WO2018146543A1 - Online reference calibration - Google Patents
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- WO2018146543A1 WO2018146543A1 PCT/IB2018/000097 IB2018000097W WO2018146543A1 WO 2018146543 A1 WO2018146543 A1 WO 2018146543A1 IB 2018000097 W IB2018000097 W IB 2018000097W WO 2018146543 A1 WO2018146543 A1 WO 2018146543A1
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01N—INVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
- G01N27/00—Investigating or analysing materials by the use of electric, electrochemical, or magnetic means
- G01N27/26—Investigating or analysing materials by the use of electric, electrochemical, or magnetic means by investigating electrochemical variables; by using electrolysis or electrophoresis
- G01N27/416—Systems
- G01N27/4163—Systems checking the operation of, or calibrating, the measuring apparatus
- G01N27/4165—Systems checking the operation of, or calibrating, the measuring apparatus for pH meters
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01N—INVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
- G01N27/00—Investigating or analysing materials by the use of electric, electrochemical, or magnetic means
- G01N27/26—Investigating or analysing materials by the use of electric, electrochemical, or magnetic means by investigating electrochemical variables; by using electrolysis or electrophoresis
- G01N27/28—Electrolytic cell components
- G01N27/30—Electrodes, e.g. test electrodes; Half-cells
- G01N27/301—Reference electrodes
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01N—INVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
- G01N27/00—Investigating or analysing materials by the use of electric, electrochemical, or magnetic means
- G01N27/26—Investigating or analysing materials by the use of electric, electrochemical, or magnetic means by investigating electrochemical variables; by using electrolysis or electrophoresis
- G01N27/28—Electrolytic cell components
- G01N27/30—Electrodes, e.g. test electrodes; Half-cells
- G01N27/302—Electrodes, e.g. test electrodes; Half-cells pH sensitive, e.g. quinhydron, antimony or hydrogen electrodes
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01N—INVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
- G01N27/00—Investigating or analysing materials by the use of electric, electrochemical, or magnetic means
- G01N27/26—Investigating or analysing materials by the use of electric, electrochemical, or magnetic means by investigating electrochemical variables; by using electrolysis or electrophoresis
- G01N27/28—Electrolytic cell components
- G01N27/30—Electrodes, e.g. test electrodes; Half-cells
- G01N27/327—Biochemical electrodes, e.g. electrical or mechanical details for in vitro measurements
- G01N27/3275—Sensing specific biomolecules, e.g. nucleic acid strands, based on an electrode surface reaction
- G01N27/3277—Sensing specific biomolecules, e.g. nucleic acid strands, based on an electrode surface reaction being a redox reaction, e.g. detection by cyclic voltammetry
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01N—INVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
- G01N27/00—Investigating or analysing materials by the use of electric, electrochemical, or magnetic means
- G01N27/26—Investigating or analysing materials by the use of electric, electrochemical, or magnetic means by investigating electrochemical variables; by using electrolysis or electrophoresis
- G01N27/416—Systems
- G01N27/4163—Systems checking the operation of, or calibrating, the measuring apparatus
-
- G—PHYSICS
- G01—MEASURING; TESTING
- G01N—INVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
- G01N27/00—Investigating or analysing materials by the use of electric, electrochemical, or magnetic means
- G01N27/26—Investigating or analysing materials by the use of electric, electrochemical, or magnetic means by investigating electrochemical variables; by using electrolysis or electrophoresis
- G01N27/416—Systems
- G01N27/48—Systems using polarography, i.e. measuring changes in current under a slowly-varying voltage
Definitions
- the present disclosure describes an online calibration system for an electrochemical sensor.
- the online calibration system comprises a calibration electrode configured to be deployed in a reference cell of the electrochemical sensor and to contact a reference solution therein.
- the calibration electrode comprises a redox species that is sensitive to pH/hydrogen ion concentration and is configured to set a pH of the reference solution local to the calibration electrode, such that when an electrochemical/voltammetric signal is applied to the calibration electrode, the calibration electrode generates an electrochemical/voltammetric response that has a constant feature, such as a peak potential, corresponding to the set pH of the reference solution local to the calibration electrode.
- the reference potential of the electrochemical sensor produced by the reference cell is calibrated by comparing a difference between the constant feature of the electrochemical/voltammetric response of the calibration electrode and the reference potential while the electrochemical sensor is deployed and/or being used. By repeatedly processing this difference, the reference potential can be calibrated online, without manual intervention.
- electrochemical sensors In general there are three types of electrochemical sensors, voltammetric sensors, potentiometric sensors and/or amperometric sensors.
- Amperometric sensors normally comprise at least a first electrode and a reference electrode.
- a voltage is applied between the first electrode and the reference electrode and the resulting current between the first electrode and the reference electrode is measured.
- the current is produced by oxidation/reduction of a chemical species that the sensor is configured to detect and the measured current is indicative of the concentration of the chemical species.
- the potential applied between the first electrode and the reference electrode needs to be a known potential.
- a reference solution which is a solution containing chloride ions, such as potassium chloride (KC1) solution, a sodium chloride (NaCl) solution and/or the like, to maintain the potential of the reference electrode as a constant.
- KC1 potassium chloride
- NaCl sodium chloride
- the reference solution may become diluted, reducing the concentration of CI ions, contaminated and, as a result, the potential applied between the first electrode and the reference electrode may drift, reducing the accuracy of the reference system.
- Voltammetric/potentiometric sensors are some of the most common types of electrochemical sensor.
- Potentiometric sensors are the basis for glass electrodes (used for measuring pH, sodium (Na+), potassium (K+), lithium (Li+) and the like), solid membrane electrodes (based on the chemical process AgX for X-), liquid membrane electrodes (e.g. containing a ligand for M+ complexation and used in calcium (Ca+) and K+ sensors), pH-meter-based gas detectors (e.g. carbon dioxide (C02) sensors, ammonia (NH3) sensors etc.) and some solid oxide sensors (e.g. zirconia-based oxygen (02) sensors). Voltammetric sensors may be used to measure pH, glucose, oxygen, hydrogen sulphide, for biosensing, for pharmaceutical sensing and/or the like.
