细胞色素c在硒代胱氨酸修饰电极上的直接电化学

采用电化学和接触角实验方法研究了硒代胱氨酸自组装膜修饰金电极(SeCys SAMs/Au)和十六烷基三甲基溴化铵(CTAB)-硒代胱氨酸自组装复合膜修饰金电极(CTAB-SeCys SAMs/Au)的特性. 探讨了细胞色素c(Cyt c)在SeCys SAMs/Au电极和CTAB-SeCys SAMs/Au电极上的电化学行为. 实验证明SeCys可促进Cyt c在电极上的氧化还原反应, 加入CTAB后其与SeCys之间的协同作用可在Cyt c与电极之间形成一个开放的通道, 促进作用更加明显, 且在一定浓度范围内, 随CTAB浓度(1×10^-5-1×10^-4 mol·L^-1)的增大, Cyt c在CTAB-SeCys SAMs/Au电极上的氧化还原电流增大, 在接近临界胶束浓度处出现极大值. 在CTAB-SeCys SAMs/Au电极上Cyt c产生一对氧化还原峰, 其峰电位分别为0.305和0.235 V, 其电化学过程受扩散控制. 光谱实验证实SeCys对Cyt c电化学过程的促进作用是由于SeCys与Cyt c中赖氨酸残基的结合.     

硒代蛋氨酸的电化学行为及其定量分析

本文采用循环伏安法(CV)研究了硒代蛋氨酸(SeMet)在银电极表面的电化学行为。实验发现,在0.03mol/L的硼砂 NaOH(pH9.5)介质中,于+0.30V(vs.SCE)电位下进行吸附,在-0.62V和-0.68V处获得一对氧化还原峰。探讨了SeMet在银电极表面的电极反应机理,并建立其定量分析方法。方法线性范围为2.0×10-11～8.0×10-9mol/L,检出限为4.0×10-12mol/L。该方法用于谷物样品中SeMet含量的测定,结果满意。     

硒代胱氨酸在银电极上的电化学行为及其定量分析

研究了硒代胱氨酸 (SeCys)于0.03mol/L的硼砂 -NaOH( pH9.5)介质中在银电极上的电化学行为 ;实验发现在 -0.62V和 -0.68V(vsSCE)处存在一对氧化还原峰 ,其峰电流与硒代胱氨酸浓度具有良好的线性关系 ,由此建立了SeCys的电分析化学测定方法, (1)循环伏安法 ,其线性范围为8.6×10 -9～1.1×10 -7mol/L,检出限为4.3×10 -10mol/L, (2)二次微分线性扫描伏安法 ,其线性范围为2.2×10 -10～1.0×10 -8mol/L,检出限为8.6×10-11mol/L;该法应用于中药黄芪中SeCys含量的测定 ,结果令人满意 ;该文还探讨了硒代胱氨酸在上述条件下的电极反应机理     

高效液相色谱-电感耦合等离子体质谱（HPLC-ICP-MS）联用测定富硒小麦中硒代氨基酸

为科学补硒和促进富硒小麦的种植推广,建立了高效液相色谱-电感耦合等离子体质谱联用技术(HPLC-ICP-MS)检测富硒小麦中硒代氨基酸的方法。用蛋白酶XIV辅助微波振荡提取富硒小麦中硒代氨基酸,采用C18 分离柱分离,以30.0mmol/L磷酸氢二铵+1.0%甲醇+2.0mmol/L四丁基溴化铵溶液(pH=6.5)为流动相,能在10min内实现5种硒代氨基酸的分离。在高能氦气模式（HEHe）下,用78Se的色谱峰积分面积作为定量依据,5种硒代氨基酸在1.0～200.0μg/L范围内线性相关性良好,检出限在 0.11~0.29μg/L之间。以富硒小麦为基体进行加标回收试验,除硒代胱氨酸（SeCys2）可能不稳定,易分解造成回收率偏低外,其他4种硒代氨基酸的加标回收率在92.34～102.46%之间,相对标准偏差为 1.6 %~4.2 %（n=7）。用该方法测定了农业科技工作者种植推广的富硒小麦,结果发现小麦中的硒赋存形态多为硒代蛋氨酸（SeMet）,此外,小麦中还含有少量硒代胱氨酸（SeCys2）、硒代半胱氨酸（SeCys）、甲基硒代半胱氨酸（MeSeCys）和硒代乙硫氨酸（SeEt)。该方法具有良好的精密度和准确度,适用于富硒小麦中硒代氨基酸的形态分析。     

