Your search keyword '"Bakker, Eric"' showing total 32 results

1. Direct ion speciation analysis with ion-selective membranes operated in a sequential potentiometric/time resolved chronopotentiometric sensing mode.

Author

Ghahraman Afshar M, Crespo GA, and Bakker E

Subjects

Calcium blood, Equipment Design, Humans, Ions blood, Membranes, Artificial, Polypropylenes chemistry, Potassium blood, Sensitivity and Specificity, Calcium analysis, Ion-Selective Electrodes, Ions analysis, Potassium analysis, Potentiometry instrumentation

Abstract

Ion-selective membranes based on porous polypropylene membranes doped with an ionophore and a lipophilic cation-exchanger are used here in a new tandem measurement mode that combines dynamic electrochemistry and zero current potentiometry into a single protocol. Open circuit potential measurements yield near-nernstian response slopes in complete analogy to established ion-selective electrode methodology. Such measurements are well established to give direct information on the so-called free ion concentration (strictly, activity) in the sample. The same membrane is here also operated in a constant current mode, in which the localized ion depletion at a transition time is visualized by chronopotentiometry. This dynamic electrochemistry methodology gives information on the labile ion concentration in the sample. The sequential protocol is established on potassium and calcium ion-selective membranes. An increase of the ionophore concentration in the membrane to 180 mM makes it possible to determine calcium concentrations as high as 3 mM by chronopotentiometry, thereby making it possible to directly detect total calcium in undiluted blood samples. Recovery times after current perturbation depend on the current amplitude but can be kept to below 1 min for the polypropylene based ion-selective membranes studied here. Plasticized PVC as membrane material is less suited for this protocol, especially when the measurement at elevated concentrations is desired. An analysis of current amplitudes, transition times, and concentrations shows that the data are described by the Sand equation and that migration effects are insignificant. A numerical model describes the experimental findings with good agreement and gives guidance on the required selectivity in order to observe a well-resolved transition time and on the expected errors due to insufficient selectivity. The simulations suggest that the methodology compares well to that of open circuit potentiometry, despite giving complementary information about the sample. The tandem methodology is demonstrated in a titration of calcium with nitrilotriacetic acid (NTA) and in the direct detection of calcium in undiluted heparinized and citrated blood.

Published

2012

2. Advancing membrane electrodes and optical ion sensors.

Author

Bakker E, Crespo G, Grygolowicz-Pawlak E, Mistlberger G, Pawlak M, and Xie X

Subjects

Electrochemistry, Electrodes, Ions, Membranes, Artificial, Optics and Photonics

Abstract

While potentiometric sensors experienced a golden age in the 1970s that drove innovation and implementation in the clinical laboratory as sensors of choice, it has been only fairly recently that a theoretical understanding coupled with modern materials approaches transformed the area of membrane electrodes from a playful, yet empirical field to one firmly rooted in scientific understanding. This paper summarizes key progress in the field during the past two decades, emphasizing that the key impulses at the time originated from the emerging field of optical ion sensors. This simplified and transformed the underlying theory of their potentiometric membrane electrode counterparts, where subsequently substantial progress was made, including the realization of ultra-trace detection limits. The better understanding of zero-current ion fluxes and transport processes in turn allowed the development of approaches utilizing dynamic electrochemistry principles, thereby drastically expanding the field of membrane electrodes and making available a range of new methodologies that would have been difficult to predict only a few years ago. These significant developments are now starting to come back and influence the field of optical sensors, where the control and triggering of dynamic processes, away from simpler equilibrium principles, are becoming a highly promising field of research.

Published

2011

3. Ferrocene bound poly(vinyl chloride) as ion to electron transducer in electrochemical ion sensors.

Author

Pawlak M, Grygolowicz-Pawlak E, and Bakker E

Subjects

Carbon chemistry, Electrodes, Metallocenes, Oxidation-Reduction, Electrochemical Techniques methods, Electrons, Ferrous Compounds chemistry, Ions chemistry, Polyvinyl Chloride chemistry

Abstract

We report here on the synthesis of poly(vinyl chloride) (PVC) covalently modified with ferrocene groups (FcPVC) and the electrochemical behavior of the resulting polymeric membranes in view of designing all solid state voltammetric ion sensors. The Huisgen cycloaddition ("click chemistry") was found to be a simple and efficient method for ferrocene attachment. A degree of PVC modification with ferrocene groups between 1.9 and 6.1 mol % was achieved. The chemical modification of the PVC backbone does not significantly affect the ion-selective properties (selectivity, mobility, and solvent casting ability) of potentiometric sensing membranes applying this polymer. Importantly, the presence of such ferrocene groups may eliminate the need for an additional redox-active layer between the membrane and the inner electric contact in all solid state sensor designs. Electrochemical doping of this system was studied in a symmetrical sandwich configuration: glassy carbon electrode |FcPVC| glassy carbon electrode. Prior electrochemical doping from aqueous solution, resulting in a partial oxidation of the ferrocene groups, was confirmed to be necessary for the sandwich configuration to pass current effectively. The results suggest that only approximately 2.3 mol % of the ferrocene groups are electrochemically accessible, likely due to surface confined electrochemical behavior in the polymer. Indeed, cyclic voltammetry of aqueous hexacyanoferrate (III) remains featureless at cathodic potentials (down to -0.5 V). This indicates that the modified membrane is not responsive to redox-active species in the sample solution, making it possible to apply this polymer as a traditional, single membrane. Yet, the redox capacity of the electrode modified with this type of membrane was more than 520 microC considering a 20 mm(2) active electrode area, which appears to be sufficient for numerous practical ion voltammetric applications. The electrode was observed to operate reproducibly, with 1% standard deviation, when applying pulsed amperometric techniques.

Published

2010

4. Multiplexed flow cytometric sensing of blood electrolytes in physiological samples using fluorescent bulk optode microspheres.