- Potentiometric/voltammetric sensors measure a potential difference between an electrode or environment that is sensitive to the desired analyte and an electrode or environment that is insensitive to the analyte.
- an electrode or environment that is sensitive to the analyte is known as the sensing electrode and the electrode or environment that is insensitive to the analyte is known as the reference electrode.
- ISFETs Ion-sensitive field-effect transistors
- the sensing electrode is replaced with ion selective field effect transmitter, which measures a voltage between a source and a drain that is dependent on a concentration of an analyte in a solution being measured.
- this source-drain voltage is measured against an output from a reference electrode housed in a well-defined environment.
- the reference electrode comprises a silver/silver chloride (Ag/AgCl) electrode that is held within a defined environment, containing a reference solution, behind a porous frit that allows for electrical conductivity to the solution that the sensor is measuring.
- Ag/AgCl silver/silver chloride
- the Ag/AgCl electrode is stored in a solution with known properties when not in operation as the electrode can dry out when held in a dry atmosphere.
- the Ag/AgCl sensor requires periodic recalibration due to drifts in the reference electrode potential because the chemistry of the electrode may change and/or ions may pass through the frit and perturb the environment.
- potentiometric systems typically operate in a continuous single point measurement mode, which is a mode where a known current is held between the reference and sensing electrode (typically 0) and the potential difference is constantly measured.
- United States Patent Number 5,419,826 describes an ion-selective reference probe adapted for use with potentiometric measurement systems.
- the reference probe is non-chloride based and employs a specially adapted electrolyte, which is reversible with regard to ionic activity.
- United States Patent Publication Number 20030024812 discloses a solid state electrochemical reference system, containing two or more electrodes, wherein the half-cell potential of at least one electrode is determined by the concentration of a specific ion anticipated to be present in all test solutions.
- the ion concentration measured in the cell by a first electroanalytical technique does not depend on a known reference electrode potential, such that said electrode, its half-cell potential being calculable from the measured ion concentration, can serve as a reference electrode in one or more subsequent electroanalytical techniques that do depend on a known reference electrode potential, said subsequent technique or techniques being carried out in the same cell.
- United States Patent Number 6,398,931 details an improved combination ion-selective electrode apparatus comprising an electrode body, a reference electrode, and an ion-sensing electrode.
- the reference electrode comprises an ion-permeable junction and a removable membrane cap contains an ion-selective membrane. The membrane cap can be removed from the ion- selective electrode apparatus without endangering the integrity of the reference electrode and is distinct from the ion-permeable junction.
- European Patent Number 2 932 249 describes a reference electrode for an electrochemical sensor that comprises an inner reference element, where inner reference element has been embedded into a solid electrochemically active composite material.
- United States Patent Number 7,462,267 describes a reference electrode consisting of a metal in contact with an electrolyte containing an anion or cation whose concentration in part determines the redox potential of the electrode.
- This electrolyte contains a polyelectrolyte that partially and reversibly binds the chemical cation or anion thus lowering the free concentration of the cation or anion compared to the osmotic pressure of the same concentration of cation or anion if present as a simple salt.
- the polyelectrolyte can be anionic or cationic depending on the chemistry of the redox electrode and a thickener may also be added to the electrolyte.
- the techniques for stabilizing/calibrating the reference electrode are complex, require manual intervention and regular maintenance, and use potentiometric operation, which may compound/mask stability errors. Because of the need to recalibrate the reference system of most electrochemical sensors, the sensors cannot be accurately used for long duration operation, cannot be used in an autonomous/networked system, and require costly manual calibration.
- a calibration system comprises a calibration electrode, which may comprise a working electrode, that is used to make a voltammetric/electrochemical measurement and this measurement is used to verify/calibrate the electrochemical potential of a reference electrode of a potentiometric sensor.
- the calibration system can provide a correction to any drift in the reference electrode, without manual intervention.
- the calibration measurement is an electrochemical/voltammetric measurement the drift is not masked by, and /or is independent of potentiometric operation of the electrochemical sensor.
- electrochemical and voltammetric are used interchangeably with respect to applying a potential to a redox species.
- a potential is swept across the calibration electrode and this swept potential may be referred to as a voltammetric or electrochemical signal or as a voltammetric or electrochemical sweep.
- the term 'voltammetric' is commonly used to a potential sweep and the term 'electrochemical' is used to refer to a potential applied to a chemical species and/or the resulting electrical signal generated by the application of the potential since it is an electrochemical process.
- the calibration electrode is configured to be a working electrode in an electrochemical cell.
- the other electrodes in the electrochemical cell with the calibration electrode may be referred to as counter electrodes, reference electrodes and/or auxiliary electrodes.
- the calibration electrode is used in an electrochemical/voltammetric system, which may comprise a counter and a reference/auxiliary electrode, to generate a voltammetric response.
- the electrochemical/voltammetric response of the calibration electrode is used to calibrate a reference system of the electrochemical sensor that generates a reference potential, where the reference potential is produced by a reference system comprising a reference cell.
- the calibration electrode comprises a redox active species (a species that undergoes oxidation reduction when a current/potential is applied) that is sensitive to pH (the oxidation/reduction current changing with respect to pH/hydrogen ion concentration) and configured to control the pH of a reference solution local to the calibration electrode.
- the redox active species may control the pH of the local environment proximal to the calibration electrode in the following ways.
- the redox active species may comprise either an acid or a base and or contain acid or base moieties.
- the acidic or basic nature of the redox active species sets the pH of the local environment of the reference because the reference solution, having a low buffering capacity, cannot buffer the effect of the acidic or basic redox active species.
- the redox active species may trigger the pH of the local environment of the reference solution by consuming or donating protons to the reference solution when a potential is applied to the redox active species.
- the reference solution cannot buffer the effect of the proton consumption or donation, the redox active species sets the local pH of the reference solution proximal to the calibration electrode.
