CA2126555C - Analyte and ph measuring sensor assembly and method - Google Patents
Analyte and ph measuring sensor assembly and methodInfo
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- CA2126555C CA2126555C CA002126555A CA2126555A CA2126555C CA 2126555 C CA2126555 C CA 2126555C CA 002126555 A CA002126555 A CA 002126555A CA 2126555 A CA2126555 A CA 2126555A CA 2126555 C CA2126555 C CA 2126555C
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- electrode
- electrodes
- analyte
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- fluid
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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
- G01N27/403—Cells and electrode assemblies
Abstract
The sensor apparatus of the present invention includes on a nonconducting substrate (11) electrically conductive pathways (20, 22, 24) leading to at least two analyte electrodes (32, 34) and one reference electrode (36). The analyte electrodes (32, 34) each have sensitivities for both analytes but each has a membrane (48, 52) and/or electrolyte (50, 54) that favors the conversion of ionic potential to electronic potential for a different analyte. The apparatus has a fluid circuit means (68) for liquid contact between the electrodes (32, 34, 36) so that electric signals can be sent by electric circuitry (16) to an analyzing means (116). The analyzing means (116) determines the values of the analytes from simultaneously mathematical relationships.
Description
'~'0 93~13411 2 1 2 6 5 S ~ P ~ /US92/11286 -ANATYTE AND P~ M~A~URI~G S~SOR A~S~RT Y A~D M~TUOD
The present invention is related to an analyte sensor assembly apparatus and method for measuring coupled analytes. More particularly, the present invention relate6 to an apparatus of a carbon dioxide and pH sensor assembly for measuring both in fluid samples .
BACKGROUND OF THE ~VENTION
Numerous methods and apparatus exist in the art for measuring chemical components of fluids and current technology utilizes many types of sensors for detecting components and analytes in numerous types of fluids. For example, carbon dioxide and pH
15 sensors are used for measuring these components in various fluids including gases and liquids. For instance, the mea6urement of blood gases, along with the pH from a sample of arterial blood, give6 the state of the acid base balance or the effectiveness of both the re6piratory and cardiovascular 6ystems of the human or vertebrate 20 body. Measuring the blood gases usually involve6 a measurement of the partial pre6sures of oxygen and carbon dioxide along with the measurement of the pH since carbon dioxide dissolved in the aqueous solution can affect the pH through the presence of carbonic acid.
These are examples of coupled snalytes.
It is conventional practice in many of the existing measurement methods, even where the fluid is a liquid or liquid with a dissolved gas with or without the pre6ence of 601id6 to tran6port a sample to a central location for testing. With centralized testing, the bulky, stationary, elaborate and sophisticated equipment performs 30 the analy8is on a practically endle6s number of 6amples. Originally, this equipment employed carbon dioxide sensor like the Severinghaus W O 93/134ll P ~ /US92/11286 212 655 ~ 2 -potentiometric sensor for a qualitative and/or quantitative measure of carbon dioxide. This sensor has a gas-permeable membrane between the sample solution for measurement and the measuring cell. The cell has a pH-sensing glass electrode, a reference electrode, and an 5 intermediate electrolyte layer. Recently, more sophisticated carbon dioxide sensors have utilized polymeric membranes like those of the combined pH and carbon dioxide sensor of U.S. Patent 4,818,361.
Al60, recent attempts have been made to introduce more portable equipment into the marketplace of fluid analysis. An example 10 of thi6 is the qualitative and/or quantitative measurement of constituents or analytes of blood. The bulky stationary equipment is fairly expensive and the procedures for its use can be cumbersome depending on the type of fluid to be measured. For instance, mea6uring blood gases from the arterial blood sample involves:
15 drawing the blood sample in a syringe, immersing it in ice and transporting it quickly to the lab where the equipment is usually located for a measurement of the gases. More portable devices would shorten or overcome transporting the sample to the measuring equipment at a fixed location. For ex~mple, portable sensing units which can be 20 coupled to a digital readout device would be useful at the patient's bedside in a manner similar to a way that temperatures are measured at the patient bedside.
U.S. Patent Nos. 3,000,805 and 3,497,442 show two such devices. The former has electrodes located on a syringe plunger and 25 the latter has electrodes placed on the syringe well to conduct the measurements. The electrodes of these sensors may be particularly sensitive to small sample volumes 6ince they consume oxygen in their operation. In U.S. Patent No. 5,046,496, Applicants' assignee describes and claims a portable blood gas sensor which includes 30 sensors fabricated using a conventional silk screening process where ~ 93/l34ll 2 1 2 6 5 ~ ~ PC~r/US92/ll286 the electrodes are screened on to a ceramic substrate. Typically, these electrodes have the conductor along with an electrolyte and analyte permeable polymeric membrane that cover6 the sensor. Some of these membranes may be hydratable membranes by water vapor permeation 5 and they can be stored in a dry state and hydrated just prior to use as in U.S. Patent No. 4,818,361. The more portable the equipment the larger the demand for the miniaturization of the electrodes that still produce precise outputs for the analyte concentration or tension.
SUMMARY OF THE INV~TION
It is an object of the present invention to provide a sensor apparatus that utilizes analyte electrodes where each electrode has sensitivities for the analytes to be measured and where the analytes are water soluble analytes that upon solublization in water can influence the pH.
The sensor apparatus has in its broadest aspect a holding means for electrodes and for electronic conductive patterns at least two analyte electrodes, at least one reference electrode, a fluid circuit means in fluid contact with the electrodes, analyzing means, and the electrical circuitry means.
The at least three electrodes are held by the holding means in spaced apart relationship to each other and in electrical connection with electronic conductive patterns of the electric circuitry means which is also held by the holding means in insulated fashion for conveyance of electrical signals from the electrodes.
The analyte electrodes have ion selective membranes and/or a particular electrolyte composition that is selected to favor the conversion of the ionic potential to electronic potential of one analyte over the other. Each electrode has a sensitivity of the analytes to be measured but the sensitivities are different in each 30 electrode. Both of the ion selective membranes have a first and W 0 93/13411 2 12 6 5 5 ~ P ~ /US92/11286 second side and the membranes are positioned in the respective electrodes for one side to be in contact with the electrolyte of that electrode and for the other side to bè available for exposure to the fluid circuit. The fluid circuit can have a storage fluid, hydrating 5 fluid, analyte-containing fluid, or calibration fluids for analysis or a mixture of two of these. Additionally, the membrane of each electrode holds the respective electrolyte in contact with the conductor of that electrode.
The reference electrode can be an electrochemical half-cell lO or second order electrode that is provided in order to establish a substantially accurate and constant comparative potential. The reference electrode either with or without a membrane can have as an electrolyte the fluid that is in its vicinity in the fluid circuit means. Additionally, the electrolyte can include a metal cation of 15 the electrode.
The electrodes are arranged further on the holding means to match the fluid circuit means so that the membranes of the analyte electrodes can contact the fluid in the fluid circuit. In this arrangement the analyte electrodes can contact the storage fluid, 20 hydration fluid, calibration or standardized fluid, sample fluid, or all of these at different times when they are present in the fluid circuit mean6. The reference electrode can also contact one or more of these fluids either in axial or in no~ l alignment with the analyte electrodes. The contact can be from channels or conduits 25 having the fluid in a flow-through or nonflow-through fluid circuit means. The channel or channels can be in a cover encompassing the holding means for the electrodes or on a holder or card that slides into a recording instrument that has the electrodes held in a stationary position for the contact.
_- W 0 93/13411 ~ 5 9 PCT/US92/11286 The electric circuitry mean6 can be prlnted wire circuitry for the portion that i6 held by the electrode holding means. This electronic conductive pattern means portlon of the circuitry allows for electrical connection of the electrodes to each other through one 5 connection and for conveyance of the electronic potential to the analyzing means. Another portion of the electrical circuitry means can be a cable to convey electrical impulses from the holding means to the analyzing means.
The anslyzing means receives digital or analog input and 10 produces digital and/or analog output from the input via the simultaneous solution of the following equations:
delta mVAl = - SElAl x delta pH - SElA2 x log A2f/A2i Equation 1 delta mVA2 = - SElA2 x delta pH - SE2A2 x log A2f/A2i Equation 2 A2f = A2ixlOn Equation 3 where n = ~SE~,Al x delta mVAl - S~lAl delta mVA2 [-SE2Al x SElA2 + SElAl x SE2A2~
20 Alf = ~l~B mY~l t ~EL9_ ~ lQg A2f/A2i ~ Ali Equation 4 -SElAl where:
delts mV = change in millivolt~
25 Al = first analyte A2 = second analyte El = electrode constructed to favor the first analyte E2 = electrode constructed to favor the second analyte SElAl = sensitivity of the electrode favoring the first analyte for the first analyte SElA2 = sensitivity of the electrode favoring the first analyte for the second analyte W 0 93/13411 ~ 6 s 5 S P ~ /US92/11286 SEZAl = sen~itivity of the electrode favoring the second analyte for the fir6t analyte SEZA2 = sen6itivity of the electrode favoring the second analyte for the second analyte 5 f = final mea6urement i = initial mea6urement In a narrower a6pect of the present invention, the first analyte is the hydrogen ion concentration 80 that the first analyte electrode i6 a pH electrode. The second analyte i~ a carbon dioxide lO and the 6econd analyte electrode is a carbon dioxide electrode. The - electrode holding means is a nonconducting substrate suitable for attachment of the pH, carbon dioxide, and reference electrodes spaced apart from each other and connected to printing wiring circuits for conveyance of the electronic potential from the electrode6 to the 15 analyzing means.
BRIEF D~SCRIPTION OF TU~ DRAWINGS
Figure la is a top planar view of the one side of the 6ubstrate or wiring board of the pre6ent invention, having an arrangement of two analyte 6en60r6 with one reference electrode with 20 accompanying electronic conductive pattern6 of the electric circuitry, and Figure lb show6 a portion of the opposite slde.
Figure 2 is a planar view of the one side of the substrate or wiring board of the present invention having two analyte sensor6 (one analyte and pH) with two reference electrodes spaced apart from 25 each other and from the axis of the analyte electrodes and accompanying electronic conductive patterns and al60 having a thermistor.
Figure 2b is a planar view of the other side of the wiring board (substrate) of Figure Z having a resi6tor and a heater that 30 traver6e6 the board and a number of lead6 through the board from the ..~
'''O 93/13411 2 1 2 6 ~ ~ S PC~r/US92/11286 side depicted in Figure 2 to provide an external electrical connection from the board.
Figure 3 shows a matching fluid circuit means for the substrate in Figures l, lb, 2 and 2b.
Figure 4 is a schematic of the circuitry including the analyzing means.
Figure 5 is a graph of the millivolts (mV) along the ordinate versus time in seconds along the abscig6a for the analy6is of two analytes, carbon dioxide and hydrogen ion (pH) for a blood lO sample.
DETATT~n DESCRIPTION OF T~F l~V~;~LION
Similar numeral6 are used throughout the drawings to denote the same feature in each of the drawings.
The holding means ll with electrode6 and the a6sociated 15 portion of the electrical circuit means of the electrochemical sensor apparatus of the present invention as 6hown in Figure l have particular shapes for the components. Other shapes than those shown in Figure l that are known to those skilled in the art for the particular components can be used.
The electrode and circuit holding means ll may be produced from any number of well known layered circuit technologies as, for example, thick film, thin film, plating, pressurized laminating and photolithographic etching of a combination of two or more of these;
however, the thick film technique is preferred for all of the 25 components. Of course, it would be possible to produce the analyte electrodes by thick film process snd the reference electrode by thin film proce6s. The holding meanf~ ll can be of any shape adequate to hold the electrodes and electric circuit; one suitable example is a printed wire board substrate.
W o 93/13411 ~ i 2 6 ~ S S PC~r/US92/11286 The holding means, hereinafter in the specification referred to as the substrate, ll can be any glass or ceramic including sheet or chip or nonconducting substrate like wood or nonconducting polymers or commercially available frit that can be used as the substantially 5 smooth flat surface of the substrate layer ll. Nonexclusive examples include borosilicate glass as is known to those skilled in the art for producing thick film or layered circuits. A nonexclusive and preferred example of which includes a ceramic base having around 96%
Al203 such as that available commercially from Coors Ceramic Company, lO Grand Junction, Colorado. The substrate layer ll can be and preferably is essentially flat with two sides and any substrate known to those skilled in the art for forming printed wiring circuits can be used. It is preferred that the composition of the substrate can endure the presence of electrolytes that have acidic or basic pH and 15 remain unaffected for a substantial period of time.
Substrate ll can have several layers to form the electrodes and associated circuitry. One layer is a patterned metallic layer 12 with a number of extensions which act as the electric conductive pattern portion 18 of the electrical circuit means, collectively 20 referred to as 22, between a voltage or current source (not shown) that is external to the substrate ll. Each extension can have a component (electrode conductors) at its end. The several extensions also have the ability to transmit voltage changes from the components of the substrate ll to the analysis means (shown in Figure 4).
The patterned metallic layer 12 is formed by printing pastes deposited onto a substrate in the desired pattern to act as ohmic conductors. Nonexclusive examples of suitable heat resisting metals include: noble metals such as platinum (Pt), ruthenium (Ru), palladium (Pd), rhodium (Rh), iridium (Ir), gold (Au) or silver (Ag) 30 or other metals traditionally used in Severinghaus potentiometric ~ 93/134ll 2 1 ~ S 5 ~ 5 P ~ /US92/11286 sensors. A nonexclusive but preferred example of a suitable paste is a silver pa6te of the type produced and svailable from Electro-Science Laboratorie6, Inc. under the trade de6ignation ESL 9912. The metallic layer 12 i8 dried to produce the above noted conductive pattern 18 5 which comprise the conductive pathways 20, 22, and 24 of Figures 1 and 2 and the external leads 26, 28, and 30 of Figure lb. Any method known to those skilled in the art for producing a sufficient thickness of metallic tracing can be u6ed. Preferably, the silver paste6 are oven dried and fired at a high temperature in a furnace. Firing can 10 be accomplished at a temperature in the range of around 800~C to around 950~C for a period of around 1 to 20 minutes. With this procedure, the thickness of the layer of the metallic conducting tracing is usually in the range of around 0.0005 to 0.001 inches.
Although the aforementioned are preferred conditions, general 15 conditions for obt~in;ng a proper thickness can be used where the thickness can be generally range from about 0.0004 to 0.0015 inch.
The aforementioned conductive pattern6 18 are encapsulated with a glass ceramic mixture or a ceramic insulating material such as alumina or spinal. This encapsulation insulates the pathways and can 20 range from a total encapsulation to encapsulation except at the end of the metallic pattern.
The encapsulation of the metallic patterns can range from encapsulating each from the other to a sufficient degree for electrical insulation of the conductive patterns and any conductive 25 layer~ from each other. As shown in Figure 1, the encapsulant can extend across the whole board from edge to edge as generally shown at numeral 14. Preferably, the thickness of the encapsulant layer is ~ that which is adequate to seal the underlining metallic layer and to provide insulation for the metallic patterns. Preferably, the 30 thicknes8 of the layer is around 20 to around 30 microns. Preferably, W O 93/l34ll ~ ~ ~ 6 S S S PC~r/US92/11286 _ the glass composltion for the encapsulant as with the substrate 11 is selected to possess good chemical stability and/or moisture resistance. Also, the metallic and encapsulant materials are selected so that they can endure the presence of an electrolyte in a similar 5 manner as the substrate composition. A most preferred glass ceramic mixture useful as the encap~ulant is the type produced and available from Electro-Science Laboratories, Inc. under the trade designation ESL 4903.
As can best be seen in Figures 1 and 2, the substrate 11 is 10 provided with a number of electrodes, 32, 34, 36, and 38, and more particularly, electrodes useful in the measurement of a fluid analyte that is 601uble or dissociates in liquid, for in6tance water, to influence the pH of the liquid. A suitable example is carbon dioxide in a fluid like blood in the measurement of blood gase6. Other 15 analytes include those that are water soluble or dissociate in water snd upon solubllization or dissociation influence the pH of water in a me~surable manner. Nonexclusive examples of such analytes include:
carbon dioxide, ammonia, sulfur dioxide, nitric oxide, and halides like chlorine, bromine, and iodine, and acids which do not dissolve in 20 water to form a hydrogen ion but which have more than a certain degree of vapor pressure, like acetic acid, ammonia gas. This a~60ciation of analytes with the pH is hereinafter referred to as coupled analytes.