Author

Xu C, Wygladacz K, Retter R, Bell M, and Bakker E

Subjects

Animals, Calcium blood, Fluorescent Dyes, Hydrogen-Ion Concentration, Microspheres, Potassium blood, Reproducibility of Results, Sheep, Sodium blood, Flow Cytometry methods, Ions blood, Metals blood

Abstract

Polymeric bulk optode microsphere ion sensors in combination with suspension array technologies such as analytical flow cytometry may become a power tool for measuring electrolytes in physiological samples. In this work, the methodology for the direct measurement of common blood electrolytes in physiological samples using bulk optode microsphere sensors was explored. The simultaneous determination of Na(+), K(+), and Ca(2+) in diluted sheep blood plasma was demonstrated for the first time, using a random suspension array containing three types of mixed microsphere bulk optodes of similar size, fabricated from the same chromoionophore without additional labeling. Sodium ionophore X, potassium ionophore III, and grafted AU-1 in poly(butyl acrylate) were the ionophores used in the bulk optode microsphere ion sensors for Na(+), K(+), and Ca(2+), respectively, in combination with the cation-exchanger NaTFPB (sodium tetrakis-[3,5-bis(trifluoromethyl)phenyl]borate) and the same concentration of the chromoionophore ETH 5294 (9-(di-ethylamino)-5-octadecanoylimino-5H-benzo[a]phen-oxazine) in plasticized poly(vinyl chloride). Excellent reproducibility was achieved for the sensing of potassium ions. The effect of sample pH was relatively small at near-physiological pH and followed theoretical predictions, yet the sample temperature was found to influence the sensor response to a larger extent. Multiplexed ion sensing was achieved by taking advantage of the chemical tunability of the sensor response, adjusting the sensor compositions so that the three types of ion sensors responded with distinct levels of protonation of the chromoionophore. Consequently, three well-resolved peaks were simultaneously observed in the single-channel histogram during the multiplexed calibration as well as in the subsequent measurement of the three cations in 10-fold-diluted sheep plasma. The assigned peak positions corresponded very well to the physiological range of the measured ions.

Published

2007

5. Multicolor quantum dot encoding for polymeric particle-based optical ion sensors.

Author

Xu C and Bakker E

Subjects

Color, Fluorescence, Microspheres, Sodium analysis, Electronic Data Processing methods, Ions analysis, Polymers chemistry, Quantum Dots

Abstract

Multicolor quantum dot-encoded polymeric microspheres are prepared with controllable and uniform doping levels that function as chemical sensors on the basis of bulk optode theory. TOP/TOPO-capped CdSe quantum dots and CdTe quantum dots capped with CdS (lambdaem = 610 and 700 nm, lambdaex = 510 nm) are blended with a THF solution of poly(methyl methacrylate-co-decyl methacrylate), poly(n-butylacrylate), or poly(vinyl chloride) plasticized with bis(2-ethylhexyl) sebacate without a need for ligand exchange. Polymeric microspheres are generated under mild, nonreactive conditions with a particle caster that breaks down a polymer stream containing the quantum dots into fine droplets by the vibration of a piezocrystal. The resulting microspheres exhibit uniform size and fluorescence emission intensities. Fluorescent bar codes are obtained by subsequent doping of two quantum dots with different colors and mass ratios into the microspheres. A linear relationship is found between the readout fluorescence ratio of the two types of nanocrystals and the mixing ratio. Quantum dot-encoded ion sensing optode microspheres are prepared by simultaneous doping of sodium ionophore X, chromoionophore II, a lipophilic tetraphenylborate cation exchanger, and TOPO-capped CdSe/CdS quantum dot as the fluorescent label. A net positive charge of the quantum dots is found to induce an anion-exchange effect on the sensor function, and therefore, an increased concentration of the lipophilic cation exchanger is required to achieve proper ion sensing properties. The modified quantum dot-labeled sodium sensing microspheres show satisfactory sodium response between 10(-4) and 0.1 M at pH 4.8, with excellent selectivity toward common interferences. The amount of the carried positive charges of the CdSe quantum dots is estimated as 2.8 mumol/g of quantum dots used in this study.

Published

2007

6. Ion-selective supported liquid membranes placed under steady-state diffusion control.

Author

Tompa K, Birbaum K, Malon A, Vigassy T, Bakker E, and Pretsch E

Subjects

Diffusion, Solvents, Ions chemistry

Abstract

Supported liquid membranes are used here to establish steady-state concentration profiles across ion-selective membranes rapidly and reproducibly. This opens up new avenues in the area of nonequilibrium potentiometry, where reproducible accumulation and depletion processes at ion-selective membranes may be used to gain valuable analytical information about the sample. Until today, drifting signals originating from a slowly developing concentration profile across the ion-selective membrane made such approaches impractical in zero current potentiometry. Here, calcium- and silver-selective membranes were placed between two identical aqueous electrolyte solutions, and the open circuit potential was monitored upon changing the composition of one solution. Steady state was reached in approximately 1 min with 25-microm porous polypropylene membranes filled with bis(2-ethylhexyl) sebacate doped with ionophore and lipophilic ion exchanger. Ion transport across the membrane resulted on the basis of nonsymmetric ion-exchange processes at both membrane sides. The steady-state potential was calculated as the sum of the two membrane phase boundary potentials, and good correspondence to experiment was observed. Concentration polarizations in the contacting aqueous phases were confirmed with stirring experiments. It was found that interferences (barium in the case of calcium electrodes and potassium with silver electrodes) induce a larger potential change than expected with the Nicolsky equation because they influence the level of polarization of the primary ion (calcium or silver) that remains potential determining.

Published

2005

7. Reversible electrochemical monitoring of surface confined reactions at liquid-liquid interfaces by modulation of ion transfer fluxes.

