Elemental analysis of glass was conducted by 16 forensic science laboratories, providing a direct comparison between three analytical methods [micro-x-ray fluorescence spectroscopy (μ-XRF), solution analysis using inductively coupled plasma mass spectrometry (ICP-MS), and laser ablation inductively coupled plasma mass spectrometry]. Interlaboratory studies using glass standard reference materials and other glass samples were designed to (a) evaluate the analytical performance between different laboratories using the same method, (b) evaluate the analytical performance of the different methods, (c) evaluate the capabilities of the methods to correctly associate glass that originated from the same source and to correctly discriminate glass samples that do not share the same source, and (d) standardize the methods of analysis and interpretation of results. Reference materials NIST 612, NIST 1831, FGS 1, and FGS 2 were employed to cross-validate these sensitive techniques and to optimize and standardize the analytical protocols. The resulting figures of merit for the ICP-MS methods include repeatability better than 5% RSD, reproducibility between laboratories better than 10% RSD, bias better than 10%, and limits of detection between 0.03 and 9 μg g(-1) for the majority of the elements monitored. The figures of merit for the μ-XRF methods include repeatability better than 11% RSD, reproducibility between laboratories after normalization of the data better than 16% RSD, and limits of detection between 5.8 and 7,400 μg g(-1). The results from this study also compare the analytical performance of different forensic science laboratories conducting elemental analysis of glass evidence fragments using the three analytical methods.
Mass spectrometry-based
DNA adductomics is an emerging approach
for the human biomonitoring of hazardous chemicals. A mass spectral
database of DNA adducts will be created for the scientific community
to investigate the associations between chemical exposures, DNA damage,
and disease risk.
Aptamers are promising biorecognition elements for sensors.However,aptamer-based assays often lack the requisite levels of sensitivity and/or selectivity because they typically employs tructure-switching aptamers with attenuated affinity and/or utilize reporters that require aptamer labeling or which are susceptible to false positives.Dye-displacement assays offer al abel-free,s ensitive means for overcoming these issues, wherein target binding liberates ad ye that is complexed with the aptamer,p roducing an optical readout. However,b road utilization of these assays has been limited. Here,w ed emonstrate arational approach to develop colorimetric cyanine dyedisplacement assays that can be broadly applied to DNA aptamers regardless of their structure,sequence,affinity,orthe physicochemical properties of their targets.O ur approach should accelerate the development of mix-and-measure assays that could be applied for diverse analytical applications.
Aptamers are promising biorecognition elements for sensors. However, aptamer‐based assays often lack the requisite levels of sensitivity and/or selectivity because they typically employ structure‐switching aptamers with attenuated affinity and/or utilize reporters that require aptamer labeling or which are susceptible to false positives. Dye‐displacement assays offer a label‐free, sensitive means for overcoming these issues, wherein target binding liberates a dye that is complexed with the aptamer, producing an optical readout. However, broad utilization of these assays has been limited. Here, we demonstrate a rational approach to develop colorimetric cyanine dye‐displacement assays that can be broadly applied to DNA aptamers regardless of their structure, sequence, affinity, or the physicochemical properties of their targets. Our approach should accelerate the development of mix‐and‐measure assays that could be applied for diverse analytical applications.
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