- the reference solution is the solution contained in a reference chamber of the electrochemical sensor, and as described above, normally comprises potassium chloride solution or the like.
- the reference solution provides a saturated chloride ion solution to maintain a constant reference potential.
- Potassium chloride, sodium chloride and the like are bufferless, low buffering capacity solutions. Because these reference solutions have a low buffering capacity or contain no buffer, the redox species will affect the local environment of the reference solution proximal to the redox species as there is no buffer/buffering capacity to buffer the local effect of the redox species.
- redox active species sensitive to pH may comprise: a chemistry that affects hydrogen ion concentration (consumes or produces protons during oxidation/reduction), a base, an acid, base moieties, acid moieties or the like to set a local pH of the reference solution to a value greater or less than a pH of 7.
- the redox species may comprise anthraquinone, ferrocene, salicylic acid or the like.
- all redox active systems that are sensitive to pH will set the local pH of a low buffering capacity solution during oxidation/reduction, and this effect can only be prevented by using a redox active system that essentially negates the effect. While embodiments of the present disclosure can use a redox species that sets the local pH of the reference solution to 7, this is not a preferred embodiment as it may complicate calibration processing.
- an electrochemical/voltammetric sweep is applied to the calibration (working) electrode to generate an electrochemical/voltammetric response from the calibration electrode, where the electrochemical/voltammetric response comprises oxidation/reduction of the redox active species.
- the voltammetric response includes singularities/peaks in the oxidation/reduction current and a potential corresponding to these peaks/singularities is known as the peak potential.
- the peak potential for redox active species sensitive to pH is set by the pH of the solution that the calibration electrode is contacting.
- the pH of the reference solution local to the calibration electrode is set by the redox active species.
- the peak potential generated by the calibration electrode is a constant value.
- the redox active species undergoes oxidation/reduction.
- the redox active species donates or consumes protons, depending upon the chemistry of the redox active species, and because the contacted solution has a low buffer capacity this effect is not buffered by the solution so the redox species produces an electrochemical/voltammetric response that is governed by the proton/hydrogen ion concentration proximal to the calibration electrode that it has generated.
- this constant peak potential, and/or a related potential in the electrochemical/voltammetric response is used as a reference/calibration value to calibrate the reference potential of the electrochemical sensor.
- the calibration/working electrode may be swept periodically, while the electrochemical is deployed/in use and the determined peak potential used to calibrate the reference potential, without manual intervention.
- calibration of the reference electrode potential is provided by measuring a difference between the potential of the reference electrode and a peak potential or the like produced by the calibration electrode, where any changes in the difference are used to correct/calibrate the output from the sensor since the peak potential is a constant potential and any changes will be due to drift in the reference potential.
- the reference solution of most electrochemical sensors comprise chloride ions
- the redox active species of the calibration electrode is selected such that it is insensitive to chloride ion concentration. In this way, the calibration electrode and the peak potential generated by the calibration electrode is independent of the concentration of chloride ions of the reference solution.
- peak potential a peak in the electrochemical/voltammetric signal generated by the calibration electrode may be used to calibrate the reference potential
- other potentials in the electrochemical/voltammetric response such as a change in direction of the generated sweep signal, a maximum rate of change on the sweep signal or other characteristic that can be ascertained by signal processing - may be used to obtain a calibration potential of the calibration electrode and this may then be used to calibrate the reference electrode.
- multiple points of the electrochemical/voltammetric sweep response of the calibration electrode may be analysed to generate a calibration potential.
- the signal processor can analyze the electrochemical/voltammetric response to an applied potential sweep using this knowledge.
- the voltammetric/electrochemical measurement is not a potentiometric measurement, unlike the measurement from the reference electrode, the measurement provides a truly independent calibration. Moreover, the voltammetric/electrochemical measurement may be made periodically reducing issues/maintenance requirements associated with continuous/high frequency measurements. Also, the calibration system may be used with a robust reference system, such as an Ag/AgCl reference system and does not rely on potentiometrically measuring the presence of an ion.
- the calibration electrode comprises a redox active species that controls the local environment of a reference solution of the electrochemical sensor proximal to the electrode.
- This control of the local environment may in some embodiments be provided by contacting the electrode with a low buffer/low ionic strength solution, such as water, seawater, sodium chloride solution, silver, potassium chloride solution and/or the like.
- a low buffer/low ionic strength solution such as water, seawater, sodium chloride solution, silver, potassium chloride solution and/or the like.
- anthraquinone will measure a pH of about 10 or 11 when a voltammetric signal is applied because the anthraquinone will consume protons during reduction triggering a change in pH in the local environment that is measured by the sensor.
- This effect of the redox species will occur for most redox active species, unless they are specially configured, when the analyte contacted with the redox species is a low buffer/low ionic strength analyte
- a redox species containing acid groups such as salicylic acid etc., or alkali groups, such as species containing amine groups, acid groups will create an acidic or alkaline local environment irrespective of the acidity/alkalinity of the fluid being sensed.
- the local environment is controlled by the acidic/alkaline redox species even if the buffer/ionic strength of the analyte contacting the redox species is not low.
- redox species with acid or alkali groups are used to move the pH of the local environment away from a neutral reading, a pH of 7, to provide a known reference potential output from the calibration electrode when a voltammetric signal is applied to the calibration electrode.
- Potassium ion sensors utilize a valinomycin modified membrane to provide the ion-selective response, in conjunction with a standard Ag/AgCl electrode.
- the longevity of such systems is often compromised by instability in the reference electrode.
- the addition of a calibration sweep system using an electrode with a controlled environment would obviate the lifetime issues associated with the drift in the reference electrode.
- the effect of the redox species controlling the local environment has been identified as a weakness in electrochemical sensor operation as it produces incorrect output from the sensor since the sensor measures properties of the local environment, which is controlled by the redox species, not the properties of the solution being tested.
- the effect provides an electrode that has a known output, due to its control of the local environment, that may be used for calibration.
- the calibration electrode may be contacted directly with the low buffer/low ionic strength fluid and the redox species control the local environment to produce a known/stable potential output from the calibration electrode.
