作物秸秆降解中稀有机酸的萃取回收

作物秸秆有机降解的研究中,有机酸的回收利用是一个非常重要的环节,本研究采用低沸点的乙酸乙酯和高沸点的磷酸三丁酯（TBP）作萃取剂,对作物秸秆有机酸（乙酸,丙酸）降解中不同浓度的稀有机酸溶液（汽提液和洗涤液）用液－液淬取法回收,结果表明：磷酸三丁酯的萃取能力大于乙酸乙酯,同一萃取剂对丙酸的萃取效果比对乙酸好。     

反相高效液相色谱法测定丙酸发酵液中的有机酸

对于生物法制备丙酸的微生物发酵体系,利用Waters Atlantis dC18反相色谱柱,以0.01mol/L KH2PO4缓冲液(pH2.8)-乙腈(95∶5,V/V)作流动相,在流速为1.0mL/min,柱温为25℃时,于紫外波长215nm处检测,9min内发酵液中的草酸、甲酸、乙酸、乳酸、琥珀酸和丙酸能得到良好分离。6种有机酸线性相关系数均在0.9992~1.0000之间;方法的回收率为99%~102%;RSD为0.56~1.66。本方法能够简便、快速测定丙酸发酵体系中主产物丙酸与其它有机酸含量,适于指导整个发酵过程条件的优化及发酵产物的监控。     

柱前衍生-气相色谱法同时测定功能食品中8种有机酸

建立了功能食品中8种有机酸同时测定的方法。样品中的有机酸(乙酸、丙酸、丁酸、草酸、乳酸、丙二酸、丁二酸、柠檬酸)经体积分数15%的硫酸甲醇提取酯化,三氯甲烷萃取,最后用气相色谱法测定。色谱条件:SPB-5毛细管柱(30 m×0.53 mm×0.5μm)为分离柱,火焰离子化检测器检测,进样口温度为250℃,检测器温度为300℃,程序升温。载气(N2)流速为0.8 mL/min,分流比为10:1,富马酸二甲酯内标法定量。8种有机酸衍生物达到基线分离,检测限范围为0.01~0.04 mg/L,精密度(RSD)范围为2.4%~5.5%,平均回收率范围为79.5%~106%。方法适合于功能食品中8种有机酸的快速测定。     

气相色谱直接进样法分析环己烷氧化废液中的有机酸

环己烷氧化废液经酸化、抽滤等预处理后 ,采用气相色谱直接进样法分离了样品中的 1 0种有机酸 ,并测定了其含量。测定废液中各有机酸的回收率在 95 %～ 1 0 5 %之间。气相色谱固定相为 5 %新戊二醇己二酸酯 +0 .2 %磷酸/1 0 1酸洗白色担体。     

离子色谱法及聚类分析研究主流烟气中的有机酸

建立了超声辅助萃取-离子色谱法同时测定卷烟主流烟气中主要有机酸的方法.采用20 mL 30 mmol/L J NaOH溶液在50℃下对捕集了卷烟主流烟气的剑桥滤片超声萃取50 min,AS11-HC分离柱、Ion AG11-HC保护柱、ASRS-ULTRAⅡ抑制器,KOH溶液为淋洗液,用电导检测器同时测定了卷烟主流烟气中的乳酸、甲酸、乙酸、丙酸、苹果酸和草酸的含量.方法的线性范围1.0～400 mg/L,相关系数为0.9990～0.9995,相对标准偏差1.4%～4.8%,检出限0.03～0.09 mg/L,回收率为92%～104%.采用此方法测定了19种不同规格卷烟样品主流烟气中6种有机酸的含量,并且以6种有机酸为指标对样品进行了聚类分析.结果表明,6种有机酸的含量分布特征可反映不同等级卷烟产品的特性,可用于不用等级卷烟产品的比较和分类.     

