A Glass Capillary Ultramicroelectrode with an Electrokinetic Sampling Ability

Hirano, Atsushi; Kanai, Miki; Nara, Tomoko; Sugawara, Masao

doi:10.2116/analsci.17.37

Cited by 15 publications

(5 citation statements)

References 32 publications

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“…The environmental limit of inorganic mercuric from the United States Environmental Protection Agency (US EPA) in drinking water is below 2 ppb (2 μg/L) http://www.epa.gov/ogwdw000/contaminants/dw_contamfs/mercury.html. Mercury content in human blood is normally within the range of 0.87 to 3.51 μg/L [34,35] and the warning level of mercury in human blood is 22.8 to 30 μg/L [34,36]. The reproducible, rapid and dose-dependent responsiveness of these genes to a range of HgCl 2 concentrations from 10 to 200 μg/L suggested that these genes can be potentially used as robust biomarkers in combination with analytical chemistry detection of mercury for investigating and assessing the severity of mercury exposure.…”

Section: Resultsmentioning

confidence: 99%

Mercury-induced hepatotoxicity in zebrafish: in vivo mechanistic insights from transcriptome analysis, phenotype anchoring and targeted gene expression validation

et al. 2010

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BackgroundMercury is a prominent environmental contaminant that causes detrimental effects to human health. Although the liver has been known to be a main target organ, there is limited information on in vivo molecular mechanism of mercury-induced toxicity in the liver. By using transcriptome analysis, phenotypic anchoring and validation of targeted gene expression in zebrafish, mercury-induced hepatotoxicity was investigated and a number of perturbed cellular processes were identified and compared with those captured in the in vitro human cell line studies.ResultsHepato-transcriptome analysis of mercury-exposed zebrafish revealed that the earliest deregulated genes were associated with electron transport chain, mitochondrial fatty acid beta-oxidation, nuclear receptor signaling and apoptotic pathway, followed by complement system and proteasome pathway, and thereafter DNA damage, hypoxia, Wnt signaling, fatty acid synthesis, gluconeogenesis, cell cycle and motility. Comparative meta-analysis of microarray data between zebrafish liver and human HepG2 cells exposed to mercury identified some common toxicological effects of mercury-induced hepatotoxicity in both models. Histological analyses of liver from mercury-exposed fish revealed morphological changes of liver parenchyma, decreased nucleated cell count, increased lipid vesicles, glycogen and apoptotic bodies, thus providing phenotypic evidence for anchoring of the transcriptome analysis. Validation of targeted gene expression confirmed deregulated gene-pathways from enrichment analysis. Some of these genes responding to low concentrations of mercury may serve as toxicogenomic-based markers for detection and health risk assessment of environmental mercury contaminations.ConclusionMercury-induced hepatotoxicity was triggered by oxidative stresses, intrinsic apoptotic pathway, deregulation of nuclear receptor and kinase activities including Gsk3 that deregulates Wnt signaling pathway, gluconeogenesis, and adipogenesis, leading to mitochondrial dysfunction, endocrine disruption and metabolic disorders. This study provides important mechanistic insights into mercury-induced liver toxicity in a whole-animal physiology context, which will help in understanding the syndromes caused by mercury poisoning. The molecular conservation of mercury-induced hepatotoxicity between zebrafish and human cell line reveals the feasibility of using zebrafish to model molecular toxicity in human for toxicant risk assessments.

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Section: Resultsmentioning

confidence: 99%

Mercury-induced hepatotoxicity in zebrafish: in vivo mechanistic insights from transcriptome analysis, phenotype anchoring and targeted gene expression validation

et al. 2010

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“…8 Improvements of the spatial dissolution of L-glutamate measurements by miniaturizing the size of sampling probe and/or that of enzyme-based electrodes are important, because the neuronal activity that releases and metabolizes L-glutamate is a very fast event, 10 and hence the concentration of Lglutamate detected at a sensing probe depends on the location and distance of the probe from the neurons. For the purpose of miniaturizing the size of the sensing probes, pulled glass capillaries 27,28 have a unique feature: the tip diameters range from submicro-to several µm, and the glass surface has an affinity to lipids and biocompatibility.…”

Section: Introductionmentioning

confidence: 99%

A Glass Capillary Microelectrode Based on Capillarity and Its Application to the Detection of l-Glutamate Release from Mouse Brain Slices

