茶叶中7种有机磷农药残留量的同时测定

采用配有FPD检测器的气相色谱仪测定茶叶中多种有机磷的农药残留量. 对样品的前处理进行了探讨, 结果表明, 样品用乙酸乙酯和少量苯提取, 过硅胶-活性炭柱净化, 同时用乙酸乙酯和少量苯洗脱, 7种有机磷在HP-35柱上得到很好的分离, 且方法准确快速、重现性、回收率好, 符合实际工作需要.     

甲胺磷离子选择性电极的研制及其应用

以四苯硼钠与甲胺磷在盐酸介质中生成的离子缔合物为电活性物质,首次研制出一种甲胺磷PVC涂层玻璃电极。并对该电极的响应机理及性能进行了研究。实验表明,该电极的Nernst响应范围为1×10-2~1×10-4(φ),斜率为50.28 mV/pφ。该电极响应迅速,重复性好,用于蔬菜中残留甲胺磷的测定,方法快速、准确,结果满意。     

Solid sampling Fourier transform infrared determination of Mancozeb in pesticide formulations

A series of approaches have been assayed for FTIR determination of Mancozeb in several solid commercial fungicides using different calibration strategies. The simplest procedure was based on the use of the ratio between the absorbance of a characteristic band of Mancozeb and that of a KSCN internal standard measured in the FTIR spectra obtained from KBr pellets. It was employed the quotient between peak height absorbance values at 1525 cm⁻¹ for Mancozeb and 2070 cm⁻¹ for KSCN. In these conditions a precision as relative standard deviation (RSD) of 0.6% and a relative accuracy error of 0.8% (w/w) were found. For complex formulations, containing other compounds with characteristic absorption bands at different wavenumbers than Mancozeb, one of them was used as internal reference being employed the standard addition approach. In this case, the Mancozeb bands at 1525 cm⁻¹ or at 1289 cm⁻¹ were employed, being used the ferrocyanide band at 2075 cm⁻¹ as internal reference. RSD values between 0.7-1.4% and a relative accuracy error of 3% (w/w) were found. A third strategy was based on the use of partial least squares (PLS) calibration. A reference set was prepared mixing Mancozeb, Kaolin, Cymoxanil and KBr, being predicted the Mancozeb concentration in pesticide formulations by using the quotient between absorbance bands of Mancozeb and those of Cymoxanil. In these conditions a relative accuracy error of 0.6% (w/w) and a relative standard deviation of 1.3% were found.     

Zur direkten ma?analytischen Bestimmung von Carbamaten als sehr schwache S?uren

Zusammenfassung Eine direkte maßanalytische Methode zur Bestimmung diverser Carbamate wird beschrieben. Die potentiometrische Titration mit käuflicher Tetra-n-butylammoniumhydroxid-Lösung, verdünnt mit Propanol-(2), ist bequem durchzuführen, und die erhaltenen Titrationskurven gestatten eine korrekte Auswertung.

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Direct volumetric determination of carbamates as very weak acids

Summary A volumetric procedure for the determination of some carbamates is described. The potentiometric titration with commercial tetra-n-butylammonium hydroxide solution diluted with propanol-(2) is convenient and the obtained titration curves permit a correct calculation.

     

环境水中甲基对硫磷、对硫磷和辛硫磷农药残留的SPE-HPLC分析

采用离线固相萃取 (SPE)富集 -高效液相色谱(HPLC)分离和紫外分光光度法检测 ,对环境水中甲基对硫磷、对硫磷和辛硫磷3种有机磷农药进行分析;固相萃取用C18 萃取柱 ,用甲醇洗脱 ,高效液相色谱分离以Shim_PackCLCODS柱(150mm×4.6mmid,5μm)为分离柱 ,流动相为甲醇 -水(体积比70∶30) ,紫外检测波长为280nm;该法稳定可靠 ,回收率高     

用于测量农药残留的小麦酯酶的选择

为研制探测农药残留的生物传感器，研究了农药乐果[O,O-二甲基S－（N－甲基胺基甲酰甲戎）二硫代磷酸酯]对各种小麦植物酯酶的抑制，从小麦中提取植物酶，以农药乐果为抑制剂，采用分光光度法研究了乐果对各种小麦酯酶活性的影响；研究显示，不同品种小麦酯酶对农药乐果的敏感度不同，在所研究的品种中，豫麦39和小麦周9对乐果较敏感，研究结果说明了选择小麦酶源的必要性。     

