Ultratrace Determination of Lead in Whole Blood Using Electrothermal Atomization Laser-Excited Atomic Fluorescence Spectrometry

Wagner, Eugene P.; Smith, Benjamin W.; Winefordner, J. D.

doi:10.1021/ac9603587

Cited by 42 publications

(27 citation statements)

References 19 publications

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“…Laser-excited atomic fluorescence using a copper vapor laser has proven to be a very sensitive method for the determination of lead where a limit of detection of 0.1 fg has been reported in a previous study made in our laboratory 4 , in contrast to 5 pg that can be achieved by graphite furnace atomic absorption spectrometry. 2 Taking advantage of this high sensitivity, the amount of blood deposited in the filter furnace was reduced to 1 µl to minimize the amount of organic matter and the amount of fumes released.…”

Section: Resultsmentioning

confidence: 82%

“…The difference in intensities in this case can be attributed mainly to the attenuation of the excitation laser radiation as well as the emitted fluorescence by the smoke released and to fluorescence quenching of excited species by the high concentration of molecular species in the analytical zone during atomization. 4 With the filter furnace technique, several heating programs were evaluated. The best program (Table 1) included a pre-atomization cycle with two drying steps and a low temperature ashing step (300˚C), to avoid the problems related to the use of the high temperature preatomization discussed above.…”

Section: Resultsmentioning

confidence: 99%

“…4 A platform, which delays the atomization of the analyte until a temperature equilibrium is reached between the walls and the center of the tube, in many cases is a very useful approach to minimize problems related with the formation of compounds after the vaporization of highly volatile and medium volatile elements. Chemical modifiers can chemically transform the analyte of interest making it less volatile, and so higher ashing and/or atomization temperatures can be applied.…”

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confidence: 99%

“…Ideally, a method to analyze complex samples should allow the correlation of complex standards to aqueous standards simplifying the calibration curve procedure by eliminating the need for blood standards. In previous work by Wagner et al 4 , correlation was successfully accomplished for lead by using a photodiode placed behind the furnace, in line with the laser beam, correcting for the decrease of laser intensity of the sample relative to the blank. Potentially, the Katskov filter is a cheaper and simpler alternative to achieve such correlation of standards.…”

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Determination of Lead in Whole Blood by Filter Furnace Laser-Excited Atomic Fluorescence Spectrometry

1999

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Electrothermal atomization is considered one of the most efficient means to atomize samples prior to the detection of atoms by either fluorescence or absorption. However, this technique is far from perfect because of the interactions that can take place among the analyte, the carbon of the graphite atomizer and principally the components from the matrix containing the analyte of interest. Analytical matrices containing high amounts of organic matter very often present problems related to the decrease of analyte sensitivity. The two main causes are losses of analyte during the heating cycle because of formation of volatile molecular containing the analyte of interest and/or increases of background of molecular origin. The problem is usually addressed and, in many cases, minimized by the optimization of the temperature program together with stabilized temperature platform furnace (SPTF) technique 1,2 and by chemical modification. 3Although the choice of proper ashing temperatures and heating rates is very effective for elements with high thermal and chemical stability, this approach does not seem to be always effective for elements which form volatile molecular species like lead. 4 A platform, which delays the atomization of the analyte until a temperature equilibrium is reached between the walls and the center of the tube, in many cases is a very useful approach to minimize problems related with the formation of compounds after the vaporization of highly volatile and medium volatile elements. Chemical modifiers can chemically transform the analyte of interest making it less volatile, and so higher ashing and/or atomization temperatures can be applied. Chemical modifiers also can be employed to interact with interfering species in order to achieve a time-resolved release of products during the heating cycle achieving a separation of the analyte from the matrix components. A disadvantage of using chemical modifiers is that they are usually employed in concentrations of the order of thousands of times higher than the analyte concentration present in the sample. This procedure can introduce impurities into the sample and cause false analytical results, principally if detection of ultratrace amounts of a common element like lead is intended. In addition, finding an appropriate chemical modifier is not always guaranteed.The graphite filter furnace (FF) is a new concept of electrothermal atomization, recently introduced by Katskov 5 and it has been applied successfully in atomic absorption spectroscopy. 6 The possibility of the introduction of larger volumes of sample, the decreased preatomization time and temperatures, and the elimination of spectral background as well as chemical interferences without the use of chemical modifiers are improvements that the FF technique have to offer over the commonly used atomization techniques. The spool shaped graphite filter, made of porous graphite, is inserted inside a pyrolytic graphite tube where the sample is deposited in the gap between the wall of the tube and the filter, ou...