The aforementioned electrodes 32, 34, 36, and 38 are preferably produced by one of the layered circuit technique6. This 25 involves leaving the respective shaped end6 uncovered while the rest of the metallic patterns are completely covered by the encapsulant.
The conductors 40, 42, and 44 of Figure 1 and in addition 46 of Figure 2 may be masked during the encap6ulation to keep them suitably uncovered by the encapsulant for the addition of active materials 30 (e.g. electrolytes and polymeric membranes) to produce the electrodes ~ ~ 93/13411 212 6 5 5 ~ PC~r/US92/11286 on the surface of the substrate layer ll. This process involves masking the electrodes by the use of a polymer film coating on the screen used to screen print the encapsulant. This leaves the underlying silver exposed to form the conducting portion of the 5 analyte and reference electrodes and the conducting pattern 18 on the substrate ll. It is also possible to use multiple layers of the metalllc conductive layer and/or encapsulant, and the outer layer of the encapsulant may be solvent or thermoplastically bondable and may include polymers, as for example, acrylates or polyvinyl chloride as lO the major component in the encapsulant. The purpose of the outer coating or encapsulant is to enhance bonding of the active materials and, in particular, to provide a reliable surface for the attachment of the liquid or solid film type membrane materials. The geometry of the several electrodes could be made by a laser beam to carve or cut 15 or trim the electrode; however, they are preferably prepared by the aforementioned layered circuit technique.
Each of the analyte electrodes are fabricated with electrolyte and membranes to perform their specific task and may be selected from many commercially available electrode components. The 20 two analyte electrodes 32 and 34 on the substrate ll in Figures l and 2 are prepared to maximize the electronic response from one of the analytes to be measured over the other. Either one or both of the membrane 48 and electrolyte 50 for electrode 32 are constructed to favor to some degree the conversion of the ionic potential of one 25 analyte to an electronic response for the electrode. Membrane materials known to those skilled in the art are selected to enhance the permeability of the one analyte over the other and/or electrolyte materials known to those skilled in the art are selected in favor of the one analyte over the other. For the latter the electrolyte can be 30 buffered to minimize the ionic potential of the other analyte while W O 93/13411 - P ~ /US92/11286 ?,~?,6S~
the desired analyte's ionic potentisl i6 favored. The membrane 52 and/or electrolyte 54 for electrode 34 can be selected in a similar manner to favor the conversion of the ionic potential to electronic potential for the analyte not favored by electrode 32.
In the preferred embodiment of the present invention in accordance with both Figures 1 and 2, one electrode, for instance, 32 is a pH electrode and the other electrode 34 i8 a C02 electrode. Each electrode i6 fabricated with a membrane which maintains their respective electrolytes in a fluid tight manner in the cavities or 10 openings in which the electrodes are positioned. The pH electrode 32 and the C02 electrode 34 may be similar in regards to the circuit geometry and electrolyte and may be provided with membranes suitable for the particular characteristic being measured.
Electrode 32, preferably, a pH measuring electrode, has an 15 electrolyte 50 in contact with the conductor 40. The electrolyte preferably has an acidic pH in the range of around 3 to around 4. A
suitable acid electrolyte is an aqueous 601ution of potassium hydrophosphate (KH2P04). A most suitable and preferred aqueous electrolyte is one from 13.6 grams of potas6ium hydrophosphate in one 20 liter of deionized water. Preferably, the membrane for the pH
electrode is a polyvinylchloride polymer, which is plasticized, and has the ionophore and the anion blocker. This membrane is prepared as the dried residue of a solution having the polyvinylchloride polymer which is a very high molecular weight polymer having a molecular 25 weight in the range of around 10,000 to around 500,000 weight average molecular weight. Preferably, the plasticizers are o-nitrophenyl octyl ether (NPOE) and bis-(ethylhexyl)adipate or di-2-ethylhexyladipate (BEHA) and the ionophore tridodecylamine and the potassium tetrakis chlorophenylborate (KTClPB) anion blocker in 30 the cyclohexanone solvent. The use of the very high molecular 93/13411 P ~ /US92/11286 polyvinylchloride polymer reduces the permeability of the membrane to carbon dioxide. The acidic electrolyte suppresses the reaction of the carbon dioxide and water to minimize the extent to which the carbon dioxide changes the pH. This favors the electronic response for the 5 pH measurement since the carbon dioxide produces little electronic response.
Electrode 34, which is preferably a carbon dioxide electrode, can have a membrane that is fabricated from a wide range of commercially available carbon dioxide permeable polymeric materials.
10 As with the pH electrode, the electrolytes of the C02 electrode 34 is bound by its respective membrane. The electrolyte for the carbon dioxide sen~or is initially at an alkaline pH in the range of greater than 7 to 14 and most preferably at a pH of around 8 with the presence of bicarbonate ions. A suitable formulation for the electrolyte is 15 0.02 moles of sodium bicarbonate in a liter of deionized water. The membrane for the carbon dioxide electrode holds the electrolyte in contact with the conductor; preferably, the membrane is water vapor porous and is made of a high molecular weight polyvinylchloride polymer that is plasticized and has the ionophore, tridodecylamine, in 20 an organic solvent. A suitable membrane i8 produced from a polyvinylchloride powder which i8 a high molecular weight having a weight average molecular weight in the range of 10,000 to 500,000.
Although this is the same range as for the pH electrode the molecular weight for the carbon dioxide electrode is lower than that for the pH
25 electrode. The lower molecular weight polyvinylchloride membrane allows transport of the carbon dioxide through the membrane since it is more permeable to carbon dioxide. This PVC is plagticized with ~ NPOE and BEHA in nitrobenzene with the presence of the ionophore.
Preferably, KTCLPB is the anion blocker and cyclohexanone is solvent.
30 The membrane most preferably is formed of the dried residue of the W O 93/1341l ~ P ~ /US92/11286 ~,~26~S ~) '~
601ution that has the following percentages by weight, high molecular weight, polyvinylchloride around 5, NPOE around 5, BEHA around 5, nitrobenzene around 5, tridodecylamine 1.78, pota6sium tetrakis (4-chlorophenyl) borate 0.9, and 76 cyclohexanone solvent. The carbon 5 dioxide di6601ves in the aqueous electrolyte and the pH changes so that the ionic potential of the electrolyte changes and this is converted at the conductor of the electrolyte to an electronic potential.
Although the aforedescribed pH and carbon dioxide electrodes 10 were described as hydrated electrodes in that the electrolyte was an aqueous solution, the electrolyte can be a dried material or a gelled electrolyte. The dried electrolyte would require hydration prior to u6e through the membrane which i6 permeable to at lea6t water vapor.
In addition to the electrodes, other polymeric materials, 15 plasticizer6, ionophore6, anion blocker6 and sol~ents can be used which are known to those 6killed in the art. The material8 8hould be used with electrolytes that favor ~~ Izing the response of one analyte over the other for one electrode while ~ 1zing the respon6e for the other analyte in the other electrode. Nonexclu6ive examples 20 of polymer6 for membranes that are permeable to carbon dioxide and other gases that are 601uble in water and water vapor include cellulose acetate, polybi6phenol-A carbonate (polysiloxane/poly(bisphenol-A carbonate) blocked copolymer;
poly(methylmethacrylate), poly(vinylidene chloride), polystyrene, 25 lower alkyl acrylate and methacrylate copolymers and polymers, polyurethane, and 6ilicone rubber. Other suitable pla6ticizer6 are tho6e like dioctyl adipate, tri(2-ethylhexyl) phosphate, dibutyl 6ebacate, diphenyl ether, dinonyl phthalate, dipenyl phthalate, di-2-nitrophenyl ether, glycerol triacetate, tributyl phosphate and 30 dioctyl phenyl phosphate. An additional ionophore that can be used 2126~5 '~0 93/l341l P ~ /US92/11286 for hydrogen ion i8 trioctyl amine and for bicarbonate or total carbon dioxide quaternary ammonium ion exchanger p-octodecyloxy-m-hlorophenyl-hydrazone-mesaoxalonitrile (ocph). Where the analyte is ammonia, the ionophore can be nonacetine; where the analyte is nitrous 5 oxide, the ionophore can be tridodecylhexadecylammonium nitrate plus normal octyl-o-nitrophenyl and other ionophores known for a specific analyte as known by those skilled in the art. A1BO~ other polymers useful for forming membranes for hydrated electrodes are cation permeable and particularly hydrogen ion permeable membranes such as 10 cationic exchange materials like copolymeric vinyl ethers as manufactured by E.I. duPont under registered trademark NAFION. Also other suitable hydrophillic polymers that can be used with solid electrolytes include- polyvinylalcohol, polyethylene oxides, polyethylene oxide ethers and various polysaccarides. Other examples 15 of suitable solvents include: tetrahydrofuran (THF) and dimethylformamide (DMF).
The reference electrode 36 of Figure 1 and 37 and 38 of Figure 2 have conductor 56, 58, and 60, respectively. For this electrode, the electrolyte is present with or without a membrane and 20 preferably without a membrane. The electrolyte can be i8 a storage, hydrating or calibrating solution which is a salt solution. The electrolyte for the reference electrode is basically a 6alt-bridge layer that acts as a source for a constant concentration of the measured ion species. This salt-bridge serve6 as an ion bridge 25 between an analyte-cont~;ning solution and the reference electrode.
It consists of small amounts of appropriate electrolytes dissolved in a water permeable hydrophillic polymer or water by itself.
Additionally, other reference electrodes can be used which are in fluid contact with the analyte electrodes and suitable examples of 30 such reference electrodes include that of U.S. Patent Nos. 4,706,678 WO 93/13411 PCI'/US92/11286 6~'j 16-and 3,705,089, hereby incorporated by reference for their disclosure of reference electrodes.
As shown in Figure lb, which is a view of the opposite side from Figure la where the substrate is flipped 180~ about its 5 longitudinal axis, the patterned metallic layer 12 has metallic external leads 26, 28, and 30 on the other side of the sub6trate 11.
Preferably, there is one external lead for each conducting pathway 20, 22, 24. Although the external lead~ are shown on the opposite side of the 6ubstrate 11, they can also be on the same side or surface as 10 their associated metallic lead patterns and components. External lead~ 26, 28, and 30 are conductively a6sociated with the components on the Figure la side of the substrate layer 11 through conductive holes 62, 64 and 66.
These holes may be drilled by a laser through the 15 substrate 12 to conductively connect the conducting pathways 20, 22, and 24 traced on the Figure la side of the substrate layer 11 with their respective metallic external leads 26, 28, 30 on the Figure lb side of the substrate layer 11. In general, these holes are produced by the focused laser beam drilling a hole by heating a small volume of 20 material to a sufficiently high temperature for localized melting and/or vaporization. The holes can be drilled through the substrate layer 12 and when the metallic layers are screened such electrical connections are formed. Alternatively, the holes can be produced and preferably are produced by a very high powered carbon dioxide laser.
25 This can be accomplished by the supplier of the nonconducting substrate and in this case the metallic layer is added to the sub6trate 60 each conducting pathway electrically connects with an external lead.
The external leads 26, 28, 30 may be produced on the other 30 side of the substrate layer 11 with the same paste and firing as that , 21265~
93/13411 P ~ /US92/11286 done for aforementioned metallic patterns. The metallic external leads 26, 28, and 30 are in metallic electrical conducting contact with the various components on each side of the substrate 11.
External lead 26 is in metallic electrical conducting contact with the 5 pH sensing electrode 32; external lead 28 is in metallic electrical conducting contact with the C02 sen6ing electrode 34; external lead 30 is in metallic electrical conducting contact with one reference electrode 36 in Figure 1 or two reference electrodes 37 and 38 in Figure 2, which are located at the end of- pathway 22.
The two analyte electrodes 32 and 34 and the one or more reference electrodes 36 and 37 and 38 are in 6paced apart relation to each other and their conductors are insulated from each other but they are in a liquid junction electrical connection with each other. The membranes for at lea6t the analyte electrodes and the electrolyte and 15 any membrane that may be present in the reference electrode are in fluid contact with the fluid in the fluid circuit means 68 in Figure 3. To as6i6t in this liquid junction contact and electrical insulation of the electrical circuit pattern 18, the arrangement of the electrode6 can exi6t in a variety of patterns on 6ub6trate 11. A
20 preferred arrangement is that of Figures 1 and 2 where the pH
electrode 32 is located st the end of extension 20; the other analyte sensing electrode 34 is located at the end of extension 22; and the one or more reference electrodes 36 in Figure 1 and 37 and 38 in Figure 2 are located at the end of exten6ion 22. A8 noted in 25 Figures 1 and 2, the two analyte 6ensor6 32 and 34 are axially aligned along a longitudinal axis of the substrate 11. The one or more reference electrodes are located off of this axial alignment but can be located anywhere else on the sub6trate 11. This longitudinal axial alignment for the analyte electrodes 32 and 34 are for the preferred 30 u6e of the 6ensor apparatus of the pre6ent invention. The preferred 1 .
A
~ 93/~3411 PCI'~US92/11286 5 ~ 5 use is in a portable blood gas analyzer as further described in cases assigned to the same assignee as the present application, U.S. Patent 5,284,570, issued 8 February 1994 and 5 WO 93/00582 published 7 January 1993 Alternatively, the sensor apparatus of the present lnventio~
if used in a different environment or device, the analyte electrodes 32 and 34 and reference electrodes 36 or 37 and 38 as ln Flgure 2 could be positioned differently on the substrate 11. For in6 tance, 10 when the sensor apparatus of the present invention is utilized in a stationary device with 6amples inserted on a card or carrier to contact the electrodes the electrodes csn be located anywhere on the 6ubstrate to match the location of the sample on the coupon or card.
Their arrangement could even be in a stralght line and the fluid 15 circuit flow pattern might allow for a different fluld to be in contact wlth the one or more reference electrodes than wlth the two or more analyte electrodes.
Also shown in Figure 2b, which is the reverse side of substrate 11, is heater 68 that is used in the preferred embodiment of 20 the present invention to measure the concentration of the analyte at a temperature above room temperature. For example, when the fluid to be measured 18 blood or another bodily fluid, the elevated temperature i~
the normal body temperature of the vertebrate animal from which the blood was obtained. For control of heater 68, it ls preferred to have 25 present a thermistor 70 and resistor 72 arrangement as 6hown in Figures 2 and 2b. Thi6 arrangement makes it possible to indicate the temperature at any time on substrate 11 although it is also posslble to have the heater, thermlstor and resistor on the substrate of Figures 1 and lb ln a similar manner as in Figures 2 and 2b.
,~
21~6~S~
'~ ~ 93/13411 ~ PC~r/US92/11286 -External leads 78 and 80 are in metallic electrical conducting contact with the heater 68 which is preferably a thick film heater provided on the Figure 2b side of the sub6trate layer 11. The heater 68 can traver6e the board in a serpentine fashion. External 5 leads 82 and 84 are in metallic electrical conducting contact with a resistor 72 which is also provided on the Figure 2b side of the substrate 11. The resistor 72 is in a half-bridge relationship with the thermistor 70 and, as such, it commonly shares external lead 82 with the thermistor 70, thermistor 70 also being in metallic 10 electrical conducting contact with external lead 82. The function of the thermistor 70 and resistor 72 arrangement will be described below.
The serpentine formed heater 68 and the resistor 72 on the Figure 2b side of the substrate 11 may be prepared by a number of commercially available techniques, however, they are preferably thick 15 film device6 prepared by the aforementioned layered circuit technique.
As before mentioned, external leads 78 and 80 are in metallic electrical conducting contact with the heater 72 and external leads 82 and 84 are in metallic electrical conducting contact with a 20 resistor 72 which commonly shares external lead 82 with the the- ;stor 70; thermistor 70 also being in metallic electrical conducting contact with external lead 64.
