Spectrophotometric determination of lithium with Quinizarin in drugs and serum

An endemic peripheral vascular disorder resulting in gangrene of the lower extremities, especially of the feet, is called 'Blackfoot disease (BFD)'. Clinically, the symptoms and signs of Blackfoot disease are similar to those of Buerger's disease. In this study, the objective is to examine the amount of arsenic, mercury, zinc, lead, and selenium in urine samples from BFD patients. After pre-treatment with acids, the samples were digested by means of a microwave oven. The determination of arsenic mercury, zinc, lead and selenium were by hydride atomic absorption spectrometry (HAAS), cold vapor atomic absorption spectrometry (CVAAS), flame atomic absorption spectrometry (FAAS), graphite furnace absorption spectrometry (GFAAS), respectively. The results indicated that urinary arsenic, mercury and lead of the BFD patients were significantly higher than those of the normal controls, while urinary zinc and selenium were significantly lower than those of the normal controls. The possibility that these elements are involved in the etiology of diseases is discussed.     

Direct determination of nickel in gas oil by atomic absorption spectrometry with electrothermal atomization

A rapid graphite-furnace atomic absorption procedure with simple dilution of samples was tested for the direct determination of sub-ppm levels of nickel in gas oils. The selection of appropriate graphite-furnace parameters, the type of solvent and organometallic standard, the effect of gas oil concentration in diluted samples, precision, accuracy and detection limit were investigated. Sample dilution was necessary because of high viscosity. Results obtained by standard addition for heavy gas oils were confirmed by a wet-ashing flame atomic absorption procedure. The relative standard deviation (r.s.d.) for consecutive determinations of nickel in gas oil solution containing 19 μg Ni l^?1 was 3.1%, and day-to-day r.s.d. for a reference gas oil sample was 5.3%. Accuracy was determined with an NBS standard reference oil GM-5 (4.6 ± 4.7% relative error in four determinations). Recovery experiments gas 104 ± 12% of the added nickel.     

Simultaneous determination of thallium,silver and gold in urine by flame and graphite-furnace atomic absorption spectrometry after extraction of the iodide complexes as ion-pairs with tri-n-octylamine

A simple, rapid and sensitive atomic absorption spectrometric method is described for the determination of thallium, silver and gold in urine. The metals are extracted as their iodide complexes with tri-n-octylamine into n-butyl acetate and are determined either by direct nebulization of the extract into an air/acetylene flame, or by graphite-furnace atomic absorption spectrometry with the L'vov platform. Detection limits for thallium, silver and gold in urine by flame and graphite-furnace spectrometry are: 65, 1.5; 15, 0.3; 30, 0.6×10 ^?9 M, respectively. The graphite-furnace method is suitable for the detection of thallium, silver and gold in the urine of occupationally exposed and unexposed persons.     

The determination of arsenic by electrothermal atomic absorption spectrometry with a graphite furnace : Part 1. Difficulties in the direct determination

The direct determination of arsenic by graphite-furnace atomic absorption spectrometry is critically examined. Matrix stabilization by nickel salts is effective for preventing charring losses of arsenic, but cannot eliminate strong interferences. Direct analysis of environmental and biological samples is impossible because of the presence of aluminium, sodium, potassium and sulphates.     

Quantitative measurements of inorganic and organic arsenic by flameless atomic absorption spectrometry

Procedures are described for the determination of arsenicals in water and urine by flameless atomic absorption spectrometry ; these avoid the isolation and transfer of arsine(s) and permit some differentiation between the inorganic and organic (methyl) arsenic content of a sample. Samples of water or urine are heated with hydrochloric acid, and treated with iodide ion. Arsenic species, as the iodides, are extracted into chloroform and then either reextracted into deionized water for measurement of inorganic arsenic, or reextracted into dilute dichromate solution for total arsenic determination; the difference furnishes levels of organic arsenic. Aliquots of the final aqueous extracts are analyzed by graphite-furnace atomic absorption spectrometry, with an arsenic electrodeless discharge lamp. The lower detection limit for water and urine was 10 p.p.b. The recoveries (and Sg values) were: 87.0% (3.0) and 93.0 % (7.9), for inorganic arsenic in water and urine, respectively; 92.3 % (5.3) for mixtures of inorganic and methylated arsenic (total arsenic) in water and urine; and 98.7 % (3.9) and 88.4% (3.6) for dimethylarsenic in water and urine, respectively.     

