Co-reporter:Jin Luo, Fujian Xu, Jing Hu, Ping Lin, Jiping Tu, Xi Wu, Xiandeng Hou
Microchemical Journal 2017 Volume 133(Volume 133) pp:
Publication Date(Web):1 July 2017
DOI:10.1016/j.microc.2017.03.056
•UiO-66 was fast synthesized under microwave irradiation.•Arsenic was preconcentrated onto the UiO-66.•Arsine was directly realized via slurry sampling of the UiO-66.•Arsine was swept into AFS for determination of ultratrace arsenic.In this work, metal organic framework (MOF) UiO-66 with strong stability in water was synthesized and used for the preconcentration of ultratrace arsenic in environment water and the precipitated UiO-66 was converted to slurry for direct determination with hydride generation-atomic fluorescence spectrometry (HG-AFS). Factors affecting the adsorption of arsenic by UiO-66, including pH, adsorption time, stability of UiO-66, masking agents together with the optimum conditions of HG-AFS were investigated in detail. The performance of UiO-66 for adsorbing arsenic was excellent at room temperature over a wide range of pH from 1 to 11, and adsorption efficiencies of > 95% could be achieved within only 5 min. Meanwhile, since conventional digestion process is avoided, the slurry sampling method is fast and convenient with greatly reduced matrix interference. Under the optimum conditions, it shows a good linear relationship between AFS intensities (I) and the concentrations of arsenic (C) (I = 547C + 61) with linear correlation coefficients better than 0.99. A precision of 3% (RSD%, n = 11) at 1 ng/mL and a limit of detection (LOD) of 0.0002 ng/mL were obtained.
Co-reporter:Fujian Xu, Xiaoming Jiang, Jing Hu, Jinyi Zhang, Zhirong Zou, Xiandeng Hou, Hongjian Yan
Microchemical Journal 2017 Volume 135(Volume 135) pp:
Publication Date(Web):1 November 2017
DOI:10.1016/j.microc.2017.09.005
•Nano g-C3N4/TiO2 composite was prepared as photocatalyst in the photochemical vapor generation (PCVG) of selenium (VI).•High efficiency of PCVG for Se (VI) was obtained for its ultrasensitive determination by atomic fluorescence spectrometry.•Photocatalytic enhancement mechanism of the g-C3N4/TiO2 composite in PCVG was proposed.Nano g-C3N4/TiO2 composite was synthetized and utilized as a novel photocatalyst for enhanced photochemical vapor generation for sample introduction to atomic fluorescence spectrometry. High reduction efficiency for Se (VI) was obtained to facilitate its ultrasensitive determination by atomic fluorescence spectrometry, with a limit of detection of 0.08 ng mL− 1. The photocatalytic mechanism of this composite was also discussed and demonstrated its highly efficient photocatalytic capacity and promissing applications in trace selenium (VI) determination and extraction.
Co-reporter:Shuli Zeng, Ronghui Zhou, Xiaoke Zheng, Lan Wu, Xiandeng Hou
Microchemical Journal 2017 Volume 134(Volume 134) pp:
Publication Date(Web):1 September 2017
DOI:10.1016/j.microc.2017.05.003
•A CT/fluorescence bioimaging probe is established with Ba2 +-doped nano-hydroxyapatite conjugated with Cu-doped CdS QDs.•It has the advantages of mono-dispersion, near-infrared fluorescence, good biocompatibility and photostability.•Simultaneous dual-modal bioimaging and tumor-targeting can be realized.Nano-hydroxyapatite particles (Ca10(PO4)6(OH)2, nano-HAp), the main inorganic components of human bone and teeth, has attracted much attentions as a kind of biocompatible carrier to construct dual/multi modal bioimaging probes in recent years. However, the currently developed HAp-based probes still have some shortcomings, such as poor mono-dispersion, potential toxicity and none near-infrared emission, which hinder their further applications in the field of bioimaging. In order to solve the above problems and to combine the high space resolution of CT and high sensitivity of fluorescence together, here we developed a novel dual-modal (CT/fluorescence) bioimaging probe based on nano-HAp. Ba2 + as a CT contrast agent was doped into the lattice of nano-HAp, and Cu-doped quantum dots with near-infrared fluorescent emission and hyaluronic acid (HA) were conjugated with the HAp as a fluorescent agent and tumor-targeting ligand individually to realize its near-infrared imaging and tumor-targeting. The as-received Ba2 +-doped HAp-QDs-HA conjugates not only well maintained the good dispersion of nano-HAp, but also possessed near-infrared emission at about 700 nm, good biocompatibility and photostability. Furthermore, the in-vitro CT and fluorescence cell imaging of the conjugates also exhibited good dual-modal bioimaging and tumor-targeting ability for potential applications in the field of early diagnosis and therapy of cancer.
Co-reporter:Ronghui Zhou, Xiaomei Lu, Huimin Yu, Lan Wu, Peng Wu, Xiandeng Hou
Microchemical Journal 2017 Volume 134(Volume 134) pp:
Publication Date(Web):1 September 2017
DOI:10.1016/j.microc.2017.06.003
•Mn-doped ZnSe QDs were fast synthesized via direct use of heterogeneous Se powder as anionic precursor.•Defect luminescence of the QDs can be effectively weakened through ligand exchange with mercaptopropionic acid.•The QDs possess good crystallizability, favorable monodispersity and large Stokes shift.•The high-purity of the QDs was further verified by ICP-MS analysis and fluorecence emission spectra.As a typical doped quantum dots, Mn doped ZnSe quantum dots (Mn:ZnSe QDs) is widely used for bio-imaging applications due to its excellent optical properties and low toxicity. However, it is difficult to dissolve and easy to oxidize selenium powder. In order to solve this problem, a heterogeneous Se powder instead of homogeneous Se solution was used here as anionic precursor for synthesis of Mn doped ZnSe QDs based on “nucleation-doping” method. Selenium powder was directly injected into manganese precursors under high temperature, then selenium powder slowly but constantly dissolved and promoted the formation of MnSe nanocrystals with the balance of chemical reaction, which would quickly generate Mn-doped ZnSe QDs with the addition of zinc ion precursor. Compared with homogeneous Se for synthesis of Mn doped ZnSe QDs, this method can achieve fast synthesis of high quality QDs that can also be water-soluble through ligand change with mercaptopropionic acid (MPA). The obtained product was carefully charaterized, and trace impurities was analytically determined.
Co-reporter:Xiaoliang Zeng, Yajun Zhang, Jinyi Zhang, Hao Hu, Xi Wu, Zhou Long, Xiandeng Hou
Microchemical Journal 2017 Volume 134(Volume 134) pp:
Publication Date(Web):1 September 2017
DOI:10.1016/j.microc.2017.05.011
•A colorimetric sensor for Pb2 + was developed with bimetallic lanthanide metal-organic frameworks (MOFs).•The MOFs was prepared by using a simple and fast synthetic procedure.•The color change of the sensor could be visually observed by the naked eyes.•It is rapid, cost-effective and selective for field screen analysis of lead-polluted environmental water.A new colorimetric sensor for Pb2 + based on bimetallic (Eu-Tb) lanthanide (Ln) metal-organic frameworks (MOFs) was developed for field screen analysis of lead-polluted environmental water. The Ln-MOFs were prepared by using a simple and fast synthetic method, with Tb3 +/Eu3 + and 1,4-benzenedicarboxylate (BDC) as precursors. The color of the luminescent Ln-MOFs could be fine-tuned from green to red by doping the MOFs with different ratios of Tb3 +/Eu3 +, and a specific MOFs Tb1.7Eu0.3(BDC)3·(H2O)4 was synthesized and employed as the sensing probe. With the existence of Pb2 + in an appropriate concentration range with a certain amount of Tb1.7Eu0.3(BDC)3·(H2O)4, the emission color of the MOFs changed from red-orange to green, which could be visually observed by the naked eyes. This colorimetric sensing method turned out to be simple, rapid, cost-effective and highly selective, without any requirement for complicated instrumentation. Furthermore, lead-polluted environmental water samples were analyzed for Pb2 +, illustrating the promising perspective of the developed method for field screen analysis.
Co-reporter:Juan He, Fujian Xu, Jing Hu, Shanling Wang, Xiandeng Hou, Zhou Long
Microchemical Journal 2017 Volume 135(Volume 135) pp:
Publication Date(Web):1 November 2017
DOI:10.1016/j.microc.2017.08.009
•CTF-1 was quickly synthesized with a simple microwave-assisted ionothermal polymerization method.•CTF-1 without any modification was verified to have dual enzyme activities: peroxidase-like and oxidase-like activity.•Using CTF-1 as oxidase mimic, a simple and fast colorimetric platform for biothiol detection was developed.•The advantages also include low cost, easy preparation and highly stability.A triazine-based covalent organic framework, CTF-1, for the first time, was found to possess both intrinsic peroxidase-like activity and oxidase-like activity and be capable to catalyze the oxidation of chromogenic substrates with or without H2O2 with high efficiency as a robust catalyst. Related oxidization mechanism was thoroughly studied, and the according catalytic properties of CTF-1 was also evaluated. What's more, a facile and effective colorimetric assay was established to detect biothiols without using any oxidizing agents. Compared to natural enzymes and other reported artificial enzymes, CTF-1 has also demonstrated the advantages including low cost, easy preparation, good stability, and high catalytic activity, which made it a very promising enzyme-mimetic alternative in potential applications in biosensors for the future.
Co-reporter:Chenghui Li, Peng Wu and Xiandeng Hou
Nanoscale 2016 vol. 8(Issue 7) pp:4291-4298
Publication Date(Web):21 Jan 2016
DOI:10.1039/C5NR09130F
Information extraction from nano-bio-systems is crucial for understanding their inner molecular level interactions and can help in the development of multidimensional/multimodal sensing devices to realize novel or expanded functionalities. The intrinsic fluorescence (IF) of proteins has long been considered as an effective tool for studying protein structures and dynamics, but not for protein recognition analysis partially because it generally contributes to the fluorescence background in bioanalysis. Here we explored the use of IF as the fourth channel optical input for a multidimensional optosensing device, together with the triple-channel optical output of Mn-doped ZnS QDs (fluorescence from ZnS host, phosphorescence from Mn2+ dopant, and Rayleigh light scattering from the QDs), to dramatically improve the protein recognition and discrimination resolution. To further increase the cross-reactivity of the multidimensional optosensing device, plasma modification of proteins was explored to enhance the IF difference as well as their interactions with Mn-doped ZnS QDs. Such a sensor device was demonstrated for highly discriminative and precise identification of proteins in human serum and urine samples, and for cancer and normal cells as well.
Co-reporter:Junbo Chen, Bin Deng, Peng Wu, Feng Li, Xing-Fang Li, X. Chris Le, Hongquan Zhang and Xiandeng Hou
Chemical Communications 2016 vol. 52(Issue 9) pp:1816-1819
Publication Date(Web):02 Dec 2015
DOI:10.1039/C5CC08879H
By using the principle of binding-induced DNA assembly, we have developed a novel homogeneous assay that is able to convert an affinity protein binding event into a predesigned DNA assembly. The assembled DNA sequence can be ligated into an intact DNA strand and hundreds of DNA hairpins can be cleaved by a nicking endonuclease. Each cleavage releases a single-stranded DNA (ssDNA) probe that is initially caged in the DNA hairpin. This released ssDNA probe can then turn on the fluorescence signal by desorbing a fluorescently-labelled complementary DNA probe from graphene oxide through hybridization. We demonstrate that this homogeneous, isothermal, and amplifiable assay can be tailored to detect a number of proteins, including a cancer biomarker, human prostate specific antigen, at picomolar levels in both buffer and human serum samples.
Co-reporter:Piaopiao Chen, Peng Wu, Junbo Chen, Peng Yang, Xinfeng Zhang, Chengbin Zheng, and Xiandeng Hou
Analytical Chemistry 2016 Volume 88(Issue 4) pp:2065
Publication Date(Web):January 19, 2016
DOI:10.1021/acs.analchem.5b03307
Based on selective and sensitive determination of Hg2+ released from mercury complex by cold vapor generation (CVG) atomic fluorescence spectrometry (AFS) using SnCl2 as a reductant, a novel label-free and separation-free strategy was proposed for DNA and protein bioassay. To construct the DNA bioassay platform, an Hg2+-mediated molecular beacon (hairpin) without labeling but possessing several thymine (T) bases at both ends was employed as the probe. It is well-known that Hg2+ could trigger the formation of the hairpin structure through T–Hg2+–T connection. In the presence of a specific target, the hairpin structure could be broken and the captured Hg2+ was released. Interestingly, it was found that SnCl2 could selectively reduce only free Hg2+ to Hg0 vapor in the presence of T–Hg2+–T complex, which could be separated from sample matrices for sensitive AFS detection. Three different types of analyte, namely, single-strand DNA (ssDNA), protein, and double-strand DNA (dsDNA), were investigated as the target analytes. Under the optimized conditions, this bioassay provided high sensitivity for ssDNA, protein, and dsDNA determination with the limits of detection as low as 0.2, 0.08, and 0.3 nM and the linear dynamic ranges of 10–150, 5–175, and 1–250 nM, respectively. The analytical performance for these analytes compares favorably with those by previously reported methods, demonstrating the potential usefulness and versatility of this new AFS-based bioassay. Moreover, the bioassay retains advantages of simplicity, cost-effectiveness, and sensitivity compared to most of the conventional methods.
Co-reporter:Ke Huang, Kailai Xu, Wei Zhu, Lu Yang, Xiandeng Hou, and Chengbin Zheng
Analytical Chemistry 2016 Volume 88(Issue 1) pp:789
Publication Date(Web):December 3, 2015
DOI:10.1021/acs.analchem.5b03128
A low-cost, simple, and highly selective analytical method was developed for sensitive visual detection of selenium in human urine both outdoors and at home, by coupling hydride generation with headspace solid-phase extraction using quantum dots (QDs) immobilized on paper. The visible fluorescence from the CdTe QDs immobilized on paper was quenched by H2Se from hydride generation reaction and headspace solid-phase extraction. The potential mechanism was investigated by using X-ray diffraction (XRD) and X-ray photoelectron spectroscopy (XPS) as well as Density Functional Theory (DFT). Potential interferences from coexisting ions, particularly Ag+, Cu2+, and Zn2+, were eliminated. The selectivity was significantly increased because the selenium hydride was effectively separated from sample matrices by hydride generation. Moreover, due to the high sampling efficiency of hydride generation and headspace solid phase extraction, the sensitivity and the limit of detection (LOD) were significantly improved compared to conventional methods. A LOD of 0.1 μg L–1 and a relative standard deviation (RSD, n = 7) of 2.4% at a concentration of 20 μg L–1 were obtained when using a commercial spectrofluorometer as the detector. Furthermore, a visual assay based on the proposed method was developed for the detection of Se, 5 μg L–1 of selenium in urine can be discriminated from the blank solution with the naked eye. The proposed method was validated by analysis of certified reference materials and human urine samples with satisfactory results.
Co-reporter:Xue Jiang, Xinliang Xu, Xiandeng Hou, Zhou Long, Yunfei Tian, Xiaoming Jiang, Fujian Xu and Chengbin Zheng
Journal of Analytical Atomic Spectrometry 2016 vol. 31(Issue 7) pp:1423-1429
Publication Date(Web):06 May 2016
DOI:10.1039/C6JA00142D
It was found that a capillary electrophoresis (CE) process can be induced by starting a low-temperature d.c. liquid-electrode glow discharge (GD). A novel capillary microplasma analytical system (C-μPAS) was constructed by interface-free coupling of d.c. glow discharge optical emission spectrometry (GD-OES) to CE and was applied in elemental (speciation) analysis. A GD was generated at one end of a capillary, and initiated not only a capillary electrophoresis process but also a microplasma; a sample was injected at the other end of the capillary, separated by CE, and detected by GD-OES. This portable C-μPAS integrates introduction of the sample, separation of the analyte species, and detection of the analytical signal into one unit. The performance of this new analytical system was first evaluated by the analysis of a mixed aqueous solution of mercury, cadmium, chromium, sodium and organic or inorganic species without derivatization, and the absolute limits of detection (LODs) were found to be in the range of 0.5 to 500 picograms under the optimized experimental conditions. Preliminary experimental results for mercury speciation showed that it provided effective separation and results as accurate as those obtained by HPLC-ICP-MS. The working mechanism of this system is discussed, with the theoretically calculated electron temperature and electron density of the microplasma. This C-μPAS has the advantages of portable instrumentation, green chemistry (low power consumption, tiny sampling volume and almost no pollutants), high sensitivity (detection of optical emissions), low interference (separation by CE and spectral resolution), versatility (organic, inorganic, cationic or anionic analytes), and fast analysis (several minutes). It should have a very promising future in a range of areas such as environmental analysis, metallomics research, water analysis, online monitoring and field analytical chemistry.
