磷钼钨三元杂多酸光度法测定药物中的抗坏血酸

研究了抗坏血酸与磷钼钨三元杂多酸的显色反应，提出了借磷钼钨杂多蓝测定抗坏血酸的分光光度法。最大吸收波长为７３０ｎｍ，抗坏血酸在０．０８～１０ｍｇ／Ｌ范围内线性良好。回归方程为Ａ＝１．０５×１０４Ｃ＋０．０１７，线性相关系数γ＝０．９９９５，表观摩尔吸光系数ξ７３０＝１．０５×１０４Ｌ·ｍｏｌ－１·ｃｍ－１，方法检出限为０．０４ｍｇ／Ｌ，回收率为９４～１０２％，相对标准偏差≤１．５％（ｎ＝８）。本方法由于钨钼的混合配位增强了氧化能力，较之二元杂多酸的方法，省去了水浴加热等操作，只需在室温下反应３０ｍｉｎ，吸光值至少可稳定６ｈ。过量的黄色杂多酸可加入适量的氢氧化钠溶液分解，从而获得色泽纯正的高灵敏度显色体系。     

磷钼杂多酸光度法测定水果中的维生素C

在一定条件下,PO43-与Mo(VI)形成的磷钼杂多酸H3[P(Mo3Ol0)4]被维生素C还原成磷钼蓝,其最大吸收波长为710 nm,磷钼蓝的表观摩尔吸光系数为4.8×103L/(mol.cm),维生素C在1.0～80.0μg/mL浓度范围内符合比尔定律,线性回归方程为A=-0.01747+0.02722ρ(μg/mL),相关系数为0.9992,检测限为0.23μg/mL。该方法已用于水果中维生素C含量的测定。     

磷钼钒杂多酸光度法测定钒

磷钼钒杂多酸早已用于磷的光度分析,其它应用尚未见报道。本文提出利用磷钼钒杂多酸光度测定高速钢中常量的钒,共存元素中铬、钴的影响以试样空白扣除,钨的负干扰可采用经验系数补正,样中1％Si和1％Nb不干扰测定。方法简便、快速、准确。本文还提出了在一定条件下形成磷钼钒酸、磷钨钒酸和磷钨钼酸的经验规律。 1 试剂与仪器 钼酸铵溶液:53g·L~(-1) 盐磷混酸:1.19g·ml~(-1)盐酸+1.74g·ml~(-1)磷酸=3+2 钒标准溶液:0.900mg·ml~(-1)(里偏钒酸铵配制并以滴定法标定) 721型分光光度计 2 分析方法称取试样0.1000g于200ml锥形瓶中(同时称一份不含钒的钢样作试剂空白A_0),加盐磷混酸1.5ml,硫酸(1+1)8ml,加热溶解,滴加浓硝酸助溶,继续加热     

用氯丙嗪-磷钼杂多酸分光光度法测定烟叶中的磷

在１－５ ｍｏｌ／ＬＨＣｌ 介质中及聚乙烯醇（ＰＶＡ） 存在的条件下,氯丙嗪能与磷钼杂多酸形成摩尔比１∶１ 的离子缔合物, 可稳定１－５ ｈ 以上, 其最大吸收波长在３４５ ｎｍ 处, 磷在０ ～０－４８ ｍｇ／Ｌ 范围内符合Ｂｅｅｒ 定律, 表观摩尔吸光系数为６－０５ ×１０４ Ｌ·ｍｏｌ－ １ ·ｃｍ － １ 。 该法用于烟叶中磷的测定, 操作简便, 选择性好, 灵敏度高, 结果令人满意。     

磷钼杂多酸光度法测定吲哚乙酸

研究了吲哚乙酸与磷钼杂多酸在浓度为 0 .0 3 mol/L的硫酸介质中发生氧化还原反应 ,形成的还原产物 (钼蓝 )在 NH3-NH4Cl缓冲溶液 (p H8.4)中最大吸收波长为 314 nm,表观摩尔吸光系数 ε值为 3.5 4× 10 4L· mol-1·cm-1 ,吲哚乙酸含量在 5 .0× 10 -7～ 5 .0× 10 -5 mol/L范围内符合比尔定律 ,检出限为 1.0× 10 -7mol/L,对 2 .0 0× 10 -5 mol/L吲哚乙酸测定 10次的相对标准偏差为 6 .42 % ,加标回收率为 94.2 %～ 10 0 .1%     

