peptides, their κ_cec values increased slightly with increasing temperature. Moreover, when the content of organic modifier, acetonitrile, was sufficiently high, e.g. > 40% (v/v) and nonpolar interactions with the Hypersil n‐octadecyl‐silica sorbent were suppressed, mixtures of both the basic and acidic synthetic peptides could be baseline resolved under isocratic conditions by exploiting the mutual processes of electrophoretic mobility and electrostatic interaction. A linear relationship between the ln κ_cec values and the volume fractions, ψ, of the organic modifier over a limited range of ψ‐values, was established for the negatively charged peptides under these isocratic conditions. These findings thus provide useful guidelines in a more general context for the resolution and analysis of structurally related synthetic peptides using CEC methods.     

Utility of peptide–protein affinity complexes in proteomics: identification of interaction partners of a tumor suppressor peptide*

Abstract: We used a N‐biotinylated peptide analog of the C‐terminal domain of the tumor suppressor protein, p21^cip1/waf1 to elucidate peptide/protein interacting partners. The C‐terminal domain of p21^cip1/waf1 protein spanning 141–160 amino acid residues is known to bind PCNA and this interaction is important in many biological processes including cell‐cycle control. This C‐terminal 20‐mer efficiently extracts PCNA in the presence of a variety of N‐ or C‐terminally attached affinity tags. Using difference silver stained 2D gels combined with in‐gel tryptic digests, we identified the difference spots using MALDI‐TOF mass spectrometry‐based peptide mass fingerprinting followed by a database search using profound against NCBIs human nonredundant protein sequence data bank. Identified spots include the p48 subunit of chromatin assembly factor‐1, the heat shock 70 protein analog BiP, calmodulin, nucleolin and a spot similar in size to dimeric PCNA. In contrast, microcapillary ion‐trap LC‐MS/MS analysis of a tryptic digest of entire affinity extracts derived from both control and experimental runs followed by database searches using sequest confirmed the presence of most of the above proteins. This strategy also identified hnRNPA1, HPSP90α, HSP40 and T‐complex protein 1, a protein similar to prothymosin, and a possible allelic variant of the p21^cip1/waf1 protein. The use of N‐biotinylated peptide derived from the C‐terminal domain of p21^cip1/waf1 protein in proteomic analysis exemplified here suggests that peptides obtained from intracellular functional screens could also potentially serve as efficient baits to discover new drug targets.     

盐酸美普他酚的毛细管电泳手性分离

目的建立了一种盐酸美普他酚的毛细管电泳分离方法.方法采用开管式熔融石英毛细管柱,以β-环糊精为手性添加剂可使盐酸美普他酚对映体分离.对β-环糊精类型进行了选择,对缓冲液pH、三甲基-β-环糊精的浓度、有机添加剂等实验条件进行了优化.结果在所确定的条件下盐酸美普他酚对映体达到基线分离.结论所建立的方法方便、快速,可用于该类药物的手性研究.