Co-reporter:Ruoxi Zhang, Mengting Peng, Chengbin Zheng, Kailai Xu, Xiandeng Hou
Microchemical Journal 2016 Volume 127() pp:62-67
Publication Date(Web):July 2016
DOI:10.1016/j.microc.2016.02.006
•Photochemical or ultrasonic vapor generation generates Hg0 from total mercury or inorganic Hg2 +.•Flow injection–vapor generation–atomic fluorescence spectrometry mode was adapted.•Ultrasensitive and matrix interference-free analysis was achieved.•Water and fish samples were successfully analyzed for trace mercury species.A simple, non-chromatographic and green method based on flow injection UV photochemical or ultrasonic vapor generation atomic fluorescence spectrometry (AFS) was developed for the determination and speciation analysis of mercury. Mercury cold vapor (Hg0) was generated by using only formic acid and UV or ultrasonic irradiation, and was subsequently detected by AFS. Both mercury (Hg2 +) and methyl mercury (MeHg) can be converted to Hg0 for the determination of total mercury with UV irradiation, while only Hg2 + can be reduced to Hg0 with ultrasonic irradiation, thus determining only Hg2 +. Then, the concentration of MeHg can be calculated by subtracting the Hg2 + concentration from the total mercury concentration. The optimal conditions for the best cold vapor generation efficiencies are discussed in detail, together with interference from transition metals. This new speciation analysis not only provides high sensitivity for the determination of mercury species but further eliminates the use of toxic reducing reagents and avoids potential destruction of analyte species that occur in chromatographic separation. Moreover, a simpler and less toxic Hg2 + standard series can be used for the calibration of both Hg2 + and MeHg. The limit of detection is 0.005 or 0.01 μg L− 1 for total mercury with the UV or inorganic mercury with the ultrasonic irradiation, respectively. This method was successfully applied to ultrasensitive mercury speciation analysis of water and biological samples.
Co-reporter:Ruoxi Zhang, Biao Shen, Chenghui Li, Chengbin Zheng, Xiandeng Hou
Microchemical Journal 2016 Volume 129() pp:98-103
Publication Date(Web):November 2016
DOI:10.1016/j.microc.2016.06.014
•Photochemical vapor generation is used for mercury removal from polluted water.•Photo-oxidation is used for trapping the removed mercury onto a quartz tube.•An atomic fluorescence spectrometer is used for sensitive on-line monitoring.•It could be useful in treating slightly mercury-polluted water for drinking in the field.A new system was constructed and its performance evaluated for simultaneous mercury removal from water and on-line monitoring. The system consisted of a photochemical vapor generator (Photo-CVG, for mercury removal), a photo-oxidation trapping reactor (for collection of removed mercury) and a commercial atomic fluorescence spectrometer (AFS, for on-line monitoring). In the presence of organic acids, inorganic Hg(II) was converted by UV irradiation to mercury cold vapor in the Photo-CVG, which was then rapidly separated from the water sample in a gas-liquid separator (GLS) and transported to the photo-oxidation trapping reactor by air or argon for collection of the removed mercury and subsequent on-line monitoring by AFS for early-warning of mercury vapor leak to the environment. The factors affecting the efficiencies of cold vapor generation, transport, collection and on-line monitoring were carefully investigated. Under the optimized conditions, a limit of detection of 0.003 μg L− 1 was obtained for the proposed system by using only formic acid. Meanwhile, both the efficiencies of mercury removal and collection can be even close to 100% in the mercury concentration range of 2–100 μg L− 1. The proposed system provided a safe, green, complete, simple and fast yet inexpensive method for low concentration mercury removal and on-line monitoring.
Co-reporter:Xiaodong Wen, Ying Gao, Peng Wu, Zhiqiang Tan, Chengbin Zheng and Xiandeng Hou
Journal of Analytical Atomic Spectrometry 2016 vol. 31(Issue 2) pp:415-422
Publication Date(Web):22 Sep 2015
DOI:10.1039/C5JA00323G
Generation of volatile hydrides and elemental mercury was accomplished in non-aqueous media by using a solid reductant of lithium aluminium tetrahydride (LiAlH4), stannous chloride dehydrate (SnCl2) or tetrahydroborate (THB) as a derivation reagent. A room temperature ionic liquid (RTIL) was used as the non-aqueous media for the chemical vapor generation (CVG), and atomic fluorescence spectrometry was used for the elemental determination. The analyte ions were firstly extracted into the RTIL media from the bulk aqueous phase of the analyte/sample solution via a liquid–liquid extraction process and then directly mixed with the solid reductant to generate volatile analyte-containing species, which were then rapidly transported to a commercial atomic fluorescence spectrometer for detection. Hg(II), As(III) and Sb(III) were selected as the model analytes for evaluating this new CVG technique. The three reductants could all reduce Hg(II) to the elemental state, but only THB could generate volatile species of As(III) and Sb(III). Compared to conventional CVG in the aqueous phase, the efficiencies of CVG accomplished with solid reductants were similar or even better, there was less interference from transition and noble metal ions, and much better limits of detection were obtained. The proposed method was successfully used for the determination of ultratrace mercury and arsenic in several certified reference materials, including soil, water and human hair samples.
Co-reporter:Pan Hou, Chaoting Shi, Lan Wu, Xiandeng Hou
Microchemical Journal 2016 Volume 128() pp:218-225
Publication Date(Web):September 2016
DOI:10.1016/j.microc.2016.04.022
•A new heterogeneous Fenton catalyst chitosan/hydroxyapatite/Fe3O4 (CS/HA/Fe3O4) magnetic composite was prepared.•CS/HA/Fe3O4 was efficiently (95.0%) used for AY220 removal.•CS/HA/Fe3O4 can efficiently adsorb Co2 + released from AY220 degradation and thus avoid a secondary pollution.•With Co2 + adsorbed on the surface of CS/HA/Fe3O4, its degradation efficiency of AY220 dramatically increased.Cross-linked Chitosan (CS) loaded with iron species has been widely used as heterogeneous Fenton catalysts for organic contaminant removal. In comparison with raw-CS based Fenton catalysts, it exhibited an improved degradation efficiency due to the stabilization of cross-linking agents. With cross-linking, however, most reactive sites of CS were occupied by cross-linking agents, making its capability decreased sharply for adsorbing the released metal ions from metal-complex dye degradation. In this work, in order to efficiently adsorb the released metal ions from metal-complex dyes and avoid a secondary pollution, a new CS-based heterogeneous Fenton catalyst (Chitosan/Hydroxyapatite/Fe3O4 magnetic composite) was developed for AY220 (a model of metal-complex dyes) removal. Hydroxyapatite (HA), a well-known biocompatible material with strong ability for metal ion adsorption, was introduced to combine with CS for Fe3O4 loading. The total removal efficiency of AY220 by the magnetic composite can reach as high as 95.0%, and the degradation efficiency of AY220 was greatly enhanced compared with a raw-CS based catalyst and bare Fe3O4. Meanwhile, the composite can efficiently adsorb Co2 + released from AY220 degradation, which can further promote the degradation of AY220. After five recyclable runs of the composite, the degradation efficiency of AY220 increased from 25.1% to 45.6%, demonstrating its potential usefulness in recyclable degradation of metal-complex dyes.
Co-reporter:Xue Jiang, Zhangmei Hu, Hengwei He, Jin Luo, Yunfei Tian, Xiandeng Hou
Microchemical Journal 2016 Volume 129() pp:16-22
Publication Date(Web):November 2016
DOI:10.1016/j.microc.2016.05.018
•A two-dimensional sensor using DBD multi-channel OES and CL.•Improved sensitivity and linear dynamic ranges.•Discrimination and identification of eight hazard volatile halohydrocarbons.•Simple construction, compact instrumentation, low power consumption.In this work, a two-dimensional sensor based on dielectric barrier discharge (DBD) molecular optical emission and liquid phase chemiluminescence (CL) was constructed for the discrimination analysis of hazard volatile halohydrocarbons (VHCs) including dichloromethane, chloroform, tetrachloromethane, 1,1,2,2,-tetrachloroethane, 1,4-dichloropropane, 1,2-dichloroethane, bromoform and iodomethane without any separation. Atmospheric pressure DBD induced not only multi-channel molecular optical emission spectroscopy (MES), but also chemiluminescence through the reaction of the DBD-split VHCs with luminol in aqueous solution. The DBD-MES and CL pattern of each analyte were unique, and the linear discriminant analysis (LDA) demonstrated the robustness of this optical sensor. Principal component analysis (PCA) revealed that MES and CL channels contributed at varied concentrations to the good discrimination capability due to the two distinct sensing mechanisms. The miniaturized optical sensor possessed the advantages of simple construction, low power consumption, and high sensitivity to VHCs, especially chlorinated hydrocarbons. It demonstrated for highly discriminative and precise identification of VHCs in air samples.
Co-reporter:Zhirong Zou, Shanling Wang, Jia Jia, Fujian Xu, Zhou Long, Xiandeng Hou
Microchemical Journal 2016 Volume 124() pp:578-583
Publication Date(Web):January 2016
DOI:10.1016/j.microc.2015.10.005
•Effective adsorption of arsenic with Fe3O4@ZIF-8 core-shell magnetic nanoparticles•Easy separation of the Fe3O4@ZIF-8 with a magnet from water sample after the adsorption•Sensitive determination of the absorbed arsenic by AFS without matrix interference•Simple and facile step-by-step preparation of the Fe3O4@ZIF-8In this work, magnetic Fe3O4@ZIF-8 core-shell nanoparticles (MNPs) were employed for effective adsorption of inorganic arsenic for preconcentration, with adsorption mechanism thoroughly discussed. The adsorbed inorganic arsenic was easily separated by a magnet along with the MNPs from the sample matrix, with possible matrix interference eliminated. The MNPs were then completely dissolved in hydrochloric acid prior to the determination of inorganic arsenic by hydride generation-atomic fluorescence spectrometry. The Fe3O4@ZIF-8 MNPs were prepared with a facile step-by-step assembly method in aqueous solution at room temperature. Under the optimized conditions, the sensitivity for inorganic arsenic determination was significantly increased through preconcentration, with satisfactory analytical merits obtained.
Co-reporter:Piaopiao Chen, Peng Wu, Yuxiang Zhang, Junbo Chen, Xiaoming Jiang, Chengbin Zheng, and Xiandeng Hou
Analytical Chemistry 2016 Volume 88(Issue 24) pp:
Publication Date(Web):November 14, 2016
DOI:10.1021/acs.analchem.6b03633
In previous work, we have developed a simple strategy for a label-free and separation-free bioassay for target DNA and protein, with the limit of detection at the nM level only. Herein, taking advantage of atomic fluorescence spectrometric detection of metal ions and amplification of DNA, a label-free and separation-free ultrasensitive homogeneous DNA analytical platform for target DNA and protein detection was developed on the basis of an enzyme-free strand displacement signal amplification strategy for dramatically improved detectability. Using the T–Hg2+–T hairpin structure as the probe, the target DNA binds with HP (T–Hg2+–T hairpin structure) and released the Hg2+ first; then, the P4 (help DNA) hybridizes with target–P3 complex and free the target DNA, which is used to trigger another reaction cycle. The cycling use of the target amplifies the mercury atomic fluorescence intensity for ultrasensitive DNA detection. Moreover, the enzyme-free strand displacement signal amplification analytical system was further extended for protein detection by introducing an aptamer–P2 arched structure with thrombin as a model analyte. The current homogeneous strategy provides an ultrasensitive AFS detection of DNA and thrombin down to the 0.3 aM and 0.1 aM level, respectively, with a high selectivity. This strategy could be a promising unique alternative for nucleic acid and protein assay.
Co-reporter:Chenghui Li, Zhou Long, Xiaoming Jiang, Peng Wu, Xiandeng Hou
TrAC Trends in Analytical Chemistry 2016 Volume 77() pp:139-155
Publication Date(Web):March 2016
DOI:10.1016/j.trac.2015.11.012
•Various atomic spectrometric detectors have been used in gas chromatography.•They provide not only high sensitivity but also elemental selectivity for speciation analysis.•Non-ideal chromatographic resolution and matrix interference can be reduced or even eliminated.•Simultaneous multi-element detection can be realized for separated species.Various atomic spectrometric detectors have been used in gas chromatography (GC) for widespread analytical applications. Their excellent characteristics including high sensitivity and selectivity, low limits of detection (LODs), and the possibility of simultaneous multi-element detection for metallic and non-metallic species make them ideal detectors as a unique solution for many analytical problems. Different types of atomic spectrometric detectors coupled to GC, including those based on atomic absorption spectrometry (AAS), atomic fluorescence spectrometry (AFS), plasma atomic emission spectrometry/mass spectrometry (AES/MS), are discussed in this article, primarily in terms of operational characteristics, analytical performance and practical applications.
Co-reporter:Yunfei Tian, Peng Wu, Qin Liu, Xi Wu, Xiandeng Hou
Talanta 2016 Volume 161() pp:151-156
Publication Date(Web):1 December 2016
DOI:10.1016/j.talanta.2016.08.049
•Total SERS strategy was established by mapping the whole sample surface.•Gold films fabricated by argon ion sputtering deposition was used for the test.•Significant improvement in precision was achieved with good linearity.•It can be a very stable/practical working mode for quantification with a 2-D detector.Surface-enhanced Raman scattering (SERS) has been applied in a range of fields for its super high sensitivity which can even reach the single molecule level. But the quantification methods based on SERS still have some challenges such as stability, repeatability, and linearity at low concentrations. Here we propose a new quantification approach by using a total mapping scheme, and then add all the spectra together to obtain a final merged spectrum (a total SERS spectrum). The total SERS spectra were used to perform quantification analysis. The results of this approach show that it can improve the signal stability by at least 50% (RSD) and extend the linear quantification range by one order of magnitude. The proposed total SERS mapping quantification strategy is a promising practical working mode to improve its analytical figures of merit.
Co-reporter:Xinfeng Zhang, Chengpeng Huang, Shuxia Xu, Junbo Chen, Ying Zeng, Peng Wu and Xiandeng Hou
Chemical Communications 2015 vol. 51(Issue 77) pp:14465-14468
Publication Date(Web):07 Aug 2015
DOI:10.1039/C5CC06105A
We report here the newly discovered photocatalytic activity of the dsDNA–SYBR Green I (SG) complex, which can catalyze the oxidation of 3,3′,5,5′-tetramethylbenzidine (TMB) under light irradiation corresponding to the excitation of the dsDNA–SG complex. The most appealing feature of the photocatalytic system here is that it can be obtained using random DNA sequences that can form a duplex. Considering the universality of the photooxidase, a label-free and universal platform was proposed for highly sensitive visual bioassays.
Co-reporter:Ke Huang, Kailai Xu, Jie Tang, Lu Yang, Jingrong Zhou, Xiandeng Hou, and Chengbin Zheng
Analytical Chemistry 2015 Volume 87(Issue 13) pp:6584
Publication Date(Web):May 28, 2015
DOI:10.1021/acs.analchem.5b00511
To evaluate the toxicity of silver nanoparticles (AgNPs) and Ag+ and gain deep insight into the transformation of AgNPs in the environment or organisms, ultrasensitive analytical methods are needed for their speciation analysis. About 40-fold of Cd2+ in CdTe ionic nanocrystals can be “bombarded-and-exploded” (exchanged) in less than 1 min simply by mixing the nanocrystals with Ag+ solution at room temperature, while this cation exchange reaction did not occur when only silver nanoparticles were present. On the basis of this striking difference, an ultrasensitive method was developed for speciation analysis of Ag+ and AgNPs in complex matrices. The released Cd2+ was reduced to its volatile species by sodium tetrahydroborate, which was separated and swept to an inductively coupled plasma mass spectrometer (ICPMS) or an atomic fluorescence spectrometer (AFS) for the indirect but ultrasensitive detection of Ag+. Owing to the remarkable signal amplification via the cation exchange reaction and the advantages of chemical vapor generation for sampling, the limit of detection was 0.0003 μg L–1 for Ag+ by ICPMS, which was improved by 100-fold compared to the conventional method. Relative standard deviations are better than 2.5% at a concentration of 0.5 μg L–1 Ag+ or AgNPs regardless of the detector. The proposed method retains several unique advantages, including ultrahigh sensitivity, speciation analysis, simplicity and being organic reagent-free, and has been successfully utilized for speciation analysis of Ag+ and AgNPs in environmental water samples and paramecium cells.
Co-reporter:Dongyan Deng, Shu Zhang, He Chen, Lu Yang, Hui Yin, Xiandeng Hou and Chengbin Zheng
Journal of Analytical Atomic Spectrometry 2015 vol. 30(Issue 4) pp:882-887
Publication Date(Web):09 Jan 2015
DOI:10.1039/C4JA00436A
The integrity of chemical species throughout the analytical procedure and sample throughput are usually two serious impediments in elemental speciation. In this work, a simple solid sampling platform using multi-wall carbon nanotubes (MWCNTs) assisted matrix solid phase dispersion (MSPD) was constructed for online coupling to high performance liquid chromatography inductively coupled plasma mass spectrometry (HPLC-ICP-MS) for the high accuracy and sample throughput mercury speciation in fish samples. Owing to the large surface area and excellent mechanical strength of MWCNTs, which facilitate a sufficient dispersion of a sample matrix and diffusion of the eluent into the mixture of solid support and fish samples, a fast, efficient and online extraction of mercury species was achieved. Compared to the conventional MSPD and other sample pretreatment methods, the proposed method has several advantages including the integration of extraction, clean-up, separation and determination into one single step to achieve a high sample throughput, eliminating the need for derivatization of the Hg species and/or subsequent purification steps, reduced usage of solid supports, minimized contamination and mild operation conditions. The limits of detection of 9.9 ng g−1 and 8.4 ng g−1 were obtained for Hg2+ and CH3Hg+, respectively, based on 1 mg of fish sample. The accuracy of the proposed method was validated by analyzing two certified reference materials. The proposed method was applied for two fresh fish samples for Hg speciation.