Author

Xu Y, De Marco R, Shvarev A, and Bakker E

Subjects

Adsorption, Polymers, Surface Properties, Surface-Active Agents, Electrochemistry methods, Ions chemistry, Solutions chemistry

Abstract

The adsorption of the neutral surfactant Brij35 at a liquid-liquid interface is reversibly monitored via its disturbance of an electrochemically imposed ion flux across the interface, forming a promising experimental tool for the detection of surface confined reactions at such liquids and polymers.

Published

2005

8. Rational design of potentiometric trace level ion sensors. A Ag+-selective electrode with a 100 ppt detection limit.

Author

Ceresa A, Radu A, Peper S, Bakker E, and Pretsch E

Subjects

Cations, Divalent analysis, Cations, Monovalent analysis, Electrochemistry, Equipment Design, Fresh Water analysis, Sensitivity and Specificity, Water Supply analysis, Ion-Selective Electrodes standards, Ions analysis

Abstract

Submicromolar to picomolar lower detection limits have recently been obtained with various polymer membrane ion-selective electrodes by minimizing biases due to ion fluxes through the membrane. For the best performance, the compositions of the membrane and inner solution should be optimized for each application. Given the number of parameters to be adjusted, it has been difficult to find the best parameters for a target sample. In this paper, a much simplified and more practical steady-state model of zero-current ion fluxes is derived, which is based on measurable parameters. The model allows one to predict achievable lower detection limits for a membrane with given selectivities. It can also be used to predict the optimal composition of the inner filling solution for the measurement of samples with a known, typical ionic background. Selectivity coefficients of monovalent and divalent analyte ions required for desired detection limits in drinking water are calculated. As an application of the proposed general recipe, a silver-selective electrode is developed on the basis of the ionophore O,O''-bis[2-(methylthio)ethyl]-tert-butylcalix[4]arene. With the predicted optimal composition of the inner electrolyte, its lower detection limit is found to be 10(-9) M or 100 ppt Ag+ with an ionic background of 10(-5) M LiNO3, which is very close to the expected value.

Published

2002

9. How Do Pulsed Amperometric Ion Sensors Work? A Simple PDE Model

Author

Bakker, Eric and Meir, A. J.

Published

2003

10. A copolymerized dodecacarborane anion as covalently attached cation exchanger in ion-selective sensors

Author

Qin, Yu and Bakker, Eric

Subjects

Vinyl chloride, Polymers, Decomposition (Chemistry) -- Analysis, Electrodes -- Composition, Ions, Cations, Chemistry, Analytic -- Research, Chemical compounds, Chemistry

Abstract

The traditional cation exchangers used in ion-selective electrodes and optodes are tetraphenylborate derivatives, which are generally adequate for most analytical applications but may in some cases suffer from decomposition by acid hydrolysis, oxidants, and light. Recently, halogenated dodecacarboranes were found to be improved cation exchangers in terms of lipophilicity and chemical stability. This forms the basis for the convenient covalent attachment of the cation exchanger to the polymeric backbone of the sensing material. This is a challenge that has not satisfactorily been solved and which is especially important in view of developing ultraminiaturized sensing arrays. Here, a C-derivative of the closo-dodecacarborane anion (C[B.sub.11][H.sub.12.sup.-]) with a polymerizable group was synthesized as a chemically stable cation exchanger. This new derivative was copolymerized with methyl methacrylate and decyl methacrylate (MMA-DMA) to fabricate a plasticizer-free polymer with cation-exchange properties. This polymer could be conveniently blended with traditional plasticized poly(vinyl chloride) or with noncrosslinked methacrylic polymers to give solvent cast films that appear to be clear and homogeneous and that could be doped with ionophores. Optode leaching experiments supported the covalent grafting of the carborane anions. Ion-selective membranes and optode thin films were evaluated in terms of response function, response time, and selectivity. In all cases, the new material exhibited behavior similar to free tetraphenylborate derivative-based membranes. As a result of these studies, an all-polymeric plasticizer-free calcium-selective membrane was fabricated on the basis of the covalently attached carborane, a recently introduced grafted calcium ionophore, and an MMA-DMA polymer matrix. The resulting ion-selective electrodes showed Nernstian response slopes and rapid response times, demonstrating that covalent grafting of all sensing components is a feasible approach to the development of ion sensors.

Published

2003

11. Flow cytometric ion detection with plasticized poly(vinyl chloride) microspheres containing selective ionophores

Author

Retter, Robert, Peper, Shane, Bell, Michael, Tsagkatakis, Ioannis, and Bakker, Eric

Subjects

Chemistry, Analytic -- Research, Flow cytometry -- Usage, Ions, Extraction (Chemistry) -- Research, Solution (Chemistry), Cations -- Composition, Surface chemistry -- Research, Potassium compounds, Chemistry

Abstract

The use of flow cytometry as a rapid, high-throughput diagnostic tool for the analysis of ions is described. Monodisperse, uniform microspheres, which obey bulk optode theory and are governed by bulk extraction processes rather than surface phenomena, were prepared under mild, nonreactive conditions using a sonic stream particle casting apparatus. As an initial example demonstrating the utility of this approach, microspheres that contained a [H.sup.+]-selective fluorescent chromoionophore (ETH 5294), a cation-exchanger (NaTFPB), and either a highly sodium-selective (sodium ionophore X) or a potassium-selective ionophore (BME-44) were prepared. Separate solution analysis of sodium- and potassium-selective microspheres resulted in the generation of functional response curves using peak channel fluorescence intensities. The selectivity observed for both types of particles is sufficient for the clinical determination of [Na.sup.+] and [K.sup.+]. Furthermore, sodium- and potassium-selective microspheres were analyzed in parallel using sodium sample solutions, resulting in the successful determination of sodium ion concentrations and providing important information about the selectivity of the potassium-selective sensors over sodium. This work demonstrates the potential applicability of flow cytometry as a means for developing multiplexed, rapid, high-throughput analyses for clinically relevant ions.