间接光度法测定药物中的抗坏血酸

研究了一种简便的选择性高的药物中抗坏血酸含量的测定方法。该方法基于在弱酸性介质中 ,有盐酸羟胺、碘酸存在下 ,抗坏血酸还原对氨基苯磺酸与N 1 萘乙二胺盐酸盐混合体系生成的有色物质 ,体系的最大吸收波长为 5 40nm ,工作曲线的线性范围为 0 .5～ 4 .0 μg·ml- 1。方法灵敏度高 ,选择性好 ,对药用维生素C中抗坏血酸含量进行测定 ,结果满意     

对苯二酚—磷钼杂多酸光度法测定比色钢中的磷

研究了对苯二酚-氟化钠-氯化亚锡联合还原磷钼蓝光度法测定钢铁中的磷含量,使磷钼蓝的吸光度值能够稳定在40 min以上不变。最佳实验条件下,磷含量在0.00～0.80μg/mL范围内符合比尔定律,最大摩尔吸光系数εmax,730 nm=3.32×104L.mol-1.cm-1。对钢标样进行多次测定相对误差小于5%,回收率在99.3%～104.3%之间,适用于比色钢中磷含量的快速、准确测定。     

微波消解-磷钼蓝分光光度法测定钨矿石中的磷含量

针对钨矿石中的微量元素磷,采用混合酸快速微波消解结合磷钼蓝分光光度法进行测定。经选择优化样品的微波消解和实验测定条件,结果表明:HCl+HNO3+HF的混合酸微波消解后的样品,在硫酸介质中,有钼酸铵存在时,用抗坏血酸将磷还原成磷钼蓝络合物,在825nm处比色测定。方法的加标回收率为98.9%~101.6%,结果准确可靠。硅在熔样过程中挥发除去不会干扰测定,砷会干扰实验,可在酸介质中加入碘化钾,使砷还原至低价而不干扰磷的测定。     

Resin Bead Detection and Spectrophotometric Determination of Ascorbic Acid in Pharmaceutical Preparations Using m-Dinitrobenzene

Abstract

A colorimetric reaction has been studied for the detection and determination of ascorbic acid in samples at the microgram level. the method is simple, rapid, and sensitive, the ascorbic acid was detected using resin beads and determined spectrophotometrically using m-dinitrobenzene in formaldehyde. the detection limit was 10μg. Beer's law is obeyed in the concentration range of 2 – 50μg/ml of ascorbic acid.     

固蓝盐B分光光度法测定药物中抗坏血酸

探讨了一种简便的选择性高的药物中抗坏血酸的测定方法。该方法是基于在酸性介质中抗坏血酸和固蓝盐B的反应,产物的最大吸收为420nm.摩尔吸光系数为1.31×10~4L·mol~(-1)·cm~(-1).方法已应用于某些药物中抗坏血酸的测定,结果与碘量法一致,回收率为98.4％～105％,相对标准偏差低于3.7％。     

A Spectrophotometric Determination of Ascorbic Acid

A new, simple and sensitive method for the spectrophotometric indirect determination of ascorbic acid in fruits, beverages, and pharmaceuticals is described. In this method, the ascorbic acid reduces Cu²⁺ to Cu⁺ and reacts with 2,9‐dimethyl‐1,10‐phenanothroline (neucoproine) to form Cu (neucoproine)⁺ complex, and it was extracted with N‐phenylbenzimidoylthiourea (PBITU) in chloroform. The apparent value of molar absorptivity of the complex in terms of ascorbic acid is (3.52) × 10⁴ L mole^?1 cm^?1 at λ_max, 460. The detection limit of ascorbic acid is 40 μg L^?1 and the method obeys Beer's law over the concentration range of 0.1–4.0 μg mL^?1. The proposed method was successfully applied for the determination of ascorbic acid in various samples. The validity of the present method was checked by the flow injection analysis (FIA) method.     