Thermistor 70 is located at the end of conducting pathways 74 and 76, and is preferably a thick film thermally sensitive resistor 25 whose conductivity varies with the changes in temperature. The thermistor 70 may be fabricated from a number of semi-conductive materials as, for example, oxides of metals. The the ~stor may be formed and applied to the substrate 11 by the use of the aforementioned layered technique. The temperature coefficient of the 30 the_ {~tor 70 preferrably is large and negative and is used to sense W O 93/13411 9 ~26~ P ~ /US92/11286 the temperature of the substrate ll at all times when the sub6trate 11 is electrically connected Vi8 electric circuitry 16 to a power source and the analyzing means of Figure 4. Thermistor 70 is operated at relatively low current levels 80 the resistance is affected only by 5 the ambient temperature and not by the applied current.
The half-bridge circuit configuration involving resistor 72 preferably is a voltage divider and generates a ratiometric output to the analyzing means of Figure 4. Thi6 is important for it allows the actual resi6tance values to float and results in highly consistent and 10 accurate temperature sensing and control of the substrate 11 on a substrate-to-substrate basis. Accuracy and consistency of the resistor 72 and thermistor 70 arrangement is preferably achieved by calibrating the substrate 11 with conductive patterns by laser trimming of the re6istor 72 to produce zero volts at 37~C. The la6er 15 beam i8 precisely deflected across the thick film resistor 72 to produce the desired temperature voltage relationship. A current is applied at external leads 82 and 86 by the analysis means of Figure 4 with a power source until zero volts is achieved. This gives a linear output so that the temperatures can be mea6ured other than 37~C from 20 the slope of the line from the calibration at room temperature and 37~C. The resistor 72 has essentially zero temperature coefficient and, accordingly, may be placed without any adverse effect on the sen6ing capability of the associated thermistor 70 on the Figure 2b side of the substrate 11 with the heater 68.
Accurate sensing of the ambient temperature of the substrate 11 is required to precisely control the heater 74 to ultimately maintain, within a narrow distribution of temperatures, the desired operating surface temperature on the Figure 1 or Figure 2 sensor side of the substrate 11.
.
'0 93/13411 2 ~ 2 ~ 5 S 7 PC~r/US92/1~286 Placement of the thermistor 70 is another important aspect of the present invention. As can be seen in Figure 2, the thermistor 70 is placed in the same plane and in close relation to the electrodes 3Z, 34, 37 and 38 to thereby accurately sense the ambient temperature 5 at or near such sensors. This physical placement of the thermistor 70 allows for the rapid adjustment of the heater 68 by the analysis means of Figure 4 with a power supply to maintain the de6ired operating temperature. The thermistor 70 and resistor 72 arrangement can provide temperature measurement accuracy of within 25~C. This 10 physical placement of the thermistor 70, 80 close to the electrodes, requires that it be correctly fabricated to ensure that it is electrically isolated from the electrolytes of the several electrodes. The encapsulant for the thermistor 70 should be thick enough to accomplish the electrical isolation, yet thin enough 80 as 15 not to lose any response time.
The heater 68, provided on the Figure 2b side of the substrate 11, rapidly and accurately produces the necessary heat in response to any temperature change sensed by the thermistor 70; the thermistor 70 and the several electrodes preferably all being in the 20 heated region produced by the heater 68. Thick film heaters are not generally considered to be rapid response devices and their heat output tends to take a relatively long time, in terms of electronic devices, to change. To improve the responsiveness of the heater 68, it can be powered by pulsed DC 80 that the heater ls continually 25 turned on and off by the analyzing means with power supply of Figure 4. This not only increases the responsiveness of the heater 68 but also allows for better overall thermal control including avoiding the heater 68 from overshooting or undershooting the desired temperature.
6 ~ S ~ - 22 -Whatever the arrangement of the electrodes on substrate 11, their arrangement is matched by a fluid pattern 86 which may be flow through or non-flow-through design. A suitable flow-through design, which is preferred, is shown in Figure 3. The one or more fluids are 5 continuou6 in the pattern to provide the liquid junction between the electrodes for electrical conductivity. Preferably, the fluid pattern 86 is occupied by at least two different fluids. Preferably, a storage fluid is in contact with the reference electrodes 36 in Figure 1 or 37 and 38 in Figure 2 while the fluid pattern 86 allows 10 for contact of a storage fluid, hydrating fluid, if needed, calibrating fluid, and sample fluid for the analyte electrode6 32 and 34.
Figure 3 shows a suitable cover 88 having one section to enclose or surround the substrate 11 with electrodes 32, 34, 36 and, 15 in Figure 2, 37 and 38 and conductive pattern 18. The cover 88 can be made of any fairly rigid moldable material such as rigid thermoplastic polymers although thermosetting polymers can also be used. A suitable example is a methyl methacrylate styrene butadiene terpolymer and rigid pla6tics such as polyesters like polyethyleneterephthlate or 20 polycarbonate or blends or alloys thereof and other similar materials known to tho6e skilled in the art. The cover 88 can be any basic geometric shape 6uitable for containing a channel 90 and substrate 11. The number of parts or sections comprising the cover can range from 1 to a plurality but two parts are preferred. A single part 25 cover as shown in Figure 3 has the substrate 11 forming one side like a backing to the cover 88 when the substrate 11 is positioned in the cover 88. Another possibility is for the cover 88 to have a fir6t and second opposing sections where one section is the cover section and the second section is a back section. Each section has an exterior 21~55~S
~vo 93/134ll PCI'/US92/11286 w and interior surface and when both 6ections are matchet together, they completely encase the substrate 11.
The cover 88 by itself when the substrate 11 is the backing or the two sections of the cover when matched together form an 5 interior space 92. Space 92 need not be of any particular geometric configuration just 80 long as substrate 11 fits into the space. The internal space 92 and substrate 11 are preferably of matched configuration and are preferably generally rectangular. Preferably, when the cover 88 has two sections, the t~p section with the fluid 10 circuit pattern 86 comprises a substantial portion of the cover 88 as shown in Figure 3 and the other is a backing for substrate 11. With this arrangement and with the internal space 92 having dimensions that closely match those of the substrate 11 for a snug fit of the latter into the former, and both sections can assist in providing electrical 15 isolation between any fluid in the channel 90 and the electric circuit means 16. The former is at least in fluid pattern 86 and the latter is on substrate 11. This reduces the risk of leakage current or short circuiting of the conductive patterns 18 of the electrical circuitry means 16.
The cover 88 can be adhesively connected to a back, i.e. the substrate 11 or a backing for the substrate (not shown) to improve their attachment to each other through connection means 94. The cover 88 also can allow for communication from the conductive patterns 18 to an electrical connection mean6 96 which electrically connects the 25 conductive patterns 18 to the analysis means shown in Figure 4. The electrical connection means 96 in conjunction with the conductive patterns 18 comprise the electrical circuitry means 16.
Cover 88 in conjunction with the substrate 11 provides for at least one channel 90 to pass over at least one analyte electrode on 30 substrate 11 and for any other channels to interconnect. Channel 90 2 ~ ? P ~ /US92/11286 i8 constructed to have any shape that allows for fluid flow to, over, and from the one or more electrodes and to allow for ingress and egress of fluid from the channel. The channel 90 can have two opposing openings to allow fluid flow through the channel from a 5 receiving opening 98 to an exit opening 100, where the former is before and the latter after the electrodes. The receiving opening 98 can be suitable for attachment to a sample receiving means (not shown) and the exit opening 100 can be suitable for attachment to a collection means (not shown) such as a syringe or reservoir in 10 general. Also, when the channel 90 is flow through and contains a fluid for storage or preconditioning, the opening6 98 and 100 can be sealed by a substantially moisture impervious seal 102 and 104, respectively. The openings 98 and 100 can serve as an inlet to or outlet from cover 88 that is preferably formed by conical tips 15 preferably aligned in the same plane and along the same axis at opposite ends of the channel 90. In this arrangement channel 90 passes longitudinally over the substrate 11. The interlor space 92 of the covering communicates with the one or more channels to contain the substrate 11 so that the electrodes that are on the substrate are so 20 disposed to lie in the path of the channel for fluid contact. The 1~ -;n;ng portions of the channel 90 and any other channels are formed by substrate 11 occupying the internal space 92 so that the surface of substrate 11 with one or more electrodes actually forms a wall of the channel 90.
Seals 102 and 104 can have one or more surfaces where at least one surface is substantially a non-oxidizing metal such as aluminum that is useful with an adhesive-type polymer. The adhesive-type polymer can be used either as an application to the surface to be sealed or as another surface of the seal. The seal is 2 1 2 6 5 ~ ~ PCT/US92/11286 -fixedly attached to the housing by a chemical means and/or by a mechanical means.
Preferably, the cover 88 in conjunction with the substrate 11 provides for a plurality of channels. The number of channels for 5 the fluid pattern 86 is sufficient that the analyte electrodes 32 and 34 are on one or more channels that are separate from the one or more channels for the one or more reference electrodes. This arrangement allows the reference electrodes as 36 and, for Figure 2, 37 and 38 to have a different fluid in contact with them than the fluid in contact 10 with the analyte electrodes 32 and 34. The fluid in contact with the reference electrodes can be a calibrating or hydrating fluid while a sample fluid is in contact with the analyte electrodes 32 and 34.
With connecting channel sections 106 and 108 connecting side channels 110 and 112, respectively, with channel 90, the one or more reference 15 electrodes of Figures 1 and 2, respectively, can be off the axial alignment with the analyte electrodes 32 and 34 and still be in liquid junction contact with them through the fluid circuit 86. The substrate 11 of Figures 1 and 2 can be po6itioned in the cover 88 so that the a reference electrode is in fluid contact with the fluid in 20 one or both of the side channel 110 and 112. Concomitantly, the analyte electrodes 32 and 34 are in fluid contact with the fluid in channel 90. In an alternative embodiment, only channel 90 i8 present and all of the electrodes both analyte and reference contact the fluid in the channel 90.
The fluid occupying the portion or portions of the channel 90 or channels 90, 110 and 112 over the one or more electrodes can be a storage, hydrating or calibrant fluid. A storage fluid can range from air for electrodes with dried electrolyte to a liquid that has some amount of water although a minor quantity of organic liquids may 30 also be present. Preferably, the fluid is a stable liquid for storage U )3/13411 2 ~ 5 ~ i PCT/US92/1l286 ranging from a ~hort time (days or weeks) to prolonged periods of time of several months. Preferably, the fluid that occupies the fluid circuit 86 is an aqueous solution that i8 isotonic with any electrolyte in the one or more electrodes. More preferably, the fluid 5 of the fluid circuit 86 in Figure 3 can be a hydrating fluid that is also isotonic. Then the fluid can act as the electrolyte for any reference electrodes on the substrate ll that do not have a membrane.
The hydration fluid can be one that i8 added to hydrate 6clid or dried electrolyte in the electrodes or, preferably, to maintain the hydrated 10 electrolyte in the electrodes. The hydrating fluid i8 chiefly an aqueous fluid with an effective composition to hytrate at least to a partlal degree but better to a 6ubstantial degree the hydrophillc polymeric membrane6. A suitable example of a hydrating fluid i6 an aqueous solution comprising: disodium hydrogen phosphate, potsssium 15 dihydrogen phosphate, sodium bicarbonate, and sodium chloride. Such a solution can have a varying range of amounts for the individual constituents but most preferably for the aforelisted salt~ the amoun~s are in millimole9 per kilogram of water in the order listed as follows: 4.8, 13, 22, and 12.5. The quantity of hydrating fluld in 20 channel 90 or the plurality of channels i6 at lea~t that which is sufficient to co~er or remain in contact wlth the one or more electrodes. This arrangement is more fully shown in the WO 93/00582 published 7 January 1993.
Any arrangement or configuration other than that 6hown in 5 Figure-3 can be used that allow the two sections to engage and form cover 88 with one or more internal 8paces for placement of substrate 11 so that the electrodes are in fluid contact with any fluid 114 that is in the one or more channels. Other suitable arrangements include ~ ~1 2 ~
~WO 93/13411 PCT/US92/1128fi those described in European patent applications 0306158 and 0351516 and U.S.PatentNo.4,818,361.
Figure 4 shows the preferred electrical connection of the analyzing means 116 through t~e electric circuit means 16 to substrate 11. Electrical connections 118, 120, lZ2 and 124 are apart of the electric circult means 16 and electr~cally connect with the appropriate external leads of the substrate 11. Preferably, connections 118, 120, 122 and 124 are part of one ribbon-type cable connecting the analyzing means 116 as a module to the external leads 10 of the substrate through any electrical attachment means known to those ~killed in the art. In such a ribbon cable, connections 118, 120 and 122 would be indlvidual wires in the cable and connection 124 would be comprlsed of several individual wires ln the cable.
Connection 174 would include wiring for any power supplied to the 15 substrate 11 or, heater 68, or thermistor 70 or resi6tor 72 or any other electrical components on the substrate 11. Al~o connection 124 could include wiring for conveying any additional electronic potentials from additional electrodes on the substrate 11 like an oxygen sensor which is preferably present and can generally be any 20 oxygen microsensor known to those 6killed in the art.
It is also pre~erred that the pH and C02 electrodes and the sen60r apparatus of the present invention is u~ed in conjunct~on with an oxy~en electrode and sen~or and the mea~s 116 is capable of receiving input from these electrodes and reference electrodes for 25 them and outputtlng dsta for p~, C02 and oxygen. The combination of the pH and C02 along with the oxygen sensing is as described further in cases cornmonly assigned to the same assignee as the subject patent application, WO 93/00582 published 7 January 1993, and U.S. Patent 5,246,576 issued 21 September 1993.
W O 93/13411 P(~r/VS92~11286 _ 2 i ~ 6 ~ 5 S - 28 -In Figure 4 the electronic signal from one of the analyte electrodes, for example electrode 32, is conveyed by the electronic pathway 20 of Figure 1 to the lead 26 of Figure lb to electrical connection 120 and to amplifier 134. Likewise, the signal for the 5 other analyte electrode 34 is conveyed by pathway 24 to lead 30 to connection 118 and to amplifier 136. Also, the electrical signal from the one or more reference electrodes of the substrate 11 of Figures l or 2 is conveyed by pathway 22 to lead 28 to connection 122 to amplifier 138. The other connection for the amplifiers can go to 10 ground 132 through connections 126, 128, and 130. The amplifiers can be any amplifying electronic component known to those 6killed in the art and can actually be and preferably is apart of the analog input processing function of the analyzing means 116 rather than di6crete components. The amplifiers are shown in Figure 4 as discrete 15 components mostly for illustrative purposes.
The analyzing means 116 receives separate electrical signals from the two analyte electrodes and the one or more reference electrodes, for example as depicted in Figure 4 as signals 140, 142 and 144. The analyzing means 116 can be as simple as a voltmeter and 20 calculating device or an electronic circuit board with suitable electronic components to perform the functions of analog input processing, analog to digital conversion, programmed microprocessing, and a date/time circuit and battery backup random access memory, and a power supply. In the preferred embodiment, analyzing means 116 also 25 has the capability of battery power supply in addition to standard wall socket power supply. Preferably, the analyzing means is a self-contained, hand-held, preferably battery powered monitoring instrument or analyzer to process the signals and displays the information in a digital or paper mode to the operator. Also 30 preferably in means 116, the analog input processing unit interfaces ___,J93/134ll 2 1 ~ 6 ~ ~ 5 PC~r/US92/11286 with a 12 bit analog to a digital converter which itself interfaces with an 8 bit programmed microprocessor. The proce6sor accesses the date/time circuit and battery backup random access memory. Means 116 is electrically connected by connection 146 to a display device 148 5 that can be a digital or analog display with or without but preferably with a printer. Also means 116 preferably has a battery and charger a6sembly that provides battery power. Although a particular arrangement for the functional units of the means 116 has been specifically set forth, variations are possible that may delete one or 10 more of the functional units. As long as the processing, memory, and converter are present when analog signals are used, and the processor is functionally tied into these units and power is supplied, a read out can be obtained.