- the calibration electrode may be contacted with a known analyte, such as an analyte kept behind a frit or the like, for example an aqueous solution with low ionic/buffer strength.
- the calibration electrode may be contacted with the same fluid environment as the reference electrode, i.e., a reference solution held in a reservoir behind a frit that allows for electrical/ion conductivity with the solution being tested/analyzed.
- the calibration system may comprise an additional electrochemical cell that is placed inside an existing reference electrode chamber.
- the reference electrode in the existing reference electrode chamber may be used as a reference electrode for the calibration system.
- Figure 1 A illustrates a glass electrode pH sensor with a reference electrode.
- Figure IB is a schematic-type illustration of an electrochemical sensor comprising a reference electrode/reference system.
- Figure 2A illustrates an electrochemical sensor comprising a calibration system, in accordance with some embodiments of the present disclosure.
- Figure 2B illustrates an electrochemical sensor comprising a calibration system, in accordance with some embodiments of the present disclosure.
- Figure 2C depicts an electrochemical sensor comprising a calibration system, in accordance with some embodiments of the present disclosure, and outputs from the calibration system.
- Figure 3 is a flow-type illustration of a method for online calibration of a reference system of an electrochemical sensor, in accordance with some embodiments of the present disclosure.
- Some embodiments may be described as a process which is depicted as a flowchart, a flow diagram, a data flow diagram, a structure diagram, or a block diagram. Although a flowchart may describe the operations as a sequential process, many of the operations can be performed in parallel or concurrently. In addition, the order of the operations may be re-arranged. A process is terminated when its operations are completed, but could have additional steps not included in the figure and may start or end at any step or block. A process may correspond to a method, a function, a procedure, a subroutine, a subprogram, etc. When a process corresponds to a function, its termination corresponds to a return of the function to the calling function or the main function.
- the term “storage medium” may represent one or more devices for storing data, including read only memory (ROM), random access memory (RAM), magnetic RAM, core memory, magnetic disk storage mediums, optical storage mediums, flash memory devices and/or other machine readable mediums for storing information.
- ROM read only memory
- RAM random access memory
- magnetic RAM magnetic RAM
- core memory magnetic disk storage mediums
- optical storage mediums flash memory devices and/or other machine readable mediums for storing information.
- computer-readable medium includes, but is not limited to portable or fixed storage devices, optical storage devices, wireless channels and various other mediums capable of storing, containing or carrying instruction(s) and/or data.
- embodiments may be implemented by hardware, software, firmware, middleware, microcode, hardware description languages or any combination thereof.
- the program code or code segments to perform the necessary tasks may be stored in a machine readable medium such as storage medium.
- a processor(s) may perform the necessary tasks.
- a code segment may represent a procedure, a function, a subprogram, a program, a routine, a subroutine, a module, a software package, a class or any combination of instructions, data structures or program statements.
- a code segment may be coupled to another code segment or a hardware circuit by passing and/or receiving information, data, arguments, parameters or memory contents. Information, arguments, parameters, data, etc. may be passed, forwarded or transmitted via any suitable means including memory sharing, message passing, token passing, network transmission, etc.
- first, second, etc. may be used herein to describe various elements, these elements should not be limited by these terms. These terms are only used to distinguish one element from another.
- a first object or step could be termed a second object or step, and, similarly, a second object or step could be termed a first object or step.
- the first object or step, and the second object or step are both objects or steps, respectively, but they are not to be considered the same object or step.
- the terminology used in the description of the disclosure herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the subject matter.
- the phrase “if it is determined” or “if [a stated condition or event] is detected” may be construed to mean “upon determining” or “in response to determining” or “upon detecting [the stated condition or event]” or “in response to detecting [the stated condition or event],” depending on the context.
- redox-species is a compound or composition that may be oxidized and reduced.
- Redox activity refers to either or both of those processes.
- a “redox sensitive species” is redox-species that is sensitive or substantially sensitive to the presence or concentration of an analyte in a sample within those user-defined application- specific tolerances. "Substantially sensitive” to an analyte is used to mean sensitive within the tolerances required for a given application, as those tolerances are defined by an end user.
- a “redox-active material” is a compound or composition that may be oxidized and reduced. “Redox activity” refers to either or both of those processes.
- a “reference electrode” is an electrode used to establish the potential difference applied to the working electrode (WE).
- REs have a certain fixed chemical composition and therefore a fixed electrochemical potential, thus allowing measurement of the potential difference applied to the WE in a known, controlled manner.
- An RE typically comprises two halves of a redox couple in contact with an electrolyte of fixed chemical composition and ionic strength. Because both halves of the redox couple are present and the composition of all the species involved is fixed, the system is maintained at equilibrium, and the potential drop (i.e., the measured voltage) across the electrode-electrolyte interface of the RE is then thermodynamically fixed and constant.
- a commonly used RE system is the Ag/AgCl/KCl system with a defined and constant concentration of KC1.
- the two half-cell reactions are therefore: Ag++e— »Ag; and AgCl+e— *Ag+C
- the potential of this system depends only on the concentration (more strictly speaking the activity) of CI- ion present, which, if this is fixed, provides a stable, fixed potential.
- Many other RE systems are known in the art. It is imperative that the composition of the RE remains constant, and hence almost no current should be passed through the RE (otherwise electrolysis will occur and the composition of the RE will change), which necessitates the use of a third electrode, the counter electrode (CE), to complete the circuit.
- CE counter electrode
- two-electrode configurations can be used in the special case where the WE is a microelectrode, having at least one dimension typically smaller than 100 micrometers.
- a “sensor” is an electrode or collection of electrodes that generates a signal in response to the presence of an analyte.
- a sensor can include, for example, a working electrode, a counter- electrode and a reference electrode (either a conventional reference electrode or a pseudo reference electrode).
- a sensor can include, for example, a working electrode, a counter electrode and an analyte-insensitive electrode.
- Electrode is a component of a sensor and may comprise a metal, carbon and/or the like.