HPLC-DRC-ICP-MS测定富硒蔬菜中的硒形态

建立了高效液相色谱-动态反应池-电感耦合等离子体质谱(HPLC-DRC-ICP-MS)联用测定硒代胱氨酸(SeCys2)、甲基硒代半光氨酸(MeSeCys)、亚硒酸盐(SeIV)、硒代蛋氨酸(SeMet)和硒酸盐(SeVI)的方法。样品通过胃蛋白酶提取,采用Hamilton PRP X-100色谱柱(250 mm×4.6 mm,10μm),使用5 mmol/L的柠檬酸溶液(pH 4.7)作为流动相,在10 min内可以完全分离5种硒形态。在80Se质量数下,采用甲烷作为DRC反应气,可有效消除40Ar40Ar+对80Se的干扰,提高检测灵敏度。电感耦合等离子体质谱(ICP-MS)检测,各硒形态的线性相关系数均大于0.9990,Se(IV)、Se(VI)、SeMet、SeCys2、MeSeCys的定量限分别为5,10,10,5,5μg/kg,5种硒形态的加标回收率在80.1%～99.2%之间,可满足蔬菜中硒形态定量分析。     

高效液相色谱-氢化物发生-原子荧光光谱法测定富硒大豆中硒代氨基酸的含量

取0.1 g脱脂后富硒大豆样品于离心管中,用5 mL pH 7.5的130 mmol·L^-1三(羟甲基)氨基甲烷-盐酸缓冲液超声振荡30 min,用15 mg链霉蛋白酶于37℃振荡酶解5 h,离心后取上清液,过0.22μm尼龙有机滤膜。滤液中的硒代半胱氨酸(SeCys)、硒代蛋氨酸(SeMet)、甲基硒代半胱氨酸(MeSeCys)在Agela MP-C₁₈色谱柱上分离,以含2%(体积分数)甲醇和0.5 mmol·L^-1四丁基溴化铵的40 mmol·L^-1磷酸氢二铵溶液(pH 7.0)进行等度洗脱,并采用氢化物发生-原子荧光光谱法测定3种硒代氨基酸的含量。结果表明,3种硒代氨基酸在7 min内可以实现基线分离,标准曲线的线性范围均为5～100μg·L^-1,检出限依次为0.086,0.075,0.047 mg·kg^-1。按照标准加入法进行回收试验,回收率为85.5%～103%,测定值的相对标准偏差(n=7)不大于3.0%。方法用于分析富硒大豆中的硒代氨基酸,大...     

微波水解-液相色谱-原子荧光光谱法测定硒蛋白中的硒代氨基酸

针对酶解法测定硒代氨基酸操作复杂,时间长,水解不完全且水解产物不稳定等问题,建立一种微波水解-液相色谱-原子荧光光谱仪测定硒蛋白中硒代氨基酸的方法。样品经HCl(6 mol/L)微波水解后,调节pH值至7.5,采用阴离子色谱柱,pH=6.0的(NH_(4))_(2)HPO_(4)(40 mmol/L)溶液为流动相,流速0.6 mL/min,等度洗脱12 min的条件对硒代胱氨酸(SeCys_(2))、甲基-硒代半胱氨酸(MeSeCys)和硒代蛋氨酸(SeMet)进行分离,用原子荧光光谱仪测定其含量。微波水解条件采用星点设计-响应面法进行优化,优选最佳水解条件为:称样量20 mg,水解温度150℃,水解时间40 min。SeCys_(2)、MeSeCys和SeMet均在0~100 ng浓度范围内呈线性关系,相关系数均大于0.999,检出限分别为0.07、0.03和0.14 mg/kg,RSD分别为5.6%、4.6%、3.7%(n=6)。用来测定硒代氨基酸,耗时短,成本低,水解完全,操作简单,水解产物稳定,能够科学评价硒蛋白中硒代氨基酸的组成,对硒蛋白产品的质量控制和溯源提供了科学方法,值得推广应用。     

高效液相色谱-电感耦合等离子体质谱联用检测食品中的五种硒形态

建立了高效液相色谱-电感耦合等离子体质谱(HPLC-ICP-MS)联用检测硒酸盐(SeVI)、亚硒酸盐(SeIV)、硒代蛋氨酸(SeMet)、硒代胱氨酸(SeCys2)和硒代乙硫氨酸(SeEt)的方法。采用Hamilton PRP X-100色谱柱（250 mm×4.6 mm, 5 μm）,使用5 mmol/L的柠檬酸溶液(pH 4.5)作为流动相,电感耦合等离子体质谱(ICP-MS)检测,在21 min内可以完全分离5种硒形态。各形态硒的线性相关系数均大于0.9995, SeVI、SeIV、SeMet、SeCys2、SeEt的检出限分别为0.4、0.4、5.6、0.9、1.2 μg/L。探讨了不同提取方法的提取效果,鲜蘑菇和猪肉样品加标回收实验表明,对水溶性良好的无机硒和硒代蛋氨酸而言,采用柠檬酸溶液提取的效果非常好,SeIV和SeVI的回收率均在100%左右,SeMet的回收率为85.0%～95.3%;用蛋白酶水解提取,SeCys2和SeEt的回收率为79.9%～91.5%。该方法可完全满足食品中这5种硒形态的准确定量分析。     