Published

2002

12. Response Characteristics of a Reversible Electrochemical Sensor for the Polyion Protamine.

Author

Shvarev, Alexey and Bakker, Eric

Subjects

*ELECTROCHEMICAL sensors, *CHEMICAL detectors, *AMINES, *PROTEINS, *IONS, *CHEMISTRY

Abstract

We describe here in detail the first reversible electrochemical sensors for the polyion protamine. Potentiometric sensors were proposed in recent years, mainly for the determination of the polyions heparin and protamine. Such potentiometri polyion sensors functioned on the nonequilibrium extraction of polyions into a hydrophobic membrane phase via ion pairing with lipophilic ion exchangers. This made it difficult to design sensors that operate in a truly reversible fashion. The reversible sensors described here utilize the same basic response mechanism as their potentiometric counterparts, but the processes of extraction and ion stripping are now fully controlled electrochemically. Spontaneous polyion extraction is avoided by using membranes containing highly lipophilic electrolytes that possess no ion-exchange properties. Reversible extraction of polyions is induced if a constant current pulse of fixed duration is applied across the membrane, followed by a baseline potential pulse. The key theoretical response principles of this new class of polyion sensors are discussed here and compared to those of its classical potentiometric counterpart:. The electrochemical sensing system is characterized in terms of optimal working conditions, membrane composition, selectivity, and influence of sample stirring and organic-phase diffusion coefficient on the response characteristics. Excellent potential stability and reversibility of the sensors are observed, and measurements of heparin concentration in whole blood samples via protamine titration are demonstrated. [ABSTRACT FROM AUTHOR]

Published

2005

13. The phase-boundary potential model

Author

Bakker, Eric, Bühlmann, Philippe, and Pretsch, Ernö

Subjects

*ELECTRODES, *IONS, *IONOPHORES, *ORGANIC compounds

Abstract

The response of ion-selective electrodes (ISEs) can be described on the basis of two different theoretical approaches. On one hand, the phase-boundary model is based on the assumption of local equilibria at the aqueous/organic interface. The phase-boundary model allows the description of all practically relevant cases of steady state and even transient responses with sufficient accuracy. Moreover, it has the advantage of relating simple thermodynamic parameters to the response function of the electrodes and hence allowing an intuitive interpretation of many observed facts. On the other hand, the comprehensive but quite involved dynamic model requires knowledge of mobilities and ion transfer rate constants. It has never been applied to ionophore-based electrodes in its full complexity. Both models were first suggested decades ago but have been recently extended to explain so far poorly understood aspects of ionophore-based ISEs. Due to space restrictions, only the most important original references are given in this paper, which summarizes the major assumptions of the phase-boundary potential model and discusses the usefulness and limits of this approach. Recent applications are discussed towards understanding sensor selectivity, upper and lower detection limits (even when concentration polarizations are relevant), the so-called sandwich membrane method to determine thermodynamic parameters, apparently non-Nernstian responses, potential drifts with solid contact electrodes, polyion sensors, and galvanostatically controlled ion sensors. [Copyright &y& Elsevier]

Published

2004

14. Quantification of the Concentration of Ionic Impurities in Polymeric Sensing Membranes with the...

Author

Yu Qin and Bakker, Eric

Subjects

*INDUSTRIAL contamination, *IONS, *ELECTRODES, *ELECTROLYTES, *ANALYTICAL chemistry

Abstract

Focuses on the quantification of the concentration of ionic impurities in polymeric sensing membranes with the segmented sandwich technique. Use of ion-selective electrodes in the assessment of ionic and neutral electrolytes; Nature of anionic impurities; Effect of high concentration of inert electrolyte.

Published

2001

15. Selectivity Behavior and Multianalyte Detection Capability of Voltammetric Ionophore-Based...

Author

Jadhav, Smita and Bakker, Eric

Subjects

*DETECTORS, *EXTRACTION (Chemistry), *IONS

Abstract

Reveals the selectivity behavior and multianalyte detection capability of voltammetric ionophore-based plasticized polymeric membrane sensors. Extraction of ions; Current at the end of an uptake pulse; Role of the applied potential; Range expected for ions in an inner electrolyte.

Published

2001

16. General description of the simultaneous response of potentiometric ionophore-based sensors to...

Author

Nagele, Mathias and Bakker, Eric

Subjects

*ION selective electrodes, *IONS

Abstract

Presents equations to describe the general mixed ion response behavior of ion-selective membrane electrodes. Phase boundary potential model as the basis of the equations; Development of an equation for ions of any charge; Comparing the equation to the Nicolskii-Eisenman equation; Factors affecting equation deviations at low interferences and bias calibrations.

Published

1999

17. Colorimetric ratiometry with ion optodes for spatially resolved concentration analysis.

Author

Soda, Yoshiki and Bakker, Eric

Subjects

*OPTODES, *SPECTRAL sensitivity, *COLORIMETRY, *OPTICAL sensors, *IMAGE analysis, *IONS, *COLORIMETRIC analysis, *MICROEMULSIONS

Abstract

The deprotonation degree of the lipophilic pH indicator dye (chromoionophore) in ionophore-based ion optodes (so-called bulk optodes) has traditionally been measured spectrophotometrically. This makes it difficult to obtain spatially resolved concentration information, for example in the study of heterogenous systems. This article reports on a new colorimetric method that relies on a ratiometric image analysis. The acquision of image data allows one to map the deprotonation degree in two dimensions, which in turn is used to obtain the spatially-resolved ion concentration of the image. Using the detection of potassium as an example, the deprotonation degree data calculated on the basis of image analysis correlate quantitatively with those from spectrophotometry. They showed no dependence on the type of camera used in spite of their different gamma correction values and spectral sensitivities, as expected from theory. As an example, the method is successfully applied to the pixel level analysis of an ensemble of pictures acquired at different times to spatially and temporally observe potassium ion diffusion into an agarose gel containing a potassium-selective optical sensor microemulsion. [Display omitted] • RGB colorimetry is used for calculating the deprotonation degree of ion optodes. • The resulting data are independent of the imaging device used. • The data are independent of background light intensity. • The method is applied to the temporal and spatial analysis of K+ diffusion. [ABSTRACT FROM AUTHOR]

Published

2021

18. Reversible Electrochemical Detection of Nonelectroactive Polyions.

Author

Shvarev, Alexey and Bakker, Eric

Subjects

*IONS, *ELECTROCHEMISTRY

Abstract

Focuses on reversible electrochemical detection principle for nonelectroactive polyions. Comparison with selective extraction principle; Mechanism of polyion detection principle; Application to critical care.