Co-reporter:Yan Shen, Chengbin Zheng, Xiaoming Jiang, Xi Wu, Xiandeng Hou
Microchemical Journal 2015 Volume 123() pp:164-169
Publication Date(Web):November 2015
DOI:10.1016/j.microc.2015.06.002
•Hydride generation (HG) and photochemical vapor generation (PVG) were integrated for sample introduction to ICP-OES.•Formic acid was used as the simple medium of sample solution for the HG and PVG for accurate results.•The method was used for simultaneous multi-element analysis of traditional Chinese herbal medicine for several trace elements.A dual-mode chemical vapor generation (DM-CVG) sample introduction system that integrates hydride generation (HG) and photochemical vapor generation (PVG) was coupled to a commercial inductively coupled plasma optical emission spectrometer (ICP-OES) for simultaneous multi-element analysis of traditional Chinese medicine samples for trace hydride-forming elements and non–hydride-forming elements. Three hydride-forming elements (Cd, As, and Ge) and two non–hydride-forming but photochemical vapor–generating elements (Co and Ni) were selected as target elements to validate the proposed method. Optimum experimental conditions for DM-CVG-ICP-OES were carefully investigated, and satisfactory limits of detection (LODs), 0.2–1.4 μg L− 1, and relative standard deviations (RSDs), 1.3%–4.6%, were obtained for these target elements. A certified reference celery sample (GBW10048) was used to investigate the feasibility of the proposed method for real analysis. Strong suppression on the PVG efficiency occurred either when little nitric acid residue or some unknown coexisting materials remained in the sample solutions. Complete acid-evaporation/catching and moderate dilution of the digests could effectively alleviate this negative effect. Four different acid-evaporation/catching methods were performed and compared. Catching acid by adding an appropriate volume of formic acid gave the best signal response and the results agreed well with the certified values. Satisfactory analytical results were also obtained in real sample analysis of TCM Curcuma wenyujin Y.H. Chen et C. Ling.
Co-reporter:Jia Jia, Zhou Long, Chengbin Zheng, Xi Wu and Xiandeng Hou
Journal of Analytical Atomic Spectrometry 2015 vol. 30(Issue 2) pp:339-342
Publication Date(Web):19 Nov 2014
DOI:10.1039/C4JA00360H
Metal organic frameworks CAU-1 was used as a new photocatalyst for photochemical vapor generation, for the first time, with high reduction efficiency obtained for volatile species of Se(VI) for its sensitive determination by atomic fluorescence spectrometry with a limit of detection of 0.04 ppb for Se.
Co-reporter:Chenghui Li, Xue Jiang, Xiandeng Hou
Microchemical Journal 2015 Volume 119() pp:108-113
Publication Date(Web):March 2015
DOI:10.1016/j.microc.2014.11.005
•Nano-SiO2 was immobilized on the inner wall of a dielectric barrier discharge (DBD) tube.•Amine molecular optical emission in the DBD plasma was enhanced by the nano-SiO2.•The DBD device was used as a sensitive gas chromatograpic detector for five amines.•Trimethylamine in a carp fish sample was monitored with storage time.Nano-SiO2 was immobilized on the inner wall of a dielectric barrier discharge (DBD) tube, and it was coupled to a conventional gas chromatographer to investigate its performance as a molecular emission spectrometric detector for the determination of five volatile aliphatic amines. A charge-coupled device (CCD) was applied to observe the nano-SiO2-enhanced molecular emission spectra. The characteristic molecular emission bands of volatile aliphatic amines at 326.5 nm, 336.0 nm and 388.3 nm can be clearly resolved from the background emission spectra of carrier gas argon. The emission band of CN at 388.3 nm was used for quantitative detection of volatile aliphatic amines due to its high sensitivity. Nanomaterial catalysts including TiO2, MnO2, SiO2 and ZnO were tested to enhance the emission signal of amines, and SiO2 shows the best performance. The factors that influence the emission signal, such as discharge voltage, inner electrode length and carrier gas flow rate, were investigated in detail. The analytical performance of this method was evaluated by separation and detection of the mixture of five volatile aliphatic amines. Under the optimal experimental conditions, the limits of detection were found to be 4.4, 2.5, 2.2, 1.8 and 2.4 μg for dimethylamine, trimethylamine, n-butylamine, cyclohexylamine and ethylenediamine, respectively. This GC detector is not only sensitive but also fast in response to volatile aliphatic amines with good stability. Trimethylamine in a carp fish sample was monitored with storage time by the proposed method.
Co-reporter:Xue Jiang, Chenghui Li, Zhou Long and Xiandeng Hou
Analytical Methods 2015 vol. 7(Issue 2) pp:400-404
Publication Date(Web):20 Nov 2014
DOI:10.1039/C4AY02194K
In this work, nano-MnO2 was used to selectively enhance molecular/radical emission spectra in an atmospheric ambient temperature dielectric barrier discharge, based on which a portable spectrometer was developed for potential in-field analysis of trace benzene, toluene and xylene.
Co-reporter:Bingjun Han, Xiaoming Jiang, Xiandeng Hou, and Chengbin Zheng
Analytical Chemistry 2014 Volume 86(Issue 13) pp:6214
Publication Date(Web):May 26, 2014
DOI:10.1021/ac501272m
A simple, rapid, and portable system consisted of a laboratory-built miniaturized dielectric barrier discharge atomic emission spectrometer and a microwave-assisted persulfate oxidation reactor was developed for sensitive flow injection analysis or continuous monitoring of total organic carbon (TOC) in environmental water samples. The standard/sample solution together with persulfate was pumped to the reactor to convert organic compounds to CO2, which was separated from liquid phase and transported to the spectrometer for detection of the elemental specific carbon atomic emission at 193.0 nm. The experimental parameters were systematically investigated. A limit of detection of 0.01 mg L–1 (as C) was obtained based on a 10 mL sample injection volume, and the precision was better than 6.5% (relative standard deviation, RSD) at 0.1 mg L–1. The system was successfully applied for TOC analysis of real environmental water samples. The obtained TOC value of 30 test samples agreed well with those by the standard high-temperature combustion coupled nondispersive infrared absorption method. Most importantly, the system showed good capability of in situ continuous monitoring of total organic carbon in environmental water.
Co-reporter:Peng Wu, Ting Zhao, Jinyi Zhang, Lan Wu, and Xiandeng Hou
Analytical Chemistry 2014 Volume 86(Issue 20) pp:10078
Publication Date(Web):September 24, 2014
DOI:10.1021/ac501250g
A new sensor format was proposed here by integrating conjugation of analyte-recognition sites and quenching the luminescence of quantum dots (QDs) in one pot during the synthesis of QDs, with protease as the model analyte. Inherently phosphorescence-attenuated Mn-doped ZnS QDs were prepared with electron transfer protein cytochrome C (Cyt C) as the ligand, which was capable of protease sensing in both label-free and activable format. This detection strategy eliminates the postsynthetic protein conjugation and responses to analyte in the turn-on mode, lowering the signal background. In the presence of protease, the initially “locked” phosphorescence of Mn-doped ZnS QDs could be activated, due to the enzymatic digestion of surface Cyt C ligand and removal of the electron-transfer quenching unit away from the close-proximity of QDs. The proposed probe exhibited good selectivity toward proteases over other proteins and enzymes. Besides, it was also capable of differentiating active and inactive serine proteases. Analytical performance of this probe was evaluated using trypsin as the model serine protease. Limits of detection (LOD) of 2 nM was obtained, which is well below the average urine trypsin level of patients. The analytical application of this probe was demonstrated in determination of trypsin in human pancreatic carcinoma (PANC-1 and 818.4) cells lysates, demonstrating the potential usefulness of this probe in future clinical diagnosis.
Co-reporter:Bingjun Han, Xiaoming Jiang, Xiandeng Hou, and Chengbin Zheng
Analytical Chemistry 2014 Volume 86(Issue 1) pp:936
Publication Date(Web):December 11, 2013
DOI:10.1021/ac403662w
It was found that carbon atomic emission can be excited in low temperature dielectric barrier discharge (DBD), and an atmospheric pressure, low power consumption, and compact microplasma carbon atomic emission spectrometer (AES) was constructed and used as a universal and sensitive gas chromatographic (GC) detector for detection of volatile carbon-containing compounds. A concentric DBD device was housed in a heating box to increase the plasma operation temperature to 300 °C to intensify carbon atomic emission at 193.0 nm. Carbon-containing compounds directly injected or eluted from GC can be decomposed, atomized, and excited in this heated DBD for carbon atomic emission. The performance of this new optical detector was first evaluated by determination of a series of volatile carbon-containing compounds including formaldehyde, ethyl acetate, methanol, ethanol, 1-propanol, 1-butanol, and 1-pentanol, and absolute limits of detection (LODs) were found at a range of 0.12–0.28 ng under the optimized conditions. Preliminary experimental results showed that it provided slightly higher LODs than those obtained by GC with a flame ionization detector (FID). Furthermore, it is a new universal GC detector for volatile carbon-containing compounds that even includes those compounds which are difficult to detect by FID, such as HCHO, CO, and CO2. Meanwhile, hydrogen gas used in conventional techniques was eliminated; and molecular optical emission detection can also be performed with this GC detector for multichannel analysis to improve resolution of overlapped chromatographic peaks of complex mixtures.
Co-reporter:Xiaoming Jiang, Yi Chen, Chengbin Zheng, and Xiandeng Hou
Analytical Chemistry 2014 Volume 86(Issue 11) pp:5220
Publication Date(Web):May 7, 2014
DOI:10.1021/ac500637p
Direct introduction of liquid sample into a microplasma for analytical atomic spectrometry can be a problem for its lowered atomization/excitation capability or can even extinguish it. The low power dielectric barrier discharge (DBD) microplasma has been widely used in optical spectrometry, but the number of detectable elements by atomic emission spectrometry (AES) is very limited, partially for the same reason. Here we use electrothermally vaporized analyte-containing species for sample introduction into a DBD microplasma, together with simple heating of the DBD, to enhance its atomization/excitation capability for AES. A compact tungsten coil electrothermal vaporizer (W-coil ETV) was used in this work, onto which a tiny volume of liquid sample was pipetted. Through administrating the heating program for the W-coil, sample solvent and matrix were removed first and subsequently atomized/vaporized analyte with extra energy provided by the W-coil was swept directly into the DBD microplasma for further atomization/excitation. These significantly contribute the stability of the DBD microplasma and save its power for reatomization/excitation of analyte thus improving the detectability. Under optimized experimental conditions, limits of detection of 0.8 μg L–1 (0.008 ng) for cadmium and 24 μg L–1 (0.24 ng) for zinc were obtained, with relative standard deviation (RSD) of 3.2% for 5 μg L–1 Cd and 3.7% for 100 μg L–1 Zn. Its potential application was also demonstrated by successfully analyzing several Certified Reference Materials. Its characteristics including compactness, low power consumption, cost effectiveness, tiny sample requirement, and easy operation make it very promising for field analytical chemistry.
Co-reporter:Jia Jia, Fujian Xu, Shanling Wang, Xue Jiang, Zhou Long and Xiandeng Hou
Analyst 2014 vol. 139(Issue 14) pp:3533-3536
Publication Date(Web):06 May 2014
DOI:10.1039/C4AN00332B
Stable layered MoS2 nanosheets were employed as a stationary phase in gas chromatography. A wide range of different analytes were screened with excellent separation efficiency.
Co-reporter:Piaopiao Chen, Yujia Deng, Kuncheng Guo, Xiaoming Jiang, Chengbin Zheng, Xiandeng Hou
Microchemical Journal 2014 Volume 112() pp:7-12
Publication Date(Web):January 2014
DOI:10.1016/j.microc.2013.09.009
•A tungsten-coil was used as a trapping device and atomizer for cadmium volatile species.•Hydride generation was used for producing cadmium volatile species.•Cadmium atomic absorption was measured with a portable atomic absorption spectrometer.•Flow injection was used for high sample throughput.•The method is simple, fast and highly sensitive.Here we report the use of the tungsten-coil atomizer of a portable atomic absorption spectrometer as an on-atomizer trapping device and atomizer for the determination of trace cadmium, with flow injection hydride generation for production of volatile cadmium species from sample solutions. By mixing acidic analyte solution with tetrahydroborate solution, volatile cadmium species is produced and separated from the solution, and then transported and impacted onto the surface of the atomizer with a heating current set at 2.3 A. Subsequent atomic absorption measurement was accomplished with in situ atomization at 8.5 A. Compared to conventional direct injection, the sensitivity and the limit of detection were improved by 58- and 66-fold, respectively, based on 5.0 mL sampling volume. In addition, use of flow injection significantly improved sample throughput. The proposed method was used for the analysis of several real water samples with good spiked recoveries.
Co-reporter:Yan Zeng, Chengbin Zheng, Xiandeng Hou, Shanling Wang
Microchemical Journal 2014 Volume 117() pp:83-88
Publication Date(Web):November 2014
DOI:10.1016/j.microc.2014.06.010
•Photochemical carbonyl generation removes nickel impurities from carbon nanotubes.•The purified product well keeps the physical and chemical properties.•The purification process is simple, green and cost-effective.•This can be easily real-time monitored by atomic fluorescence spectrometry.A new method was proposed to remove trace nickel catalyst impurities from carbon nanotube (CNT) materials by the use of UV-induced photochemical carbonyl generation, and the process was real-time monitored by atomic fluorescence spectrometry. The CNTs were purified under mild optimal experimental conditions, and the characteristics of the purified CNTs were kept well. After purification, the content of nickel in the CNT materials was reduced from 1% to 0.4%, with a removal efficiency of 60%. The produced volatile nickel carbonyl was separated and introduced into an argon/hydrogen flame atomizer-atomic fluorescence spectrometer for measuring nickel atomic fluorescence signal to real-time monitor the purification process.
Co-reporter:Xi Wu, Xiaoming Jiang, Qian Chen, Yunfei Tian, Xiandeng Hou
Microchemical Journal 2014 Volume 116() pp:157-162
Publication Date(Web):September 2014
DOI:10.1016/j.microc.2014.05.001
•Spark discharge was coupled with ICP-OES to expand its applications.•Direct solid sampling was achieved through the spark ablation.•Elemental depth profiling of thin film metallic samples was achieved.•Elemental imaging of conductive sample surface was possible.Spark ablation was coupled to inductively coupled plasma-optical emission spectrometry (ICP-OES) for direct solid sample introduction. The preliminary applications including elemental depth profiling of metallic thin films and surface elemental imaging for solid conductive samples were explored to expand the applications of traditional ICP-OES. The parameters affecting the spark discharge for ablation sampling including electrode materials, electrode gap, discharge voltage, and gas flow rate were investigated in details. The mechanism of spark ablation was also briefly discussed with data of X-ray photoelectron spectroscopy.
Co-reporter:Yi Chen, Mengtian Li, Lulu Fu, Xiandeng Hou, Xiaoming Jiang
Microchemical Journal 2014 Volume 114() pp:182-186
Publication Date(Web):May 2014
DOI:10.1016/j.microc.2014.01.002
•Ultrasensitive elemental analysis of a single human hair was achieved by electrothermal vaporization-flame AFS.•Simple, fast and efficient digestion of hair was adapted.•Simultaneous determination of Cd and Pb was achieved by a dual-channel detection mode.•The method featured with high sensitivity, tiny sampling volume, simplicity and cost-effectiveness.•It is potentially useful for fingerprinting trace elements of a single string of hair for forensic purpose.A new method was proposed for simultaneous determination of ultratrace cadmium and lead in a single string of human hair by coupling of a tungsten coil electrothermal vaporizer (W-coil ETV) and an argon–hydrogen flame for atomic fluorescence spectrometry (Ar–H2 flame AFS). The sample digestion and experimental conditions for the determination of cadmium and lead in a single hair were investigated in detail. Under the optimal conditions, the limits of detection (LODs, 3σ) were 0.05 pg and 3 pg for Cd and Pb, respectively. The accuracy of the proposed method was demonstrated by analyzing a certified reference hair sample and several adult hair samples for trace Cd and Pb. By use of its high sensitivity and low sample consumption (typically 10 μL), it is potentially useful for determination of trace elements in a single string of hair from career and crime scenes for forensic purpose.
Co-reporter:Yan Zeng, Kailai Xu, Xiandeng Hou, Xiaoming Jiang
Microchemical Journal 2014 Volume 114() pp:16-21
Publication Date(Web):May 2014
DOI:10.1016/j.microc.2013.11.013
•A gas chromatographer was integrated with an atomic fluorescence spectrometer;•An argon-hydrogen flame guaranteed compact integration without any transportation interface;•Speciation analysis of dimethyl selenide and dimethyl diselenide was achieved;•Simultaneous determination of tetramethyl tin and tetraethyl lead was achieved by two-channel detection.Gas chromatographic separation was coupled with atomic fluorescence spectrometry (GC–AFS) directly via argon-hydrogen flame for integrated GC–AFS instrumentation, i.e., the outlet end of the GC column was directly put into the bottom of the Ar-H2 flame atomizer without any transportation interface. This laboratory-constructed GC–AFS instrument was preliminarily characterized by its application for the speciation analysis of dimethyl selenide ((Met)2Se) and dimethyl diselenide ((Met)2Se2) as well as the two-channel simultaneous determination of tetramethyl tin (Sn(Met)4) and tetraethyl lead (Pb(Et)4). Under the optimized experimental conditions, the absolute limits of detection of 9.4 pg for (Met)2Se, 3.8 pg for (Met)2Se2, 0.23 ng for Sn(Met)4 and 0.39 ng for Pb(Et)4 were obtained. The coupling is simple, and the whole instrument is compact.