液相色谱-双通道原子荧光检测联用法同时测定砷和硒的形态

建立了一种利用高效液相色谱-双通道原子荧光检测联用同时进行砷和硒形态分析的方法。以10 mmol/L NH4H2PO4溶液(pH 5.6)(添加2.5%(体积分数)的甲醇)为流动相,在12 min内同时分离了三价砷(As(III))、一甲基砷(MMA)、二甲基砷(DMA)、五价砷(As(V))、硒代胱氨酸(SeCys)、硒代蛋氨酸(SeMet)和四价硒［Se(IV)］等化合物。As(III)、DMA、MMA、As(V)、SeCys、SeMet和Se(IV)的检出限分别为1,3,2,3,4,18和3 μg/L (进样量为200 μL),5次测定的相对标准偏差为1.9%～6.1%(As 100 μg/L, Se 300 μg/L)。应用该方法对人体尿样及硒酵母片中砷和硒的形态进行了分析,目标物在尿样中的加标回收率为83%～108%,在硒酵母片中的加标回收率为88%～105%。实验结果表明,该方法可用于尿样及药品中砷和硒形态的日常分析。该方法减少了样品的分析时间和试剂用量,降低了工作强度,提高了工作效率。     

离子交换色谱-氢化物发生原子荧光法测定水产品中硒的形态

建立了利用离子交换色谱-原子荧光联用技术同时测定水产品中3种硒形态的方法,研究了仪器的工作条件、载流、KBH4浓度对硒荧光信号值的影响。采用Hamilton PRP X-100色谱柱(250×4.1 mm,10μm),以30 mmol/L NH4H2PO4为流动相,可以在10 min内同时分离、检测了硒代胱氨酸SeCys、硒代蛋氨酸SeMet和Se(Ⅳ)。当3种形态的质量浓度范围为0~80μg/L时,各形态均得到良好的线性关系,线性相关系数均大于0.9990,各形态的检出限分别为SeCys 1.66μg/L,SeMet 0.91μg/L,Se(Ⅳ)1.10μg/L,相对标准偏差RSD均小于5%(n=11)。在最佳条件下,应用该方法测定了水产品中的硒形态,3种硒形态化合物加标回收率在87.3%~102.6%之间。方法可满足水产品中硒形态的定量分析。     

Electrochemical oxidation of selenocystine and selenomethionine

Electrochemical oxidation of selenocystine (SeCys) and selenomethionine (SeMet), on a gold electrode was studied by cyclic voltammetry (CV), rotating disk electrode technique (RDE) and chronocoulometry (CC). In 0.2 mol/L HAc-NaAc (pH = 3.90) supporting electrolyte, anodic peak I potential of SeCys and SeMet was 810 mV and 638 mV, respectively, and this electrode process was diffused controlled. The electrochemical oxidation process of SeCys, in which six electron-transfers were involved, yielded selenocystine selenoxide. The electrochemical oxidation process of SeMet, in which two electron-transfers were involved, yielded selemethionine selenoxide.     

Determination of selenocysteine and selenomethionine in edible animal tissues by 2D size-exclusion reversed-phase HPLC-ICP MS following carbamidomethylation and proteolytic extraction

A method was developed for the simultaneous determination of selenomethionine (SeMet) and selenocysteine (SeCys) in meat (chicken and lamb muscles) and different offal tissues (heart, liver, kidney). The analytical procedure was based on the protein extraction with urea under reducing conditions (dithiothreitol), derivatization of SeCys and SeMet by carbamidomethylation with iodoacetamide (IAM) followed by quantitative proteolysis. The mixture of the derivatized Se-amino acids was purified by size-exclusion liquid chromatography (LC) and analysed by ion-paring reversed-phase HPLC–inductively coupled plasma mass spectroscopy (ICP MS). The quantification of SeCys and SeMet was carried out by the method of standard additions. ⁷⁷SeMet was used to control the SeMet derivatization efficiency and recovery. The method was validated by the determination of the Se mass balance. The Se-amino acids accounted for 91 ± 8% of the total selenium (mean of 95 samples of seven tissues analysed over a period of 18 months). The method was applied to the discrimination of the contribution of selenoproteins (containing SeCys) and other Se-containing proteins (containing SeMet) in tissues of animals during supplementation studies (dose–effect and tolerance).     