Published

2003

19. Thin Layer Ionophore-Based Membrane for Multianalyte Ion Activity Detection.

Author

Crespo, Gastón A., Cuartero, Maria, and Bakker, Eric

Subjects

*IONOPHORES, *BIOLOGICAL transport, *BIOLOGICAL membranes, *IONS, *ELECTRODES

Abstract

A concept is introduced that allows one to detect the activity of multiple ions simultaneously and selectively with a single ion-selective membrane. This is demonstrated with ~300 nm thin plasticized PVC membranes containing up to two ionophores in addition to a lipophilic cation-exchanger, overlaid on an electropolymerized poly-3-octylthiophene (POT) film as the electron to ion transducer. The ion-selective membranes are formulated under ionophore depleted conditions (avoiding excess of ionophore over ion-exchanger), which is purposely different from common practice with ion-selective electrodes. Cyclic voltammetry is used to interrogate the films. An anodic scan partially oxidizes the POT underlayer, which results in the expulsion of cations from the membrane at an appropriate potential. During the scan of a membrane containing multiple ionophores, the least bound ion is expelled first, giving distinct Gaussian peak shaped ion transfer voltammetric waves that are analyzed in terms of their peak potential. These potentials are found to change with the logarithm of the ion activity, in complete analogy to ion-selective electrodes, and multiple such waves are observed with multiple ionophores that exhibit no obvious interference from the other ionophores present in the membrane. The concept is established with lithium and calcium ionophores and accompanied by a response model that assumes complete equilibration of the membrane at every applied potential. On the basis of the model, diffusion coefficients in the membrane or aqueous phase bear no influence on the peak potentials as long as thin layer behavior is observed, further confirming the analogy to a potentiometric experiment. Idealized ion transfer waves are narrower than experimental findings, which is explained by a broader than expected anodic peak for the oxidation of conducting polymer. The correspondence between experiment and theory is otherwise excellent in terms of thin layer behavior and Nernstian shift of the peaks with analyte concentration. [ABSTRACT FROM AUTHOR]

Published

2015

20. pH Independent Nano-Optode Sensors Based on Exhaustive Ion-Selective Nanospheres.

Author

Xiaojiang Xie, Jingying Zhai, and Bakker, Eric

Subjects

*OPTODES, *OPTICAL sensors, *IONS, *NANOSENSORS, *CHEMICAL detectors

Abstract

Bulk optode-based ion selective optical sensors work on the basis of extraction equilibria, and their response toward the analyte ion is known to dependent on the sample pH. This pH dependence has been one of the major disadvantages that have hampered the broad acceptance of bulk optodes in chemical sensing. We present here for the first time the use of exhaustive Ca2+-selective nanosensors that may overcome this pH dependent response. The nanosensors were characterized at different pH and the same linear calibration was obtained in the Ca2+ concentration range from 10-7 M to 10-5 M. [ABSTRACT FROM AUTHOR]

Published

2014

21. Ultrasmall Fluorescent Ion-Exchanging Nanospheres Containing Selective Ionophores.

Author

Xiaojiang Xie, Mistlberger, Günter, and Bakker, Eric

Subjects

*FLUORESCENCE, *IONS, *NANOSTRUCTURES, *IONOPHORES, *PRECIPITATION (Chemistry), *COPOLYMERS, *FLUORESCENCE spectroscopy, *ATOMIC absorption spectroscopy

Abstract

We present a convenient precipitation procedure to fabricate ultrasmall fluorescent ion-selective nanosensors that operate on the basis of bulk ion-exchange sensing principles. The nanosphere matrix is composed of bis(2- ethylhexyl) sebacate (DOS) and a triblock copolymer Pluronic® F-127, which also functions as a surfactant to stabilize the nanoparticle. The particles can be prepared easily in large quantity without resorting to further complicated purification. Dynamic light scattering shows that these particles have a monodisperse size distribution with an average diameter of ∼40 nm, suggesting that the nanoparticles are among the smallest ionophore-based ion-selective nanosensors reported to date. A newly reported oxazinoindoline (Ox) as well as a Nile blue derivative (chromoionophore I) was used as a chromoionophore. Na+- and H+-selective nanospheres were characterized by absorbance and fluorescence spectroscopy. Owing to the very small size of the nanospheres, the suspension containing the particles is transparent. In the additional presence of the pH indicator HPTS, spectroscopic interrogation of pH and Na+ in the same sample was demonstrated. As an example, the nanospheres were used to measure the Na+ level in commercial mineral waters, and the results showed good agreement with atomic absorption spectroscopy (AAS). [ABSTRACT FROM AUTHOR]

Published

2013

22. Direct Ion Speciation Analysis with Ion-Selective Membranes Operated in a Sequential Potentiometric/Time Resolved Chronopotentiometric Sensing Mode.