Co-reporter:Dr. Peng Wu;Jinyi Zhang;Dr. Shanlin Wang;Airu Zhu ;Dr. Xieng Hou
Chemistry - A European Journal 2014 Volume 20( Issue 4) pp:952-956
Publication Date(Web):
DOI:10.1002/chem.201303753
Abstract
Monitoring the in situ growth of Mn-doped ZnS quantum dots is shown to be a route to selectively detect H2S, an important endogenously produced signalling molecule. The use of Mn2+ as a dopant resulted in orange phosphorescence, making it possible to avoid the background fluorescence from biological surroundings that can occur at other wavelengths. The choice of ZnS QDs as the host material ensured selectivity, since only sulfide can precipitate Zn2+ and Mn2+ from aqueous solution.
Co-reporter:Hui Xia, Ronghui Zhou, Chengbin Zheng, Peng Wu, Yunfei Tian and Xiandeng Hou
Analyst 2013 vol. 138(Issue 13) pp:3687-3691
Publication Date(Web):08 Apr 2013
DOI:10.1039/C3AN00407D
The present work describes a new solution-free strategy for preparation of cluster-like nano/micro CuO/ZnO particles in dielectric barrier discharge (DBD) in which the brass acts as the inner electrode. The cataluminescence (CTL) behaviour of such prepared material for acetic acid was studied for analytical application. Under the optimized conditions, the linear range of CTL intensity versus concentration of acetic acid are 6 mg L−1 to 500 mg L−1 with the limit of detection (LOD) of 3 mg L−1, no significant interference was found. The new method shows great advantages because it is a process without any solution and complex equipment. The synthetic material was directly used for the cataluminescence sensing of acetic acid without other preliminary treatment and it shows high selectivity, satisfactory stability, and better sensitivity and linearity.
Co-reporter:Yunfei Tian, Peng Wu, Xi Wu, Xiaoming Jiang, Kailai Xu and Xiandeng Hou
Analyst 2013 vol. 138(Issue 8) pp:2249-2253
Publication Date(Web):20 Feb 2013
DOI:10.1039/C3AN36859A
A simple and economical multi-channel optical sensor using corona discharge radical emission spectroscopy is developed and explored as an optical nose for discrimination analysis of volatile organic compounds, wines, and even isomers.
Co-reporter:Xianxiang Wang, Peng Wu, Xiandeng Hou and Yi Lv
Analyst 2013 vol. 138(Issue 1) pp:229-233
Publication Date(Web):19 Oct 2012
DOI:10.1039/C2AN36112D
A simple fluorescence sensor for sensitive turn-off detection of ascorbic acid (AA) was developed by using protein-modified Au nanoclusters in aqueous media. The sensing mechanism is originated from the oxidation state change of Au nanoclusters controlled by AA. Under optimal experimental conditions, a good linear relationship between the relative fluorescence quenching intensity and the concentration of AA can be obtained in the range of 1.5 to 10 μM, with a detection limit as low as 0.2 μM. The proposed method is simple, efficient and reliable for monitoring of AA in some biological samples.
Co-reporter:Jing Hu, Peng Wu, Dongyan Deng, Xiaoming Jiang, Xiandeng Hou, Yi Lv
Microchemical Journal 2013 Volume 108() pp:100-105
Publication Date(Web):May 2013
DOI:10.1016/j.microc.2012.10.005
In this work, mimicking the preparation of solid catalyst in heterogeneous catalysis, a composite for sensing was constructed by the loading of mercaptopropionic acid (MPA) capped CdTe nanocrystals (NCs) on the porous silicon surface (PSi/CdTe NCs composite). Since water vapor could effectively enhance the photoluminescence of CdTe NCs on PSi, the as-prepared composite was engineered into an optical humidity sensor. Time-resolved fluorescence measurements showed that the loading of CdTe NCs onto PSi and post-photoradiation led to the generation of surface traps on the surface of CdTe NCs. Upon adsorption of water molecules, the amounts of surface traps were effectively decreased, thus providing PL improvement. By employing the proper modification strategy, this humidity sensor achieved the convenience and repeatability in construction of the sensing layer, good sensitivity and stability. This humidity sensor also shows good selectivity against common volatile organic compounds. For absolute humidity, the linear range was 2–40 μg/mL in N2 or 1.3–26.7 μg/mL in dry air, both with a limit of detection of 0.3 μg/mL. For relative humidity (RH), the linear range could be from 12% to 93% at 20 °C. This sensor was also successfully applied in the RH determination of real air samples, with results well agreed with a commercial hygrometer.Highlights► CdTe NCs modified porous silicon is employed as sensing composite. ► Water vapor can effectively enhance the photoluminescence of CdTe NCs on PSi. ► Electrostatic assembly presents the convenience and repeatability in its construction. ► It should be promising in on-site monitoring humidity of environment, warehouse areas and more.
Co-reporter:Ke Huang, Kailai Xu, Xiandeng Hou, Yun Jia, Chengbin Zheng and Lu Yang
Journal of Analytical Atomic Spectrometry 2013 vol. 28(Issue 4) pp:510-515
Publication Date(Web):23 Jan 2013
DOI:10.1039/C3JA30363B
A novel, simple, low power, low temperature (<45 °C) and high efficiency atomization technique using ultraviolet (UV) radiation was proposed for the atomization of gaseous mercury hydrides for their determination by atomic fluorescence spectrometry (AFS). This technique was used for the detection of inorganic mercury (Hg2+) and organic mercury (MeHg+ and EtHg+) after high performance liquid chromatographic separation. In the proposed method, with 0.5% (m/v) KBH4 used as a reductant, inorganic mercury was reduced to elemental mercury, whereas the organic mercury species formed their respective volatile organic mercury hydrides (MeHgH and EtHgH) which were flushed to the UV atomizer for atomization and AFS detection. Under the optimized experimental conditions, the limits of detection were found to be 0.38, 0.41 and 0.56 μg L−1, and the relative standard deviations (n = 3) were 1.1%, 2.6% and 1.4% for Hg2+, MeHg+ and EtHg+, respectively. The accuracy of the proposed method was validated by analyzing a certified reference sample (fish muscle tissue) with a satisfactory analytical result, and two water samples with recoveries in the range of 93.8–97.4%.
Co-reporter:ChengHui Li;Rui Liu;Yi Lü;Peng Wu
Science Bulletin 2013 Volume 58( Issue 17) pp:2017-2026
Publication Date(Web):2013 June
DOI:10.1007/s11434-013-5795-1
The applications of nano-surface chemistry in the field of spectral analysis have attracted growing interest in recent years. In this article, we reviewed the applications of nanomaterials-based chemical reactions for spectral analysis, including the development in plasma-catalysis, surface-enhanced spectroscopy, separation and preconcentration, chemical vapor generation, labeling and signal amplification. Introduction of nano-surface chemistry to spectral analysis not only improves the sensitivity and selectivity, broadens the application range of spectral analysis, but also affords analytical community special characterization tools.
Co-reporter:Yunfei Tian, Xi Wu, Xiaoming Jiang, Xiandeng Hou
Microchemical Journal 2013 110() pp: 140-145
Publication Date(Web):
DOI:10.1016/j.microc.2013.03.008
Co-reporter:Dr. Peng Wu;Ting Zhao;Yunfei Tian;Dr. Lan Wu ;Dr. Xieng Hou
Chemistry - A European Journal 2013 Volume 19( Issue 23) pp:7473-7479
Publication Date(Web):
DOI:10.1002/chem.201204035
Abstract
Proteins typically have nanoscale dimensions and multiple binding sites with inorganic ions, which facilitates the templated synthesis of nanoparticles to yield nanoparticle–protein hybrids with tailored functionality, water solubility, and tunable frameworks with well-defined structure. In this work, we report a protein-templated synthesis of Mn-doped ZnS quantum dots (QDs) by exploring bovine serum albumin (BSA) as the template. The obtained Mn-doped ZnS QDs give phosphorescence emission centered at 590 nm, with a decay time of about 1.9 ms. A dual-channel sensing system for two different proteins was developed through integration of the optical responses (phosphorescence emission and resonant light scattering (RLS)) of Mn-doped ZnS QDs and recognition of them by surface BSA phosphorescent sensing of trypsin and RLS sensing of lysozyme. Trypsin can digest BSA and remove BSA from the surface of Mn-doped ZnS QDs, thus quenching the phosphorescence of QDs, whereas lysozyme can assemble with BSA to lead to aggregation of QDs and enhanced RLS intensity. The detection limits for trypsin and lysozyme were 40 and 3 nM, respectively. The selectivity of the respective channel for trypsin and lysozyme was evaluated with a series of other proteins. Unlike other protein sensors based on nanobioconjugates, the proposed dual-channel sensor employs only one type of QDs but can detect two different proteins. Further, we found the RLS of QDs can also be useful for studying the BSA–lysozyme binding stoichiometry, which has not been reported in the literature. These successful biosensor applications clearly demonstrate that BSA not only serves as a template for growth of Mn-doped ZnS QDs, but also impacts the QDs for selective recognition of analyte proteins.
Co-reporter:Dongyan Deng, Jingrong Zhou, Xi Ai, Lu Yang, Xiandeng Hou and Chengbin Zheng
Journal of Analytical Atomic Spectrometry 2012 vol. 27(Issue 2) pp:270-275
Publication Date(Web):01 Dec 2011
DOI:10.1039/C1JA10244C
An ultrasensitive, simple and interference-free method using nano-TiO2 preconcentration and in situ slurry hydride generation (HG) coupled with atomic fluorescence spectrometry (AFS) was developed for the determination of trace selenium. Total Se reduced in Se(IV) form can be selectively adsorbed on TiO2 at pH < 8 for pre-concentration, and then separated and slurried/released by a mixture containing 3% (m/v) KBH4 and 1% (m/v) KOH. The slurry solution was mixed with 25% (v/v) HCl to generate selenium hydrides, which was subsequently separated from the liquid phase for subsequent AFS detection. Optimum conditions for adsorption, disadsorption and hydride generation of selenium as well as potential interferences from concomitant ions were investigated. Due to the repulsive force between the positively charged TiO2 and metal cationic ions, this approach permits 1000 mg L−1 for Fe3+, Ni2+ and Co2+, 500 mg L−1 for Cu2+ or 100 mg L−1 for Ag+ and Au3+ present in a 5 μg L−1Se(IV) solution without any significant interferences. A limit of detection of 0.0006 μg L−1 was obtained by sampling a 40 mL sample solution. Compared to the conventional HG method, the sensitivity and the limit of detection were improved 17- and 16-fold by the present method, respectively. The proposed method was successfully applied for the determination of trace selenium in several real samples.
Co-reporter:Xiaoming Jiang, Peng Wu, Dongyan Deng, Ying Gao, Xiandeng Hou and Chengbin Zheng
Journal of Analytical Atomic Spectrometry 2012 vol. 27(Issue 10) pp:1780-1786
Publication Date(Web):11 Jun 2012
DOI:10.1039/C2JA30110E
A novel compact tandem atomizer is described and evaluated for its analytical performance using atomic fluorescence spectrometry (AFS). The atomizer simply comprises an argon–hydrogen (Ar–H2) flame atomizer and an electrothermal atomization/vaporization (ETV) sampling device, which utilizes a tungsten coil (W-coil) onto which a liquid sample is pipetted, and subsequently the analyte is electrothermally atomized/vaporized and swept directly into the highly reducing environment of the Ar–H2 flame atomizer for further atomization and detection. The flame sits directly on top of the W-coil without any interface tubing. Improvements in elemental coverage, sensitivity and minimization of analyte loss as well as reduction of reagent consumption were simultaneously achieved by the use of this technique. The absolute limits of detection (LODs) are comparable to those obtained by GF-AAS but provide significant improvements over FAAS and ICP-OES. Its application example was demonstrated by analyzing several Certified Reference Materials and environmental water samples for ultratrace Cd, Pb, Au and Ag.
Co-reporter:Yi Wu, Yong-Ill Lee, Li Wu, Xiandeng Hou
Microchemical Journal 2012 Volume 103() pp:105-109
Publication Date(Web):July 2012
DOI:10.1016/j.microc.2012.01.011
A simple method was proposed for mercury cold vapor generation (CVG) in tetramethylammoniumhydroxide (TMAH) solution for speciation analysis of ultratrace inorganic mercury and total mercury in biological samples by inductively coupled plasma mass spectrometry (ICP-MS). Prior to analysis, 100–300 mg of the biological sample was accurately weighed into a conical tube. Then, 2 mL of 25% (m/v) TMAH solution was added to the sample, incubated at room temperature for several hours (hair, 3 h), and diluted to 25 mL with water. Finally, inorganic mercury was directly determined by CVG-ICP-MS, while microwave-assisted oxidation with H2O2 was needed for total mercury detection. The concentration of organic mercury, mainly methylmercury, was obtained by difference of total mercury and inorganic mercury. Only one calibration curve against mercury aqueous standards in 2% TMAH medium was needed for both procedures. Optimum conditions for mercury CVG, as well as sample preparation and microwave-assisted digestion were investigated in detail. A limit of detection (LOD, 3σ) of 3 ng L− 1 was obtained and the linear working range was 0.1–100 μg L− 1. Validation data were provided based on the analysis of water samples, as well as a CRM human hair sample (GBW 070601). This is a simple, rapid, ultrasensitive and relatively green method for the determination of mercury in water and biological samples.Highlights► Mercury and methylmercury were determined by cold vapor generation-inductively coupled plasma-mass spectrometry. ► Tetramethylammoniumhydroxide was used for sample digestion and mercury cold vapor generation. ► Water and hair samples were analyzed for mercury and methylmercury by this simple and ultrasensitive method.
Co-reporter:Ying Gao, Zeming Shi, Zhou Long, Peng Wu, Chengbin Zheng, Xiandeng Hou
Microchemical Journal 2012 Volume 103() pp:1-14
Publication Date(Web):July 2012
DOI:10.1016/j.microc.2012.02.001
Mercury and its compounds are ubiquitous in the environment. Much concern has been attracted to the determination of mercury and its species due to their high toxicity and biomagnification. The state of the arts of mercury determination and speciation analysis and its applications in environmental and biological sciences since 2008 are reviewed with 133 references. The methodological innovations in sample preparation, preconcentration, instrumentation and speciation analysis are summarized, and the future perspectives are briefly discussed and speculated.Highlights► A comprehensive review on mercury species detemination by atomic spectrometry with 133 references. ► Sample preparation, preconcentration, instrumentation and speciation analysis of real samples are summarized. ► The future perspectives are briefly discussed and speculated.
Co-reporter:Ke Huang, Hui Xia, Mengtian Li, Ying Gao, Chengbin Zheng and Xiandeng Hou
Analytical Methods 2012 vol. 4(Issue 12) pp:4058-4062
Publication Date(Web):26 Sep 2012
DOI:10.1039/C2AY25888A
A new efficient method was described for the purification of K3[Fe(CN)6] for the purpose of minimization of the blank in the determination of trace lead by hydride generation-atomic fluorescence spectrometry using the HCl–K3[Fe(CN)6]–KBH4 system. The lead impurity in K3[Fe(CN)6] solution was removed by reacting with KBH4 to form PbH4, which was efficiently separated from the solution by a nitrogen gas flow. The purified K3[Fe(CN)6] was obtained via Cl2 oxidation and subsequent ethanol purification of its reduced compound. The optimum conditions for hydride generation of lead and purification of K3[Fe(CN)6] were carefully investigated. A limit of detection (LOD) of 0.05 μg L−1 was obtained, 100-fold better than that achieved with unpurified K3[Fe(CN)6]. The accuracy of the proposed method was validated by analyzing a Certified Reference hair sample (GBW07610) and two ore samples (GBW07106 and GBW07112) with satisfactory analytical results.
Co-reporter:Xiaoming Jiang, Ke Huang, Dongyan Deng, Hui Xia, Xiandeng Hou, Chengbin Zheng
TrAC Trends in Analytical Chemistry 2012 Volume 39() pp:38-59
Publication Date(Web):October 2012
DOI:10.1016/j.trac.2012.06.002
Nanomaterials have attracted considerable interest in analytical chemistry (e.g., sample pre-concentration, molecular probes, and biological and electrochemical sensing). However, their physico-chemical and surface properties are significantly affected by their size and morphology, and impurities.This article reviews the general applications of nanomaterials in analytical atomic spectrometry, including their use to improve the sensitivity and the selectivity of atomic spectrometric methods, to broaden the application range to biological-molecule detection, and to characterize and to determine nanomaterials themselves and their impurities.Highlights► Nanomaterials used in analytical atomic spectrometry for preconcentration/separation. ► Nanomaterials are used in analytical atomic spectrometry to enhance sensitivity. ► Elemental impurities in nanomaterials determined by analytical atomic spectrometry. ► Nanomaterials can be characterized by using analytical atomic spectrometry.