- a variety of carbon substrates are suitable for use as substrate material in the electrodes of the present invention, including but not limited to carbon allotropes such as graphites, including pyrolytic graphite and isotropic graphite, amorphous carbon, carbon black, single- or multi- walled carbon nanotubes, graphene, glassy carbon, boron-doped diamond, pyrolyzed photoresist films, and others known in the art.
- a “working electrode” is the electrode at which the electrochemical process for detecting the analyte of interest occurs.
- the working electrode may be sensitive to one or more analyte(s) in the test sample, or it may be chemically modified with analyte sensitive species/materials.
- the electrochemical response of the working electrode is measured after some perturbation to the system under study has been applied.
- the perturbation may be the application of a potential difference to the working electrode that induces electron transfer to occur, and the resulting current at the working electrode is then recorded as a function of the applied potential (voltammetric mode). This example of mode of operation is illustrative and not exhaustive, as many other modes are known in the art.
- the working electrode may comprise a redox species that can undergo a reversible electrochemical redox reaction dependent upon the concentration of an analyte (hydrogen ions for a pH meter; other analytes for other analyte sensing devices) in a sample solution and an applied electrical potential. For example, where there is a high concentration of hydrogen ions present in a sample solution, the redox reaction occurs at a lower potential. Conversely, where there is a low concentration of hydrogen ions present in a sample solution, the redox reaction occurs at a higher potential.
- the relationship between these characteristic potentials and the sample solution pH is a function of the chemical identity of the redox species.
- An algorithm converts electrical potential to pH value to provide a means of determining the pH of an unknown sample.
- Figure 1A illustrates a glass electrode pH sensor. Glass electrodes are some of the most common electrochemical sensors. The glass electrode is an example of an ion selective electrode/sensor.
- Glass electrode pH sensors are some of the most ubiquitous electrochemical sensors, since they use a well-established technology to measure a fundamental property, pH.
- the glass electrode comprises an internal electrode 10 contained in a measurement chamber 12.
- the glass electrode is disposed in a test solution 20 and the internal electrode 10 is in electrical communication with the test solution 20 via a glass membrane 15.
- the glass membrane 15 provides for ion exchange between a fluid in the measurement chamber 12 and the test solution 20.
- the glass electrode includes a reference electrode 25.
- the reference electrode 25 is disposed within a reference chamber 22 that contains a reference solution 25.
- the reference solution 25 is configured to electrically communicate with the test solution 20 through a porous frit 27, which allows for equalization of electrical properties of the two solutions.
- an output potential which is set by the ion concentration of the test solution 20, can be communicated to the pH meter.
- the glass electrode essentially consists of four major components, the glass membrane 15, the internal electrode 10, the reference electrode 25 and a glass stem.
- the internal electrode 10 and the reference electrode 25 are both disposed in solutions.
- the solutions are the same solutions and may comprise solutions saturated with chloride ions, such as potassium chloride, sodium chloride etc.
- chloride ions such as potassium chloride, sodium chloride etc.
- a symmetrical liquid cell is set up on both sides of the glass membrane.
- the internal fill solution in the glass and the reference fill solution are similar in their makeup.
- the symmetry is important so that the temperature curves for the two solutions are close, thereby canceling each other's temperature effect.
- Reference electrodes work like a battery with the chemical components producing a predictable voltage that is also in electrical contact with the solution being measured.
- the reference output is a constant voltage thus, giving the glass a reference point to distinguish changes in hydrogen ion concentration seen as a potential across the glass membrane.
- Figure IB is a schematic-type illustration of an electrochemical sensor.
- an electrochemical sensor 30 comprises a sensing system 35 and a reference system 33.
- the sensing system 35 may comprise a working electrode and be configured to contact a test solution 45.
- the sensing system 35 comprises a chemistry configured to undergo oxidation/reduction when an electrical signal is applied to the sensing system 35.
- the chemistry is selected such that the amplitude of the oxidation/reduction current and/or the potential associated with a peak of the oxidation/reduction current changes depending upon a concentration of a particular ion/chemical species that the electrochemical sensor is designed to detect/measure.
- the reaction from which concentration of an ion/chemistry of interest can be determined occurs at the surface of the working electrode 35 of the sensing system 35.
- the potential drop across the interface between the surface of the working electrode 35 and the test solution 45 i.e., the interfacial potential
- the interfacial potential is controlled in the electrochemical sensor 30.
- a counter electrode not shown
- a requirement for the counter electrode is that its interfacial potential remains constant, so that any changes in the cell potential produce identical changes in the working electrode interfacial potential.
- An electrode whose potential does not vary with current is referred to an ideal non-polarizable electrode, and is characterized by a vertical region on a current versus potential plot. However, there are no electrodes that behave in this ideal manner. As a result non-ideal behavior, the interfacial potential of the counter electrode in the two-electrode system discussed above varies as current is passed through the cell.
- This problem is overcome by using a three- electrode system, in which the function of the counter electrode is divided between a reference electrode 36 and one or more auxiliary electrodes (not shown).
- the potential between the working electrode 35 and the reference electrode 36 and the one or more auxiliary electrodes is controlled and current passes between the working electrode 35 and the one or more auxiliary electrodes.
- the current passing through the reference electrode 36 is reduced, as it is not desirable to have current flow through the reference electrode, by using a high- input-impedance operational amplifier as an input to reference electrode 36.
- the reference system 33 may comprise a reference chamber 34.
- the reference chamber 34 contains a reference solution 39 and the reference electrode 36.
- the reference electrode 36 is at least partially disposed within the reference solution 39.
- One of the most common reference systems is the silver-silver chloride reference system in which the reference electrode is formed from silver with a coating of silver chloride.
- the reference solution for the silver-silver chloride reference solution comprise a solution containing chloride ions, such as potassium chloride solution or sodium chloride solution.
- the reference solution 39 may comprise of the order of 3 Molar sodium chloride or potassium chloride.
- the potential E for any electrode is determined by the Nernst equation, which relates E to the standard potential E0 and the activities of the redox components (the standard potential is the potential of the electrode at unit activity under standard conditions).