Author

Afshar, Majid Ghahraman, Crespo, Gastón A., and Bakker, Eric

Subjects

*CHEMICAL speciation, *IONS, *POTENTIOMETRY, *IONOPHORES, *POLYPROPYLENE, *ION exchange (Chemistry), *POLYVINYL chloride, *NITRILOTRIACETIC acid

Abstract

Ion-selective membranes based on porous polypropylene membranes doped with an ionophore and a lipophilic cation-exchanger are used here in a new tandem measurement mode that combines dynamic electrochemistry and zero current potentiometry into a single protocol. Open circuit potential measurements yield near-Nernstian response slopes in complete analogy to established ion-selective electrode methodology. Such measurements are well established to give direct information on the so-called free ion concentration (strictly, activity) in the sample. The same membrane is here also operated in a constant current mode, in which the localized ion depletion at a transition time is visualized by chronopotentiometry. This dynamic electrochemistry methodology gives information on the labile ion concentration in the sample. The sequential protocol is established on potassium and calcium ion-selective membranes. An increase of the ionophore concentration in the membrane to 180 mM makes it possible to determine calcium concentrations as high as 3 mM by chronopotentiometry, thereby making it possible to directly detect total calcium in undiluted blood samples. Recovery times after current perturbation depend on the current amplitude but can be kept to below 1 min for the polypropylene based ion-selective membranes studied here. Plasticized PVC as membrane material is less suited for this protocol, especially when the measurement at elevated concentrations is desired. An analysis of current amplitudes, transition times, and concentrations shows that the data are described by the Sand equation and that migration effects are insignificant. A numerical model describes the experimental findings with good agreement and gives guidance on the required selectivity in order to observe a well-resolved transition time and on the expected errors due to insufficient selectivity. The simulations suggest that the methodology compares well to that of open circuit potentiometry, despite giving complementary information about the sample. The tandem methodology is demonstrated in a titration of calcium with nitrilotriacetic acid (NTA) and in the direct detection of calcium in undiluted heparinized and citrated blood. [ABSTRACT FROM AUTHOR]

Published

2012

23. Detection Limits of Thin Layer Coulometry with Ionophore Based Ion-Selective Membranes.

Author

Shvarev, Alexey, Neel, Bastien, and Bakker, Eric

Subjects

*COULOMETRY, *IONOPHORES, *IONS, *POTASSIUM, *ELECTRODES, *ELECTROLYSIS, *ARTIFICIAL membranes, *SODIUM

Abstract

We report here on a significant improvement in lowering the low detection limit of thin layer coulometric sensors based on liquid ion-selective membranes, using a potassium-selective system as a model example. Various possible processes that may result in an elevated residual current reading after electrolysis were eliminated. Self-dissolution of AgCl on the Ag/AgCl inner element may result in a residual ion flux that could adversely affect the lower detection limit. It was here replaced with an Ag/AgI inner pseudoreference electrode where the self-dissolution equilibrium is largely suppressed. Possible residual currents originating from a direct contact between inner element and ion-selective membranes were eliminated by introducing an inert PVDF separator of 50 μm diameter that was coiled around the inner element by a custom-made instrument. Finally, the influence of electrolyte fluxes from the outer solution across the membrane into the sample was evaluated by altering its lipophilic nature and reducing its concentration. It was found that this last effect is most likely responsible for the observed residual current for the potassium-selective membranes studied here. For the optimized conditions, the calibration curves demonstrated a near zero intercept, thereby paving the way to the coulometric calibration-free sensing of ionic species. A linear calibration curve for the coulometric cell with valinomycin potassium-selective membrane was obtained in the range of 100 nM to 10 μM potassium in the presence of a 10 μM sodium background. In the presence of a higher (100 μM) concentration of sodium, a reliable detection of 1-100 μM of potassium was achieved. [ABSTRACT FROM AUTHOR]

Published

2012

24. Selectivity enhancement of anion-responsive electrodes by pulsed chronopotentiometry

Author

Gemene, Kebede L., Shvarev, Alexey, and Bakker, Eric

Subjects

*ION selective electrodes, *IONS, *PERCHLORATES, *CHLORIDES

Abstract

Abstract: A large and robust selectivity improvement of ion-selective electrodes is presented for the measurement of abundant ions. An improvement in selectivity by more than two orders of magnitude has been attained for the hydrophilic chloride ions measured in a dilute background of the lipophilic ions perchlorate and salicylate in a pulsed chronopotentiometric measurement mode. This is attributed to a robust kinetic discrimination of the dilute lipophilic ions in this measuring mode, which is not possible to achieve in classical potentiometry. Maximum tolerable concentrations of the interfering ions are found to be on the order of 30μM before causing substantial changes in potential. As an example of practical relevance, the robust detection of chloride in 72μM salicylate (reflecting 1:10 diluted blood) with a detection limit of 0.5mM chloride is demonstrated. Corresponding potentiometric sensors did not give a useful chloride response under these conditions. [Copyright &y& Elsevier]

Published

2007

25. Calcium Pulstrodes with 10-Fold Enhanced Sensitivity for Measurements in the Physiological Concentration Range.

Author

Makarychev-Mikhailov, Sergey, Shvarev, Alexey, and Bakker, Eric

Subjects

*IONS, *ELECTRODES, *THIRD law of thermodynamics, *TEMPERATURE, *CALCIUM ions, *POTENTIOMETRY, *ELECTROLYTES, *TEMPERATURE control, *DETECTORS