Means 116 can be prog~~ -d in any language known to those 15 skilled in the art like "C" where the program can reside on a floppy disk when means 116 has a floppy drive or and preferably can reside in firmware like a PROM or ~PROM. The program allows means 116 to give two analyte concentration values from the electronic signals. The program takes the electronic response of the analyte electrodes 20 compared to the reference electrodes along with sensitivities of the analyte electrodes and initial readings on fluids with known values of analytes to determine the unknown analyte values. The determination is according to relationships derived from the Nernst and Henderson-Hasselbalch equations. With the known analyte value, like 25 that for carbon dioxide in a calibrating fluid, the analyte electrodes, like carbon dioxide and pH electrodes, can be calibrated.
Both of the8e electrodes have a certain 8en8itivity in millivolts per millimeters of mercury for carbon dioxide tension. This is determined via a statistical process by measuring many samples which are compared 30 against the sensor being checked. Means 116 checks or predicts the i ~ 6 ~ S S - 30 _ millivolt change from the millivolts measured for the one or more calibrant fluids and this change should be within the statistical range of acceptable values or the sensitivity of the sensor i6 not within specifications. This tests the sensitivity of the electrodes 5 to determine if they are accurate.
The program takes the data and the aforementioned relationships and utilizes them as illustrated in Figure 5 and Table l to give data for the analysis of the preferred embodiment of the present invention. Preferably, carbon dioxide and the pH of a blood lO sample is measured. In Figure 5, "A" indicates the millivolts per second for the pH sensor and "B" indicates the millivolts per second for the carbon dioxide sensor. Time period "C" indicates the calibration period during which time a calibration fluid with known values of pH and carbon dioxide are presented to the two analyte 15 electrodes, one for carbon dioxide and one for pH, on the substrate ll like that of Figures l, lb or 2 and 2b. Preferably, the measu~ ~rt is taken at a temperature comparable to body temperature and the heater and thermistor and resi6tor arrangement of the substrate ll control this temperature.
In Figure 5, point "D" and point "E" indicate the initial values for the pH and carbon dioxide, respectively. These values are recorded for later use. At point "F" in Figure S, the sample of blood i6 in the fluid circuit in contact with the analyte electrodes.
Points "G" and "H" indicate the final values for the pH and carbon 25 dioxide, respectively. These final values are also recorded.
Table l 6hows the calibrant values and the sample values at points "D", "E", "F" and "G" and also show6 the calculated values from the formulas for the blood sample.
The time line for the analysis cycle shown in Figure 5 30 includes connecting the substrate with electrodes to the analyzing ~ ~93/13411 2 1 ~ 6 ~ 5 ~ PCT/US92/11286 _ .
means 116 as the aforedescribed a progL ~d computer means and within about five seconds taking the pH and carbon dioxide millivolt readings for the 6torage fluid. After a period of time greater than 15 second~, a calibration fluid is pa6sed over the analyte electrode~.
5 Twenty-four seconds after the calibration fluid contacts the electrodes, the calibration pH and carbon dioxide millivolt reading6 are taken at room temperature. A second later the sensor is heated by the heater 68 on the substrate 11 and for about 10 seconds the thermistor stabilizes and the calibrant pH and the carbon dioxide 10 millivolt readings are taken. Within a second or so the blood sample contacts the analyte electrodes and the thermistor stabilizes over a short period of time (in seconds) and the pH and carbon dioxide millivolt readings are taken for the blood sample within 60 seconds from the blood contacting the analyte electrodes.
W 0 93/13411 PC~r/us92/ll286 ,.265~s ,~
Calibrant Blood Calibr~nt SamDle V~lues V~luec pH 6 6 mV -13 0 mV 7 185 7 470 C~2 -17 3 mV -27 7 mV 57,3 36 3 Pcak ~ 17 022, 7 724) ,:
C~2 ~ S0 59 Room Tempcr-ture ~ 23 06 Scnsor OX' mV COz ~ (C02f - C02~) ~ (-27 7 - (-17 3)) ~ -10 4 mV
mV pH ~ (pHf - pHI) ~ (-13 0 - 6 6) ~ -19 6 mV
C02f ~ C02~ * lOt -(SENrC021rDHl~(mVDH~ - ~SENrDHlrDHl~(mVC02~
-(SEN[C02]~pH])(SEN[pH]~C02]) + (SEN~pH]~pH])(sEN~co2]~co2]) ~ 36 3~ H8 pHf . -~VDH + SENrDHlrC021 * LOG Co2fLçQ2l + PHi n 7,470 -SEN~pH]~pH]
where SEN~pH]~C02] ~ ~ensltivlty of the pH electrote fa~oring the COz ~g anclyte SEN~pH~pH~ ~ scns~ti~ity of the pH electrote fa~orlng the H+ analyte for thc ~ccond analyte SEN~COz~pH~ ~ ~ens~tlvlty of the COz electrode fa~orin~ the H+
analytc SEN~C02~C02] ~ ~ensiti~ity of the C02 electrode favoring the C02 analyte f ~ final measurement i = lnitlal mecsurement
The present invention is related to an analyte sensor assembly apparatus and method for measuring coupled analytes. More particularly, the present invention relate6 to an apparatus of a carbon dioxide and pH sensor assembly for measuring both in fluid samples .
BACKGROUND OF THE ~VENTION
Numerous methods and apparatus exist in the art for measuring chemical components of fluids and current technology utilizes many types of sensors for detecting components and analytes in numerous types of fluids. For example, carbon dioxide and pH
15 sensors are used for measuring these components in various fluids including gases and liquids. For instance, the mea6urement of blood gases, along with the pH from a sample of arterial blood, give6 the state of the acid base balance or the effectiveness of both the re6piratory and cardiovascular 6ystems of the human or vertebrate 20 body. Measuring the blood gases usually involve6 a measurement of the partial pre6sures of oxygen and carbon dioxide along with the measurement of the pH since carbon dioxide dissolved in the aqueous solution can affect the pH through the presence of carbonic acid.
These are examples of coupled snalytes.
It is conventional practice in many of the existing measurement methods, even where the fluid is a liquid or liquid with a dissolved gas with or without the pre6ence of 601id6 to tran6port a sample to a central location for testing. With centralized testing, the bulky, stationary, elaborate and sophisticated equipment performs 30 the analy8is on a practically endle6s number of 6amples. Originally, this equipment employed carbon dioxide sensor like the Severinghaus W O 93/134ll P ~ /US92/11286 212 655 ~ 2 -potentiometric sensor for a qualitative and/or quantitative measure of carbon dioxide. This sensor has a gas-permeable membrane between the sample solution for measurement and the measuring cell. The cell has a pH-sensing glass electrode, a reference electrode, and an 5 intermediate electrolyte layer. Recently, more sophisticated carbon dioxide sensors have utilized polymeric membranes like those of the combined pH and carbon dioxide sensor of U.S. Patent 4,818,361.
Al60, recent attempts have been made to introduce more portable equipment into the marketplace of fluid analysis. An example 10 of thi6 is the qualitative and/or quantitative measurement of constituents or analytes of blood. The bulky stationary equipment is fairly expensive and the procedures for its use can be cumbersome depending on the type of fluid to be measured. For instance, mea6uring blood gases from the arterial blood sample involves:
15 drawing the blood sample in a syringe, immersing it in ice and transporting it quickly to the lab where the equipment is usually located for a measurement of the gases. More portable devices would shorten or overcome transporting the sample to the measuring equipment at a fixed location. For ex~mple, portable sensing units which can be 20 coupled to a digital readout device would be useful at the patient's bedside in a manner similar to a way that temperatures are measured at the patient bedside.
U.S. Patent Nos. 3,000,805 and 3,497,442 show two such devices. The former has electrodes located on a syringe plunger and 25 the latter has electrodes placed on the syringe well to conduct the measurements. The electrodes of these sensors may be particularly sensitive to small sample volumes 6ince they consume oxygen in their operation. In U.S. Patent No. 5,046,496, Applicants' assignee describes and claims a portable blood gas sensor which includes 30 sensors fabricated using a conventional silk screening process where ~ 93/l34ll 2 1 2 6 5 ~ ~ PC~r/US92/ll286 the electrodes are screened on to a ceramic substrate. Typically, these electrodes have the conductor along with an electrolyte and analyte permeable polymeric membrane that cover6 the sensor. Some of these membranes may be hydratable membranes by water vapor permeation 5 and they can be stored in a dry state and hydrated just prior to use as in U.S. Patent No. 4,818,361. The more portable the equipment the larger the demand for the miniaturization of the electrodes that still produce precise outputs for the analyte concentration or tension.
SUMMARY OF THE INV~TION
It is an object of the present invention to provide a sensor apparatus that utilizes analyte electrodes where each electrode has sensitivities for the analytes to be measured and where the analytes are water soluble analytes that upon solublization in water can influence the pH.
The sensor apparatus has in its broadest aspect a holding means for electrodes and for electronic conductive patterns at least two analyte electrodes, at least one reference electrode, a fluid circuit means in fluid contact with the electrodes, analyzing means, and the electrical circuitry means.
The at least three electrodes are held by the holding means in spaced apart relationship to each other and in electrical connection with electronic conductive patterns of the electric circuitry means which is also held by the holding means in insulated fashion for conveyance of electrical signals from the electrodes.
The analyte electrodes have ion selective membranes and/or a particular electrolyte composition that is selected to favor the conversion of the ionic potential to electronic potential of one analyte over the other. Each electrode has a sensitivity of the analytes to be measured but the sensitivities are different in each 30 electrode. Both of the ion selective membranes have a first and W 0 93/13411 2 12 6 5 5 ~ P ~ /US92/11286 second side and the membranes are positioned in the respective electrodes for one side to be in contact with the electrolyte of that electrode and for the other side to bè available for exposure to the fluid circuit. The fluid circuit can have a storage fluid, hydrating 5 fluid, analyte-containing fluid, or calibration fluids for analysis or a mixture of two of these. Additionally, the membrane of each electrode holds the respective electrolyte in contact with the conductor of that electrode.
The reference electrode can be an electrochemical half-cell lO or second order electrode that is provided in order to establish a substantially accurate and constant comparative potential. The reference electrode either with or without a membrane can have as an electrolyte the fluid that is in its vicinity in the fluid circuit means. Additionally, the electrolyte can include a metal cation of 15 the electrode.
The electrodes are arranged further on the holding means to match the fluid circuit means so that the membranes of the analyte electrodes can contact the fluid in the fluid circuit. In this arrangement the analyte electrodes can contact the storage fluid, 20 hydration fluid, calibration or standardized fluid, sample fluid, or all of these at different times when they are present in the fluid circuit mean6. The reference electrode can also contact one or more of these fluids either in axial or in no~ l alignment with the analyte electrodes. The contact can be from channels or conduits 25 having the fluid in a flow-through or nonflow-through fluid circuit means. The channel or channels can be in a cover encompassing the holding means for the electrodes or on a holder or card that slides into a recording instrument that has the electrodes held in a stationary position for the contact.
_- W 0 93/13411 ~ 5 9 PCT/US92/11286 The electric circuitry mean6 can be prlnted wire circuitry for the portion that i6 held by the electrode holding means. This electronic conductive pattern means portlon of the circuitry allows for electrical connection of the electrodes to each other through one 5 connection and for conveyance of the electronic potential to the analyzing means. Another portion of the electrical circuitry means can be a cable to convey electrical impulses from the holding means to the analyzing means.
The anslyzing means receives digital or analog input and 10 produces digital and/or analog output from the input via the simultaneous solution of the following equations:
delta mVAl = - SElAl x delta pH - SElA2 x log A2f/A2i Equation 1 delta mVA2 = - SElA2 x delta pH - SE2A2 x log A2f/A2i Equation 2 A2f = A2ixlOn Equation 3 where n = ~SE~,Al x delta mVAl - S~lAl delta mVA2 [-SE2Al x SElA2 + SElAl x SE2A2~
20 Alf = ~l~B mY~l t ~EL9_ ~ lQg A2f/A2i ~ Ali Equation 4 -SElAl where:
delts mV = change in millivolt~
25 Al = first analyte A2 = second analyte El = electrode constructed to favor the first analyte E2 = electrode constructed to favor the second analyte SElAl = sensitivity of the electrode favoring the first analyte for the first analyte SElA2 = sensitivity of the electrode favoring the first analyte for the second analyte W 0 93/13411 ~ 6 s 5 S P ~ /US92/11286 SEZAl = sen~itivity of the electrode favoring the second analyte for the fir6t analyte SEZA2 = sen6itivity of the electrode favoring the second analyte for the second analyte 5 f = final mea6urement i = initial mea6urement In a narrower a6pect of the present invention, the first analyte is the hydrogen ion concentration 80 that the first analyte electrode i6 a pH electrode. The second analyte i~ a carbon dioxide lO and the 6econd analyte electrode is a carbon dioxide electrode. The - electrode holding means is a nonconducting substrate suitable for attachment of the pH, carbon dioxide, and reference electrodes spaced apart from each other and connected to printing wiring circuits for conveyance of the electronic potential from the electrode6 to the 15 analyzing means.
BRIEF D~SCRIPTION OF TU~ DRAWINGS
Figure la is a top planar view of the one side of the 6ubstrate or wiring board of the pre6ent invention, having an arrangement of two analyte 6en60r6 with one reference electrode with 20 accompanying electronic conductive pattern6 of the electric circuitry, and Figure lb show6 a portion of the opposite slde.
Figure 2 is a planar view of the one side of the substrate or wiring board of the present invention having two analyte sensor6 (one analyte and pH) with two reference electrodes spaced apart from 25 each other and from the axis of the analyte electrodes and accompanying electronic conductive patterns and al60 having a thermistor.
Figure 2b is a planar view of the other side of the wiring board (substrate) of Figure Z having a resi6tor and a heater that 30 traver6e6 the board and a number of lead6 through the board from the ..~
'''O 93/13411 2 1 2 6 ~ ~ S PC~r/US92/11286 side depicted in Figure 2 to provide an external electrical connection from the board.
Figure 3 shows a matching fluid circuit means for the substrate in Figures l, lb, 2 and 2b.
Figure 4 is a schematic of the circuitry including the analyzing means.
Figure 5 is a graph of the millivolts (mV) along the ordinate versus time in seconds along the abscig6a for the analy6is of two analytes, carbon dioxide and hydrogen ion (pH) for a blood lO sample.
DETATT~n DESCRIPTION OF T~F l~V~;~LION
Similar numeral6 are used throughout the drawings to denote the same feature in each of the drawings.
The holding means ll with electrode6 and the a6sociated 15 portion of the electrical circuit means of the electrochemical sensor apparatus of the present invention as 6hown in Figure l have particular shapes for the components. Other shapes than those shown in Figure l that are known to those skilled in the art for the particular components can be used.
The electrode and circuit holding means ll may be produced from any number of well known layered circuit technologies as, for example, thick film, thin film, plating, pressurized laminating and photolithographic etching of a combination of two or more of these;
however, the thick film technique is preferred for all of the 25 components. Of course, it would be possible to produce the analyte electrodes by thick film process snd the reference electrode by thin film proce6s. The holding meanf~ ll can be of any shape adequate to hold the electrodes and electric circuit; one suitable example is a printed wire board substrate.
W o 93/13411 ~ i 2 6 ~ S S PC~r/US92/11286 The holding means, hereinafter in the specification referred to as the substrate, ll can be any glass or ceramic including sheet or chip or nonconducting substrate like wood or nonconducting polymers or commercially available frit that can be used as the substantially 5 smooth flat surface of the substrate layer ll. Nonexclusive examples include borosilicate glass as is known to those skilled in the art for producing thick film or layered circuits. A nonexclusive and preferred example of which includes a ceramic base having around 96%
Al203 such as that available commercially from Coors Ceramic Company, lO Grand Junction, Colorado. The substrate layer ll can be and preferably is essentially flat with two sides and any substrate known to those skilled in the art for forming printed wiring circuits can be used. It is preferred that the composition of the substrate can endure the presence of electrolytes that have acidic or basic pH and 15 remain unaffected for a substantial period of time.
Substrate ll can have several layers to form the electrodes and associated circuitry. One layer is a patterned metallic layer 12 with a number of extensions which act as the electric conductive pattern portion 18 of the electrical circuit means, collectively 20 referred to as 22, between a voltage or current source (not shown) that is external to the substrate ll. Each extension can have a component (electrode conductors) at its end. The several extensions also have the ability to transmit voltage changes from the components of the substrate ll to the analysis means (shown in Figure 4).