Atomic absorption with ultracold atoms

Recent advances in laser-atom cooling techniques and diode-laser technology now allow one to conduct an idealised atomic absorption experiment comprising a sample of ultracold, quasi-stationary absorbing atoms and a source of near-monochromatic resonant light. Under such conditions, the atomic absorption coefficient at line centre is independent of the oscillator strength of the atomic resonance line. This offers the prospect of ‘oscillator-strength-free’ atomic absorption spectroscopy in which the absorption signal is equally large for both strong and weak (closed) transitions of the same wavelength and in which absolute atomic absorption could be performed without knowledge of the oscillator strength. Moreover, the resolution and sensitivity for a given atom density are greatly enhanced, typically by approximately three orders of magnitude (and even more for weak transitions), compared with conventional flame or graphite-furnace atomic absorption. We describe an atomic absorption experiment based on samples of ultracold, laser-cooled caesium atoms and a narrow-bandwidth diode laser source that approximates the idealised conditions for oscillator-strength-free atomic absorption. The absorption measurements are used to determine the number density and temperature (approx. 6 μK) of the sample of ultracold atoms. Some of the technical obstacles that would have to be overcome before samples of ultracold atoms and diode laser sources could be used in analytical atomic absorption spectroscopy are discussed.     

Determination of tin and methyltin species by hydride generation and detection with graphite-furnace atomic absorption or flame emission spectrometry

A method for the determination of tin and organotin species by hydride generation is described. Tin hydrides are detected by graphite-furnace atomic absorption, quartz-cuvette atomic absorption, or flame emission spectrometry with detection limits of 50, 50, and 20 pg as tin, respectively. Germanium interferences are eliminated with a dual-detector flame photometer with an electronic cancellation circuit.     

Design and Critical Evaluation of Improved Electrothermal Vaporization Flame Atomic Absorption/Emission Spectrometry for Direct Determination of Trace Metals in Microliter Samples

Improved tantalum-filament electrothermal vaporization flame atomic absorption spectrometry (ETV-FAAS) was developed and used for the direct determination of trace metals in microliter samples. Studies have been made for optimizing the experimental parameters that affect the performance of sample introduction to the flame. Linear calibration graphs are shown for the elements Mn (10–200 ng), Pb (5–200 ng), Cu (5–100 ng), Cd (5–50 ng), Li (1–20 ng), Na (10–80 ng), and K (10–80 ng), using only 10 μl of standard solutions. The detection limits of the elements by ETV-FAAS were much lower than those of conventional FAAS. Absolute detection limits for all elements studied were less than 0.1 ng. The relative standard deviation values for the elements were <10%. The developed method was also applied to the determination of lead concentration in blood samples.     

Determination of trace metals in sea water by chelex-100 or solvent extraction techniques and atomic absorption spectrometry

Determinations of cadmium, lead, nickel, copper and zinc in sea water are discussed. Two different methods of preconcentration are compared: the trace metals are preconcentrated either by extraction with ammonium pyrrolidinedithiocarbamate/diethylammonium diethyldithiocarbamate into freon followed by back-extraction into nitric acid, or by collection on a Chelex-100 resin followed by elution with nitric acid. Cd, Pb, Ni, and Cu are determined by graphite-furnace atomic absorption spectrometry, while zinc is determined by flame atomic absorption spectrometry. The comparison of methods shows that cadmium can be determined accurately whereas results for the other trace metals may be biased by reagent contamination in the Chelex-100 method. Recovery data are given for both methods of preconcentration. Filtering experiments with Chelex-100 method are described. Results are compared for sea-water samples preconcentrated immediately after sampling and some weeks after sampling, with only freezing for preservation. The present results are consistent with other recent work. The importance of blank values is discussed.     

Flow injection techniques for flame atomic absorption spectrophotometry

When analysing real samples by flame atomic absorption spectrophotometry, considerable sample pretreatment together with the selection of the correct calibration strategy is necessary to ensure accurate results. Flow injection techniques can be used (a) to improve existing procedures, (b) as the basis for new calibration methods, and (c) to extend the capabilities of conventional flame atomic absorption spectrophotometry.     