Abstract

Ion-selective electrodes ideally operate on the basis of the Nernst equation, which predicts less than 60- and 30-mV potential change for a 10-fold activity change of monovalent and divalent ions measured at room temperature, respectively. Typical concentration ranges in extracellular fluids are quite narrow for the electrolytes of key importance. A range of 2.2–2.6 mM for calcium ions, for instance, translates into just a 2.2-mV potential change. The direct potentiometric measurement of physiological electrolytes is certainly possible with direct potentiometry and is done routinely in clinical analyzers and handheld measuring devices. It places, however, strong demands on the precision of the reference electrode and requires careful temperature control and frequent calibration runs. In this paper, a robust 10–20-fold sensitivity enhancement for calcium measurements is attained by departing from the classical response mechanism and operating in a non-Nernstian response mode. Stable and reproducible super-Nernstian responses of these so-called pulstrodes in a narrow calcium activity range can be controlled by instrumental means in good agreement with theory. The potentials may be measured during a galvanostatic excitation pulse (mode I) or immediately after it (mode II), under open-circuit conditions. Subtraction of the potentials, sampled at different times during a single pulse, allows one to obtain a sensitive differential peak-shaped signal at a critical and fully adjustable analyte activity range. Calcium pulstrodes based on the diamide ionophore AU-1 were characterized and applied to the measurement in model physiological liquids. Super-Nernstian responses exceeding 700 mV/decade were observed in a physiological range of calcium concentration. Such remarkable sensitivity of the pulstrodes, complemented with the well-documented high selectivity of these potentiometric sensors, may provide a significant increase in the accuracy and precision of electrolyte measurements in clinical analysis. [ABSTRACT FROM AUTHOR]

Published

2006

26. Optical chloride sensor based on [9]mercuracarborand-3 with massively expanded measuring range

Author

Xu, Chao, Qin, Yu, and Bakker, Eric

Subjects

*IONS, *ORGANIC compounds, *IONOPHORES, *CELL permeability, *CATION metabolism

Abstract

Bulk optodes for monovalent ions typically exhibit a relatively narrow measuring range of about two-orders of magnitude. Here, the measuring range was expanded to about six-orders of magnitude concentration change by optimizing a fluorescent chloride optical sensing film based on a plasticized poly(vinyl chloride) film incorporating the halide-selective ionophore [9]mercuracarborand-3 and the H+-chromoionophore 9-dimethylamino-5-[4-(15-butyl-1,13-dioxo-2,14-dioxanonadecyl) phenyl-imino]benzo[a]phenox-azine (ETH 5418). This was achieved with the recently established two-step ionophore binding mechanism: the expanded sensing range sequentially makes use of the 1:2 and 1:1 binding stoichiometries between ionophore to chloride. The relevant complex formation constants were found here as log K1=9.1 and log K2=2.7, which are consistent with previously reported values. The selectivity of this optode is very good, with an excellent discrimination of thiocyanate and lipophilic anions such as salicylate, nitrate and perchlorate. As with earlier work, the main interferences are the other halides bromide and iodide. [Copyright &y& Elsevier]

Published

2004

27. Ion transfer mediated by TEMPO in ionophore-doped thin films for multi-ion sensing by cyclic voltammetry.

Author

Mattos, Gabriel J., Rothen, Justine A., Tiuftiakov, Nikolai Yu, and Bakker, Eric

Subjects

*THIN films, *LITHIUM, *IONS, *LITHIUM ions, *POTASSIUM ions, *POTENTIOMETRY, *CYCLIC voltammetry

Abstract

We report here on the development of thin-layer ion-selective membranes containing lipophilic TEMPO as a phase-transfer redox mediator for the simultaneous detection of non-redoxactive ions. This redox probe was recently introduced by our group and provides ideal ion-transfer waves when the membrane is interrogated by cyclic voltammetry. To perform multianalyte detection in the same sensing film, plasticized PVC-based membranes were doped with lithium and potassium ionophores in addition to a lipophilic cation-exchanger. The ionophores allow for ion discrimination owing to the different ionophore-cation complexation constants and the oxidation of TEMPO to the oxoammonium form results in the selective transfer of lithium and potassium at different potentials. The resulting voltammograms have half-peak widths of 100 and 102 mV, and the peak separation between anodic and cathodic scans is 8 and 9 mV for lithium and potassium, respectively, close to theoretical expectations. High peak resolution was observed, and the ion-transfer waves are still distinguishable when the ion activities differ by three orders of magnitude. These parameters are remarkably better than those obtained with other redox probes, which is important for multianalyte detection in the same voltammetric scan. Optimized membranes showed independent Nernstian shifts (slopes of 59.23 mV and 54.8 mV for K+ and Li+, respectively) of the peak position for increasing ion concentrations. An idealized model for two ionophore-based membranes combining redox and phase-boundary potentials was applied to the proposed system with excellent correlation. Potassium and lithium ions were simultaneously detected in undiluted human serum samples with good accuracy and precision. [Display omitted] • TEMPO opens new horizons as a redox probe for producing reversible multianalyte sensors. • Ion transfer by cyclic voltammetry provides ideal peak shapes for multi-ion sensing in a single voltammogram. • Thin layer membranes containing multiple ionophores allow for excellent ion discrimination. • Well-resolved ion-transfer waves have independent Nernstian behavior in agreement with an idealized model. [ABSTRACT FROM AUTHOR]

Published

2024

28. Electrogenerated Chemiluminescence for Potentiometric Sensors.

Author

Crespo, Gastón A., Mistlberger, Günter, and Bakker, Eric

Subjects

*CHEMILUMINESCENCE, *POTENTIOMETRY, *POTASSIUM, *IONS, *ELECTRODES, *RUTHENIUM, *VOLTAMMETRY, *DETECTORS

Abstract

We report here on a generic approach to read out potentiometric sensors with electrogenerated chemiluminescence (ECL). In a first example, a potassium ion-selective electrode acts as the reference electrode and is placed in contact with the sample solution. The working electrode of the three-electrode cell is responsible for ECL generation and placed in a detection solution containing tris(2,2'-bipyridyl)ruthenium(II) [Ru(bpy)32+] and the coreactant 2-(dibutylamino)ethanol (DBAE), physically separated from the sample by a bridge. Changes in the sample potassium concentration directly modulate the potential at the working electrode, and hence the ECL output, when a constant-potential pulse is applied between the two electrodes. A linear response of the ECL intensity to the logarithmic potassium concentration between 10 μm and 10 mM was found. [ABSTRACT FROM AUTHOR]