- the Nernst equation for the silver/silver chloride electrode is:
- the standard redox potential (EO) for the silver/silver chloride redox reaction at 25 degrees Celsius is +0.222 V (vs. NHE)
- the redox potential (E) for the BASi silver/silver chloride reference electrode at this temperature is +0.206 V (vs. NHE).
- the reference chamber 39 includes a porous frit 37.
- the porous frit 37 ionicly conducting electrical pathway between the inside of the reference chamber 36 and the test solution 45. This is necessary in order to equalize the electrical conditions of the working electrode 35 and the reference electrode 36
- Recalibration of the electrochemical sensor involves an operator of the electrochemical sensor measuring an output from the electrochemical sensor in at least three different solutions containing a known concentration of the ion/chemistry of interest so that the output from the electrochemical sensor can be compared to the known response that the sensor should have produced for the known concentrations and the sensor recalibrated to account for any difference found in the comparison.
- FIG. 2A illustrates an electrochemical sensor comprising an online calibration system, in accordance with some embodiments of the present disclosure.
- an electrochemical sensor 130 comprises a sensing system 135 and a reference system 133.
- the sensor system 135 may comprise a sensing/working electrode and/or the like that is configured to provide an electronic response to an applied electronic signal that is dependent upon a concentration of an ion/chemical species in a test solution 145.
- the electrochemical sensor 130 may be an ion selective electrode, such as for example a glass electrode, an amperometric sensor, a redox sensor, an ISFET and/or the like.
- a processor 140 comprising processing circuitry, is configured to communicate with the sensing system 135 to apply a signal to the sensing system 135 and to process the response of the sensing system 136 to the applied signal.
- the reference system 133 comprises a reference chamber 134.
- the reference chamber 134 contains a reference solution 139 and a reference electrode 136.
- the reference electrode 136 and the reference solution 139 are configured such that the reference electrode 136 generates a constant reference potential when a reference signal is applied to the reference electrode 136.
- the reference electrode 136 may comprise a silver- silver chloride electrode and the reference solution 139 may comprise a solution containing chloride ions, such as sodium chloride solution, a potassium chloride solution or the like.
- the reference solution 139 may comprise a paste, gel and/or the like.
- a calibration system comprising a three- electrode system is provided in the reference chamber 134.
- the three-electrode system comprising a working electrode 120, counter electrode 123 and a reference electrode 126.
- the calibration system may comprise a single working electrode, a two-electrode system or a system comprising four or more electrodes.
- the one of the electrodes of the calibration system may comprise the reference electrode 136.
- the working electrode 120 comprises a redox species 121.
- the redox species 121 is configured to be sensitive to pH, i.e., the redox species is configured to generate a response signal to an applied electrical signal that varies depending upon a pH of a solution contacted by the working electrode 120.
- the redox species 121 is configured to set the pH of a local environment of the reference solution 139 in which the working electrode 120 is disposed and to sense this set pH when a calibration signal is applied to the calibration system.
- Suitable redox species that are sensitive to pH/hydrogen ion concentration and that will set the pH of the reference solution local to the calibration electrode may include, for example and without limitation: anthraquinone (AQ), phenanthrenequinone (PAQ), N,N'-diphenyl-p- phenylenediamine (DPPD), anthracene, naphthaquinone, para-benzoquinone, diazo-containing compounds, porphyrins, nicotinamides, including NADH, NAD+ and N-methylnicotinamide, quinone thiol, monoquaternized N-alkyl-4,4'-bipyridinium, RuO, and Ni(OH)2, ferrocene carboxylate, and derivatives of those compounds; CO-sensitive ASMs: ferrocenyl ferraazetine disulfide; iron porphyrins; alkaline metal cation sensitive ASMs: l,l'-(l,4,10,
- any redox species sensitive to pH unless it has been specially configured will set the local pH of the reference solution when the redox species is oxidized/reduced because of the low buffering capacity of the reference solution.
- a problem with electrochemical pH sensors using a working electrode comprising a redox active species sensitive to pH is that when contacted with a low buffering capacity bufferless solution, the redox active species sets the pH of the local environment of the low buffering capacity/bufferless solution proximal to the working electrode. In essence, because the solution has a low buffering capacity and/or contains no buffer, it cannot buffer the local effect of the redox active species on the solution.
- the redox species 121 may comprise any redox species sensitive to pH that is not configured to overcome the effect of localized pH setting in low buffering capacity/bufferless solution.
- the redox species 121 is selected to set a pH of the local environment of the reference solution 139 to a pH value that is greater than one pH unit above or below pH 7. Applicant has found that calibration processing is optimized when the redox active species 121 sets a pH that is not at or close to pH 7.
- the redox active species 121 may comprise an acid, a base, acid moieties or base moieties.
- Applicant has found that nearly all of the generally used redox species sensitive to pH can be used to set the pH of the local environment and to produce a response to this set pH, as very few of the redox active species sensitive to pH provide for overcoming the low buffer capacity issue.
- Applicant has found that anthraquinone and its derivatives, some of the most commonly used redox species sensitive to pH, can be used as the redox active species 121.
- anthraquinone sets the pH of the local environment of the reference solution to a pH value of about 10.
- the redox species 121 is configured to be sensitive to pH and to set a local pH of the reference solution 139 proximal to the working electrode 120. These features of the redox species 121 and the fact that the redox species 121 is not sensitive to chloride ion concentration, provide that a response of the redox species will be a constant value whatever the changes to the chloride concentration.
- the reference solution 139 comprises a low buffering capacity/bufferless solution.
- the most common reference solutions for the reference system 133 comprise sodium chloride, potassium chloride, or the like. Both potassium chloride and sodium chloride solutions comprise low buffering capacity/bufferless solutions. Potassium chloride (KC1) reference solutions do not comprise any buffer in the reference solution, so are well suited to use in embodiments of the present disclsoure.
- a calibration processor 150 may apply an electrochemical/voltammetric signal to the working electrode 120.