Co-reporter:Wei Li, Chengbin Zheng, Guangyu Fan, Li Tang, Kailai Xu, Yi Lv, and Xiandeng Hou
Analytical Chemistry 2011 Volume 83(Issue 13) pp:5050
Publication Date(Web):May 23, 2011
DOI:10.1021/ac2007224
A novel microplasma molecular emission spectrometer based on an atmospheric pressure dielectric barrier discharge (DBD) is described and further used as a promising multichannel GC detector for halohydrocarbons. The plasma is generated in a DBD device consisting of an outer electrode (1.2 mm in diameter) and an inner electrode (1.7 mm in diameter) within a small quartz tube (3.0 mm i.d. × 5.0 mm o.d. × 50 mm), wherein analyte molecules are excited by the microplasma to generate molecular emission. Therefore, the analytes are selectively and simultaneously detected with a portable charge-coupled device (CCD) via multichannel detection of their specific emission lines. The performance of this method was evaluated by separation and detection of a model mixture of chlorinated hydrocarbons (CHCl3 and CCl4), brominated hydrocarbons (CH2Br2 and CH2BrCH2Br), and iodinated hydrocarbons (CH3I and (CH3)2CHI) undergoing GC with the new detector. The completely resolved identification of the tested compounds was achieved by taking advantages of both chromatographic and spectral resolution. Under the optimized conditions with the CCD spectrometer set at 258, 292, and 342 nm channels for determination of chlorinated hydrocarbons, brominated hydrocarbons, and iodinated hydrocarbons, respectively, this detector with direct injection provided detection limits of 0.07, 0.06, 0.3, 0.04, 0.05, and 0.02 μg mL–1 for CCl4, CHCl3, CH2Cl2, CH3I, CH3CH2I, and (CH3)2CHI, respectively.
Co-reporter:Jing Hu, Xiaoming Jiang, Lan Wu, Kailai Xu, Xiandeng Hou, and Yi Lv
Analytical Chemistry 2011 Volume 83(Issue 17) pp:6552
Publication Date(Web):July 18, 2011
DOI:10.1021/ac2008459
In this work, a novel dual-channel sensing mode, i.e., UV-induced surface photovoltage (SPV) and photoluminescence (PL) on n-type Si/TiO2/Eu3+-doped TiO2 (n-Si/TiO2/TiO2:Eu), was demonstrated for the discrimination of 20 volatile compounds. The SPV signaling in this work employed a laboratory-constructed microvoltammeter with good analytical performances. This device also features wireless communication, portability, along with low cost and power consumption. The SPV and PL pattern of each analyte was distinct, and the hierarchical clustering analysis (HCA) result showed that these 20 volatile species were distinguishable, even for structural isomers. Linear discriminant analysis (LDA) further demonstrated the robustness of this sensor: 180 unknown samples from three groups at concentrations of 15.3, 31.7, and 79.2 mg/L were classified with accuracies of 96.7%, 95.0%, and 100%, respectively. Principal component analysis (PCA) revealed that SPV and PL channels contributed equally to the good discrimination ability due to two distinct sensing mechanisms. This dual-channel sensor was also successfully applied in the discrimination of beverage samples such as liquor, wine, and vinegar.
Co-reporter:Wei Li, Xiaoming Jiang, Kailai Xu, Xiandeng Hou, Chengbin Zheng
Microchemical Journal 2011 Volume 99(Issue 1) pp:114-117
Publication Date(Web):September 2011
DOI:10.1016/j.microc.2011.04.005
A dielectric barrier discharge (DBD) was used as a new atmospheric optical emission detector for the determination of trace nitrogen in pure argon gas in this work. The whole system was composed of an ac ozone generation device for power supply, a six-way valve, a laboratory-built DBD device and a USB2000 charge coupled device (CCD). Trace nitrogen in argon was detected at nitrogen molecular emission line of 337 nm. This method features with several advantages: atmospheric working condition, low power consumption (≤ 12 W), simple and cheap instrumentation, fast response and high sensitivity and accuracy. Under the optimized conditions, the limits of detection can be down to 34 ppb.
Co-reporter:Xi Wu, Wulin Yang, Menggang Liu, Xiandeng Hou and Chengbin Zheng
Journal of Analytical Atomic Spectrometry 2011 vol. 26(Issue 6) pp:1204-1209
Publication Date(Web):14 Mar 2011
DOI:10.1039/C1JA10016E
Mercury solution without or with formic acid was introduced into a low temperature argon plasma from dielectric barrier discharge (DBD). Mercury vapor generated in the DBD was separated from the liquid phase and finally swept into an inductively coupled plasma optical emission spectrometer (ICP-OES) for determination. The optimum conditions for the proposed technique and operation of the ICP-OES, as well as interferences from concomitants, were investigated in detail. It was found that the vapor generation efficiency of mercury could be significantly enhanced with the addition of formic acid. However, the efficiency was reduced sharply in the presence of chloride ions or oxidizing substances of high concentration. Under the optimized conditions, a limit of detection of 0.090 μg L−1 and a precision of 2.1% RSD at a concentration of 10 μg L−1 were achieved by the proposed method. The new DBD-induced mercury vapor generation provides several advantages including low power consumption (<25 W), green analytical chemistry, cost-effectiveness, smaller size, long operation lifetime, and ease of on-line operation. The methodology has been successfully applied to the determination of mercury in a certified reference water sample and mineral water samples.
Co-reporter:Xiandeng Hou
Journal of Analytical Atomic Spectrometry 2011 vol. 26(Issue 6) pp:1113-1114
Publication Date(Web):11 Mar 2011
DOI:10.1039/C1JA90010B
A graphical abstract is available for this content
Co-reporter:Xianxiang Wang, Peng Wu, Yi Lv, Xiandeng Hou
Microchemical Journal 2011 Volume 99(Issue 2) pp:327-331
Publication Date(Web):November 2011
DOI:10.1016/j.microc.2011.06.004
Based on the cross-linking nature of BSA in the presence of glutaraldehyde (GA), the fluorescence of BSA-stabilized Au nanoclusters was effectively quenched by GA. A new method for ultrasensitive GA detection in water samples was thus developed with fluorescent BSA-stabilized Au nanoclusters. The fluorescence quenching of BSA-stabilized Au nanoclusters in the presence of GA fitted to Stern-Volmer equation. In the GA concentration range of 0.8–6 μM, a linear relationship of F0/F versus GA concentration was obtained with a limit of detection (LOD) of 0.2 μM. The relative standard deviation of 5 replicate measurements of 4 μM GA is 1.3%. This method shows good selectivity over other organics in water samples. The feasibility of the new sensor for GA in different water samples was demonstrated.
Co-reporter:Xianxiang Wang, Yi Lv, Xiandeng Hou
Talanta 2011 Volume 84(Issue 2) pp:382-386
Publication Date(Web):15 April 2011
DOI:10.1016/j.talanta.2011.01.012
The interaction between mercaptoacetic acid (MA)-capped CdTe QDs, MA-capped CdTe/ZnS QDs or glutathione (GSH)-capped CdTe QDs with As(III) was studied using fluorescence spectrometry. As (III) has a high-affinity to reduced-GSH to form As(SG)3, and the emission of the GSH-capped CdTe QDs (λem. = 612 nm) is quenched effectively. Thus, a novel fluorescence spectrometric method was developed for As (III) determination by using GSH-CdTe QDs. Under optimal conditions, the quenched fluorescence intensity (F0/F) increased linearly with the concentration of As (III) ranging from 5.0 × 10−6 to 25 × 10−5 mol L−1. The limit of detection (3σ) for As (III) was found to be 2 × 10−8 mol L−1. This method is potentially useful in visual detection of As (III) under irradiation of the ultraviolet light.
Co-reporter:Lichun Zhang;Xiaoling Hou;Dr. Ming Liu; Yi Lv; Xieng Hou
Chemistry - A European Journal 2011 Volume 17( Issue 25) pp:7105-7111
Publication Date(Web):
DOI:10.1002/chem.201002626
Abstract
Y2O3 dumbbells, microspheres, and nanosheets were synthesized by a facile hydrothermal procedure followed by calcination. Electron microscopy, X-ray diffraction, and N2 adsorption measurements were used to characterize the yttrium oxide microstructures. On the basis of a time-dependent study of nanostructure evolution and the effect of other processing parameters, a kinetic “homogeneous nucleation–self assembly–anisotropic growth” mechanism is proposed to explain the growth of these microstructures under hydrothermal conditions. The sensitivity of as-prepared Y2O3 structures to a series of gaseous chemicals was examined by using a homemade cataluminescence sensing system. The designed cataluminescence sensor based on the yttrium oxide dumbbells shows good sensing performance for 16 common volatile organic compounds.
Co-reporter:Chengbin Zheng, Ralph E. Sturgeon, Christine S. Brophy, Shaopan He and Xiandeng Hou
Analytical Chemistry 2010 Volume 82(Issue 7) pp:2996
Publication Date(Web):March 11, 2010
DOI:10.1021/ac100059b
A novel approach to the generation of volatile iron compounds (likely the pentacarbonyl) with high efficiency is described, wherein solutions containing either Fe2+ or Fe3+ and low molecular weight organic acids such as formic, acetic or propionic are exposed to a UV source. An optimum generation efficiency of 60 ± 2% was achieved in 50% formic acid at pH 2.5 with an irradiation time of 250 s by use of a 17 W low-pressure mercury grid lamp. Compared to conventional solution nebulization, sensitivity and limit of detection were improved 80- and 100-fold, respectively, at the 238.204 nm Fe II emission line. A precision of 0.75% RSD was achieved at a concentration of 100 ng/mL. Photochemical vapor generation sample introduction was used for the determination of trace iron in several environmental Certified Reference Materials, including National Research Council Canada DORM-3 fish muscle tissue, DOLT-3 and DOLT-4 fish liver tissues, and SLRS-5 river water, providing analytical results in excellent agreement with certified values based on a simple external calibration.
Co-reporter:Chengbin Zheng, Lu Yang, Ralph E. Sturgeon and Xiandeng Hou
Analytical Chemistry 2010 Volume 82(Issue 9) pp:3899
Publication Date(Web):April 5, 2010
DOI:10.1021/ac1004376
A novel, sensitive method is described for the accurate determination of Ni, Se, and Fe in biological tissues by isotope dilution inductively coupled plasma mass spectrometry (ID ICPMS) based on sample introduction arising from online UV photochemical vapor generation (UV-PVG). Volatile species of Ni, Se, and Fe were liberated from a formic acid medium following exposure to a UV source. Sensitivities were enhanced 27- to 355-fold compared to those obtained using pneumatic nebulization sample introduction. Although precision was slightly degraded (a factor of 2) with ultraviolet photochemical mediated vapor generation (UV-PVG), limits of detection (LODs) of 0.18, 1.7, and 1.0 pg g−1 for Ni, Se, and Fe, respectively, based on an external calibration, provided 28-, 150-, and 29-fold improvements over that realized with conventional pneumatic solution nebulization. Method validation was demonstrated by determination of Ni, Se, and Fe in biological tissue certified reference materials (CRMs) TORT-2 and DORM-3. Concentrations of 2.33 ± 0.03, 5.80 ± 0.28, and 109 ± 2 μg g−1 (1SD, n = 4) and 1.31 ± 0.04, 3.35 ± 0.18, and 353 ± 5 μg g−1 (1SD, n = 4) for Ni, Se, and Fe, respectively were obtained in TORT-2 and DORM-3, in good agreement with certified values.
Co-reporter:Xinfeng Zhang, Qin Zhou, Yi Lv, Lan Wu, Xiandeng Hou
Microchemical Journal 2010 Volume 95(Issue 1) pp:80-84
Publication Date(Web):May 2010
DOI:10.1016/j.microc.2009.10.009
By use of the high separation capability of capillary electrophoresis (CE) and ultrasensitive chemiluminescence (CL) detection, a CE–CL method was proposed for the ultrasensitive determination of trace cobalt in a single hair, which is potentially useful in construction of the fingerprint of trace elements in the hair collected from crime scenes. In this work, the CE experimental conditions, CL experimental conditions and the digestion methods for the analysis of a single hair sample for cobalt were investigated in detail. The relative limit of detection (LOD, 3σ) was 0.01 ng/mL, and the absolute LOD was 2.4 × 10− 16 g considering the sampling volume of 24 nL. Using a dry digestion method, the analytical results for certified reference hair samples by the proposed method were in good agreement with the certified values. Finally, this method was successfully used to detect trace cobalt in a single hair from three adults. It has potential applications in forensic analysis.
Co-reporter:Chujie Zeng, Xiaodong Wen, Zhiqiang Tan, Pingyang Cai, Xiandeng Hou
Microchemical Journal 2010 Volume 96(Issue 2) pp:238-242
Publication Date(Web):November 2010
DOI:10.1016/j.microc.2010.03.008
Hollow fiber supported liquid membrane extraction (HF-SLME) was used to separate and enrich trace lead from a large volume of 250 mL water sample to a final tiny volume of 30 μL of 1-octanol, 5 μL of which was inject into a tungsten coil electrothermal atomic absorption spectrometer (W-coil ET-AAS) for determination of lead. Some important parameters that influenced the extraction and determination were investigated in detail, such as the concentration of ammonium pyrrolidine dithiocarbamate (APDC), pH of sample solution, stirring rate, extraction time, pyrolysis current, atomization current, carrier gas flow rate, as well as interferences. Under the optimized conditions, a practical enrichment factor of 499 and a limit of detection (3σ) of 0.2 ng mL− 1 were obtained. The calibration curve was linear in the range of 0.5–10 ng mL− 1. The relative standard deviation (RSD) was 5.6% for five measurements of a 4 ng mL− 1 lead standard solution. The accuracy of this method was examined by the analysis of certified reference water samples (GBW(E)080398 and GSBZ(E) 50009-88) for lead. Finally, the proposed method was applied to the determination of lead in local tap water, pond water and river water, with recoveries in the range of 96–109% for spiked samples.
Co-reporter:Hao Deng, Chengbin Zheng, Liwei Liu, Li Wu, Xiandeng Hou, Yi Lv
Microchemical Journal 2010 Volume 96(Issue 2) pp:277-282
Publication Date(Web):November 2010
DOI:10.1016/j.microc.2010.04.002
UV photochemical vapor generation (photo-CVG) as sample introduction was first adapted for determination of ultratrace cobalt by atomic fluorescence spectrometry (AFS). Cobalt volatile species can be generated when the buffer system of formic acid and formate containing Co (II) is exposed to UV radiation. The generated gaseous products were separated from liquid phase within a gas–liquid separator and then transported to AFS for determination of cobalt. Factors affecting the efficiency of photo-CVG were investigated in detail, including type and concentration of low molecular weight (LMW) organic acid, buffer system, UV irradiation time, reaction temperature, carrier gas flow rate and hydrogen flow rate. With 4% (v/v) HCOOH and 0.4 mol L− 1 HCOONa buffer solution, 150 s irradiation time and 15 W low pressure mercury lamp, a generation efficiency of 23–25% was achieved. A limit of detection (LOD) of 0.08 ng mL− 1 without any pre-concentration procedure and a precision of 2.2% (RSD, n = 11) at 20 ng mL− 1 were obtained under the optimized conditions. The proposed method was successfully applied in the analysis of several simple matrix real water samples.
Co-reporter:Chengbin Zheng, Qian Ma, Li Wu, Xiandeng Hou, Ralph E. Sturgeon
Microchemical Journal 2010 Volume 95(Issue 1) pp:32-37
Publication Date(Web):May 2010
DOI:10.1016/j.microc.2009.09.010
A systematic investigation of UV photochemical vapor generation (photo-CVG) and its potential application for seven typical hydride-forming elements (As, Sb, Bi, Te, Sn, Pb and Cd) when combined with atomic fluorescence spectrometry (AFS) detection is presented. These analyte ions were converted to volatile species following UV irradiation of their aqueous solution to which low molecular weight organic acids (such as formic, acetic or propionic acid) had been added, and introduced to an atomic fluorescence spectrometer for subsequent analytical measurements. The experimental conditions for photo-CVG and the interferences arising from concomitant elements were carefully investigated. Limits of detection as low as 0.08, 0.1, 0.2 and 0.5 ng mL− 1 were obtained for Te, Bi, Sb and As, respectively, comparable to those by hydride generation–AFS. The RSDs obtained with the proposed method for these elements were better than 5% at 50 ng mL− 1. It is noteworthy that the presence of TiO2 nanoparticles combined with UV irradiation remarkably enhances the CVG efficiencies of Se(VI) and Te(VI), which cannot form hydrides with KBH4/NaBH4. Moreover, photo-CVG has a greater tolerance toward interferences arising from transition elements than hydride generation, and this facilitates its application to the analysis of complicated sample matrices.