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Section: Resultsmentioning

confidence: 82%

Section: Resultsmentioning

confidence: 99%

mentioning

confidence: 99%

mentioning

confidence: 99%

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Determination of Lead in Whole Blood by Filter Furnace Laser-Excited Atomic Fluorescence Spectrometry

1999

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“…To monitor Pb 2+ level, several methods have been developed, including inductively coupled plasma mass spectrometry [6,7], atomic fluorescence spectrometry [8,9], atomic absorption spectroscopy [10], reversed-phased high-performance liquid chromatography [11], and so on. Even with sensitivity and accuracy, there also share some disadvantages, such as timeconsuming, expensive, and/or require sophisticated equipment, etc.…”

Section: Introductionmentioning

confidence: 99%

Colorimetric assay of lead using unmodified gold nanorods

et al. 2012

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Lead poisoning in adults can affect the peripheral and central nervous systems, the kidneys, and blood pressure. Thus, the development of environment-friendly and simple methods for Pb 2+ detection is of great importance. Herein, a label-free colorimetric method has been developed for the detection of Pb 2+ based on the conformational switch from single-stranded DNA to G-quadruplex. The electrostatic interactions between DNA probe and gold nanorods (GNRs) induce GNRs to space closely. However, the electrostatic interaction is not strong enough to change the suspension state of GNRs. In the presence of Pb 2+ , the formation of G-quadruplexes increases the surface charge density around DNA, which is expected to strengthen the electrostatic interaction between the GNRs and the DNA. Therefore, the longitudinal absorption of GNRs decreased because the stronger interaction induced aggregation of GNRs. Importantly, the decrease in longitudinal absorption is proportional to concentration of Pb 2+ . By monitoring the change of absorbance, Pb 2+ can be detected at a level of 3 nM with a linear range from 5 nM to 1 μM. The overall test only takes a few minutes and very little interference is observed from other metal ions. The major advantages of this method are its low cost, convenience, simplicity, sensitivity, and specificity.

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Atomic Fluorescence in Environmental Analysis

Cai

2000

Encyclopedia of Analytical Chemistry

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Atomic fluorescence is a spectroscopic process which is based upon the absorption of radiation of a certain wavelength by an atomic vapor and subsequent radiational deactivation of the excited atoms toward the detection device. Both the absorption and the subsequent atomic emission processes occur at wavelengths which are characteristic of the atomic species present. Atomic fluorescence spectroscopy (AFS) is a very sensitive and selective method for the determination of a number of environmentally and biomedically important elements such as mercury, arsenic, selenium, bismuth, antimony, tellurium, lead, and cadmium. This technique has become one of the most important analytical tools for trace element analysis in environmental samples, such as mercury, owing to its advantages over other methods in terms of linearity and detection levels. Several books and a number of book chapters and review articles have been published dealing with the theory and instrumentation of AFS. This article will provide up‐to‐date AFS information regarding its application in environmental analysis.

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Ultratrace Determination of Lead in Whole Blood Using Electrothermal Atomization Laser-Excited Atomic Fluorescence Spectrometry

Cited by 42 publications

References 19 publications

Determination of Lead in Whole Blood by Filter Furnace Laser-Excited Atomic Fluorescence Spectrometry

Determination of Lead in Whole Blood by Filter Furnace Laser-Excited Atomic Fluorescence Spectrometry

Colorimetric assay of lead using unmodified gold nanorods

Atomic Fluorescence in Environmental Analysis

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