阀切换-离子色谱法测定1,2-环氧丁烷产品中有机酸

建立了阀切换-离子色谱法测定1,2-环氧丁烷（1,2-BO）产品中有机酸（甲酸、乙酸和丙酸）的方法。样品经乙醇稀释后,通过阀切换技术,有机酸被IonPac TAC-ULP1捕集柱捕集,然后进入IonPac AS11分析柱分离,并由电导检测器检测。结果表明：甲酸、乙酸和丙酸均能实现较好地分离,在各自的范围内其色谱峰面积呈现良好的线性关系。实际样品的加标回收率为92.5%~111.8%,相对标准偏差小于5.6%（n=3）,检出限为0.60~4.80 μg/L。该方法具有前处理简单、快速、准确等特点,适用于不溶于水的有机体系中有机酸的分析。     

直接电导检测离子排斥色谱法测定C1～C6脂肪族有机酸

建立了直接电导检测离子排斥色谱分离测定C1~C6脂肪族有机酸(甲酸、乙酸、丙酸、丁酸、戊酸、己酸)的方法。以Shim-pack SCR-102H 色谱柱为分离柱,选用p-甲苯磺酸水溶液为流动相,考察了流动相中p-甲苯磺酸的浓度、流速、pH、色谱柱温度对分离和测定脂肪族有机酸的影响,确定了最佳的色谱条件为：0.2 mmol/L p-甲苯磺酸水溶液作为流动相,流速1.2 mL/min,柱温45 ℃。所测有机酸的检测限为0.03～0.99 mg/L,相对标准偏差在2.3%以下(n= 5),回收率为91.2%～105.6%,整个分析过程在28 min内完成。该法用于白酒样品的分析,结果令人满意。     

非抑制型电导检测离子排斥色谱法分析有机酸

本文以对甲苯磺，酸加硼酸作为淋洗液，采用非抑制型电导检测，研究了离子排斥色谱法分离和检测苹果酸，抗坏血酸，乳酸，琥珀酸，甲酸，乙酸，丙酸等有机酸的色谱条件，并进行了实际样品的分析。     

梯度洗脱高效液相色谱法快速检测厌氧菌代谢物中的有机酸

提出了一种快速分析厌氧细菌代谢物中5种有机酸的高效液相色谱方法。该方法采用乙腈-0.02mol/L磷酸二氢钾缓冲溶液(pH 2.8)作为流动相,流速和流动相中两种组分的比例均采用四元泵程序梯度洗脱方法控制,检测波长为215 nm,柱温30℃时,能够快速、准确地分离和测定细菌培养基中的甲酸、乙酸、乳酸、琥珀酸和丙酸等5种有机酸,总分析时间只需4 m in。方法的相对标准偏差为0.26%~1.26%,回收率95.0%~100.8%,各种有机酸的线性相关系数r≥0.99981,具有较高的精密度和准确度,可以用于细菌代谢物中有机酸的分析。     

固相萃取-离子色谱法测定甘蔗糖蜜及糖蜜酒精废液中的非氮有机酸和无机阴离子

建立了固相萃取-离子色谱测定甘蔗糖蜜及糖蜜酒精废液中乙酸、乳酸、琥珀酸、苹果酸、酒石酸、草酸、富马酸、柠檬酸、乌头酸等非氮有机酸和盐酸根、硫酸根、磷酸根等3种无机阴离子的方法。样品稀释液经强阴离子(SAX)固相萃取小柱净化除去糖类和色素等干扰基质,再用稀KOH溶液洗脱,经0.45 μm水膜过滤后,用IonPac AS15阴离子分离柱、KOH溶液梯度淋洗-抑制电导检测分离分析。考察了固相萃取小柱对待测离子的保留和洗脱条件。实验结果表明,除乙酸和乳酸的分离不完全、苹果酸与琥珀酸的组分重叠外,其余组分可达到完全分离,被测组分的浓度与其峰高在一定的范围呈良好的线性关系,检出限均低于0.20 mg/L,相对标准偏差(RSD)小于6.7%。测定了2种甘蔗糖蜜和1种糖蜜酒精废液中有机酸及无机阴离子,结果满足检测的要求,样品中各组分的加标回收率为94%～109%。     