The patterned metallic layer 12 is formed by printing pastes deposited onto a substrate in the desired pattern to act as ohmic conductors. Nonexclusive examples of suitable heat resisting metals include: noble metals such as platinum (Pt), ruthenium (Ru), palladium (Pd), rhodium (Rh), iridium (Ir), gold (Au) or silver (Ag) 30 or other metals traditionally used in Severinghaus potentiometric ~ 93/134ll 2 1 ~ S 5 ~ 5 P ~ /US92/11286 sensors. A nonexclusive but preferred example of a suitable paste is a silver pa6te of the type produced and svailable from Electro-Science Laboratorie6, Inc. under the trade de6ignation ESL 9912. The metallic layer 12 i8 dried to produce the above noted conductive pattern 18 5 which comprise the conductive pathways 20, 22, and 24 of Figures 1 and 2 and the external leads 26, 28, and 30 of Figure lb. Any method known to those skilled in the art for producing a sufficient thickness of metallic tracing can be u6ed. Preferably, the silver paste6 are oven dried and fired at a high temperature in a furnace. Firing can 10 be accomplished at a temperature in the range of around 800~C to around 950~C for a period of around 1 to 20 minutes. With this procedure, the thickness of the layer of the metallic conducting tracing is usually in the range of around 0.0005 to 0.001 inches.
Although the aforementioned are preferred conditions, general 15 conditions for obt~in;ng a proper thickness can be used where the thickness can be generally range from about 0.0004 to 0.0015 inch.
The aforementioned conductive pattern6 18 are encapsulated with a glass ceramic mixture or a ceramic insulating material such as alumina or spinal. This encapsulation insulates the pathways and can 20 range from a total encapsulation to encapsulation except at the end of the metallic pattern.
The encapsulation of the metallic patterns can range from encapsulating each from the other to a sufficient degree for electrical insulation of the conductive patterns and any conductive 25 layer~ from each other. As shown in Figure 1, the encapsulant can extend across the whole board from edge to edge as generally shown at numeral 14. Preferably, the thickness of the encapsulant layer is ~ that which is adequate to seal the underlining metallic layer and to provide insulation for the metallic patterns. Preferably, the 30 thicknes8 of the layer is around 20 to around 30 microns. Preferably, W O 93/l34ll ~ ~ ~ 6 S S S PC~r/US92/11286 _ the glass composltion for the encapsulant as with the substrate 11 is selected to possess good chemical stability and/or moisture resistance. Also, the metallic and encapsulant materials are selected so that they can endure the presence of an electrolyte in a similar 5 manner as the substrate composition. A most preferred glass ceramic mixture useful as the encap~ulant is the type produced and available from Electro-Science Laboratories, Inc. under the trade designation ESL 4903.
As can best be seen in Figures 1 and 2, the substrate 11 is 10 provided with a number of electrodes, 32, 34, 36, and 38, and more particularly, electrodes useful in the measurement of a fluid analyte that is 601uble or dissociates in liquid, for in6tance water, to influence the pH of the liquid. A suitable example is carbon dioxide in a fluid like blood in the measurement of blood gase6. Other 15 analytes include those that are water soluble or dissociate in water snd upon solubllization or dissociation influence the pH of water in a me~surable manner. Nonexclusive examples of such analytes include:
carbon dioxide, ammonia, sulfur dioxide, nitric oxide, and halides like chlorine, bromine, and iodine, and acids which do not dissolve in 20 water to form a hydrogen ion but which have more than a certain degree of vapor pressure, like acetic acid, ammonia gas. This a~60ciation of analytes with the pH is hereinafter referred to as coupled analytes.
The aforementioned electrodes 32, 34, 36, and 38 are preferably produced by one of the layered circuit technique6. This 25 involves leaving the respective shaped end6 uncovered while the rest of the metallic patterns are completely covered by the encapsulant.
The conductors 40, 42, and 44 of Figure 1 and in addition 46 of Figure 2 may be masked during the encap6ulation to keep them suitably uncovered by the encapsulant for the addition of active materials 30 (e.g. electrolytes and polymeric membranes) to produce the electrodes ~ ~ 93/13411 212 6 5 5 ~ PC~r/US92/11286 on the surface of the substrate layer ll. This process involves masking the electrodes by the use of a polymer film coating on the screen used to screen print the encapsulant. This leaves the underlying silver exposed to form the conducting portion of the 5 analyte and reference electrodes and the conducting pattern 18 on the substrate ll. It is also possible to use multiple layers of the metalllc conductive layer and/or encapsulant, and the outer layer of the encapsulant may be solvent or thermoplastically bondable and may include polymers, as for example, acrylates or polyvinyl chloride as lO the major component in the encapsulant. The purpose of the outer coating or encapsulant is to enhance bonding of the active materials and, in particular, to provide a reliable surface for the attachment of the liquid or solid film type membrane materials. The geometry of the several electrodes could be made by a laser beam to carve or cut 15 or trim the electrode; however, they are preferably prepared by the aforementioned layered circuit technique.
Each of the analyte electrodes are fabricated with electrolyte and membranes to perform their specific task and may be selected from many commercially available electrode components. The 20 two analyte electrodes 32 and 34 on the substrate ll in Figures l and 2 are prepared to maximize the electronic response from one of the analytes to be measured over the other. Either one or both of the membrane 48 and electrolyte 50 for electrode 32 are constructed to favor to some degree the conversion of the ionic potential of one 25 analyte to an electronic response for the electrode. Membrane materials known to those skilled in the art are selected to enhance the permeability of the one analyte over the other and/or electrolyte materials known to those skilled in the art are selected in favor of the one analyte over the other. For the latter the electrolyte can be 30 buffered to minimize the ionic potential of the other analyte while W O 93/13411 - P ~ /US92/11286 ?,~?,6S~
the desired analyte's ionic potentisl i6 favored. The membrane 52 and/or electrolyte 54 for electrode 34 can be selected in a similar manner to favor the conversion of the ionic potential to electronic potential for the analyte not favored by electrode 32.
In the preferred embodiment of the present invention in accordance with both Figures 1 and 2, one electrode, for instance, 32 is a pH electrode and the other electrode 34 i8 a C02 electrode. Each electrode i6 fabricated with a membrane which maintains their respective electrolytes in a fluid tight manner in the cavities or 10 openings in which the electrodes are positioned. The pH electrode 32 and the C02 electrode 34 may be similar in regards to the circuit geometry and electrolyte and may be provided with membranes suitable for the particular characteristic being measured.
Electrode 32, preferably, a pH measuring electrode, has an 15 electrolyte 50 in contact with the conductor 40. The electrolyte preferably has an acidic pH in the range of around 3 to around 4. A
suitable acid electrolyte is an aqueous 601ution of potassium hydrophosphate (KH2P04). A most suitable and preferred aqueous electrolyte is one from 13.6 grams of potas6ium hydrophosphate in one 20 liter of deionized water. Preferably, the membrane for the pH
electrode is a polyvinylchloride polymer, which is plasticized, and has the ionophore and the anion blocker. This membrane is prepared as the dried residue of a solution having the polyvinylchloride polymer which is a very high molecular weight polymer having a molecular 25 weight in the range of around 10,000 to around 500,000 weight average molecular weight. Preferably, the plasticizers are o-nitrophenyl octyl ether (NPOE) and bis-(ethylhexyl)adipate or di-2-ethylhexyladipate (BEHA) and the ionophore tridodecylamine and the potassium tetrakis chlorophenylborate (KTClPB) anion blocker in 30 the cyclohexanone solvent. The use of the very high molecular 93/13411 P ~ /US92/11286 polyvinylchloride polymer reduces the permeability of the membrane to carbon dioxide. The acidic electrolyte suppresses the reaction of the carbon dioxide and water to minimize the extent to which the carbon dioxide changes the pH. This favors the electronic response for the 5 pH measurement since the carbon dioxide produces little electronic response.
Electrode 34, which is preferably a carbon dioxide electrode, can have a membrane that is fabricated from a wide range of commercially available carbon dioxide permeable polymeric materials.
10 As with the pH electrode, the electrolytes of the C02 electrode 34 is bound by its respective membrane. The electrolyte for the carbon dioxide sen~or is initially at an alkaline pH in the range of greater than 7 to 14 and most preferably at a pH of around 8 with the presence of bicarbonate ions. A suitable formulation for the electrolyte is 15 0.02 moles of sodium bicarbonate in a liter of deionized water. The membrane for the carbon dioxide electrode holds the electrolyte in contact with the conductor; preferably, the membrane is water vapor porous and is made of a high molecular weight polyvinylchloride polymer that is plasticized and has the ionophore, tridodecylamine, in 20 an organic solvent. A suitable membrane i8 produced from a polyvinylchloride powder which i8 a high molecular weight having a weight average molecular weight in the range of 10,000 to 500,000.
Although this is the same range as for the pH electrode the molecular weight for the carbon dioxide electrode is lower than that for the pH
25 electrode. The lower molecular weight polyvinylchloride membrane allows transport of the carbon dioxide through the membrane since it is more permeable to carbon dioxide. This PVC is plagticized with ~ NPOE and BEHA in nitrobenzene with the presence of the ionophore.
Preferably, KTCLPB is the anion blocker and cyclohexanone is solvent.
30 The membrane most preferably is formed of the dried residue of the W O 93/1341l ~ P ~ /US92/11286 ~,~26~S ~) '~
601ution that has the following percentages by weight, high molecular weight, polyvinylchloride around 5, NPOE around 5, BEHA around 5, nitrobenzene around 5, tridodecylamine 1.78, pota6sium tetrakis (4-chlorophenyl) borate 0.9, and 76 cyclohexanone solvent. The carbon 5 dioxide di6601ves in the aqueous electrolyte and the pH changes so that the ionic potential of the electrolyte changes and this is converted at the conductor of the electrolyte to an electronic potential.
Although the aforedescribed pH and carbon dioxide electrodes 10 were described as hydrated electrodes in that the electrolyte was an aqueous solution, the electrolyte can be a dried material or a gelled electrolyte. The dried electrolyte would require hydration prior to u6e through the membrane which i6 permeable to at lea6t water vapor.
In addition to the electrodes, other polymeric materials, 15 plasticizer6, ionophore6, anion blocker6 and sol~ents can be used which are known to those 6killed in the art. The material8 8hould be used with electrolytes that favor ~~ Izing the response of one analyte over the other for one electrode while ~ 1zing the respon6e for the other analyte in the other electrode. Nonexclu6ive examples 20 of polymer6 for membranes that are permeable to carbon dioxide and other gases that are 601uble in water and water vapor include cellulose acetate, polybi6phenol-A carbonate (polysiloxane/poly(bisphenol-A carbonate) blocked copolymer;
poly(methylmethacrylate), poly(vinylidene chloride), polystyrene, 25 lower alkyl acrylate and methacrylate copolymers and polymers, polyurethane, and 6ilicone rubber. Other suitable pla6ticizer6 are tho6e like dioctyl adipate, tri(2-ethylhexyl) phosphate, dibutyl 6ebacate, diphenyl ether, dinonyl phthalate, dipenyl phthalate, di-2-nitrophenyl ether, glycerol triacetate, tributyl phosphate and 30 dioctyl phenyl phosphate. An additional ionophore that can be used 2126~5 '~0 93/l341l P ~ /US92/11286 for hydrogen ion i8 trioctyl amine and for bicarbonate or total carbon dioxide quaternary ammonium ion exchanger p-octodecyloxy-m-hlorophenyl-hydrazone-mesaoxalonitrile (ocph). Where the analyte is ammonia, the ionophore can be nonacetine; where the analyte is nitrous 5 oxide, the ionophore can be tridodecylhexadecylammonium nitrate plus normal octyl-o-nitrophenyl and other ionophores known for a specific analyte as known by those skilled in the art. A1BO~ other polymers useful for forming membranes for hydrated electrodes are cation permeable and particularly hydrogen ion permeable membranes such as 10 cationic exchange materials like copolymeric vinyl ethers as manufactured by E.I. duPont under registered trademark NAFION. Also other suitable hydrophillic polymers that can be used with solid electrolytes include- polyvinylalcohol, polyethylene oxides, polyethylene oxide ethers and various polysaccarides. Other examples 15 of suitable solvents include: tetrahydrofuran (THF) and dimethylformamide (DMF).
The reference electrode 36 of Figure 1 and 37 and 38 of Figure 2 have conductor 56, 58, and 60, respectively. For this electrode, the electrolyte is present with or without a membrane and 20 preferably without a membrane. The electrolyte can be i8 a storage, hydrating or calibrating solution which is a salt solution. The electrolyte for the reference electrode is basically a 6alt-bridge layer that acts as a source for a constant concentration of the measured ion species. This salt-bridge serve6 as an ion bridge 25 between an analyte-cont~;ning solution and the reference electrode.
It consists of small amounts of appropriate electrolytes dissolved in a water permeable hydrophillic polymer or water by itself.
Additionally, other reference electrodes can be used which are in fluid contact with the analyte electrodes and suitable examples of 30 such reference electrodes include that of U.S. Patent Nos. 4,706,678 WO 93/13411 PCI'/US92/11286 6~'j 16-and 3,705,089, hereby incorporated by reference for their disclosure of reference electrodes.
As shown in Figure lb, which is a view of the opposite side from Figure la where the substrate is flipped 180~ about its 5 longitudinal axis, the patterned metallic layer 12 has metallic external leads 26, 28, and 30 on the other side of the sub6trate 11.
Preferably, there is one external lead for each conducting pathway 20, 22, 24. Although the external lead~ are shown on the opposite side of the 6ubstrate 11, they can also be on the same side or surface as 10 their associated metallic lead patterns and components. External lead~ 26, 28, and 30 are conductively a6sociated with the components on the Figure la side of the substrate layer 11 through conductive holes 62, 64 and 66.
These holes may be drilled by a laser through the 15 substrate 12 to conductively connect the conducting pathways 20, 22, and 24 traced on the Figure la side of the substrate layer 11 with their respective metallic external leads 26, 28, 30 on the Figure lb side of the substrate layer 11. In general, these holes are produced by the focused laser beam drilling a hole by heating a small volume of 20 material to a sufficiently high temperature for localized melting and/or vaporization. The holes can be drilled through the substrate layer 12 and when the metallic layers are screened such electrical connections are formed. Alternatively, the holes can be produced and preferably are produced by a very high powered carbon dioxide laser.
25 This can be accomplished by the supplier of the nonconducting substrate and in this case the metallic layer is added to the sub6trate 60 each conducting pathway electrically connects with an external lead.
The external leads 26, 28, 30 may be produced on the other 30 side of the substrate layer 11 with the same paste and firing as that , 21265~
93/13411 P ~ /US92/11286 done for aforementioned metallic patterns. The metallic external leads 26, 28, and 30 are in metallic electrical conducting contact with the various components on each side of the substrate 11.
External lead 26 is in metallic electrical conducting contact with the 5 pH sensing electrode 32; external lead 28 is in metallic electrical conducting contact with the C02 sen6ing electrode 34; external lead 30 is in metallic electrical conducting contact with one reference electrode 36 in Figure 1 or two reference electrodes 37 and 38 in Figure 2, which are located at the end of- pathway 22.
The two analyte electrodes 32 and 34 and the one or more reference electrodes 36 and 37 and 38 are in 6paced apart relation to each other and their conductors are insulated from each other but they are in a liquid junction electrical connection with each other. The membranes for at lea6t the analyte electrodes and the electrolyte and 15 any membrane that may be present in the reference electrode are in fluid contact with the fluid in the fluid circuit means 68 in Figure 3. To as6i6t in this liquid junction contact and electrical insulation of the electrical circuit pattern 18, the arrangement of the electrode6 can exi6t in a variety of patterns on 6ub6trate 11. A
20 preferred arrangement is that of Figures 1 and 2 where the pH
electrode 32 is located st the end of extension 20; the other analyte sensing electrode 34 is located at the end of extension 22; and the one or more reference electrodes 36 in Figure 1 and 37 and 38 in Figure 2 are located at the end of exten6ion 22. A8 noted in 25 Figures 1 and 2, the two analyte 6ensor6 32 and 34 are axially aligned along a longitudinal axis of the substrate 11. The one or more reference electrodes are located off of this axial alignment but can be located anywhere else on the sub6trate 11. This longitudinal axial alignment for the analyte electrodes 32 and 34 are for the preferred 30 u6e of the 6ensor apparatus of the pre6ent invention. The preferred 1 .