Co-reporter:Peng Wu, Liang He, Chengbin Zheng, Xiandeng Hou and Ralph E. Sturgeon
Journal of Analytical Atomic Spectrometry 2010 vol. 25(Issue 8) pp:1217-1246
Publication Date(Web):18 May 2010
DOI:10.1039/C003483E
Chemical vapor generation (CVG) using tetrahydroborate(III) remains the most popular and successful derivatization procedure enabling gaseous sample introduction into analytical atomic spectrometers that are routinely used for the determination of trace and ultratrace amounts of hydride-forming elements as well as Cd and Hg. The number of elements amenable to tetrahydroborate(III)-derivatization has recently been extensively enlarged. Despite its many obvious advantages, drawbacks remain, such as significant interferences from transition metals. Consequently, many alternative approaches have been developed to overcome these shortcomings and to further expand the suite of elements amenable to CVG for sample introduction. This article reviews these non-tetrahydroborate-based approaches, including photochemical vapor generation (photo-CVG), borane complexes CVG, alkylation based on Grignard reactions and derivatization with NaBEt4, cold vapor generation with SnCl2, halide generation, electrochemical hydride generation, oxide generation, and generation of volatile chelates. Special attention is given to two newly developed CVG approaches: photo-CVG and reduction in the presence of cyanoborohydrides.
Co-reporter:Liwei Liu, Hao Deng, Li Wu, Chengbin Zheng, Xiandeng Hou
Talanta 2010 Volume 80(Issue 3) pp:1239-1244
Publication Date(Web):January 2010
DOI:10.1016/j.talanta.2009.09.016
UV-induced carbonyl generation with formic acid is used for gaseous sample introduction into an atomic fluorescence spectrometer for the determination of ultra-trace nickel. Compared with conventional carbonyl generation, no toxic gas CO is involved in this work, and volatile Ni(CO)4 is generated with a single reagent formic acid under the irradiation of UV light (253.7 nm, 15 W). The reaction conditions, including reaction medium, UV irradiation time and reaction temperature, are optimized for the best signal. Under the optimized conditions, a limit of detection of 10 ng L−1 for nickel is obtained without any analyte-pre-concentration, which is comparable to that using in situ trapping technique. Interferences from common transition metal ions, noble metal ions and mineral acids are also investigated. The proposed method is applied to the analysis of three certified reference materials and two organic acid samples for trace nickel, with analytical results in good agreement with certified values or those obtained by electrothermal atomic absorption spectrometry. This is a simple, fairly green and highly sensitive method for ultra-trace nickel determination.
Co-reporter:Ying Gao, Peng Wu, Wei Li, Yuelan Xuan, Xiandeng Hou
Talanta 2010 Volume 81(1–2) pp:586-590
Publication Date(Web):15 April 2010
DOI:10.1016/j.talanta.2009.12.038
A simple, rapid and selective one-step displacement cloud point extraction (D-CPE) procedure was developed for the simultaneous preconcentration of trace Cu and Ag followed by flame atomic absorption spectrometric (FAAS) measurement. In this proposed procedure, Ni–DDTC complex instead of DDTC was used to achieve one-step extraction. Since the stability of Cu–DDTC and Ag–DDTC is higher than that of Ni–DDTC, simultaneous preconcentration of Cu and Ag can be achieved in a single step. Up to 15,000 mg L−1 Co2+, 10,000 mg L−1 Zn2+, 5000 mg L−1 Cd2+ and 5000 mg L−1 Al3+ did not cause significant interferences for the determination of 50 μg L−1 Cu by FAAS, while 8000 mg L−1 Zn2+, 4000 mg L−1 Co2+, 4000 mg L−1 Cd2+ and 5000 mg L−1 Al3+ had no distinct effect on the determination of 80 μg L−1 Ag. The limits of detection (LODs) of 0.5 μg L−1 for Cu and 1.0 μg L−1 for Ag, respectively, were obtained by FAAS detection. The accuracy of the proposed method is validated by analyzing certified reference materials (GBW 07405, GBW 07311 and GBW 07260) with satisfactory results. Furthermore, the one-step D-CPE was also applied for the preconcentration/separation of Cu and Ag in high-purity salts and artificial seawater, followed by FAAS or inductively coupled plasma-mass spectrometry (ICP-MS) determination.
Co-reporter:Xiaodong Wen, Peng Wu, Li Chen, Xiandeng Hou
Analytica Chimica Acta 2009 Volume 650(Issue 1) pp:33-38
Publication Date(Web):14 September 2009
DOI:10.1016/j.aca.2009.01.053
In this work, the microsampling nature of tungsten coil electrothermal vaporization Ar/H2 flame atomic fluorescence spectrometry (W-coil ETV-AFS) as well as tungsten coil electrothermal atomic absorption spectrometry (W-coil ET-AAS) was used with cloud point extraction (CPE) for the ultrasensitive determination of cadmium in rice and water samples. When the temperature of the extraction system is higher than the cloud point temperature of the selected surfactant Triton X-114, the complex of cadmium with dithizone can be quantitatively extracted into the surfactant-rich phase and subsequently separated from the bulk aqueous phase by centrifugation. The main factors affecting the CPE, such as concentration of Triton X-114 and dithizone, pH, equilibration temperature and incubation time, were optimized for the best extract efficiency. Under the optimal conditions, the limits of detection for cadmium by W-coil ETV-AFS and W-coil ET-AAS were 0.01 and 0.03 μg L−1, with sensitivity enhancement factors of 152 and 93, respectively. The proposed methods were applied to the determination of cadmium in certified reference rice and water samples with analytical results in good agreement with certified values.
Co-reporter:Xinfeng Zhang, Yiyu Hu, Aimin Sun, Yi Lv, Xiandeng Hou
Journal of Chromatography A 2009 Volume 1216(Issue 51) pp:8926-8932
Publication Date(Web):18 December 2009
DOI:10.1016/j.chroma.2009.10.060
Some categories of compounds, including quinones, coumarins, flavins, and xanthene dyes, were found to produce strong chemiluminescence (CL) signals with luminol in sample solution under the irradiation of light emitting diodes (LED) with proper wavelengths. Based on this phenomenon, a compact photochemical reactor was constructed to develop a novel LED induced CL detector for high performance liquid chromatography (HPLC). The effects of related parameters including LED wavelength, luminol concentration, flow rate, pH, and eluents of HPLC were investigated in detail. Under the optimized conditions, the limits of detections (LODs) were in the range of 0.2–80 ng mL−1. The applications and accuracy of the proposed method were validated by analyzing food samples such as milk powder, beer, candy and beverage with satisfactory results.
Co-reporter:Xiaodong Wen, Peng Wu, Kailai Xu, Junwei Wang, Xiandeng Hou
Microchemical Journal 2009 Volume 91(Issue 2) pp:193-196
Publication Date(Web):March 2009
DOI:10.1016/j.microc.2008.11.001
A simple, environmentally friendly, cost-effective and sensitive method was developed for the determination of trace cadmium in rice and water by using flow injection (FI) on-line precipitation–dissolution in a knotted reactor (KR) as a preconcentration scheme for thermospray flame furnace atomic absorption spectrometry (TS-FF-AAS). The preconcentration was achieved by online merging the sample solution and the precipitating reagent in a KR and subsequently eluting the resultant precipitate of cadmium hydroxide with 1 mol/L HNO3. The eluant was then introduced into TS-FF-AAS for the determination. A self-assembled FI system was employed to hyphenate the KR system with TS-FF-AAS. Under optimal chemical and instrumental conditions, a limit of detection of 0.04 μg/L and a sensitivity enrichment factor of 34 for cadmium was obtained with a total initial sample volume of 4 mL. The proposed method was applied to the determination of cadmium in certified reference rice and water samples with analytical results in good agreement with their certified values. Real rice samples and real water samples were also determined by the proposed method, with analytical results confirmed by inductively coupled plasma mass spectroscopy (ICP-MS).
Co-reporter:Peng Wu, He Chen, Guanglei Cheng and Xiandeng Hou
Journal of Analytical Atomic Spectrometry 2009 vol. 24(Issue 8) pp:1098-1104
Publication Date(Web):04 Jun 2009
DOI:10.1039/B904271G
The surface chemistry of TiO2 as well as the powerful adsorption capability of the nanometre material was used to separate inorganic chromium species in this work. When the pH of the sample solution is lower than the isoelectric point of TiO2, its surface is positively charged and anions of Cr(VI) can be adsorbed; on the contrary, the surface is negatively charged and cations of Cr(III) can be caught. Maximum adsorption rates of 34.5% and 95.4% for Cr(VI) at pH 3 and Cr(III) at pH 6 were obtained, respectively. Possible adsorption mechanisms were discussed considering the surface chemistry of TiO2 and the coordination chemistry of Ti, O and Cr. A simple and automated chromium speciation method was therefore developed using flow injection minicolumn separation and electrothermal atomic absorption spectrometric detection (ET-AAS). The adsorption and elution were incorporated in a flow injection program for selective preconcentration of Cr(III) or Cr(VI). As a result, no extra oxidizing/reducing process was necessary for an automated chromium speciation analysis. Factors influencing adsorption and elution of inorganic chromium species were carefully investigated. Detection limits as low as 0.01 µg L−1 for Cr(VI) and 0.006 µg L−1 for Cr(III) were achieved. The proposed method is highly sensitive and selective for inorganic chromium speciation analysis of drinking water.
Co-reporter:Peng Wu, Yunchang Zhang, Rui Liu, Yi Lv, Xiandeng Hou
Talanta 2009 Volume 77(Issue 5) pp:1778-1782
Publication Date(Web):15 March 2009
DOI:10.1016/j.talanta.2008.10.017
Flame furnace atomic absorption spectrometry (FF-AAS) is a newly developed flame atomic absorption spectrometric technique based on arranging a flame furnace onto the top of the flame burner head. In this fundamental investigation, 25 elements were carefully tested by using either thermospray FF-AAS or tungsten coil electrothermal vaporization FF-AAS, of which 15 volatile and semi-volatile elements (Cd, Tl, Ag, Pb, Zn, Hg, Cu, Sb, Bi, Te, In, As, Se, Sn and Au) exhibited better limits of detection compared to those by conventional FAAS; however, non-volatile or refractory elements (Fe, Co, Ni, Cr, Mn, Pd, Pt, Al, Be and V) showed inferior sensitivities by the proposed methods.
Co-reporter:Jing Hu, Kailai Xu, Yunzhen Jia, Yi Lv, Yubao Li and Xiandeng Hou
Analytical Chemistry 2008 Volume 80(Issue 21) pp:7964
Publication Date(Web):October 8, 2008
DOI:10.1021/ac800748m
A gas sensor was developed by using the chemiluminescence (CL) emission from the oxidation of ethyl ether by oxygen in the air on the surface of borate glass. Theoretical calculation, together with experimental investigation, revealed the main CL reactions: ethyl ether is first oxidized to acetaldehyde and then to acetic acid, during which main luminous intermediates such as CH3CO• are generated and emit light with a peak at 493 nm. At a reaction temperature of 245 °C, the overall maximal emission was found at around 460 nm, and the linear range of the CL intensity versus the concentration of ethyl ether was 0.12−51.7 μg mL−1 (R = 0.999, n = 7) with a limit of detection (3σ) of 0.04 μg mL−1. Interference from foreign substances including alcohol (methanol, ethanol and isopropanol), acetone, ethyl acetate, n-hexane, cyclohexane, dichloromethane, or ether (n-butyl ether, tetrahydrofuran, propylene oxide, isopropyl ether and methyl tert-butyl ether) was not significant except a minimal signal from n-butyl ether (<2%). It is a simple, sensitive and selective gas sensor for the determination of trace ethyl ether.
Co-reporter:Chengbin Zheng, Li Wu, Qian Ma, Yi Lv and Xiandeng Hou
Journal of Analytical Atomic Spectrometry 2008 vol. 23(Issue 4) pp:514-520
Publication Date(Web):13 Feb 2008
DOI:10.1039/B713651J
A simple yet ultrasensitive UV photochemical vapor generation (photo-CVG) is proposed for the speciation analysis of Se(IV) and Se(VI). The new photo-CVG, which is based on Se(IV) or Se(VI) reacting with an organic acid under different reaction conditions, can be coupled to AFS or ICP-MS for the speciation analysis of Se(IV) and Se(VI) in real samples such as table salt and water samples without chromatographic separation. At low temperature, only Se(IV) can be photochemically converted to selenium volatile species, and this is used for its selective determination; however, by using boiling water bath together with nano-TiO2 as a catalyst, both Se(IV) and Se(VI) can be photochemically converted to selenium volatile species, thus determining the total of Se(IV) and Se(VI). Therefore, Se(VI) concentration can be calculated from the difference between the total and Se(IV) concentration. Optimal reaction conditions and instrumental parameters are investigated; and the interferences from transition metals and other ions, as well as the photo-CVG mechanism, are discussed. The limits of detection range from 0.02 to 0.1 ng mL−1, depending on the kind of organic acid and the detector. The accuracy of the method is validated by determining Se(IV) in certified reference water sample. Real samples including commercial table salt, waste water and mineral water were successfully analyzed. This is a simple, relatively green, highly selective and sensitive, yet inexpensive method for the speciation analysis of Se(IV) and Se(VI).
Co-reporter:Peng Wu, Ying Gao, Guanglei Cheng, Wenshu Yang, Yi Lv and Xiandeng Hou
Journal of Analytical Atomic Spectrometry 2008 vol. 23(Issue 5) pp:752-757
Publication Date(Web):05 Mar 2008
DOI:10.1039/B719579F
A novel displacement-cloud point extraction approach was developed for the selective determination of trace silver in complicated matrices by thermospray flame furnace atomic absorption spectrometry. This method involves two steps of cloud point extraction, i.e., firstly, copper ion reacts with diethyldithiocarbamate (DDTC) to form Cu-DDTC before it is extracted; secondly, after removing the aqueous phase, a sample or standard solution containing silver ion is added and another cloud point extraction procedure is carried out. Because the stability of Ag-DDTC is larger than that of Cu-DDTC, Ag+ can displace Cu2+ from the pre-extracted Cu-DDTC and thus the preconcentration and separation of Ag+ from complicated sample matrix is achieved. Potential interference from co-existing transition metal ions with lower DDTC complex stability was largely eliminated as they cannot displace Cu2+ from Cu-DDTC complex. Up to 5000 μg mL−1Ni(II), 2000 μg mL−1 Cd(II), 1000 μg mL−1Fe(III), 2000 μg mL−1Co(II), 5000 μg mL−1Zn(II) and 5000 μg mL−1Mn(II) caused no significant interference with the determination of silver of 5 μg L−1. Compared with conventional cloud point extraction, the tolerance limit for the co-existing transition metal ions was increased by at least two orders of magnitude. Under the optimal chemical and instrumental conditions, the limit of detection was 0.2 μg L−1 for silver with a sample volume of 10 mL, and a sensitivity enhancement factor of 21 was achieved. The proposed method was successfully applied to interference-free determination of trace silver in soil, marine sediment and ore samples with high contents of co-existing heavy metals.
Co-reporter:Yingying Su;Kailai Xu;Ying Gao
Microchimica Acta 2008 Volume 160( Issue 1-2) pp:191-195
Publication Date(Web):2008 January
DOI:10.1007/s00604-007-0805-0
A new method based on ultrasonic slurry sampling atomic absorption spectrometry (AAS) was established for the determination of trace mercury in geological samples by use of recently developed mercury cold vapor generation using formic acid under ultraviolet (UV) irradiation. The generated mercury cold vapor was rapidly separated from the matrix and swept into a T-tube for the measurement of atomic absorbance. Under the optimal experimental conditions, up to 1000-fold of Cu(II), Co(II), Ni(II), Cr(VI), Mn(II), Fe(III), and Zn(II) caused no significant interference with the determination of 50 µg L−1 Hg. The limit of detection at sub-ppb level was obtained for mercury. The method was applied to the determination of mercury in geological samples with satisfactory results.
Co-reporter:Peng Wu, Xiaodong Wen, Liang He, Yihua He, Minzhu Chen, Xiandeng Hou
Talanta 2008 Volume 74(Issue 4) pp:505-511
Publication Date(Web):15 January 2008
DOI:10.1016/j.talanta.2007.06.013
A tungsten coil electrothermal vaporizer (W-coil ETV) was coupled to an Ar/H2 flame atomic fluorescence spectrometer for the determination of eight traditional hydride-forming elements (i.e., As, Bi, Ge, Pb, Sb, Se, Sn, and Te) as well as cadmium without chemical vapor generation. A small sample volume, typically 20 μL, was manually pipetted onto the W-coil and followed by a fixed electric heating program. During the vaporization step, analyte was vaporized off the coil surface and swept into the quartz tube atomizer of AFS for further atomization and excitation of atomic fluorescence by a flow of Ar/H2 gas, which was ignited to produce the Ar/H2 flame. The tungsten coil electrothermal vaporizer and Ar/H2 flame formed a tandem atomizer to produce reliable atomic fluorescence signals. Under the optimal instrumental conditions, limits of detection (LODs) were found to be better than those by flame atomic absorption spectrometry (FAAS) or inductively coupled plasma optical emission spectrometry (ICP-OES) for all the nine elements investigated. The absolute LODs are better or equivalent to those by hydride generation atomic fluorescence spectrometry (HG-AFS). Possible scattering interferences were studied and preliminary application of the proposed method was also reported.