Direct determination of arsenic in blood serum by electrothermal atomic absorption spectrometry

A method for the direct determination of arsenic in human blood serum is described. To suppress loss of arsenic by volatilization anal to remove chemical interferences in graphite-furnace atomic absorption spectrometry, the formation of involatile compounds with graphite, or with a matrix modifier is tested. With aqueous solutions, two sorts of interactions between graphite and arsenic are shown. But, in presence of serum, these interactions do not occur, Among 18 matrix modifiers tested, nickel gives the best sensitivity when used at high concentrations in the presence of Triton X-100. The proposed method allows direct arsenic determination, based on calibration with aqueous solutions. The method is applied to the serum of 20 normal subjects. The limit of detection is 0.4 μg l^?1 arsenic.     

Echelle-spectrometer/image-dissector system for elemental quantitation by continuous-source atomic absorption spectrometry

The performance of an echelle-spectrometer/image-dissector system is evaluated for elemental quantitation by continuous-source atomic absorption spectrometry. Flame and graphite-furnace atomizers were used, as well as two different spectrometer configurations. Quantitative results obtained with the flame atomizer and a low-resolution spectrometer configuration are discussed briefly; results obtained with the graphite-furnace atomizer and a higher-resolution configuration are presented in detail. Absorption sensitivities for calcium (422.7 nm), chromium (425.4 and 357.9 nm), copper (324.8 nm), and manganese (403.1 and 279.5 nm) were all within a factor of 4–6 of comparable line- source absorption sensitivities, and calibration curves were linear up to absorbances of about 0.1. Further development of the system for simultaneous multi-element quantitation is discussed.     

Evolved-gas zeeman flame atomic absorption spectrometry for the determination of arsenic compounds

An evolved-gas separation/flame Zeeman atomic absorption spectrometric approach is demonstrated for the speciation and determination of arsenic in oyster tissue. No digestion is needed and separation of inorganic arsenic compounds having similar boiling points is achieved. A stoichiometric or air-rich acetylene/air flame for atomic absorption spectrometry is not generally suitable for arsenic determination because of severe ultraviolet absorption interference at 193.7 nm and low sensitivity; polarized flame Zeeman atomic absorption spectrophotometry with a fuel-rich flame is suitable for the detection of traces of arsenic. The evolved-gas separation/Zeeman atomic absorption approach is simple, based on commercially available instrumentation, and useful for the selective determination of major arsenic compounds. Data are given to demonstrate optimal conditions and to show application to oyster tissue.     

水为载流-原子荧光光谱法同时测定土壤中痕量砷、汞

改变原子荧光光谱法以稀酸为载流的进样方式,以水为载流在新型双道原子荧光光谱仪上同时测定了土壤中的痕量砷(As)、汞(Hg)。方法采用王水水浴加热溶解样品,用50 g/L硫脲-抗坏血酸混合溶液预先将砷还原为+3价,保持10%(体积分数)以上盐酸浓度,不转移直接定容静置后测定。优化了仪器工作条件,详细考察了以水为载流测定的可行性,选择了同时测定As、Hg所需的硼氢化钾浓度和盐酸浓度。方法节省了酸试剂用量,操作快速,单个样品测定仅需20s左右。方法检出限As为0.005 mg/kg,Hg为0.0008 mg/kg,相对标准偏差(RSD%,n=7)在1.0%～7.4%,经土壤国家标准物质和实际样品验证,适合土壤中痕量As、Hg的同时快速测定。     

水载流-原子荧光光谱法同时测定土壤中痕量砷、汞

改变原子荧光光谱法以稀酸为载流的进样方式,以水为载流在新型双道原子荧光光谱仪上同时测定了土壤中的痕量砷(As)、汞(Hg)。采用王水水浴加热溶解样品,用50 g/L硫脲-抗坏血酸混合溶液预先将砷还原为As(Ⅲ),保持10%(体积分数)以上盐酸浓度,不转移直接定容静置后测定。优化了仪器工作条件,详细考察了以水为载流测定的可行性,选择了同时测定As、Hg所需的硼氢化钾浓度和盐酸浓度。节省了酸试剂用量,操作快速,单个样品测定仅需20 s左右。方法检出限As为0.005 mg/kg,Hg为0.0008 mg/kg,相对标准偏差(RSD,n=7)在1.0%~7.4%,经土壤国家标准物质和实际样品验证,适合土壤中痕量As、Hg的同时快速测定。     