GC-MS法测定粮谷及油料中55种有机磷农药残留量

采用ASE-300快速溶剂萃取仪提取样品中农药残留量,提取液经二氯甲烷液-液分配、凝胶色谱柱（GPC）净化,固相萃取柱（活性炭）再净化,浓缩定容后,用气相色谱-质谱仪（GC-MS）测定,外标法定量.采用选择离子检测进行阳性确证.选择玉米、糙米、大豆、花生为实验样品、敌敌畏等55种农药添加水平在0.5～2.00 mg/kg时,该方法回收率为68%～117%;精密度为4.04%～11.76%;方法测定低限为0.005～0.100 mg/kg,各项指标均满足有关要求.     

串联质谱法在农药残留分析中的应用

农药残留问题已经成为全球关注的热点问题,尤其是农产品和食品中的农药残留更受到各国政府和公众的普遍关注。快速、准确、灵敏的农药残留分析和检测技术已经成为保障食品安全的有效手段,是当前农药残留分析研究和发展的方向。1983年,McLafferty等发明了串联质谱技术(MS-MS),目前已发展成为一种成熟的技术,在许多研究领域发挥了巨大作用。同样,在农药残留分析领域,串联质谱技术也越来越体现出其定性准确、排除干扰能力强以及灵敏度高的特点。     

Automated at-line solid-phase extraction-gas chromatographic analysis of micropollutants in water using the PrepStation

A fully automated at-line solid-phase extraction-gas chromatography procedure has been developed for the analysis of aqueous samples using the PrepStation. The sample extract is transferred from the sample preparation module to the gas chromatograph via an autosampler vial. With flame-ionization detection, limits of determination (S/N=10) of 0.05–0.13 μg/l were obtained for the analysis of HPLC-grade water when modifying the PrepStation by: (i) increasing the sample volume to 50 ml, (ii) increasing the injection volume up to 50 μl, and (iii) decreasing the desorption volume to 300 μl. The HP autosampler had to be modified to enable the automated “at-once” on-column injection of up to 50 μl of sample extract. The amount of packing material in the original cartridge had to be reduced to effect the decrease of the desorption volume. The total set-up did not require any further optimization after having set up the method once. The analytical characteristics of the organonitrogen and organophosphorus test analytes, i.e. recoveries (typically 75–105%), repeatability (2–8%) and linearity (0.09–3.0 μg/l) were satisfactory. The potential of the system was demonstrated by determining triazines and organophosphorus pesticides in river Rhine water at the 0.6 μg/l level using flame-ionization and mass-selective detection. No practical problems were observed during the analysis of more than 100 river water samples.     

Quality control of Metamitron in agrochemicals using Fourier transform infrared spectroscopy in the middle and near range

Two vibrational spectrometry-based methodologies were developed for Metamitron determination in pesticide formulations. Fourier transform-middle infrared (FT-MIR) procedure was based on the extraction of Metamitron by CHCl₃ and latter determination by peak area measurement between 1556 and 1533 cm⁻¹, corrected with a two points baseline established from 1572 to 1514 cm⁻¹. Fourier transform-near infrared (FT-NIR) determination was made after the extraction of Metamitron in acetonitrile and measuring the peak area between 6434 and 6394 cm⁻¹ corrected using a two points baseline defined between 6555 and 6228 cm⁻¹. Repeatability, as relative standard deviation, of 5 independent measurements at mg g⁻¹ concentration level, of 0.16% and 0.07% for MIR and NIR and a limit of detection of 0.03 and 0.004 mg g⁻¹ were obtained for MIR and NIR, respectively.NIR determination provides a sample frequency of 120 h⁻¹, higher than that found by MIR and liquid chromatographic methods (60 and 15 h⁻¹, respectively). On the other hand, the NIR method reduces the solvent consumption and waste generation, to only 1 ml acetonitrile per sample as compared with 3.4 ml chloroform required for the MIR determination and 60 ml acetonitrile used in the chromatographic reference procedure. So, vibrational procedures can be considered serious alternatives to long and time consuming chromatographic methods usually recommended for quality control of commercially available pesticide formulations.