Co-reporter:Rui Liu, Peng Wu, Kailai Xu, Yi Lv, Xiandeng Hou
Spectrochimica Acta Part B: Atomic Spectroscopy 2008 Volume 63(Issue 6) pp:704-709
Publication Date(Web):June 2008
DOI:10.1016/j.sab.2008.03.010
Bismuthine was on-line trapped on tungsten coil and subsequently electrothermally vaporized for the determination by atomic fluorescence spectrometry (AFS). Several noble metals, including Pd, Rh, Pt, and Ir, were explored as permanent chemical modifier for tungsten coil on-line trapping. Investigation showed that Ir gave the best performance, in which bismuthine was on-line trapped on Ir-coated tungsten coil at 560 °C, and then released at 1550 °C for subsequent transfer to AFS by a mixture of Ar and H2. Under optimum instrumental conditions, the trapping efficiency was found to be 73 ± 3%. With 120 s (12 mL sample volume) trapping time, a limit of detection (LOD) of 4 ng L− 1 was obtained, compared to conventional hydride generation AFS (0.09 μg L− 1); the LOD can be lowered down to 1 ng L− 1 by increasing the trapping time to 480 s. The LOD was found to be better or at least comparable to literature levels involving on-line trapping and some other sophisticated instrumental methods such as ICP-MS and GF-AAS. A comprehensive interference study involving conventional hydride-forming elements and some transition metals was carried out, and the result showed that the gas phase interference from other hydride-forming elements was largely reduced, thanks to the use of on-line tungsten coil trapping. Finally, the proposed method was applied to the determination of bismuth in several biological and environmental standard reference materials, and a t-test shows that the analytical results by the proposed method have no significant difference from the certified values at the confidence level of 95%.
Co-reporter:Yingying Su, Xiaohong Li, He Chen, Yi Lv, Xiandeng Hou
Microchemical Journal 2007 Volume 87(Issue 1) pp:56-61
Publication Date(Web):October 2007
DOI:10.1016/j.microc.2007.05.003
A novel on-line method based on the combination of UV photolysis and chemiluminescence detection was established and experimentally validated for the determination of chemical oxygen demand (COD). A quantitative amount of free radicals can be produced by analytes in the UV irradiation process. By utilizing the phenomenon that luminol can be oxidized by the free radicals to produce luminescence, COD was successfully determined indirectly. This new approach overcomes many problems associated with the conventional COD determination techniques such as long analysis time, tedious operations, consumption of expressive and toxic reagents, production of secondary toxic waste and poor reproducibility. The method was successfully applied to the determination of COD in synthetic samples, certified reference samples and real samples of river water and lake water. A limit of detection of 0.08 mg/L COD with a linear dynamic range of 0.2–20 mg/L was achieved under the optimum experimental conditions. The proposed method is a unique method that is environmentally friendly (without using any strong oxidizing reagent and any catalysts such as titanium dioxide), rapid (with only 5–10 min required for each sample), sensitive (with the lowest limit of detection for COD so far), simple (mainly with a photo-reactor and a chemiluminescence detector) and automated (using an intermittent flow system).
Co-reporter:Yihua He;Chengbin Zheng
Analytical and Bioanalytical Chemistry 2007 Volume 388( Issue 4) pp:769-774
Publication Date(Web):2007 June
DOI:10.1007/s00216-006-1044-7
Chemical vapor generation (CVG) is a widely adopted sample introduction method for analytical atomic spectrometry. Nonvolatile precursors (usually ionic, metallic or organometallic species) can be transferred from the condensed phase to the gas phase, yielding the advantages of efficient matrix separation, high analyte transport efficiency, high selectivity, simple instrumentation, and ease of automation. Hydride generation enjoys the greatest popularity as a consequence of its ease of implementation, fast reaction and high yield; but photo-CVG, a newly emerging research field in analytical chemistry, may provide a powerful alternative to conventional CVG due to its simplicity, versatility and cost effectiveness. Although photocatalytic pre-reduction has been used for a number of years, the most attractive aspect of this newly emerging area is the direct generation of volatile species using photochemical reactions. Recent studies undertaken with flow through and batch reactors employing low molecular weight organic acids as photochemical agents are highlighted in this study for such systems as mercury and selenium, as well as reaction mechanisms considered for these processes. Discussion is focused on recent advances in photo-CVG, which we believe will become the subject of intensive future research initiatives.
Co-reporter:Chunfang Han;Chengbin Zheng;Jun Wang
Analytical and Bioanalytical Chemistry 2007 Volume 388( Issue 4) pp:825-830
Publication Date(Web):2007 June
DOI:10.1007/s00216-006-1006-0
With UV irradiation, Hg2+ in aqueous solution can be converted into Hg0 cold vapor by low molecular weight alcohols, aldehydes, or carboxylic acids, e.g., methanol, formaldehyde, acetaldehyde, glycol, 1,2-propanediol, glycerol, acetic acid, oxalic acid, or malonic acid. It was found that the presence of nano-TiO2 more or less improved the efficiency of the photo-induced chemical/cold vapor generation (photo-CVG) with most of the organic reductants. The nano-TiO2-enhanced photo-CVG systems can be coupled to various analytical atomic spectrometric techniques for the determination of ultratrace mercury. In this work, we evaluated the application of this method to the atomic fluorescence spectrometric (AFS) determination of mercury in cold vapor mode. Under the optimized experimental conditions, the instrumental limits of detection (based on three times the standard deviation of 11 measurements of a blank solution) were around 0.02–0.04 μg L−1, with linear dynamic ranges up to 15 μg L−1. The interference of transition metals and the mechanism of the photo-CVG are briefly discussed. Real sample analysis using the photo-CVG-AFS method revealed that it was promising for water and geological analysis of ultralow levels of mercury.
Co-reporter:Yuan Li, Chengbin Zheng, Qian Ma, Li Wu, Changwei Hu and Xiandeng Hou
Journal of Analytical Atomic Spectrometry 2006 vol. 21(Issue 1) pp:82-85
Publication Date(Web):09 Nov 2005
DOI:10.1039/B512198A
A new and unique photo-induced mercury cold/chemical vapor generation (PI-CVG), which directly uses sample matrix as a reductant, was proposed for atomic fluorescence spectrometric detection of trace mercury in wine or liquor samples. The new method was thus termed as sample matrix-assisted PI-CVG. With the ultraviolet radiation (UV), the sample matrix (ethanol) can reduce mercury compounds or ions to atomic mercury, Hg0, which is subsequently swept (by argon carrier gas) into an atomic fluorescence spectrometer for the measurements. Under the optimized experimental conditions, the LOD for mercury was found to be 70 pg mL−1 with ethanol. The standard addition method was used for the real sample analysis to achieve the reagent free goal. The proposed method features high sensitivity, simplicity (no sample pre-treatment), rapidness, freedom of reagent (the sample matrix as the reductant), cost-effectiveness, and environmental cleanness. Indeed, this is the simplest approach to generate mercury vapor from alcohol-containing samples, and it is expected to have a wide application in the analysis of wines, liquors, and the like. Also, the PI-CVG can be coupled to other analytical atomic spectrometers.
Co-reporter:Peng Wu, Yunchang Zhang, Yi Lv, Xiandeng Hou
Spectrochimica Acta Part B: Atomic Spectroscopy 2006 Volume 61(Issue 12) pp:1310-1314
Publication Date(Web):December 2006
DOI:10.1016/j.sab.2006.10.017
A simple, low cost and highly sensitive method based on cloud point extraction (CPE) for separation/preconcentration and thermospray flame quartz furnace atomic absorption spectrometry was proposed for the determination of ultratrace cadmium in water and urine samples. The analytical procedure involved the formation of analyte-entrapped surfactant micelles by mixing the analyte solution with an ammonium pyrrolidinedithiocarbamate (APDC) solution and a Triton X-114 solution. When the temperature of the system was higher than the cloud point of Triton X-114, the complex of cadmium-PDC entered the surfactant-rich phase and thus separation of the analyte from the matrix was achieved. Under optimal chemical and instrumental conditions, the limit of detection was 0.04 μg/L for cadmium with a sample volume of 10 mL. The analytical results of cadmium in water and urine samples agreed well with those by ICP-MS.
Co-reporter:Chengbin Zheng, Yuan Li, Yihua He, Qian Ma and Xiandeng Hou
Journal of Analytical Atomic Spectrometry 2005 vol. 20(Issue 8) pp:746-750
Publication Date(Web):01 Jul 2005
DOI:10.1039/B503727A
A new photochemical reaction for mercury chemical/cold vapor generation (CVG) coupled to atomic fluorescence spectrometry (AFS) is described for the speciation analysis of inorganic mercury ion (Hg2+) and organic methylmercury (MeHg) in aqueous solution. The new CVG simply uses one reagent, formic acid only, to react with Hg2+ or MeHg in aqueous solution, under room natural light (Vis) or ultraviolet irradiation (UV), for the generation of cold mercury vapor, which is subsequently detected by AFS. In the presence of the UV, both Hg2+ and MeHg can be converted to Hg0 for the determination of total mercury; and only Hg2+ can be reduced to Hg0 with the Vis, thus determining Hg2+ only. Then, the concentration of MeHg can be calculated by subtracting the Hg2+ concentration from the total mercury concentration. The optimal conditions for the best CVG efficiency are discussed, together with the interference from transition metals. There exists no significant interference from as high as 100 mg L−1 Co2+ or Ni2+, and 50 mg L−1 Cu2+ for the determination of as low as 5 μg L−1 Hg2+. The new CVG minimizes the contamination sources and avoids off-line pre-oxidation of MeHg. A simple Hg2+ standard series can be used for the calibration of both Hg2+ and MeHg, eliminating the use of more toxic and more expensive MeHg standard series. The linear dynamic ranges of the calibration curves are up to 25 μg L−1 with the UV and 300 μg L−1 with the Vis. The limit of detection is 0.003 or 0.2 μg L−1 for total mercury with the UV or Hg2+ with the Vis, respectively. The accuracy of this method was validated by determination of mercury in one certified reference water sample. The new CVG is a simple, fast, green, highly selective, and ultrasensitive yet inexpensive method for the speciation analysis of Hg2+ and MeHg. It is expected to have similar applications in other analytical atomic spectrometric techniques.
Co-reporter:Gang Li, Li Wu, Juanjuan Xin and Xiandeng Hou
Journal of Analytical Atomic Spectrometry 2004 vol. 19(Issue 8) pp:1010-1013
Publication Date(Web):08 Jul 2004
DOI:10.1039/B402581D
In the traditional chemical vapor generation system of KBH4
(or NaBH4)–Cd2+–HCl in aqueous solution, volatile components containing cadmium species can be generated but with low efficiency. In this work, it was found for the first time that the efficiency for the generation of the cadmium-containing vapor was greatly improved when halogenate, i.e., NaBrO3 or NaIO3, was added. The chemically generated vapor was separated from the reaction medium, and introduced into an atomic fluorescence spectrometer (AFS) with argon as the carrier gas, for the atomization and detection of cadmium. The experimental conditions for the efficient generation of the cadmium-containing vapor were optimized and the limit of detection (LOD, 3σ) was then found to be 10 pg mL−1. This modified chemical vapor generation system is potentially cleaner, and could have wide applications for sample introduction and/or matrix separation in analytical atomic spectrometries, such as flame atomic absorption spectrometry (FAAS), electrothermal atomic absorption spectrometry (ETAAS), inductively coupled plasma atomic emission spectrometry (ICP-AES), ICP-MS (mass spectrometry), microwave induced plasma atomic emission spectrometry (MIP-AES) and MIP-MS for the determination of ultratrace cadmium or some other elements.
Co-reporter:Jingrong Zhou, Yunfei Tian, Xi Wu, Xiandeng Hou
Microchemical Journal (May 2017) Volume 132() pp:
Publication Date(Web):May 2017
DOI:10.1016/j.microc.2017.02.016
•Facilely synthesis of photocatalyst metal-free g-C3N4/CQDs composites•First visible light photochemical vapor generation using the g-C3N4/CQDs•Application of the vapor generation in selective and ultrasensitive detection of mercury by ICP-MS•Possible application of the new vapor generation to other atomic spectrometric techniquesPhotochemical vapor generation (PCVG) is a green and effective sampling technology for analytical atomic spectrometry, and in recent years it has been received continuous attention. In this work, visible light photochemical vapor generation was achieved with metal-free g-C3N4/CQDs (carbon nitride/carbon quantum dots) composites as a photocatalyst, and used for selective and ultrasensitive detection of total mercury by inductively coupled plasma mass spectrometry (ICP-MS). The limit of detection can be as low as 8 ng L− 1, making it one of the most sensitive methods for mercury determination. The visible light photochemical vapor generation can also be coupled to other analytical atomic spectrometric techniques.
Co-reporter:Jin Luo, Fujian Xu, Jiping Tu, Xi Wu, Xiandeng Hou
Microchemical Journal (May 2017) Volume 132() pp:
Publication Date(Web):May 2017
DOI:10.1016/j.microc.2017.02.005
•MIL-125-NH2 was fast synthesized under microwave and used as a photocatalyst.•Se (VI) and Se (IV) can be converted into volatile species in the photochemistry.•Photochemical vapor generation ICP-OES was used for ultrasensitive determination of selenium.•The photochemical vapor generation could be coupled to other atomic spectrometic techniques.Metal organic framework MIL-125-NH2 was used as a photocatalyst for the photochemical vapor generation to establish an efficient and accurate method for highly sensitive determination of trace selenium by inductively coupled plasma optical emission spectrometry. The mixture of Se (IV) and Se (VI), MIL-125-NH2 nanoparticles and a low molecular weight organic acid was mixed to generate gaseous selenium-containing species which was separated from its liquid phase and transported to inductively coupled plasma optical emission spectrometer for determination. Influencing factors including carrier gas flow rate, type and concentration of catalyst, type and concentration of organic acid, UV irradiation time and power, and sample pH were carefully studied. Under the optimized conditions, a catalytic efficiency of more than 80% was achieved. The limits of detection for Se (IV) and Se (VI) were found to be the same and as low as 0.3 ng/mL. The relative standard deviation of Se (IV) and Se (VI) was 2.7% and 2.1% at 20 ng/mL (n = 11), respectively. The accuracy of the method was evaluated by analysis of natural mineral water and certified reference materials.
Co-reporter:Yujia Deng, Xi Wu, Yunfei Tian, Zhirong Zou, Xiandeng Hou, Xiaoming Jiang
Microchemical Journal (May 2017) Volume 132() pp:
Publication Date(Web):May 2017
DOI:10.1016/j.microc.2017.02.024
•A simultaneous elemental analysis system was established by sharing one ICP for ICP-MS and ICP-OES.•This instrumentation facilitates elimination of isobaric interferences from MS and spectral interferences from OES.•Synergetic determination ensured more accurate analytical results.•Combinatorial measurements could extend linear dynamic ranges.Inductively coupled plasma (ICP) is one of the most popular sources in analytical atomic spectrometers, including inductively coupled plasma mass spectrometry (ICP-MS) and inductively coupled plasma optical emission spectrometry (ICP-OES). There are several unique independent advantages for either of them. Therefore, a simultaneous elemental analysis system was established for synergetic work of ICP-MS and ICP-OES by sharing one ICP to improve the analytical figures of merit. To demonstrate its unique utility, several special applications were studied, including correction of interferences for each other, synergetic determination for accurate analysis and combinatorial analysis for larger linear ranges of calibration curves.
Co-reporter:Xiandeng Hou
Journal of Analytical Atomic Spectrometry 2011 - vol. 26(Issue 6) pp:NaN1114-1114
Publication Date(Web):2011/03/11
DOI:10.1039/C1JA90010B
A graphical abstract is available for this content
Co-reporter:Xi Wu, Wulin Yang, Menggang Liu, Xiandeng Hou and Chengbin Zheng
Journal of Analytical Atomic Spectrometry 2011 - vol. 26(Issue 6) pp:NaN1209-1209
Publication Date(Web):2011/03/14
DOI:10.1039/C1JA10016E
Mercury solution without or with formic acid was introduced into a low temperature argon plasma from dielectric barrier discharge (DBD). Mercury vapor generated in the DBD was separated from the liquid phase and finally swept into an inductively coupled plasma optical emission spectrometer (ICP-OES) for determination. The optimum conditions for the proposed technique and operation of the ICP-OES, as well as interferences from concomitants, were investigated in detail. It was found that the vapor generation efficiency of mercury could be significantly enhanced with the addition of formic acid. However, the efficiency was reduced sharply in the presence of chloride ions or oxidizing substances of high concentration. Under the optimized conditions, a limit of detection of 0.090 μg L−1 and a precision of 2.1% RSD at a concentration of 10 μg L−1 were achieved by the proposed method. The new DBD-induced mercury vapor generation provides several advantages including low power consumption (<25 W), green analytical chemistry, cost-effectiveness, smaller size, long operation lifetime, and ease of on-line operation. The methodology has been successfully applied to the determination of mercury in a certified reference water sample and mineral water samples.