et al. 2003

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The detection of local and dynamic concentration changes of various bioactive substances in the mammalian central nervous system (CNS) is important for understanding the physiological function of excitatory synaptic transmission and metabolism. Many methods have been developed for the in vivo and in vitro detection of bioactive substances in biological fluids, including in vivo voltammetry, 1-3 patch-clamp biosensors, 4-7 microdialysis (MD) combined with various analytical methods 8 and ionselective microelectrode methods. 9 These methods have been widely used for detecting neurotransmitters, second messengers and other bioactive substances that play a key role in neuronal signal transmission.L-Glutamate is an excitatory neurotransmitter, and its release is thought to play a crucial role in brain development, synaptic plasticity, memory formation and neurotoxicity. 10 25 which is much larger than the electrodes for direct measurements, and the time resolution is on the order of minutes. In addition, the recovery of MD sampling is usually low because released L-glutamate is diluted by a perfusion solution. Niwa et al. used a glass capillary, instead of an MD probe, for sampling L-glutamate in a suction mode, followed by flow-through detection at a GluOx/Os-gel-HRP modified electrode. 26 On-line approaches using liquid chromatography, flow injection analysis and capillary electrophoresis in combination with MD probes have also been reported. 8 Improvements of the spatial dissolution of L-glutamate measurements by miniaturizing the size of sampling probe and/or that of enzyme-based electrodes are important, because the neuronal activity that releases and metabolizes L-glutamate is a very fast event, 10 and hence the concentration of Lglutamate detected at a sensing probe depends on the location and distance of the probe from the neurons. For the purpose of miniaturizing the size of the sensing probes, pulled glass capillaries 27,28 have a unique feature: the tip diameters range from submicro-to several µm, and the glass surface has an affinity to lipids and biocompatibility.In the present paper, we describe a new glass capillary microelectrode (tip diameter, ∼12 µm) based on capillarity for measuring L-glutamate. The inner solution provides a reservoir for enzymes, i.e., L-glutamate oxidase and L-ascorbate oxidase, and a built-in three-electrode system Humanities and Sciences, Nihon University, Sakurajousui, Setagaya, Japan A new glass capillary microelectrode for L-glutamate is described using pulled glass capillaries (tip size, ∼12.5 µm) with a very small volume (∼2 µl) of inner solution containing glutamate oxidase (GluOx) and ascorbate oxidase. The operation of the electrode is based on capillary action that samples L-glutamate into the inner solution. The enzyme reaction by GluOx generates hydrogen peroxide that is detected at an Os-gel-HRP polymer modified Pt electrode in a three-electrode configuration. The amperometric response behavior of the electrode was characterized in terms of the capillarity, re...

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“…It must be mentioned that on MWCNT-based films, well-defined CV curves of [Fe (CN) 6 ] 3−/4− were obtained with peak-to-peak potential separation equal to that which corresponds to Nernstian oneelectron transfer reaction (ΔE p ≈0.059 V) [24]. Furthermore, the detection limit of MWCNT-based films on [Fe (CN) 6 ] 3−/4− was determined to be about 0.80 μM, which was much better compared to that determined on other electrodes reported in literature [25]. SEM was used for the analysis of the structure and surface of MWCNT-based films.…”

Section: Preparation and Characterization Of Mwcnt-based Filmsmentioning

confidence: 62%

Oxidation of dopamine on multi-walled carbon nanotubes

Tsierkezos

Ritter

2012

J Solid State Electrochem

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Novel films consisting of multi-walled carbon nanotubes (MWCNTs) were fabricated by means of the chemical vapor deposition technique with decomposition of either acetonitrile (ACN) or benzene (BZ) in the presence of ferrocene (FeCp 2 ) which served as catalyst. The electrochemical response of the two different kinds of MWCNTbased films, further referred to as MWCNT-ACN and MWCNT-BZ, towards the oxidation of dopamine (DA) to dopamine-o-quinone (DAQ) was tested by means of cyclic voltammetry, differential pulse voltammetry, and electrochemical impedance spectroscopy. Both MWCNT-based films exhibit quasi-reversible response towards DA/DAQ with some slight kinetic differences; specifically, the charge-transfer process was found to be faster on MWCNT-ACN (k s 035.3 × 10 −3 cm s −1 ) compared to MWCNT-BZ (k s 06.55×10 −3 cm s −1 ). The detection limit of MWCNT-BZ for DA (0.30 μM) appears to be poorer compared to that of MWCNT-ACN (0.03 μM), but nevertheless, both MWCNT-based films exhibit greater detection ability compared to other electrodes reported in the literature. The sensitivities of MWCNT-ACN and MWCNT-BZ towards DA/DAQ were determined as 0.65 and 0.22 A M −1 cm −2 , respectively. The findings suggest that the fabricated MWCNT-based electrodes can be successfully applied for the detection of molecules with biological interest.

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A Glass Capillary Ultramicroelectrode with an Electrokinetic Sampling Ability

Cited by 15 publications

References 32 publications

Mercury-induced hepatotoxicity in zebrafish: in vivo mechanistic insights from transcriptome analysis, phenotype anchoring and targeted gene expression validation

Mercury-induced hepatotoxicity in zebrafish: in vivo mechanistic insights from transcriptome analysis, phenotype anchoring and targeted gene expression validation

A Glass Capillary Microelectrode Based on Capillarity and Its Application to the Detection of l-Glutamate Release from Mouse Brain Slices

Oxidation of dopamine on multi-walled carbon nanotubes

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