- the voltammetric signal may comprise a varying electronic signal, such as a square wave voltammetric signal, a ramped voltammetric signal and/or the like.
- the voltammetric signal may be swept across between the working electrode 120, the counter electrode 123 and the reference electrode 126.
- the working electrode In response to the application of the voltammetric signal, the working electrode generates an electrochemical/voltammetric response. This response is dependent upon the oxidation/reduction current produce by the redox species 121.
- the oxidation/reduction current produced by the redox species 121 will depend upon the pH of the reference solution 139.
- the voltammetric response will have constant features, e.g., a peak potential corresponding to a peak/singularity in the oxidation/reduction current, corresponding to the set pH.
- the voltammetric response may be processed by the calibration processor into a voltammogram and/or into a representation showing working electrode potential versus redox current.
- the redox species 121 and the reference solution 139 are selected so that the redox species 121, which is sensitive to pH, sets the pH of the reference solution 139 local to the redox species 121.
- the peak potential in the voltammetric response is a constant.
- the peak potential is used by the calibration processor 150 and/or the processor 140 to calibrate the reference potential of the reference system 133.
- a difference between the reference potential and the peak potential may be determined and stored by at least one of the calibration processor 150 and/or the processor 140.
- This difference may be: measured when the electrochemical sensor 130 is initially deployed by a user using measurements from the reference system 133 and/or the calibration system; may be calculated from empirical calculations; may be determined from batch measurements made on one or more electrochemical sensors in a manufactured batch of electrochemical sensors; and/or the like.
- the peak potential for the redox species 121 for the set pH generated in the local environment of the reference solution 139 may be measured, calculated, determined from experiments/testing and/or the like and may be entered into the calibration processor 150 and/or the processor 140. Subsequently, when a user calibrates the reference system 133, the calibration processor 150 and/or the processor 140 may record the difference between the peak potential and the reference potential.
- the reference potential of the electrochemical sensor 130 drifts as a result of changes to the reference solution 139, such as reduced concentration of chloride ions in the reference solution 139.
- a voltammetric signal is repeatedly applied to the calibration system to generate a peak potential. This peak potential and the known/recorded difference between the peak potential and the reference potential, as described above, is used to process a calibration factor to calibrate any changes in the reference potential due to changes in the reference solution 139.
- the periodicity of the applied voltammetric signals may depend upon the use of the electrochemical sensor 130 and may be set by the calibration processor 150 and/or the processor 140, set by the user, set by the manufacturer and/or the like.
- the periodicity may be of the order of hours or days. In sensor deployments of hours or days, the periodicity may be of the order of seconds, minutes or hours.
- the calibration system is configured to provide for online calibration of the reference potential of the reference system 133.
- the reference system 133 comprises a porous frit 137 that provides an ionicly conducting electrical pathway between the inside of the reference chamber 134 and the test solution 145. This porous frit 137 allows for dilution of the reference solution 139 and/or entry of chemical species into the reference solution 139.
- the peak potential of the calibration system is stable/constant when the reference solution 139 has been diluted by up to 50%.
- the peak potent of the calibration system is stable/constant when: acids, such as hydrochloric acid; bases, such as sodium hydroxide; carbonates, such as hard water; reactive chemistries, and other reactive chemistries are added to the reference solution 139.
- acids such as hydrochloric acid
- bases such as sodium hydroxide
- carbonates such as hard water
- reactive chemistries, and other reactive chemistries are added to the reference solution 139.
- reference is made to a peak potential produced by the working electrode 120 in response to an applied voltammetric signal. This peak potential corresponds to a peak/trough in the redox current produced by the redox species 121.
- FIG. 2B illustrates an electrochemical sensor comprising a calibration system in accordance with some embodiments of the present disclosure.
- the electrochemical sensor comprises a sensor electrode 150 and a reference system 160.
- the reference system 160 comprises a reference chamber 162 containing a reference solution 165 and a reference electrode 151.
- the reference electrode 151 is at least partially in contact with the reference solution 165.
- the reference solution 165 may comprise sodium chloride, potassium chloride etc.
- the sensor electrode 150 may comprise a glass electrode, with a glass membrane etc.
- the sensor electrode 150 is configured to be in electrical communication/contact with a test solution 155.
- the reference solution 165 is configured to be in electrical communication with the test solution 155 via a porous frit 167.
- the reference electrode 151 is configured to generate a reference potential for the electrochemical sensor.
- a typical reference electrode is the silver chloride electrode.
- the silver chloride reference electrode functions as a redox electrode where an equilibrium is provided between the silver metal of the reference electrode and its salt, silver chloride, of the reference solution.
- the reference potential is constant given the constant condition of the reference electrode and the reference solution. However, the reference potential will drift if the concentration of the silver chloride in the reference chamber changes. Since the reference solution is in fluid communication with the test solution through the porous frit 167 the concentration will change during use of the electrochemical sensor.
- a calibration electrode 163 of an additional electrochemical cell is placed inside the existing reference electrode chamber.
- the electrochemical cell may comprise a counter electrode 161 and an auxiliary electrode 164.
- the reference electrode 151 may also be used as the reference electrode/auxiliary electrode 164 in the electrochemical cell.
- the calibration electrode 163 is the working electrode of the electrochemical cell and comprises a redox species that is immobilized on the calibration electrode 163 and both redox active, sensitive to pH, and also controls the local environment of the reference solution 165 close to the surface of the calibration electrode 163.
- the immobilised redox species may be solvent cast onto, electro- polymerised on, or immersed within the calibration electrode 163.
- the redox couple bound within the polymeric layer acts as a new stable redox couple, whilst the layers ability to control the local environment acts as a second layer to protect from any variations observed in the bulk solution in which the electrode is immersed.
- This additional electrochemical circuit acts as a means of correcting any drift observed in the reference electrode in-situ.
- the device runs under potentiometric sensing mode between the analyte sensing electrode and the reference electrode.
- the cell periodically runs a voltammetric sweep against the working electrode housed behind the porous frit.