A
~ 93/~3411 PCI'~US92/11286 5 ~ 5 use is in a portable blood gas analyzer as further described in cases assigned to the same assignee as the present application, U.S. Patent 5,284,570, issued 8 February 1994 and 5 WO 93/00582 published 7 January 1993 Alternatively, the sensor apparatus of the present lnventio~
if used in a different environment or device, the analyte electrodes 32 and 34 and reference electrodes 36 or 37 and 38 as ln Flgure 2 could be positioned differently on the substrate 11. For in6 tance, 10 when the sensor apparatus of the present invention is utilized in a stationary device with 6amples inserted on a card or carrier to contact the electrodes the electrodes csn be located anywhere on the 6ubstrate to match the location of the sample on the coupon or card.
Their arrangement could even be in a stralght line and the fluid 15 circuit flow pattern might allow for a different fluld to be in contact wlth the one or more reference electrodes than wlth the two or more analyte electrodes.
Also shown in Figure 2b, which is the reverse side of substrate 11, is heater 68 that is used in the preferred embodiment of 20 the present invention to measure the concentration of the analyte at a temperature above room temperature. For example, when the fluid to be measured 18 blood or another bodily fluid, the elevated temperature i~
the normal body temperature of the vertebrate animal from which the blood was obtained. For control of heater 68, it ls preferred to have 25 present a thermistor 70 and resistor 72 arrangement as 6hown in Figures 2 and 2b. Thi6 arrangement makes it possible to indicate the temperature at any time on substrate 11 although it is also posslble to have the heater, thermlstor and resistor on the substrate of Figures 1 and lb ln a similar manner as in Figures 2 and 2b.
,~
21~6~S~
'~ ~ 93/13411 ~ PC~r/US92/11286 -External leads 78 and 80 are in metallic electrical conducting contact with the heater 68 which is preferably a thick film heater provided on the Figure 2b side of the sub6trate layer 11. The heater 68 can traver6e the board in a serpentine fashion. External 5 leads 82 and 84 are in metallic electrical conducting contact with a resistor 72 which is also provided on the Figure 2b side of the substrate 11. The resistor 72 is in a half-bridge relationship with the thermistor 70 and, as such, it commonly shares external lead 82 with the thermistor 70, thermistor 70 also being in metallic 10 electrical conducting contact with external lead 82. The function of the thermistor 70 and resistor 72 arrangement will be described below.
The serpentine formed heater 68 and the resistor 72 on the Figure 2b side of the substrate 11 may be prepared by a number of commercially available techniques, however, they are preferably thick 15 film device6 prepared by the aforementioned layered circuit technique.
As before mentioned, external leads 78 and 80 are in metallic electrical conducting contact with the heater 72 and external leads 82 and 84 are in metallic electrical conducting contact with a 20 resistor 72 which commonly shares external lead 82 with the the- ;stor 70; thermistor 70 also being in metallic electrical conducting contact with external lead 64.
Thermistor 70 is located at the end of conducting pathways 74 and 76, and is preferably a thick film thermally sensitive resistor 25 whose conductivity varies with the changes in temperature. The thermistor 70 may be fabricated from a number of semi-conductive materials as, for example, oxides of metals. The the ~stor may be formed and applied to the substrate 11 by the use of the aforementioned layered technique. The temperature coefficient of the 30 the_ {~tor 70 preferrably is large and negative and is used to sense W O 93/13411 9 ~26~ P ~ /US92/11286 the temperature of the substrate ll at all times when the sub6trate 11 is electrically connected Vi8 electric circuitry 16 to a power source and the analyzing means of Figure 4. Thermistor 70 is operated at relatively low current levels 80 the resistance is affected only by 5 the ambient temperature and not by the applied current.
The half-bridge circuit configuration involving resistor 72 preferably is a voltage divider and generates a ratiometric output to the analyzing means of Figure 4. Thi6 is important for it allows the actual resi6tance values to float and results in highly consistent and 10 accurate temperature sensing and control of the substrate 11 on a substrate-to-substrate basis. Accuracy and consistency of the resistor 72 and thermistor 70 arrangement is preferably achieved by calibrating the substrate 11 with conductive patterns by laser trimming of the re6istor 72 to produce zero volts at 37~C. The la6er 15 beam i8 precisely deflected across the thick film resistor 72 to produce the desired temperature voltage relationship. A current is applied at external leads 82 and 86 by the analysis means of Figure 4 with a power source until zero volts is achieved. This gives a linear output so that the temperatures can be mea6ured other than 37~C from 20 the slope of the line from the calibration at room temperature and 37~C. The resistor 72 has essentially zero temperature coefficient and, accordingly, may be placed without any adverse effect on the sen6ing capability of the associated thermistor 70 on the Figure 2b side of the substrate 11 with the heater 68.
Accurate sensing of the ambient temperature of the substrate 11 is required to precisely control the heater 74 to ultimately maintain, within a narrow distribution of temperatures, the desired operating surface temperature on the Figure 1 or Figure 2 sensor side of the substrate 11.
.
'0 93/13411 2 ~ 2 ~ 5 S 7 PC~r/US92/1~286 Placement of the thermistor 70 is another important aspect of the present invention. As can be seen in Figure 2, the thermistor 70 is placed in the same plane and in close relation to the electrodes 3Z, 34, 37 and 38 to thereby accurately sense the ambient temperature 5 at or near such sensors. This physical placement of the thermistor 70 allows for the rapid adjustment of the heater 68 by the analysis means of Figure 4 with a power supply to maintain the de6ired operating temperature. The thermistor 70 and resistor 72 arrangement can provide temperature measurement accuracy of within 25~C. This 10 physical placement of the thermistor 70, 80 close to the electrodes, requires that it be correctly fabricated to ensure that it is electrically isolated from the electrolytes of the several electrodes. The encapsulant for the thermistor 70 should be thick enough to accomplish the electrical isolation, yet thin enough 80 as 15 not to lose any response time.
The heater 68, provided on the Figure 2b side of the substrate 11, rapidly and accurately produces the necessary heat in response to any temperature change sensed by the thermistor 70; the thermistor 70 and the several electrodes preferably all being in the 20 heated region produced by the heater 68. Thick film heaters are not generally considered to be rapid response devices and their heat output tends to take a relatively long time, in terms of electronic devices, to change. To improve the responsiveness of the heater 68, it can be powered by pulsed DC 80 that the heater ls continually 25 turned on and off by the analyzing means with power supply of Figure 4. This not only increases the responsiveness of the heater 68 but also allows for better overall thermal control including avoiding the heater 68 from overshooting or undershooting the desired temperature.
6 ~ S ~ - 22 -Whatever the arrangement of the electrodes on substrate 11, their arrangement is matched by a fluid pattern 86 which may be flow through or non-flow-through design. A suitable flow-through design, which is preferred, is shown in Figure 3. The one or more fluids are 5 continuou6 in the pattern to provide the liquid junction between the electrodes for electrical conductivity. Preferably, the fluid pattern 86 is occupied by at least two different fluids. Preferably, a storage fluid is in contact with the reference electrodes 36 in Figure 1 or 37 and 38 in Figure 2 while the fluid pattern 86 allows 10 for contact of a storage fluid, hydrating fluid, if needed, calibrating fluid, and sample fluid for the analyte electrode6 32 and 34.
Figure 3 shows a suitable cover 88 having one section to enclose or surround the substrate 11 with electrodes 32, 34, 36 and, 15 in Figure 2, 37 and 38 and conductive pattern 18. The cover 88 can be made of any fairly rigid moldable material such as rigid thermoplastic polymers although thermosetting polymers can also be used. A suitable example is a methyl methacrylate styrene butadiene terpolymer and rigid pla6tics such as polyesters like polyethyleneterephthlate or 20 polycarbonate or blends or alloys thereof and other similar materials known to tho6e skilled in the art. The cover 88 can be any basic geometric shape 6uitable for containing a channel 90 and substrate 11. The number of parts or sections comprising the cover can range from 1 to a plurality but two parts are preferred. A single part 25 cover as shown in Figure 3 has the substrate 11 forming one side like a backing to the cover 88 when the substrate 11 is positioned in the cover 88. Another possibility is for the cover 88 to have a fir6t and second opposing sections where one section is the cover section and the second section is a back section. Each section has an exterior 21~55~S
~vo 93/134ll PCI'/US92/11286 w and interior surface and when both 6ections are matchet together, they completely encase the substrate 11.
The cover 88 by itself when the substrate 11 is the backing or the two sections of the cover when matched together form an 5 interior space 92. Space 92 need not be of any particular geometric configuration just 80 long as substrate 11 fits into the space. The internal space 92 and substrate 11 are preferably of matched configuration and are preferably generally rectangular. Preferably, when the cover 88 has two sections, the t~p section with the fluid 10 circuit pattern 86 comprises a substantial portion of the cover 88 as shown in Figure 3 and the other is a backing for substrate 11. With this arrangement and with the internal space 92 having dimensions that closely match those of the substrate 11 for a snug fit of the latter into the former, and both sections can assist in providing electrical 15 isolation between any fluid in the channel 90 and the electric circuit means 16. The former is at least in fluid pattern 86 and the latter is on substrate 11. This reduces the risk of leakage current or short circuiting of the conductive patterns 18 of the electrical circuitry means 16.
The cover 88 can be adhesively connected to a back, i.e. the substrate 11 or a backing for the substrate (not shown) to improve their attachment to each other through connection means 94. The cover 88 also can allow for communication from the conductive patterns 18 to an electrical connection mean6 96 which electrically connects the 25 conductive patterns 18 to the analysis means shown in Figure 4. The electrical connection means 96 in conjunction with the conductive patterns 18 comprise the electrical circuitry means 16.
Cover 88 in conjunction with the substrate 11 provides for at least one channel 90 to pass over at least one analyte electrode on 30 substrate 11 and for any other channels to interconnect. Channel 90 2 ~ ? P ~ /US92/11286 i8 constructed to have any shape that allows for fluid flow to, over, and from the one or more electrodes and to allow for ingress and egress of fluid from the channel. The channel 90 can have two opposing openings to allow fluid flow through the channel from a 5 receiving opening 98 to an exit opening 100, where the former is before and the latter after the electrodes. The receiving opening 98 can be suitable for attachment to a sample receiving means (not shown) and the exit opening 100 can be suitable for attachment to a collection means (not shown) such as a syringe or reservoir in 10 general. Also, when the channel 90 is flow through and contains a fluid for storage or preconditioning, the opening6 98 and 100 can be sealed by a substantially moisture impervious seal 102 and 104, respectively. The openings 98 and 100 can serve as an inlet to or outlet from cover 88 that is preferably formed by conical tips 15 preferably aligned in the same plane and along the same axis at opposite ends of the channel 90. In this arrangement channel 90 passes longitudinally over the substrate 11. The interlor space 92 of the covering communicates with the one or more channels to contain the substrate 11 so that the electrodes that are on the substrate are so 20 disposed to lie in the path of the channel for fluid contact. The 1~ -;n;ng portions of the channel 90 and any other channels are formed by substrate 11 occupying the internal space 92 so that the surface of substrate 11 with one or more electrodes actually forms a wall of the channel 90.
Seals 102 and 104 can have one or more surfaces where at least one surface is substantially a non-oxidizing metal such as aluminum that is useful with an adhesive-type polymer. The adhesive-type polymer can be used either as an application to the surface to be sealed or as another surface of the seal. The seal is 2 1 2 6 5 ~ ~ PCT/US92/11286 -fixedly attached to the housing by a chemical means and/or by a mechanical means.
Preferably, the cover 88 in conjunction with the substrate 11 provides for a plurality of channels. The number of channels for 5 the fluid pattern 86 is sufficient that the analyte electrodes 32 and 34 are on one or more channels that are separate from the one or more channels for the one or more reference electrodes. This arrangement allows the reference electrodes as 36 and, for Figure 2, 37 and 38 to have a different fluid in contact with them than the fluid in contact 10 with the analyte electrodes 32 and 34. The fluid in contact with the reference electrodes can be a calibrating or hydrating fluid while a sample fluid is in contact with the analyte electrodes 32 and 34.
With connecting channel sections 106 and 108 connecting side channels 110 and 112, respectively, with channel 90, the one or more reference 15 electrodes of Figures 1 and 2, respectively, can be off the axial alignment with the analyte electrodes 32 and 34 and still be in liquid junction contact with them through the fluid circuit 86. The substrate 11 of Figures 1 and 2 can be po6itioned in the cover 88 so that the a reference electrode is in fluid contact with the fluid in 20 one or both of the side channel 110 and 112. Concomitantly, the analyte electrodes 32 and 34 are in fluid contact with the fluid in channel 90. In an alternative embodiment, only channel 90 i8 present and all of the electrodes both analyte and reference contact the fluid in the channel 90.
The fluid occupying the portion or portions of the channel 90 or channels 90, 110 and 112 over the one or more electrodes can be a storage, hydrating or calibrant fluid. A storage fluid can range from air for electrodes with dried electrolyte to a liquid that has some amount of water although a minor quantity of organic liquids may 30 also be present. Preferably, the fluid is a stable liquid for storage U )3/13411 2 ~ 5 ~ i PCT/US92/1l286 ranging from a ~hort time (days or weeks) to prolonged periods of time of several months. Preferably, the fluid that occupies the fluid circuit 86 is an aqueous solution that i8 isotonic with any electrolyte in the one or more electrodes. More preferably, the fluid 5 of the fluid circuit 86 in Figure 3 can be a hydrating fluid that is also isotonic. Then the fluid can act as the electrolyte for any reference electrodes on the substrate ll that do not have a membrane.
The hydration fluid can be one that i8 added to hydrate 6clid or dried electrolyte in the electrodes or, preferably, to maintain the hydrated 10 electrolyte in the electrodes. The hydrating fluid i8 chiefly an aqueous fluid with an effective composition to hytrate at least to a partlal degree but better to a 6ubstantial degree the hydrophillc polymeric membrane6. A suitable example of a hydrating fluid i6 an aqueous solution comprising: disodium hydrogen phosphate, potsssium 15 dihydrogen phosphate, sodium bicarbonate, and sodium chloride. Such a solution can have a varying range of amounts for the individual constituents but most preferably for the aforelisted salt~ the amoun~s are in millimole9 per kilogram of water in the order listed as follows: 4.8, 13, 22, and 12.5. The quantity of hydrating fluld in 20 channel 90 or the plurality of channels i6 at lea~t that which is sufficient to co~er or remain in contact wlth the one or more electrodes. This arrangement is more fully shown in the WO 93/00582 published 7 January 1993.
Any arrangement or configuration other than that 6hown in 5 Figure-3 can be used that allow the two sections to engage and form cover 88 with one or more internal 8paces for placement of substrate 11 so that the electrodes are in fluid contact with any fluid 114 that is in the one or more channels. Other suitable arrangements include ~ ~1 2 ~
~WO 93/13411 PCT/US92/1128fi those described in European patent applications 0306158 and 0351516 and U.S.PatentNo.4,818,361.
Figure 4 shows the preferred electrical connection of the analyzing means 116 through t~e electric circuit means 16 to substrate 11. Electrical connections 118, 120, lZ2 and 124 are apart of the electric circult means 16 and electr~cally connect with the appropriate external leads of the substrate 11. Preferably, connections 118, 120, 122 and 124 are part of one ribbon-type cable connecting the analyzing means 116 as a module to the external leads 10 of the substrate through any electrical attachment means known to those ~killed in the art. In such a ribbon cable, connections 118, 120 and 122 would be indlvidual wires in the cable and connection 124 would be comprlsed of several individual wires ln the cable.