离子色谱法同时分析董酒中的有机酸与无机阴离子

研究了用离子色谱法同时分析董酒中可离解性有机酸和无机阴离子。首次采用邻苯二甲酸氢钾和邻苯二甲酸的混合水溶液作淋洗剂,改善了分离效果,提高了检测灵敏度。所建立的方法无需进行样品前处理,无干扰,有一定的实用价值。     

离子排斥色谱法测定环境样品中挥发性有机酸及乳酸

提出了同时测定环境样品中挥发性有机酸及乳酸的离子排斥色谱法（IEC法）。考察了流动相浓度、流速对有机酸分离的影响。实验结果表明,乳酸、甲酸、乙酸、丙酸、正丁酸和正戊酸可达到完全分离,被测组分的浓度与其峰高在一定的范围呈良好的线性关系,检出限均低于0.10 mg/L。测定了糖蜜酒精废水和消化污泥中有机酸的含量,结果满足检...     

烟气中有机酸的分析

 应用甲酯衍生化试剂对卷烟烟气粒相物中有机酸进行甲酯衍生化 ,经固相微萃取 (SPME)后通过气 质联用仪分离鉴定。分析了 4个品牌的卷烟烟气 ,共鉴定了 60多种挥发及半挥发性有机酸。对丁酸、己酸、糠酸、辛酸、壬酸、苯甲酸、苯乙酸、十四酸、十六酸进行了定量分析。该方法用于烟气中有机酸的定性、定量分析 ,灵敏度较高 ,快速简便。     

Simultaneous Determination of Haloacetic Acids in Environmental Waters using Electrospray Ionization Liquid Chromatography Mass Spectrometry

Negative ionization electrospray liquid chromatography mass spectrometry was developed for the simultaneous determination of all nine haloacetic acids containing bromine and chlorine. Haloacetic acids were separated on a crosslinked polystyrene resin column using 3% acetic acid dissolved in acetonitrile:water (20:80) as mobile phase. The precision of this method varied from ±2.2 to ±7.1% for nine haloacetic acids. In addition, quantitative results obtained with spiked water samples at three different concentrations are described. The limit of detection of the proposed method using 200 mL of water samples was between 0.003 and 0.070 μg/L. This method was successfully applied to the trace determination of haloacetic acids in waste water, river water, and seawater.     

煤酸浆态床异构化制对苯二甲酸

在分别使用有机高沸点分散剂联苯和联三苯的条件下,以苯甲酸锌为催化剂,进行了煤氧化产物煤酸(水溶酸WSA)钾浆态床异构化制对苯二甲酸(TPA)的研究。主要考察了反应温度、催化剂用量、分散剂用量、二氧化碳初压和反应时间对TPA产率的影响。结果表明,在催化剂存在下煤酸可以转化成TPA。单独煤酸钾异构化时,以联苯为分散剂时较佳反应条件为温度420℃、压力3MPa、催化剂苯甲酸锌用量3%、分散剂用量60%、反应时间1h、TPA收率24.1%。以联三苯为分散剂时较佳反应条件为温度380℃、压力1MPa、催化剂苯甲酸锌用量3%、分散剂用量60%、TPA收率25.2%。煤酸钾与苯甲酸(BA)钾混合异构化时,以联苯为分散剂TPA产率可达60%,以联三苯为分散剂TPA产率可达62%。采用气相色谱对反应产物进行了定性和定量分析。     

Separation of high‐purity eicosapentaenoic acid and docosahexaenoic acid from fish oil by pH‐zone‐refining countercurrent chromatography