Published

2012

29. Determination of pKa Values of Hydrophobic Colorimetric pH Sensitive Probes in Nanospheres.

Author

Xiaojiang Xie, Jingying Zhai, Jarolimová, Zdeňka, and Bakker, Eric

Subjects

*SOLVATOCHROMISM, *NANOSTRUCTURED materials, *ANALYTICAL chemistry research, *HYDROPHOBIC compounds, *IONS

Abstract

A simple and novel method is proposed here for the first time to determine pK, values of chromogenic hydrophobic pH sensitive probes directly in nanospheres. pKa values can be obtained by measuring the pH response of the nanospheres (containing the probes and ion exchanger) followed by measuring the pH and Na+ responses of the nanospheres (containing solvatochromic dyes and ion exchanger). The pKa values of four chromoionophores were successfully determined. This method is in principle also applicable to characterize colorimetric probes in other water immiscible nanomaterials. [ABSTRACT FROM AUTHOR]

Published

2016

30. Pulstrodes: Triple Pulse Control of Potentiometric Sensors.

Author

Makarychev-Mikhailov, Sergey, Shvarev, Alexey, and Bakker, Eric

Subjects

*ELECTROCHEMICAL analysis, *QUANTITATIVE chemical analysis, *VOLTAMMETRY, *POTENTIOMETRY, *VALENCE (Chemistry), *IONS, *PROPERTIES of matter

Abstract

The concept of so-called pulstrodes is introduced where a multipulse electrochemical excitation signal is imposed onto an ionophore-based ion-selective liquid membrane operating on the basis of assisted ion transfer voltammetry principles. This yields a tunable potential difference signal that is independent of the reference electrode potential and gives a significantly larger sensitivity than predicted classically on the basis of the Nernst equation. Ion-selective electrodes normally obey the Nerst equation, which predicts that a 10-fold sample activity change of a monovalent ion yields a ca. 59 mV change in the observed electromotive force. For ions of higher valency, this sensitivity is proportionally smaller. A second important limitation of ion-selective electrodes is the direct electromotive force on the reference electrode.

Published

2004

31. High-Temperature Potentiometry: Modulated Response of Ion-Selective Electrodes During Heat Pulses.

Author

Chumbimuni-Torres, Karin Y., Thammakhet, Chongdee, Galik, Michal, Calvo-Marzal, Percy, Jie Wu, Bakker, Eric, Flechsig, Gerd-Uwe, and Wang, Joseph

Subjects

*COPPER electrodes, *HEAT pulses, *POTENTIOMETRY, *POLYELECTROLYTES, *IONS

Abstract

The concept of locally heated polymeric membrane potentiometric sensors is introduced here for the first time. This is accomplished in an all solid state sensor configuration, utilizing poly(3-octylthiophene) as the intermediate layer between the ion-selective membrane and underlying substrate that integrates the heating circuitry. Temperature pulse potentiometry (TPP) gives convenient peak-shaped analytical signals and affords an additional dimension with these sensors. Numerous advances are envisioned that will benefit the field. The heating step shown to give an increase in the slope of the copper-selective electrode from 31 to 43 mV per 10-fold activity change, with a reproducibility of the heated potential pulses of 1% at 10 μM copper levels and a potential drift of 0.2 mV/h. Importantly, the magnitude of the potential pulse upon heating the electrode changes as a function of the copper activity, suggesting an attractive way for differential measurement of these devices. The heat pulse is also shown to decrease the detection limit by half an order of magnitude. [ABSTRACT FROM AUTHOR]

Published

2009

32. Separating boundary potential changes at thin solid contact ion transfer voltammetric membrane electrodes.

Author

Mao, Canwei, Yuan, Dajing, Wang, Lu, and Bakker, Eric

Subjects

*MONOVALENT cations, *MONOMOLECULAR films, *IONS, *THIN films, *DIFFUSION processes

Abstract

Thin ion-selective membrane films deposited on solid electrode substrate are useful tools to study ion transfer processes. This is because the experimental conditions may be chosen such that diffusion processes within the membrane and contacting aqueous solution are not rate limiting. In an ideal case, therefore, equilibrium considerations may be used to describe the resulting ion transfer voltammograms. For example, the electrochemical oxidation of an electrically neutral redox molecule in the membrane results in a cationic oxidized form. To preserve electroneutrality, a cation is transferred out of the membrane into solution, freeing the cation-exchanger of the membrane to become the counterion of the oxidized redox molecule. This work describes a model system that agrees well with thermodynamic theory, using the lipophilic (1-dodecyl-1H-1,2,3-triazol-4-yl)ferrocene as redox molecule and a monovalent reference cation for ion transfer. The full peak width at half maximum was found as 0.110 V, in agreement with theory, and with peak current proportional to scan rate supporting thin layer behavior. The charge passed during the voltammetric scan was related to ion-exchanger concentration available for ion extraction as a function of potential. Subtraction of the ion transfer potential using the reference ion from the experimental one for each charge increment gave the potential change for the electrochemical ion-to-electron transducer. In one application, the potential change of the polymeric transducing layer poly(3-octylthiophene) (POT) film upon electrochemical oxidation within the membrane was characterized. A non-linear potential–charge curve was observed, in contrast to earlier assumptions. Unlabelled Image • Ion transfer at thin membrane films containing a molecular redox probe can be described in a Nernstian manner. • From the voltammogram, the integrated current is converted to available ion-exchanger concentration. • This allows one to separate the potential changes for ion transfer from that of the transducing layer. • The potential change of the transducing material poly(octyl thiophene) is isolated. • This describes the an ion transfer wave separated from the ion-to-electron transducer. [ABSTRACT FROM AUTHOR]

Published

2021