Connection 174 would include wiring for any power supplied to the 15 substrate 11 or, heater 68, or thermistor 70 or resi6tor 72 or any other electrical components on the substrate 11. Al~o connection 124 could include wiring for conveying any additional electronic potentials from additional electrodes on the substrate 11 like an oxygen sensor which is preferably present and can generally be any 20 oxygen microsensor known to those 6killed in the art.
It is also pre~erred that the pH and C02 electrodes and the sen60r apparatus of the present invention is u~ed in conjunct~on with an oxy~en electrode and sen~or and the mea~s 116 is capable of receiving input from these electrodes and reference electrodes for 25 them and outputtlng dsta for p~, C02 and oxygen. The combination of the pH and C02 along with the oxygen sensing is as described further in cases cornmonly assigned to the same assignee as the subject patent application, WO 93/00582 published 7 January 1993, and U.S. Patent 5,246,576 issued 21 September 1993.
W O 93/13411 P(~r/VS92~11286 _ 2 i ~ 6 ~ 5 S - 28 -In Figure 4 the electronic signal from one of the analyte electrodes, for example electrode 32, is conveyed by the electronic pathway 20 of Figure 1 to the lead 26 of Figure lb to electrical connection 120 and to amplifier 134. Likewise, the signal for the 5 other analyte electrode 34 is conveyed by pathway 24 to lead 30 to connection 118 and to amplifier 136. Also, the electrical signal from the one or more reference electrodes of the substrate 11 of Figures l or 2 is conveyed by pathway 22 to lead 28 to connection 122 to amplifier 138. The other connection for the amplifiers can go to 10 ground 132 through connections 126, 128, and 130. The amplifiers can be any amplifying electronic component known to those 6killed in the art and can actually be and preferably is apart of the analog input processing function of the analyzing means 116 rather than di6crete components. The amplifiers are shown in Figure 4 as discrete 15 components mostly for illustrative purposes.
The analyzing means 116 receives separate electrical signals from the two analyte electrodes and the one or more reference electrodes, for example as depicted in Figure 4 as signals 140, 142 and 144. The analyzing means 116 can be as simple as a voltmeter and 20 calculating device or an electronic circuit board with suitable electronic components to perform the functions of analog input processing, analog to digital conversion, programmed microprocessing, and a date/time circuit and battery backup random access memory, and a power supply. In the preferred embodiment, analyzing means 116 also 25 has the capability of battery power supply in addition to standard wall socket power supply. Preferably, the analyzing means is a self-contained, hand-held, preferably battery powered monitoring instrument or analyzer to process the signals and displays the information in a digital or paper mode to the operator. Also 30 preferably in means 116, the analog input processing unit interfaces ___,J93/134ll 2 1 ~ 6 ~ ~ 5 PC~r/US92/11286 with a 12 bit analog to a digital converter which itself interfaces with an 8 bit programmed microprocessor. The proce6sor accesses the date/time circuit and battery backup random access memory. Means 116 is electrically connected by connection 146 to a display device 148 5 that can be a digital or analog display with or without but preferably with a printer. Also means 116 preferably has a battery and charger a6sembly that provides battery power. Although a particular arrangement for the functional units of the means 116 has been specifically set forth, variations are possible that may delete one or 10 more of the functional units. As long as the processing, memory, and converter are present when analog signals are used, and the processor is functionally tied into these units and power is supplied, a read out can be obtained.
Means 116 can be prog~~ -d in any language known to those 15 skilled in the art like "C" where the program can reside on a floppy disk when means 116 has a floppy drive or and preferably can reside in firmware like a PROM or ~PROM. The program allows means 116 to give two analyte concentration values from the electronic signals. The program takes the electronic response of the analyte electrodes 20 compared to the reference electrodes along with sensitivities of the analyte electrodes and initial readings on fluids with known values of analytes to determine the unknown analyte values. The determination is according to relationships derived from the Nernst and Henderson-Hasselbalch equations. With the known analyte value, like 25 that for carbon dioxide in a calibrating fluid, the analyte electrodes, like carbon dioxide and pH electrodes, can be calibrated.
Both of the8e electrodes have a certain 8en8itivity in millivolts per millimeters of mercury for carbon dioxide tension. This is determined via a statistical process by measuring many samples which are compared 30 against the sensor being checked. Means 116 checks or predicts the i ~ 6 ~ S S - 30 _ millivolt change from the millivolts measured for the one or more calibrant fluids and this change should be within the statistical range of acceptable values or the sensitivity of the sensor i6 not within specifications. This tests the sensitivity of the electrodes 5 to determine if they are accurate.
The program takes the data and the aforementioned relationships and utilizes them as illustrated in Figure 5 and Table l to give data for the analysis of the preferred embodiment of the present invention. Preferably, carbon dioxide and the pH of a blood lO sample is measured. In Figure 5, "A" indicates the millivolts per second for the pH sensor and "B" indicates the millivolts per second for the carbon dioxide sensor. Time period "C" indicates the calibration period during which time a calibration fluid with known values of pH and carbon dioxide are presented to the two analyte 15 electrodes, one for carbon dioxide and one for pH, on the substrate ll like that of Figures l, lb or 2 and 2b. Preferably, the measu~ ~rt is taken at a temperature comparable to body temperature and the heater and thermistor and resi6tor arrangement of the substrate ll control this temperature.
In Figure 5, point "D" and point "E" indicate the initial values for the pH and carbon dioxide, respectively. These values are recorded for later use. At point "F" in Figure S, the sample of blood i6 in the fluid circuit in contact with the analyte electrodes.
Points "G" and "H" indicate the final values for the pH and carbon 25 dioxide, respectively. These final values are also recorded.
Table l 6hows the calibrant values and the sample values at points "D", "E", "F" and "G" and also show6 the calculated values from the formulas for the blood sample.
The time line for the analysis cycle shown in Figure 5 30 includes connecting the substrate with electrodes to the analyzing ~ ~93/13411 2 1 ~ 6 ~ 5 ~ PCT/US92/11286 _ .
means 116 as the aforedescribed a progL ~d computer means and within about five seconds taking the pH and carbon dioxide millivolt readings for the 6torage fluid. After a period of time greater than 15 second~, a calibration fluid is pa6sed over the analyte electrode~.
5 Twenty-four seconds after the calibration fluid contacts the electrodes, the calibration pH and carbon dioxide millivolt reading6 are taken at room temperature. A second later the sensor is heated by the heater 68 on the substrate 11 and for about 10 seconds the thermistor stabilizes and the calibrant pH and the carbon dioxide 10 millivolt readings are taken. Within a second or so the blood sample contacts the analyte electrodes and the thermistor stabilizes over a short period of time (in seconds) and the pH and carbon dioxide millivolt readings are taken for the blood sample within 60 seconds from the blood contacting the analyte electrodes.
W 0 93/13411 PC~r/us92/ll286 ,.265~s ,~
Calibrant Blood Calibr~nt SamDle V~lues V~luec pH 6 6 mV -13 0 mV 7 185 7 470 C~2 -17 3 mV -27 7 mV 57,3 36 3 Pcak ~ 17 022, 7 724) ,:
C~2 ~ S0 59 Room Tempcr-ture ~ 23 06 Scnsor OX' mV COz ~ (C02f - C02~) ~ (-27 7 - (-17 3)) ~ -10 4 mV
mV pH ~ (pHf - pHI) ~ (-13 0 - 6 6) ~ -19 6 mV
C02f ~ C02~ * lOt -(SENrC021rDHl~(mVDH~ - ~SENrDHlrDHl~(mVC02~
-(SEN[C02]~pH])(SEN[pH]~C02]) + (SEN~pH]~pH])(sEN~co2]~co2]) ~ 36 3~ H8 pHf . -~VDH + SENrDHlrC021 * LOG Co2fLçQ2l + PHi n 7,470 -SEN~pH]~pH]
where SEN~pH]~C02] ~ ~ensltivlty of the pH electrote fa~oring the COz ~g anclyte SEN~pH~pH~ ~ scns~ti~ity of the pH electrote fa~orlng the H+ analyte for thc ~ccond analyte SEN~COz~pH~ ~ ~ens~tlvlty of the COz electrode fa~orin~ the H+
analytc SEN~C02~C02] ~ ~ensiti~ity of the C02 electrode favoring the C02 analyte f ~ final measurement i = lnitlal mecsurement
Claims (20)
1. A combined electrochemical sensor assembly for measuring coupled analytes, comprising:
a) means for holding the electrodes in space apart, insulated relationship and in electrical conducting contact with electrical circuitry for each electrode, when the means is a nonconducting substrate;
b) a first electrode mounted on the substrate for electrical connection to an external lead from the substrate and positioned to contact sample fluid, wherein the electrode has; a conductor electrically connected to electrical circuitry, an ion selective membrane selective for permeation by a first analyteof the coupled analytes and electrolyte that maximizes the electronic response of the first analyte and that minimizes the electronic response of the second analyte of the coupled analytes in converting the ionic potentials to electronic potentials and;
c) a second eletrode mounted on the substrate for electrical connection to an external lead from the substrate and in spaced apart relation to the first electrode and positioned to contact sample fluid, wherein the second electrode has; a conductor electrically connected to electrical circuitry, an ion selective membrane, and an electrolyte to maximize the electronic response of the other analyte in the coupled multi-analytes while minimizing the electronic response of the first analyte in the conversion of the ionic potentials of the multi-analytes to electronic potentials, wherein both electrodes give some electronic response for both analytes, wherein the membranes for each electrode have a first and second side and the membrane is positioned in the electrode for one side to be in contact with the electrolyte of that electrode and the other side available for exposure to analyte-containing fluids and calibration fluids for analysis and the membrane holds the electrolyte in contact with the electrodes and provides for entry of the analyte into the electrolyte;
d) reference electrode mounted on the substrate for electrical connection to an external lead from the substrate and in spaced apart relation to the first and second electrodes and positioned to contact the sample fluid;
e) electric circuitry on the substrate to electrically connect the electrodes to an external lead from the substrate for conveyance of electrical potentials and for electrical connection of the reference electrode to the first and second electrodes;
f) fluid circuit in liquid contact with the first, second and reference electrodes and insulated from the conductive pathways from the electrodes and from any external leads from the substrate;
g) analyzing means electrically connected to the external leads of the substrate to receive the electrical potentials from the electrodes and to calculate the numerical values from simultaneous equations as follows:
delta mVA1 = - SE1A1 x delta pH - SE1A2 x log A2f/A2i Equation 1 delta mVA2 = - SE1A2 x delta pH - SE2A2 x log A2f/A2i Equation 2 A2f = A2ix10n Equation 3 where n = + Ali Alf = Equation 4 where:
delta mV = change in millivolts A1 = first analyte A2 = second analyte E1 = electrode constructed to favor the first analyte E2 = electrode constructed to favor the second analyte SE1A1 = sensitivity of the electrode favoring the first analyte for the first analyte SE1A2 = sensitivity of the electrode favoring the first analyte for the second analyte SE2A1 = sensitivity of the electrode favoring the second analyte for the first analyte SE2A2 = sensitivity of the electrode favoring the second analyte for the second analyte f = final measurement i = initial measurement
a) means for holding the electrodes in space apart, insulated relationship and in electrical conducting contact with electrical circuitry for each electrode, when the means is a nonconducting substrate;
b) a first electrode mounted on the substrate for electrical connection to an external lead from the substrate and positioned to contact sample fluid, wherein the electrode has; a conductor electrically connected to electrical circuitry, an ion selective membrane selective for permeation by a first analyteof the coupled analytes and electrolyte that maximizes the electronic response of the first analyte and that minimizes the electronic response of the second analyte of the coupled analytes in converting the ionic potentials to electronic potentials and;
c) a second eletrode mounted on the substrate for electrical connection to an external lead from the substrate and in spaced apart relation to the first electrode and positioned to contact sample fluid, wherein the second electrode has; a conductor electrically connected to electrical circuitry, an ion selective membrane, and an electrolyte to maximize the electronic response of the other analyte in the coupled multi-analytes while minimizing the electronic response of the first analyte in the conversion of the ionic potentials of the multi-analytes to electronic potentials, wherein both electrodes give some electronic response for both analytes, wherein the membranes for each electrode have a first and second side and the membrane is positioned in the electrode for one side to be in contact with the electrolyte of that electrode and the other side available for exposure to analyte-containing fluids and calibration fluids for analysis and the membrane holds the electrolyte in contact with the electrodes and provides for entry of the analyte into the electrolyte;
d) reference electrode mounted on the substrate for electrical connection to an external lead from the substrate and in spaced apart relation to the first and second electrodes and positioned to contact the sample fluid;
e) electric circuitry on the substrate to electrically connect the electrodes to an external lead from the substrate for conveyance of electrical potentials and for electrical connection of the reference electrode to the first and second electrodes;
f) fluid circuit in liquid contact with the first, second and reference electrodes and insulated from the conductive pathways from the electrodes and from any external leads from the substrate;
g) analyzing means electrically connected to the external leads of the substrate to receive the electrical potentials from the electrodes and to calculate the numerical values from simultaneous equations as follows:
delta mVA1 = - SE1A1 x delta pH - SE1A2 x log A2f/A2i Equation 1 delta mVA2 = - SE1A2 x delta pH - SE2A2 x log A2f/A2i Equation 2 A2f = A2ix10n Equation 3 where n = + Ali Alf = Equation 4 where:
delta mV = change in millivolts A1 = first analyte A2 = second analyte E1 = electrode constructed to favor the first analyte E2 = electrode constructed to favor the second analyte SE1A1 = sensitivity of the electrode favoring the first analyte for the first analyte SE1A2 = sensitivity of the electrode favoring the first analyte for the second analyte SE2A1 = sensitivity of the electrode favoring the second analyte for the first analyte SE2A2 = sensitivity of the electrode favoring the second analyte for the second analyte f = final measurement i = initial measurement
2. The apparatus of Claim 1, wherein the first electrode and second electrodes have polymeric membranes from a gas permeable polymer having a molecular weight range in weight average molecular weight in the range of around 10,000 to around 500,000 but the membrane of one of the electrodes is from a polymer with a molecular weight lower than that for the membrane of the other electrode.
3. The apparatus of Claim 1, wherein the first electrode and second electrodes have polymeric membranes from a gas permeable polymer having a similar molecular weight of that in the range of weight average molecular weights of around 10,000 to around 500,000.
4. The apparatus of Claim 2, wherein the gas permeable polymeric membranes are selected from the group consisting of:
poly(vinylchloride), poly(bisphenol-A carbonate), cellulose acetate, poly(methylmethacrylate), poly(vinylidene chloride), polystyrene, polyurethane, block copolymers of polysiloxane/poly(bisphenol-A
carbonate), polymers and copolymers of lower alkyl acrylate and methacrylate, and silicone rubber.
poly(vinylchloride), poly(bisphenol-A carbonate), cellulose acetate, poly(methylmethacrylate), poly(vinylidene chloride), polystyrene, polyurethane, block copolymers of polysiloxane/poly(bisphenol-A
carbonate), polymers and copolymers of lower alkyl acrylate and methacrylate, and silicone rubber.
5. The apparatus of Claim 4, wherein the electrolytes are aqueous based.
6. The apparatus of Claim 1, wherein the first electrode has an electrolyte that favors the conversion of the ionic potential to electronic potential of one analyte over a second analyte while the second electrode has an electrolyte that favors the conversion of ionic potential to electronic potential for the second analyte over the first while both electrodes have sensitivities for both analytes.
7. The apparatus of Claim 1, wherein the analyzing means is a programmed computer means having the functions of analog input processing, analog to digital conversion, programmed microprocessing, and a date/time circuit and battery backup random access memory, and a power supply.