The evidence for unique effects of eicosapentaenoic acid and docosahexaenoic acid is growing. Further understanding and exploration of their independent effects in the nutraceutical and pharmaceutical industry is calling for the more efficient separation techniques to overcome the equivalent chain length rule of fatty acids. In this study, free eicosapentaenoic and docosahexaenoic acid were successfully separated by pH‐zone‐refining countercurrent chromatography for the first time. The different solvent systems and the influence of retainer and eluter concentration on the separation efficiency were investigated. A two‐phase solvent system composed of n‐heptane/methanol/water (100:55:45, v/v) was selected with 50 mM of trifluoroacetic acid as retainer in the organic phase and 40 mM of ammonium hydroxide as an eluter in the aqueous phase for the separation of 500 mg of free fatty acids from a refined fish oil sample. 79.6 mg of eicosapentaenoic acid and 328.3 mg docosahexaenoic acid were obtained with the purities of 95.5 and 96.9% respectively determined by gas chromatography with mass spectrometry after methyl esterification. The scale‐up separation of 1 g of samples from both refined and crude fish oil after urea complexation were also achieved successfully with a markedly increased concentration 150 mM of retainer, producing satisfactory yields and purities of targets.     

吹扫捕集–气相色谱–质谱法同时测定环境水中101种挥发性有机物

建立吹扫捕集–气相色谱–质谱联用法测定环境水中101种常见挥发性有机物(VOCs)的方法。通过加热吹扫,样品水中的VOCs富集于捕集管中,以DB–624(60 m×0.25 mm,1.4μm)色谱柱分离,内标法定量。结果表明,101种挥发性有机物(VOCs)色谱分离效果良好,质量浓度在0.5~50 ng/mL范围内与色谱峰面积均呈线性关系,高沸点VOCs线性范围较窄。方法定量限(10 S/N)为0.11~0.77 ng/mL,均低于GB 3838–2002《地表水环境质量标准》、GB 5749–2006《生活饮用水卫生标准》及国外相关标准的限值。平均加标回收率在70.3%~123.6%之间,测定结果的相对标准偏差不大于8.8%(n=6)。该方法快速、简便,适用于环境水中挥发性有机化合物的分析检测。     

Simultaneous analysis of small organic acids and humic acids using high performance size exclusion chromatography

An accurate and fast method for simultaneous determination of small organic acids and much larger humic acids was developed using high performance size exclusion chromatography. Two small organic acids, i.e. salicylic acid and 2,3‐dihydroxybenzoic acid, and one purified humic acid material were used in this study. Under the experimental conditions, the UV peaks of salicylic acid and 2,3‐dihydroxybenzoic acid were well separated from the peaks of humic acid in the chromatogram. Concentrations of the two small organic acids could be accurately determined from their peak areas. The concentration of humic acid in the mixture could then be derived from mass balance calculations. The measured results agreed well with the nominal concentrations. The detection limits are 0.05 mg/L and 0.01 mg/L for salicylic acid and 2,3‐dihydroxybenzoic acid, respectively. Applicability of the method to natural samples was tested using groundwater, glacier, and river water samples (both original and spiked with salicylic acid and 2,3‐dihydroxybenzoic acid) with a total organic carbon concentration ranging from 2.1 to 179.5 mg C/L. The results obtained are promising, especially for groundwater samples and river water samples with a total organic carbon concentration below 9 mg C/L.     

Preparative separation of cichoric acid from Echinacea purpurea by pH-zone-refining counter-current chromatography

pH-zone-refining counter-current chromatography was successfully applied to the separation of cichoric acid from Echinacea Purpurea (L.) Moench. A 3.0 g quantity of sample was separated using the following two-phase solvent system: MtBE-CH3CN-water (4:1:5, v/v), 10 mM trifluoroacetic acid in organic stationary phase and 10 mM ammonia in aqueous mobile phase. The obtained fractions were analyzed by high-performance liquid chromatography and negative ion electrospray ionization mass spectrometry. Double separations were performed with the same solvent system yielding 563 mg cichoric acid at 95.6% purity.