Determination of Nickel,Manganese, Copper and Zinc in Blood Serum by Atomic Absorption Spectrometry after Deproteinization by Microwave Irradiation

ABSTRACT

Deproteinization of serum was performed by microwave irradiation combined with a small volume of diluted trichloracetic acid. The procedure reduced the protein level of the samples to less than 99% of the total with a small dilution factor (1+1) and allowed the determination of nickel and manganese by electrothermal atomic absorption spectrometry and copper and zinc by flame atomic absorption spectrometry directly without modifiers or matrix interferences. As metallic ions are normally bonded to serum proteins they must be released during protein precipitation. Spiked serum samples were submitted, before the deproteinization, to an incubation treatment to bond the added ions to the proteins. To check the efficiency of the incubation time for each ion, serum samples were ultrafiltered at set time intervals and the metals determined in the ultrafiltrate. The proposed method was compared with the common deproteinization by acids for the separation of the proteins. The reduction of proteins allowed a small dilution of the sample and the use of faster temperature programmes for the determination of nickel and manganese by electrothermal atomic absorption spectrometry and the aspiration of samples more similar to aqueous standards for copper and zinc determination by flame atomic absorption spectrometry. Recoveries from spiked, incubated and deproteinized samples compared to only diluted samples show that the method can satisfactorily be used for atomic absorption spectrometric determination of these elements.     

Rapid determination of copper,nickel, lead and cadmium in small samples of estuarine and coastal waters by liquid/liquid extraction and electrothermal atomic absorption spectrometry

A rapid liquid/liquid extraction of 1.25-ml samples is used with graphite-furnace atomic absorption spectrometry for the determination of dissolved trace metals in saline waters. The metals are chelated with ammonium pyrrolidine dithiocarbamate and extracted into 1,1,1-trichloroethane; 20–40 μl of extract is injected into the furnace. Sample manipulation and overall time are greatly decreased compared to other similar large-scale extraction methods; all the chemical steps are done in the sample cups of an auto-sampler for graphite-furnace a.a.s. Detection limits (Cu 0.3 μg l^?1, Cd 0.02 μg l^?1, Pb 0.7 μg l^?1, Ni 0.5 μg l^?1 are low enough for applications in routine monitoring of filterable trace metal concentrations in coastal and estuarine waters to check for compliance with Environmental Quality Standards that apply in the European Community.     

Combination of flow-injection techniques with atomic spectrometry in agricultural and environmental analysis

Combinations of flow-injection techniques with flame atomic absorption spectrometry (a.a.s.) and inductively-coupled plasma/atomic emission spectrometry (i.c.p./a.e.s.) are reviewed in the general context of agricultural and environmental analysis. The flow-injection systems are valuable for sample introduction; appropriate dispersion control allows the analysis of solutions containing as much as 40% (w/v) urea or phosphate in fertilizers. A study on the determination of cadmium in soil extracts by on-line ion-exchange preconcentration and flame a.a.s. detection is described. The interpolative standard-addition method with i.c.p./a.e.s. detection is outlined. Improvements in the determinations of selenium in environmental samples by hydride-generation a.a.s. and of mercury by cold-vapour a.a.s. are reported.     

Simultaneous extraction and determination of traces of lead and arsenic in petrol by electrothermal atomic absorption spectrometry

The lead and arsenic compounds are converted to water-soluble iodides by reaction with a solution of iodine in toluene extraction into dilute nitric acid before determination by graphite-furnace atomic absorption spectrometry against aqueous standards. The method is simple, rapid, accurate and reasonably precise.     

Simultaneous determination of cadmium and lead in urine by means of computerized potentiometric stripping analysis

In computerized potentiometric stripping analysis for cadmium and lead in urine the samples are acidified with hydrochloric acid to a total concentration equal to 0.5 M. The sample is pre-electrolyzed at —1.25 V vs. SCE for 2 min without prior sample heating or deoxygenation, the working electrode being a mercury pre-coated glassy-carbon electrode. The lead and cadmium concentrations are evaluated by means of standard addition. Detection limits are 1 nM for both elements. Results obtained by potentiometric stripping analysis and by solvent extraction/atomic absorption are compared for samples from unexposed persons and from one patient under penicillamine treatment. The relative merits of the potentiometric stripping, anodic stripping and atomic absorption techniques are discussed.