Direct amino acid analysis method for speciation of selenoamino acids using high-performance anion-exchange chromatography coupled with integrated pulsed amperometric detection

Speciation analysis of selenomethylcysteine (SeMeCys), selenomethionine (SeMet) and selenocystine (SeCys) has been performed using a direct amino acid analysis method with high-performance anion-exchange chromatography (HPAEC) coupled with integrated pulsed amperometric detection (IPAD). Three selenoamino acids could be baseline-separated from 19 amino acids using gradient elution conditions for amino acids and determined under new six-potential waveform. Detection limits for SeMeCys, SeMet and SeCys were 0.25, 1 and 20 microg/L (25 microL injection, 10 times of the baseline noise), respectively. The relative standard deviations (RSDs) of 200 microg/L SeMeCys, SeMet and SeCys were 3.1, 4.1 and 2.8%, respectively (n=9, 25 microL injection). The proposed method has been applied for determination of selenoamino acids in extracts of garlic and selenious yeast granule samples. No selenoamino acids were found in garlic. Both SeMet and SeCys were detected in selenious yeast tablet with the content of 45 and 129 microg Se/g, respectively. Selenoamino acids standards were spiked in garlic and yeast granule samples and the recovery ranged from 90 to 106%.     

Specific determination of selenoaminoacids in whole milk by 2D size-exclusion-ion-paring reversed phase high-performance liquid chromatography-inductively coupled plasma mass spectrometry (HPLC-ICP MS)

A procedure was developed for the quantitative recovery of selenomethionine (SeMet) and selenocysteine (SeCys) from whole milk. It was based on the protein unfolding, carbamidomethylation of the aminoacid residues using iodoacetamide and proteolysis using Protease XIV. The selenoaminoacids were specifically determined by ion-paring reversed phase HPLC-ICP MS after their isolation from the post-reaction mixture by size-exclusion LC. Se(IV) present in the sample was derivatized as well and was determined along with the selenoaminoacids. The origin and identity of species were identified by the co-elution with the Se(IV), isotopically labelled selenomethionine, and with the synthetic standard of carbamidomethylated selenocysteine. The method development for SeCys was assisted by using glutathione peroxidise as the SeCys standard. SeMet, SeCys and Se(IV) were quantified by the method of standard additions. The mass balance provided a measure of the method validation. The method was applied to monitoring selenium speciation during supplementation of cows (dose-effect study) with Se-rich yeast containing feed and during milk processing.     

Determination of selenomethionine, selenocysteine, and inorganic selenium in eggs by HPLC–inductively coupled plasma mass spectrometry

A method for the simultaneous determination of selenomethionine (SeMet), selenocysteine (SeCys), and selenite [Se(IV)] in chicken eggs was developed. A sample preparation protocol including defatting, protein denaturation, and carbamidomethylation was optimized in order to achieve complete protein digestion and to avoid SeCys losses. Quantification was carried out by reversed-phase HPLC–inductively coupled plasma mass spectrometry (ICP MS) after quantitative isolation of the selenium-containing fraction by size-exclusion liquid chromatography. The detection limits were 0.06, 0.003, and 0.01 μg g⁻¹ (dry weight) for SeCys, Se(IV) and SeMet, respectively, and the precision was 5–10%. The end products of carbamidomethylation of the different selenium species were identified for the first time by electrospray QTOF MS after custom-designed 2D HPLC purification. Differences in selenium speciation in egg yolk and white were highlighted, the yolk containing more SeCys and the white more SeMet. An insight into selenium bioaccessibility in eggs was obtained by digestion with simulated gastric and gastrointestinal juices and size-exclusion HPLC-ICP MS.     

用离子抑制色谱法分析二（2,2,6,6—四甲基—4—哌啶基）马来酸酯合？…

建立了用离子抑制色谱法分析二（２,２,６,６－四甲基－４－哌啶基）马来酸酯合成反应液的方法。平均回收率为９８．８％,相对标准偏差为０．５６％,测量的平均相对偏差不大于５．０％,方法简单,快速,可用于工艺条件的选择和质量检测。     

硒酵母中有机硒及硒代氨基酸含量的测定方法

报道了人工培养硒酵母中有机硒及硒代胱氨酸（ＳｅＣｙｓ）和硒代蛋氨酸（ＳｅＭｅｔ）含量的测定方法。采用透析处理法使硒酵母中的无机硒和有机硒得以分离,并采用催化分光光度法测定了硒酵母中有机硒的含量;采用氨基酸自动分析仪测定了硒酵母中ＳｅＣｙｓ和ＳｅＭｅｔ的含量。