- the potential of the redox active species immobilized on the working electrode is used to correct any drift occurring in the reference electrode.
- the frequency of voltammetric sweep depends on the application for which the electrochemical sensor is deployed.
- Figure 2C depicts a schematic representation of a sensor output from an electrochemical sensor comprising a calibration system, in accordance with some embodiments of the present disclosure, using various voltammetric sweep profiles. In the depicted configuration, the calibration system can provide QA/QC of the sensor's reference electrode.
- the depicted sensor includes an integrated electrochemical cell and potentiostat, and the system uses a voltammetric signal from the potentiostat to produce a sweep between the reference electrode and the calibration electrode in the integrated electrochemical cell to generate a potential that may be used for QA/QC of the reference electrode during operation of the sensor.
- the sensor may in some embodiments run using a modified bi-potentiostate system. Such a set-up obviates the need for reference sensor calibration prior to deployment as is the case with current commercial ISE's. In embodiments of the present disclosure, prior to deployment, the internal circuit can be measured and this may be used to set the parameters for the reference system.
- Embodiments of the present invention may use the following chemical structures on the working electrode, in which the redox active component of molecule has carboxylic, sulfonic and/or amino moieties.
- a redox active pH active polymeric layer can be formed containing carboxylic acid moieties, which in the proposed set-up the redox active components only observes a pH of solution consistent with that of the pKa of the molecule.
- the working electrode in the new electrochemical cell can have a single layer in which the redox active component has moieties attached to control the local environment directly and in other embodiments the working electrode system can have a dual layer in which the redox active components are separated/independent from the species used to control the local environment.
- the redox active species used within the working electrode system by virtue of its oxidation or reduction can control the local environment to the surface through the release/loss or gain of protons, cations or anions.
- Figure 3 is a flow-type illustration of a method for online calibration of reference electrode of an electrochemical sensor, in accordance with some embodiments of the present disclosure.
- a calibration electrode is provided to contact a reference solution of a reference system of an electrochemical sensor.
- the reference system comprises a reference chamber containing the reference solution and a reference electrode.
- the reference electrode may comprise a metal, carbon or the like and the reference solution may comprise a salt, such as sodium chloride, potassium chloride or the like.
- the reference electrode comprises a redox active species that is sensitive to pH/proton concentration.
- the reference solution comprises a bufferless/low buffer capacity solution, such as potassium chloride, sodium chloride and/or the like.
- the redox active species is configured to set a pH of the reference solution local to/proximal to the redox active species.
- the redox active species may be immobilized on the calibration electrode, covalently bound to the calibration electrode and/or the like.
- the calibration electrode may comprise carbon, a carbon derivative, a metal, and/or the like.
- the redox active species is selected not to be sensitive to chloride ions/chloride ion concentration.
- a voltammetric signal/a potential sweep is applied to the calibration electrode.
- the calibration electrode may be part of a calibration system comprising a counter electrode and the voltammetric signal may be swept between the calibration electrode, which may comprise a working electrode and the counter electrode.
- the voltammetric signal may comprise a potential sweep, such as a square wave, a ramped signal/wave and/or the like.
- the applied voltammetric signal causes the redox active species to undergo oxidation/reduction. Since the redox active species is sensitive to pH/proton concentration of the reference solution it is in contact with, the oxidation/reduction current will be determined by the pH of the reference solution. Moreover, because the reference solution is a bufferless/low buffer solution, the pH of the reference solution proximal to the redox species is set by the properties of the redox active species.
- the redox active species may comprise an acid, a base, acid moieties, basic moieties and/or the like.
- the redox active species may trigger the pH of the local environment by donating or consuming protons when an electrochemical/voltammetric signal/potential sweep is applied to the redox active species.
- the redox active species may comprise anthraquinone and the anthraquinone may set the local pH of the reference solution to a pH of approximately 10 by consuming protons. Because the redox active species is selected to set the pH of the reference solution local to the redox active species, the peak potential of the reduction/oxidation current will be determined by the pH set by the redox active species.
- a voltammetric response of the calibration electrode to the applied voltammetric signal is processed to determine a calibration potential.
- the calibration potential is the peak potential produced by the redox active species in response to the applied voltammetric signal.
- the voltammetric response may be a current versus potential and the voltammetric response may contain a peak/singularity corresponding to a peak/trough in the redox current of the redox active species. The potential corresponding to this peak/singularity in the redox current is the peak potential.
- other features of the peak/singularity may be used as a calibration potential.
- the redox current and the peak potential for the redox active species correspond to the pH of reference solution seen by the redox active species, and because the redox active species sets the pH of the reference solution local to the redox active species, the redox current and the peak potential are a constant.
- the redox active species is selected such that its redox response is not affected by chloride concentration in the reference solution. This and the fact that applicant has found that the response of the redox active species in the present arrangement is not sensitive to acids, basis, hard water, reactive chemistries and/or the like in the reference solution means that the calibration electrode provides a constant/stable response to the applied voltammetric signal over a wide range of challenging chemical applications.
- the calibration potential is used to calibrate the reference potential of the electrochemical sensor.
- a determined difference between the calibration potential and the reference potential is used for online calibration of the electrochemical sensor.
- the reference potential of the electrochemical sensor may be determined when the sensor is new, being deployed, being calibrated and/or the like. At this time, a difference between the reference potential and the calibration potential may be determined and stored.
- the calibration potential itself may be calculated, measured, determined from experimentation, be measured during manufacture of the electrochemical sensor and/or the like. In operation when the electrochemical sensor is being used, a periodic measurement of the calibration potential is processed and compared to the reference potential.
- the reference potential is recalibrated to account for this change. In this manner, the reference potential for the electrochemical sensor can be recalibrated online, while the electrochemical sensor is deployed and making measurements.
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PCT/EP2018/077797 WO2019073002A1 (en) | 2017-10-11 | 2018-10-11 | Online reference calibration |
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US11307168B2 (en) | 2022-04-19 |
CN110291387B (en) | 2023-04-28 |
JP6920473B2 (en) | 2021-08-18 |
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