Kinetic Spectrophotometric Determination of Ascorbic Acid in Pharmaceutical Samples by Oxidation of Ponceau 4R by Hydrogen Peroxide

A new sensitive and simple kinetic method is developed for determination of traces of ascorbic acid based on its activated effect on oxidation of trisodium‐2‐hydroxy‐1‐(4‐sulphonato‐1‐naphthylazo)naphthalene‐6,8‐disulphonato (red artificial color Ponceau 4R) by hydrogen peroxide, in the presence of Cu(II) as catalyst, in borate buffer. The reaction is followed spectrophotometrically by tracing the oxidation product at 478.4 nm within 1 min after addition of H₂O₂. The optimum reaction conditions are: borate buffer (pH = 11.00), Ponceau 4R (9.6·10^?6 mol/L), H₂O₂ (2·10^?2 mol/L), Cu(II) (8·10^?7 mol/L) at 22 °C. Following this procedure, ascorbic acid can be determined with a linear calibration graph up to 1.76 ng/mL and a detection limit of 0.28, based on 3S criterion. The relative error ranges between 6.77‐1.66% for the concentration interval of ascorbic acid 1.76‐17.61 ng/mL. The effects of certain foreign ions upon the reaction rate were determined for an assessment of the selectivity of the method. The method was applied for determination of ascorbic acid in pharmaceutical samples, and spectrophotometric method was used like an comparative method.     

Spectrophotometric Determination of Trace Amounts of Ascorbic Acid

Abstract

Colourless silver-gelatin complex is quantitatively reduced by ascorbic acid to yellow silver sol in water within the pH range 7.5–10.0 at room temperature. The determination of 1–10μg/ml of ascorbic acid is possible at 415 nm in the presence of glycine, alanine, fructose, sucrose, citric, tartaric, oxalic, malic, succinic acids and also in the presence of various reducing agents. The molar absorptivity of ascorbic acid at the δ_max is found to be 21500 lit mol^?1 cm^?1 and the Sandell sensitivity of the sol is 8.18x10^?3 μg ascorbic acid cm^?2 for 0.001 absorbance. The relative standard deviation is ±0.22% and the confidence limit (20 determinations, 95%) being 8.806±0.0093%.     

Genetic‐Algorithm‐Based Wavelength Selection in Multicomponent Spectrophotometric Determination by PLS: Application on Ascorbic Acid and Uric Acid Mixture

Genetic algorithm (GA) is a suitable method for selecting wavelengths for partial least squares (PLS) calibration of mixtures with almost identical spectra without loss of prediction capacity using the spectrophotometric method. In this study, the concentration model is based on absorption spectra in the range of 200‐320 nm for 25 different mixtures of ascorbic acid (AA) and uric acid (UA). The calibration curve was linear over the concentration range of 1‐15 and 2‐16 μg mL^?1 for ascorbic acid and uric acid, respectively. The root mean square deviation (RMSD) for ascorbic acid and uric acid with GA and without GA were 0.3071 and 0.3006, 0.3971 and 0.7063, respectively. The proposed method was successfully applied to the simultaneous determination of both analytes in human serum and urine samples.     

Kinetic Spectrophotometric Determination of Thiols and Ascorbic Acid

Abstract

This paper describes a kinetic spectrophotometric method for the determination of L‐ascorbic acid (AA) and thiols (RSH). Absorbance of Fe(II)‐phen complex formed during the reaction of AA or RSH with Fe(III)‐phen was continuously measured at 510 nm by double‐beam spectrophotometer with flow cell. For determination some thiols, the catalytic effect of Cu²⁺ ions was used. AA and RSH can be determined in concentration ranges from 4.0×10^?6 to 4.0×10^?5 M and from 8.0×10^?6 to 8.0×10^?5 M, respectively. The applicability of the proposed method was demonstrated by determination of chosen compounds in pharmaceutical dosage forms.     

A New Spectrophotometric Method for the Determination of Ascorbic Acid Using Leuco Malachite Green

A new simple and sensitive and selective spectrophotometric method has been developed for the determination of ascorbic acid (AA) at trace level using a new reagent, leuco malachite green (LMG). AAreacts with potassium iodide‐iodate solution under acidic conditions to liberate iodine and the liberated iodine selectively oxidizes LMG to MG dye. The colour of the dye was measured at 620 nm. Beer's law is obeyed over the concentration range of 0.8–8 iμg μAA per 25 mL of final solution (0.032–0.32 ppm). The apparent molar absorptivity and Sandell's sensitivity of the method were found to be 2.98 × 10⁵ l mol⁻¹ cm⁻¹, 0.0042 μg cm⁻², and respectively. Statistical treatment of the experimental results indicates that the method is precise and accurate. The method is free from interference of common ions and many of the ingredients commonly found in pharmaceuticals. The reliability of the method was established by parallel determination against Leucocrystal violet (LCV) method. The method described was satisfactorily applied for the determination of AA in fruit juices, pharmaceuticals and biological samples.