8. The combined pH and carbon dioxide sensor system, comprising:
a) nonconducting substrate suitable for carrying printed wiring circuits;
b) pH electrode mounted on the substrate for electrical connection to an external lead from the substrate and to contact sample fluid, wherein the electrode has an ion selective gas permeable polymeric membrane and an electrolyte to minimize the electronic response of the carbon dioxide while maximizing the electronic response for the hydrogen ion in converting ionic potentials to electronic potentials;
c) carbon dioxide electrode mounted on the substrate for electrical connection to an external lead from the substrate and in space apart relation to the pH electrode to contact sample fluid, wherein the electrode has an ion selective gas permeable polymeric membrane and an electrolyte to minimize the electronic response of the hydrogen ion while minimizing the electronic response in converting ionic potentials to electronic potentials;
d) reference electrode mounted on the substrate for electrical connection to an external lead from the substrate and in spaced apart relation to the carbon dioxide and pH
electrodes to contact the sample fluid and electrically connected to the pH and carbon dioxide electrodes;
e) electric circuitry on the substrate to electrically connect the electrodes to an external lead from the substrate for conveyance of electrical potentials and for electrical connection of the reference electrode to the pH
and carbon dioxide electrodes;
f) fluid circuit in liquid contact with the first, second and reference electrodes and insulated from the electric circuitry of the substrate; and g) analyzing means electrically connected to the external leads of the substrate to receive the electrical potentials from the electrodes and to calculate the pH and carbon dioxide according to the following simultaneous equations:
delta mVCO2 = -(SEN[CO2][pH])(delta pH) _ (SEN[CO2][CO2])(log CO2f/CO2i) delta mVpH = -(SEN[pH][pH])(delta pH) - (SEN[pH][CO2])(log CO2f/CO2i) where:
delta pH = change in pH
delta mV = change in millivolts SEN[pH][CO2] = sensitivity of the pH electrode favoring the CO2 analyte SEN[pH][pH] = sensitivity of the pH electrode favoring the H+
analyte for the second analyte SEN[CO2][pH] = sensitivity of the CO2 electrode favoring the H+
analyte SEN[CO2][CO2] = sensitivity of the CO2 electrode favoring the CO2 analyte f = final measurement i = initial measurement
a) nonconducting substrate suitable for carrying printed wiring circuits;
b) pH electrode mounted on the substrate for electrical connection to an external lead from the substrate and to contact sample fluid, wherein the electrode has an ion selective gas permeable polymeric membrane and an electrolyte to minimize the electronic response of the carbon dioxide while maximizing the electronic response for the hydrogen ion in converting ionic potentials to electronic potentials;
c) carbon dioxide electrode mounted on the substrate for electrical connection to an external lead from the substrate and in space apart relation to the pH electrode to contact sample fluid, wherein the electrode has an ion selective gas permeable polymeric membrane and an electrolyte to minimize the electronic response of the hydrogen ion while minimizing the electronic response in converting ionic potentials to electronic potentials;
d) reference electrode mounted on the substrate for electrical connection to an external lead from the substrate and in spaced apart relation to the carbon dioxide and pH
electrodes to contact the sample fluid and electrically connected to the pH and carbon dioxide electrodes;
e) electric circuitry on the substrate to electrically connect the electrodes to an external lead from the substrate for conveyance of electrical potentials and for electrical connection of the reference electrode to the pH
and carbon dioxide electrodes;
f) fluid circuit in liquid contact with the first, second and reference electrodes and insulated from the electric circuitry of the substrate; and g) analyzing means electrically connected to the external leads of the substrate to receive the electrical potentials from the electrodes and to calculate the pH and carbon dioxide according to the following simultaneous equations:
delta mVCO2 = -(SEN[CO2][pH])(delta pH) _ (SEN[CO2][CO2])(log CO2f/CO2i) delta mVpH = -(SEN[pH][pH])(delta pH) - (SEN[pH][CO2])(log CO2f/CO2i) where:
delta pH = change in pH
delta mV = change in millivolts SEN[pH][CO2] = sensitivity of the pH electrode favoring the CO2 analyte SEN[pH][pH] = sensitivity of the pH electrode favoring the H+
analyte for the second analyte SEN[CO2][pH] = sensitivity of the CO2 electrode favoring the H+
analyte SEN[CO2][CO2] = sensitivity of the CO2 electrode favoring the CO2 analyte f = final measurement i = initial measurement
9. The apparatus of Claim 8, wherein the pH and CO2 electrodes have membranes from gas and water vapor permeable polymers having a molecular weight range in weight average molecular weight in the range of around 10,000 to around 500,000 but the membrane of the CO2 electrode is from a polymer with a molecular weight lower than that for the membrane of the pH electrode.
10. The apparatus of Claim 9, wherein the gas permeable polymeric membranes are selected from the group consisting of:
poly(vinylchloride), poly(bisphenol-A carbonate), cellulose acetate, poly(methylmethacrylate), poly(vinylidene chloride), polystyrene, polyurethane, block copolymers of polysiloxane/poly(bisphenol-A
carbonate), polymers and copolymers of lower alkyl acrylate and methacrylate, and silicone rubber.
poly(vinylchloride), poly(bisphenol-A carbonate), cellulose acetate, poly(methylmethacrylate), poly(vinylidene chloride), polystyrene, polyurethane, block copolymers of polysiloxane/poly(bisphenol-A
carbonate), polymers and copolymers of lower alkyl acrylate and methacrylate, and silicone rubber.
11. The apparatus of Claim 8, wherein the pH and CO2 electrodes have membranes from gas and water vapor permeable polymers having a similar molecular weight of that in the range of weight average molecular weight of around 10,000 to around 500,000.
12. The apparatus of Claim 8, wherein the carbon dioxide electrode has a pH for the electrolyte in the range of greater than 7 up to 14 and the pH electrode has a pH for the electrolyte in the range of up to around 5.
13. The apparatus of Claim 8, wherein the analyzing means is a programmed computer means having the functions of analog input processing, analog to digital conversion, programmed microprocessing, and a date/time circuit and battery backup random access memory, and a power supply.
14. The apparatus of Claim 8, wherein the fluid circuit is filled with a fluid selected from the group consisting of storage fluid, hydrating fluid, calibrating fluid and sample fluid and mixtures of these, wherein with such mixtures the sample fluid is in contact with the analyte electrodes.
15. The apparatus of Claim 8, which includes two reference electrodes connected in series and in off axial alignment with the analyte electrodes.
16. The apparatus of Claim 8, wherein delta mVCO2 = -(SEN[CO2][pH])(de1t a pH) _ (SEN[CO2][CO2])(log CO2f/CO2i) and delta mVpH = -(SEN[pH][pH])(delta pH) - (SEN[pH][CO2])(log CO2f/CO2i) are equal to mV CO2 = (CO2f - CO2~) and mV pH = (pHf - pH~)
17. The apparatus of Claim 8, which includes on the substrate a heater, and thermistor and resistor arrangement to heat the substrate in the vicinity of the electrodes.
18. An apparatus of combined pH and carbon dioxide electrochemical sensors for measuring the pH and the partial pressure of carbon dioxide in fluids, comprising:
a) nonconducting substrate suitable for carrying printed wiring circuits, b) a pH electrode mounted on the substrate for electrical connection to an external lead from the substrate and positioned to contact sample fluid, wherein the electrode has a gas permeable hydrophobic ion selective polymeric membrane of high molecular weight polymer selected from the group consisting of: poly(vinylchloride), poly(bisphenol-A carbonate), cellulose acetate, poly(methylmethacrylate), poly(vinylidene chloride), polystyrene, polyurethane, block copolymers of polysiloxane/poly(bisphenol-A carbonate), polymers and copolymers of lower alkyl acrylate and methacrylate, silicone rubber with ionophores of trioctylamine and an aqueous dielectric with a pH in the range of up to around 5;
c) a carbon dioxide electrode mounted on the substrate for electrical connection to an external lead from the substrate and in spaced apart relation to the pH electrode and positioned to contact sample fluid, wherein the carbon dioxide electrode has an lower molecular weight gas permeable polymeric ion selective membrane selected from the group consisting of: poly(vinylchloride), poly(bisphenol-A
carbonate), cellulose acetate, poly(methylmethacrylate), poly(vinylidene chloride), polystyrene, polyurethane, block copolymers of polysiloxane/poly(bisphenol-A carbonate), polymers and copolymers of lower alkyl acrylate and methacrylate, silicone rubber with ionophores of trioctylamine and an aqueous dielectric with a pH in the range of at greater than 7 to 14, and the difference in the pH between the electrolytes is at least 0.1, and wherein both electrodes give some electronic response for both analytes;
d) reference electrode mounted on the substrate for electrical connection to an external lead form the substrate and in spaced apart relation to the pH and carbon dioxide electrodes and positioned to contact the sample fluid and electrically connected to the pH and carbon dioxide electrodes; (for each of or common to the electrodes) e) electric circuitry on the substrate to electrically connect the electrodes to an external lead from the substrate for conveyance of electrical potentials and for electrical connection of the reference electrode to the pH
and carbon dioxide electrodes;
f) fluid circuit filled with a fluid selected from the group consisting of storage fluid, hydrating fluid, calibrating fluid and sample fluid and mixtures of these, wherein with such mixtures the sample fluid is in contact with the analyte electrodes where the fluid circuit is in liquid contact with the first, second and reference electrodes and insulated from the electric circuitry of the substrate; and g) programmed computer means having the functions of analog input processing, analog to digital conversion, programmed microprocessing, and a date/time circuit and battery backup random access memory, and a power supply electrically connected to the external leads of the substrate to receive the electrical potentials form the electrodes and to calculate the numerical values from simultaneous equations as follows:
delta mVCO2 = -(SEN[CO2][pH])(de1t a pH) _ (SEN[CO2][CO2])(log CO2f/CO2i) delta mVpH = -(SEN[pH][pH])(delta pH) - (SEN[pH][CO2])(log CO2f/CO2i) so that upon measuring the calibration fluid for known values of pH and CO2:
mV CO2 = (CO2f - CO2~) and mV pH = (pHf - pH~) where:
delta pH = change in pH
delta mV = change in millivolts SEN[pH][CO2] = sensitivity of the pH electrode favoring the CO2 analyte SEN[pH][pH] = sensitivity of the pH electrode favoring the H+
analyte for the second analyte SEN[CO2][pH] = sensitivity of the CO2 electrode favoring the H+
analyte SEN[CO2][CO2] = sensitivity of the CO2 electrode favoring the CO2 analyte f = final measurement i = initial measurement
a) nonconducting substrate suitable for carrying printed wiring circuits, b) a pH electrode mounted on the substrate for electrical connection to an external lead from the substrate and positioned to contact sample fluid, wherein the electrode has a gas permeable hydrophobic ion selective polymeric membrane of high molecular weight polymer selected from the group consisting of: poly(vinylchloride), poly(bisphenol-A carbonate), cellulose acetate, poly(methylmethacrylate), poly(vinylidene chloride), polystyrene, polyurethane, block copolymers of polysiloxane/poly(bisphenol-A carbonate), polymers and copolymers of lower alkyl acrylate and methacrylate, silicone rubber with ionophores of trioctylamine and an aqueous dielectric with a pH in the range of up to around 5;
c) a carbon dioxide electrode mounted on the substrate for electrical connection to an external lead from the substrate and in spaced apart relation to the pH electrode and positioned to contact sample fluid, wherein the carbon dioxide electrode has an lower molecular weight gas permeable polymeric ion selective membrane selected from the group consisting of: poly(vinylchloride), poly(bisphenol-A
carbonate), cellulose acetate, poly(methylmethacrylate), poly(vinylidene chloride), polystyrene, polyurethane, block copolymers of polysiloxane/poly(bisphenol-A carbonate), polymers and copolymers of lower alkyl acrylate and methacrylate, silicone rubber with ionophores of trioctylamine and an aqueous dielectric with a pH in the range of at greater than 7 to 14, and the difference in the pH between the electrolytes is at least 0.1, and wherein both electrodes give some electronic response for both analytes;
d) reference electrode mounted on the substrate for electrical connection to an external lead form the substrate and in spaced apart relation to the pH and carbon dioxide electrodes and positioned to contact the sample fluid and electrically connected to the pH and carbon dioxide electrodes; (for each of or common to the electrodes) e) electric circuitry on the substrate to electrically connect the electrodes to an external lead from the substrate for conveyance of electrical potentials and for electrical connection of the reference electrode to the pH
and carbon dioxide electrodes;
f) fluid circuit filled with a fluid selected from the group consisting of storage fluid, hydrating fluid, calibrating fluid and sample fluid and mixtures of these, wherein with such mixtures the sample fluid is in contact with the analyte electrodes where the fluid circuit is in liquid contact with the first, second and reference electrodes and insulated from the electric circuitry of the substrate; and g) programmed computer means having the functions of analog input processing, analog to digital conversion, programmed microprocessing, and a date/time circuit and battery backup random access memory, and a power supply electrically connected to the external leads of the substrate to receive the electrical potentials form the electrodes and to calculate the numerical values from simultaneous equations as follows:
delta mVCO2 = -(SEN[CO2][pH])(de1t a pH) _ (SEN[CO2][CO2])(log CO2f/CO2i) delta mVpH = -(SEN[pH][pH])(delta pH) - (SEN[pH][CO2])(log CO2f/CO2i) so that upon measuring the calibration fluid for known values of pH and CO2:
mV CO2 = (CO2f - CO2~) and mV pH = (pHf - pH~) where:
delta pH = change in pH
delta mV = change in millivolts SEN[pH][CO2] = sensitivity of the pH electrode favoring the CO2 analyte SEN[pH][pH] = sensitivity of the pH electrode favoring the H+
analyte for the second analyte SEN[CO2][pH] = sensitivity of the CO2 electrode favoring the H+
analyte SEN[CO2][CO2] = sensitivity of the CO2 electrode favoring the CO2 analyte f = final measurement i = initial measurement
19. The apparatus of Claim 18, wherein the reference electrode is a silver/sliver chloride in block or wound wire form.
20. The apparatus of Claim 1, wherein the electrolytes are solid and the membranes are water soluble.
Applications Claiming Priority (3)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| US07/814,383 US5336388A (en) | 1991-12-26 | 1991-12-26 | Analyte and pH measuring sensor assembly and method |
| US814,383 | 1991-12-26 | ||
| PCT/US1992/011286 WO1993013411A1 (en) | 1991-12-26 | 1992-12-22 | ANALYTE AND pH MEASURING SENSOR ASSEMBLY AND METHOD |
Publications (2)
| Publication Number | Publication Date |
|---|---|
| CA2126555A1 CA2126555A1 (en) | 1993-07-08 |
| CA2126555C true CA2126555C (en) | 1999-06-15 |
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ID=25214906
Family Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CA002126555A Expired - Fee Related CA2126555C (en) | 1991-12-26 | 1992-12-22 | Analyte and ph measuring sensor assembly and method |
Country Status (6)
| Country | Link |
|---|---|
| US (1) | US5336388A (en) |
| EP (1) | EP0619019A4 (en) |
| JP (1) | JP2726755B2 (en) |
| CA (1) | CA2126555C (en) |
| MX (1) | MX9207526A (en) |
| WO (1) | WO1993013411A1 (en) |
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| Publication number | Priority date | Publication date | Assignee | Title |
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| US5593852A (en) | 1993-12-02 | 1997-01-14 | Heller; Adam | Subcutaneous glucose electrode |
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-
1991
- 1991-12-26 US US07/814,383 patent/US5336388A/en not_active Expired - Lifetime
-
1992
- 1992-12-22 EP EP93902808A patent/EP0619019A4/en not_active Withdrawn
- 1992-12-22 WO PCT/US1992/011286 patent/WO1993013411A1/en not_active Application Discontinuation
- 1992-12-22 CA CA002126555A patent/CA2126555C/en not_active Expired - Fee Related
- 1992-12-22 JP JP5511943A patent/JP2726755B2/en not_active Expired - Lifetime
- 1992-12-23 MX MX9207526A patent/MX9207526A/en unknown
Also Published As
| Publication number | Publication date |
|---|---|
| JPH07505711A (en) | 1995-06-22 |
| US5336388A (en) | 1994-08-09 |
| EP0619019A4 (en) | 1996-09-11 |
| MX9207526A (en) | 1993-10-01 |
| JP2726755B2 (en) | 1998-03-11 |
| CA2126555A1 (en) | 1993-07-08 |
| EP0619019A1 (en) | 1994-10-12 |
| WO1993013411A1 (en) | 1993-07-08 |
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Legal Events
| Date | Code | Title | Description |
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| EEER | Examination request | ||
| MKLA | Lapsed |