Co-reporter:Dongyan Deng, Shu Zhang, He Chen, Lu Yang, Hui Yin, Xiandeng Hou and Chengbin Zheng
Journal of Analytical Atomic Spectrometry 2015 - vol. 30(Issue 4) pp:NaN887-887
Publication Date(Web):2015/01/09
DOI:10.1039/C4JA00436A
The integrity of chemical species throughout the analytical procedure and sample throughput are usually two serious impediments in elemental speciation. In this work, a simple solid sampling platform using multi-wall carbon nanotubes (MWCNTs) assisted matrix solid phase dispersion (MSPD) was constructed for online coupling to high performance liquid chromatography inductively coupled plasma mass spectrometry (HPLC-ICP-MS) for the high accuracy and sample throughput mercury speciation in fish samples. Owing to the large surface area and excellent mechanical strength of MWCNTs, which facilitate a sufficient dispersion of a sample matrix and diffusion of the eluent into the mixture of solid support and fish samples, a fast, efficient and online extraction of mercury species was achieved. Compared to the conventional MSPD and other sample pretreatment methods, the proposed method has several advantages including the integration of extraction, clean-up, separation and determination into one single step to achieve a high sample throughput, eliminating the need for derivatization of the Hg species and/or subsequent purification steps, reduced usage of solid supports, minimized contamination and mild operation conditions. The limits of detection of 9.9 ng g−1 and 8.4 ng g−1 were obtained for Hg2+ and CH3Hg+, respectively, based on 1 mg of fish sample. The accuracy of the proposed method was validated by analyzing two certified reference materials. The proposed method was applied for two fresh fish samples for Hg speciation.
Co-reporter:Ke Huang, Hui Xia, Mengtian Li, Ying Gao, Chengbin Zheng and Xiandeng Hou
Analytical Methods (2009-Present) 2012 - vol. 4(Issue 12) pp:NaN4062-4062
Publication Date(Web):2012/09/26
DOI:10.1039/C2AY25888A
A new efficient method was described for the purification of K3[Fe(CN)6] for the purpose of minimization of the blank in the determination of trace lead by hydride generation-atomic fluorescence spectrometry using the HCl–K3[Fe(CN)6]–KBH4 system. The lead impurity in K3[Fe(CN)6] solution was removed by reacting with KBH4 to form PbH4, which was efficiently separated from the solution by a nitrogen gas flow. The purified K3[Fe(CN)6] was obtained via Cl2 oxidation and subsequent ethanol purification of its reduced compound. The optimum conditions for hydride generation of lead and purification of K3[Fe(CN)6] were carefully investigated. A limit of detection (LOD) of 0.05 μg L−1 was obtained, 100-fold better than that achieved with unpurified K3[Fe(CN)6]. The accuracy of the proposed method was validated by analyzing a Certified Reference hair sample (GBW07610) and two ore samples (GBW07106 and GBW07112) with satisfactory analytical results.
Co-reporter:Xiaoming Jiang, Peng Wu, Dongyan Deng, Ying Gao, Xiandeng Hou and Chengbin Zheng
Journal of Analytical Atomic Spectrometry 2012 - vol. 27(Issue 10) pp:NaN1786-1786
Publication Date(Web):2012/06/11
DOI:10.1039/C2JA30110E
A novel compact tandem atomizer is described and evaluated for its analytical performance using atomic fluorescence spectrometry (AFS). The atomizer simply comprises an argon–hydrogen (Ar–H2) flame atomizer and an electrothermal atomization/vaporization (ETV) sampling device, which utilizes a tungsten coil (W-coil) onto which a liquid sample is pipetted, and subsequently the analyte is electrothermally atomized/vaporized and swept directly into the highly reducing environment of the Ar–H2 flame atomizer for further atomization and detection. The flame sits directly on top of the W-coil without any interface tubing. Improvements in elemental coverage, sensitivity and minimization of analyte loss as well as reduction of reagent consumption were simultaneously achieved by the use of this technique. The absolute limits of detection (LODs) are comparable to those obtained by GF-AAS but provide significant improvements over FAAS and ICP-OES. Its application example was demonstrated by analyzing several Certified Reference Materials and environmental water samples for ultratrace Cd, Pb, Au and Ag.
Co-reporter:Xinfeng Zhang, Chengpeng Huang, Shuxia Xu, Junbo Chen, Ying Zeng, Peng Wu and Xiandeng Hou
Chemical Communications 2015 - vol. 51(Issue 77) pp:NaN14468-14468
Publication Date(Web):2015/08/07
DOI:10.1039/C5CC06105A
We report here the newly discovered photocatalytic activity of the dsDNA–SYBR Green I (SG) complex, which can catalyze the oxidation of 3,3′,5,5′-tetramethylbenzidine (TMB) under light irradiation corresponding to the excitation of the dsDNA–SG complex. The most appealing feature of the photocatalytic system here is that it can be obtained using random DNA sequences that can form a duplex. Considering the universality of the photooxidase, a label-free and universal platform was proposed for highly sensitive visual bioassays.
Co-reporter:Dongyan Deng, Jingrong Zhou, Xi Ai, Lu Yang, Xiandeng Hou and Chengbin Zheng
Journal of Analytical Atomic Spectrometry 2012 - vol. 27(Issue 2) pp:NaN275-275
Publication Date(Web):2011/12/01
DOI:10.1039/C1JA10244C
An ultrasensitive, simple and interference-free method using nano-TiO2 preconcentration and in situ slurry hydride generation (HG) coupled with atomic fluorescence spectrometry (AFS) was developed for the determination of trace selenium. Total Se reduced in Se(IV) form can be selectively adsorbed on TiO2 at pH < 8 for pre-concentration, and then separated and slurried/released by a mixture containing 3% (m/v) KBH4 and 1% (m/v) KOH. The slurry solution was mixed with 25% (v/v) HCl to generate selenium hydrides, which was subsequently separated from the liquid phase for subsequent AFS detection. Optimum conditions for adsorption, disadsorption and hydride generation of selenium as well as potential interferences from concomitant ions were investigated. Due to the repulsive force between the positively charged TiO2 and metal cationic ions, this approach permits 1000 mg L−1 for Fe3+, Ni2+ and Co2+, 500 mg L−1 for Cu2+ or 100 mg L−1 for Ag+ and Au3+ present in a 5 μg L−1Se(IV) solution without any significant interferences. A limit of detection of 0.0006 μg L−1 was obtained by sampling a 40 mL sample solution. Compared to the conventional HG method, the sensitivity and the limit of detection were improved 17- and 16-fold by the present method, respectively. The proposed method was successfully applied for the determination of trace selenium in several real samples.
Co-reporter:Junbo Chen, Bin Deng, Peng Wu, Feng Li, Xing-Fang Li, X. Chris Le, Hongquan Zhang and Xiandeng Hou
Chemical Communications 2016 - vol. 52(Issue 9) pp:NaN1819-1819
Publication Date(Web):2015/12/02
DOI:10.1039/C5CC08879H
By using the principle of binding-induced DNA assembly, we have developed a novel homogeneous assay that is able to convert an affinity protein binding event into a predesigned DNA assembly. The assembled DNA sequence can be ligated into an intact DNA strand and hundreds of DNA hairpins can be cleaved by a nicking endonuclease. Each cleavage releases a single-stranded DNA (ssDNA) probe that is initially caged in the DNA hairpin. This released ssDNA probe can then turn on the fluorescence signal by desorbing a fluorescently-labelled complementary DNA probe from graphene oxide through hybridization. We demonstrate that this homogeneous, isothermal, and amplifiable assay can be tailored to detect a number of proteins, including a cancer biomarker, human prostate specific antigen, at picomolar levels in both buffer and human serum samples.
Co-reporter:Xue Jiang, Xinliang Xu, Xiandeng Hou, Zhou Long, Yunfei Tian, Xiaoming Jiang, Fujian Xu and Chengbin Zheng
Journal of Analytical Atomic Spectrometry 2016 - vol. 31(Issue 7) pp:
Publication Date(Web):
DOI:10.1039/C6JA00142D
Co-reporter:Peng Wu, Liang He, Chengbin Zheng, Xiandeng Hou and Ralph E. Sturgeon
Journal of Analytical Atomic Spectrometry 2010 - vol. 25(Issue 8) pp:NaN1246-1246
Publication Date(Web):2010/05/18
DOI:10.1039/C003483E
Chemical vapor generation (CVG) using tetrahydroborate(III) remains the most popular and successful derivatization procedure enabling gaseous sample introduction into analytical atomic spectrometers that are routinely used for the determination of trace and ultratrace amounts of hydride-forming elements as well as Cd and Hg. The number of elements amenable to tetrahydroborate(III)-derivatization has recently been extensively enlarged. Despite its many obvious advantages, drawbacks remain, such as significant interferences from transition metals. Consequently, many alternative approaches have been developed to overcome these shortcomings and to further expand the suite of elements amenable to CVG for sample introduction. This article reviews these non-tetrahydroborate-based approaches, including photochemical vapor generation (photo-CVG), borane complexes CVG, alkylation based on Grignard reactions and derivatization with NaBEt4, cold vapor generation with SnCl2, halide generation, electrochemical hydride generation, oxide generation, and generation of volatile chelates. Special attention is given to two newly developed CVG approaches: photo-CVG and reduction in the presence of cyanoborohydrides.
Co-reporter:Peng Wu, Ying Gao, Guanglei Cheng, Wenshu Yang, Yi Lv and Xiandeng Hou
Journal of Analytical Atomic Spectrometry 2008 - vol. 23(Issue 5) pp:NaN757-757
Publication Date(Web):2008/03/05
DOI:10.1039/B719579F
A novel displacement-cloud point extraction approach was developed for the selective determination of trace silver in complicated matrices by thermospray flame furnace atomic absorption spectrometry. This method involves two steps of cloud point extraction, i.e., firstly, copper ion reacts with diethyldithiocarbamate (DDTC) to form Cu-DDTC before it is extracted; secondly, after removing the aqueous phase, a sample or standard solution containing silver ion is added and another cloud point extraction procedure is carried out. Because the stability of Ag-DDTC is larger than that of Cu-DDTC, Ag+ can displace Cu2+ from the pre-extracted Cu-DDTC and thus the preconcentration and separation of Ag+ from complicated sample matrix is achieved. Potential interference from co-existing transition metal ions with lower DDTC complex stability was largely eliminated as they cannot displace Cu2+ from Cu-DDTC complex. Up to 5000 μg mL−1Ni(II), 2000 μg mL−1 Cd(II), 1000 μg mL−1Fe(III), 2000 μg mL−1Co(II), 5000 μg mL−1Zn(II) and 5000 μg mL−1Mn(II) caused no significant interference with the determination of silver of 5 μg L−1. Compared with conventional cloud point extraction, the tolerance limit for the co-existing transition metal ions was increased by at least two orders of magnitude. Under the optimal chemical and instrumental conditions, the limit of detection was 0.2 μg L−1 for silver with a sample volume of 10 mL, and a sensitivity enhancement factor of 21 was achieved. The proposed method was successfully applied to interference-free determination of trace silver in soil, marine sediment and ore samples with high contents of co-existing heavy metals.
Co-reporter:Chengbin Zheng, Li Wu, Qian Ma, Yi Lv and Xiandeng Hou
Journal of Analytical Atomic Spectrometry 2008 - vol. 23(Issue 4) pp:NaN520-520
Publication Date(Web):2008/02/13
DOI:10.1039/B713651J
A simple yet ultrasensitive UV photochemical vapor generation (photo-CVG) is proposed for the speciation analysis of Se(IV) and Se(VI). The new photo-CVG, which is based on Se(IV) or Se(VI) reacting with an organic acid under different reaction conditions, can be coupled to AFS or ICP-MS for the speciation analysis of Se(IV) and Se(VI) in real samples such as table salt and water samples without chromatographic separation. At low temperature, only Se(IV) can be photochemically converted to selenium volatile species, and this is used for its selective determination; however, by using boiling water bath together with nano-TiO2 as a catalyst, both Se(IV) and Se(VI) can be photochemically converted to selenium volatile species, thus determining the total of Se(IV) and Se(VI). Therefore, Se(VI) concentration can be calculated from the difference between the total and Se(IV) concentration. Optimal reaction conditions and instrumental parameters are investigated; and the interferences from transition metals and other ions, as well as the photo-CVG mechanism, are discussed. The limits of detection range from 0.02 to 0.1 ng mL−1, depending on the kind of organic acid and the detector. The accuracy of the method is validated by determining Se(IV) in certified reference water sample. Real samples including commercial table salt, waste water and mineral water were successfully analyzed. This is a simple, relatively green, highly selective and sensitive, yet inexpensive method for the speciation analysis of Se(IV) and Se(VI).
Co-reporter:Peng Wu, He Chen, Guanglei Cheng and Xiandeng Hou
Journal of Analytical Atomic Spectrometry 2009 - vol. 24(Issue 8) pp:NaN1104-1104
Publication Date(Web):2009/06/04
DOI:10.1039/B904271G
The surface chemistry of TiO2 as well as the powerful adsorption capability of the nanometre material was used to separate inorganic chromium species in this work. When the pH of the sample solution is lower than the isoelectric point of TiO2, its surface is positively charged and anions of Cr(VI) can be adsorbed; on the contrary, the surface is negatively charged and cations of Cr(III) can be caught. Maximum adsorption rates of 34.5% and 95.4% for Cr(VI) at pH 3 and Cr(III) at pH 6 were obtained, respectively. Possible adsorption mechanisms were discussed considering the surface chemistry of TiO2 and the coordination chemistry of Ti, O and Cr. A simple and automated chromium speciation method was therefore developed using flow injection minicolumn separation and electrothermal atomic absorption spectrometric detection (ET-AAS). The adsorption and elution were incorporated in a flow injection program for selective preconcentration of Cr(III) or Cr(VI). As a result, no extra oxidizing/reducing process was necessary for an automated chromium speciation analysis. Factors influencing adsorption and elution of inorganic chromium species were carefully investigated. Detection limits as low as 0.01 µg L−1 for Cr(VI) and 0.006 µg L−1 for Cr(III) were achieved. The proposed method is highly sensitive and selective for inorganic chromium speciation analysis of drinking water.
Co-reporter:Xiaodong Wen, Ying Gao, Peng Wu, Zhiqiang Tan, Chengbin Zheng and Xiandeng Hou
Journal of Analytical Atomic Spectrometry 2016 - vol. 31(Issue 2) pp:NaN422-422
Publication Date(Web):2015/09/22
DOI:10.1039/C5JA00323G
Generation of volatile hydrides and elemental mercury was accomplished in non-aqueous media by using a solid reductant of lithium aluminium tetrahydride (LiAlH4), stannous chloride dehydrate (SnCl2) or tetrahydroborate (THB) as a derivation reagent. A room temperature ionic liquid (RTIL) was used as the non-aqueous media for the chemical vapor generation (CVG), and atomic fluorescence spectrometry was used for the elemental determination. The analyte ions were firstly extracted into the RTIL media from the bulk aqueous phase of the analyte/sample solution via a liquid–liquid extraction process and then directly mixed with the solid reductant to generate volatile analyte-containing species, which were then rapidly transported to a commercial atomic fluorescence spectrometer for detection. Hg(II), As(III) and Sb(III) were selected as the model analytes for evaluating this new CVG technique. The three reductants could all reduce Hg(II) to the elemental state, but only THB could generate volatile species of As(III) and Sb(III). Compared to conventional CVG in the aqueous phase, the efficiencies of CVG accomplished with solid reductants were similar or even better, there was less interference from transition and noble metal ions, and much better limits of detection were obtained. The proposed method was successfully used for the determination of ultratrace mercury and arsenic in several certified reference materials, including soil, water and human hair samples.
Co-reporter:Ke Huang, Kailai Xu, Xiandeng Hou, Yun Jia, Chengbin Zheng and Lu Yang
Journal of Analytical Atomic Spectrometry 2013 - vol. 28(Issue 4) pp:NaN515-515
Publication Date(Web):2013/01/23
DOI:10.1039/C3JA30363B
A novel, simple, low power, low temperature (<45 °C) and high efficiency atomization technique using ultraviolet (UV) radiation was proposed for the atomization of gaseous mercury hydrides for their determination by atomic fluorescence spectrometry (AFS). This technique was used for the detection of inorganic mercury (Hg2+) and organic mercury (MeHg+ and EtHg+) after high performance liquid chromatographic separation. In the proposed method, with 0.5% (m/v) KBH4 used as a reductant, inorganic mercury was reduced to elemental mercury, whereas the organic mercury species formed their respective volatile organic mercury hydrides (MeHgH and EtHgH) which were flushed to the UV atomizer for atomization and AFS detection. Under the optimized experimental conditions, the limits of detection were found to be 0.38, 0.41 and 0.56 μg L−1, and the relative standard deviations (n = 3) were 1.1%, 2.6% and 1.4% for Hg2+, MeHg+ and EtHg+, respectively. The accuracy of the proposed method was validated by analyzing a certified reference sample (fish muscle tissue) with a satisfactory analytical result, and two water samples with recoveries in the range of 93.8–97.4%.
Co-reporter:Jia Jia, Zhou Long, Chengbin Zheng, Xi Wu and Xiandeng Hou
Journal of Analytical Atomic Spectrometry 2015 - vol. 30(Issue 2) pp:NaN342-342
Publication Date(Web):2014/11/19
DOI:10.1039/C4JA00360H
Metal organic frameworks CAU-1 was used as a new photocatalyst for photochemical vapor generation, for the first time, with high reduction efficiency obtained for volatile species of Se(VI) for its sensitive determination by atomic fluorescence spectrometry with a limit of detection of 0.04 ppb for Se.
