Liquid membrane type ion-selective electrode

This invention relates to a liquid membrane type ion-selective electrode that can restrain an electric potential fluctuation of an inner electrode due to ultraviolet rays and that can conduct an analysis with high accuracy. The liquid membrane type ion-selective electrode comprises a liquid membrane type ion-sensitive membrane wherein a predetermined ionophore is supported by a base material, an inner electrode that has electrical conductivity and that is arranged at a position on the ion-sensitive membrane through which light transmitted is incident, an internal solution that contains an electrolyte and that makes contact with the ion-sensitive membrane and the inner electrode, wherein the ion-sensitive membrane contains an ultraviolet absorber or an ultraviolet reflecting agent having an insulative property.

FIELD OF THE ART

This invention relates to a liquid membrane type ion-selective electrode comprising an ion-sensitive membrane of a liquid membrane type wherein an ionophore is supported.

BACKGROUND ART

A variety of ionophores (ion-selective ligands) that can selectively capture a specific ion are conventionally known. Furthermore, a liquid membrane type ion-selective electrode comprising a liquid membrane type ion-sensitive membrane wherein an ionophore is supported has been developed by making use of the ionophores (patent document 1). It is possible for this liquid membrane type ion-selective electrode to detect a variety of analyte ions by changing the ionophore according to the target ion.

PRIOR ART DOCUMENT

Patent Document

Patent document 2 Japanese Unexamined Patent Application Publication No. 63-138255

Patent document 3 Japanese Unexamined Patent Application Publication No. 2005-308720

DISCLOSURE OF THE INVENTION

Problems to be Solved by the Invention

For example, a resin such as polyvinyl chloride and transparent silicone rubber is generally used as a base material of the ion-sensitive membrane of this liquid membrane type ion-selective electrode. However, generally the resin is high in ultraviolet ray transmission as compared with glass. Accordingly, if a flat type analyzer as described in the patent document 2 comprising a liquid membrane type ion-selective electrode is used, an inner electrode is positioned just below the ion-sensitive membrane so that the ultraviolet rays passing through the ion-sensitive membrane are irradiated on the inner electrode. As a result, an electrical voltage fluctuation problem occurs, causing sensor deterioration.

Conventionally, in order to prevent deterioration of the sensor due to the ultraviolet rays, a means such as using a package provided with a light blocking cover is provided until just prior to the sensor being used (patent document 3).

However, even though the cover is provided, it is necessary to open the package cover while conducting the analysis, and thus it is not possible to prevent the electrical voltage fluctuation of the inner electrode due to the ultraviolet rays at the time of analysis.

Accordingly, the present claimed invention intends to provide a liquid membrane type ion-selective electrode that can restrain the electronic voltage fluctuation of the inner electrode due to ultraviolet rays, and that can conduct the analysis with high accuracy.

Means to Solve the Problems

Conventionally, it has been found that performance of the ion-sensitive membrane is affected if an ion-sensitive membrane contains an ultraviolet absorber or an ultraviolet reflecting agent. However, after keen examination by the present inventors, it has been revealed that the electrical voltage fluctuation of the internal electrode due to the ultraviolet rays can be restrained while keeping the performance of the ion-sensitive membrane even though the ion-sensitive membrane contains an ultraviolet absorber or the ultraviolet reflecting agent so long as the ultraviolet absorber of the ultraviolet reflecting agent has insulative properties.

More specifically, the liquid membrane type ion-selective electrode comprises a liquid membrane type ion-sensitive membrane wherein a predetermined ionophore (ion-selective ligand) is supported by a base material, an electrically conductive inner electrode that is arranged at a position at which the ion-sensitive membrane transmitted light is incident, and an internal solution that contains an electrolyte and that makes contact with the ion-sensitive membrane and the inner electrode, and is characterized by the ion-sensitive membrane containing an ultraviolet absorber or an ultraviolet reflecting agent having an insulative property.

In accordance with this arrangement, since the liquid membrane type ion-sensitive member is mixed with the ultraviolet absorber or the ultraviolet reflecting agent having the insulative property, it is possible to prevent the inner electrode from being irradiated by the ultraviolet rays even though a flat type analysis device is constituted by the use of the liquid membrane type ion-selective electrode. As a result, it becomes possible to restrain the electric potential fluctuation of the inner electrode due to the ultraviolet rays so that a highly accurate analysis can be conducted.

The base material of the ion-sensitive membrane is not especially limited, and for example, a transparent resin having high ultraviolet ray permeability such as polyvinyl chloride, transparent silicone rubber, polyethylene, polypropylene, polyvinyl alcohol is used as the base material of the ion-sensitive membrane. In the case where the base material of the ion-sensitive membrane is a resin having high ultraviolet ray permeability, this invention performs effectively. In addition, if the resin is used as the base material, it is possible to use a simple method for making a membrane, whereby a resin, an ionophore and a ultraviolet absorber or a ultraviolet reflecting agent are dissolved into a solvent and the dissolved resin, ionophore and ultraviolet ray absorber or ultraviolet reflecting agent are applied to a response part and then the solvent is evaporated. As a result, the ion-sensitive membrane can be made with ease.

The inner electrode is not especially limited, for example, the inner electrode may be made of Ag/AgCl, Hg/Hg2Cl2, Hg/Hg2SO4or the like. Among these, the present claimed invention performs effectively when the inner electrode is the Ag/AgCl electrode, since electric potential fluctuation is caused readily because Ag is oxidized and AgCl becomes silvemegatively charged chloride ion due to the ultraviolet rays (the maximum absorption wavelength 200 nm). The electric potential fluctuation of the Ag/AgCl electrode due to ultraviolet rays is not especially limited as long as the light contains ultraviolet rays. For example, the electric potential fluctuation can be caused by, not only irradiation of light from a fluorescent lamp but also sunlight. Irradiating the Ag/AgCl electrode with sunlight causes about 10˜100 mV electric potential fluctuation

The ultraviolet absorber or the ultraviolet reflecting agent is not especially limited as long as it contains insulative properties, it can be represented by an organic system pigment such as a quinacridone system pigment such as quinacridone red, quinacridone magenta, and quinacridone violet; a dimethyl quinacridone system pigment; a perylene system pigment such as perylene red, perylene orange, perylene maroon, perylene vermilion, and perylene Bordeaux; a diketo pyrrolo pyrrole system pigment such as diketo pyrrolo pyrrole red, and diketo pyrrolo pyrrole orange; a polyazo condensed pigment such as polyazo red, polyazo yellow, chromo phthal orange, chromo phthal red, and chromo phthal scarlet; a disazo system pigment such as disazo yellow; a monoazo system pigment such as monoazo red, monoazo yellow, and monoazo brown; and an isoindolinone system pigment such as isoindolinone yellow. These organic system pigments do not affect an electromotive force of the ion-sensitive membrane. Since an ultraviolet absorber or an ultraviolet reflecting agent such as, for example, a carbon having electrically conductive properties, causes the electric potential fluctuation, it is not appropriate for this invention.

A dosage of the ultraviolet absorber or the ultraviolet reflecting agent to the base material is preferably a mass ratio of the base material to the ultraviolet absorber or the ultraviolet reflecting agent of 1:3˜1:10, and more preferably 1:5˜1:7.5. As long as the mass ratio falls within this range, even though the ultraviolet absorber or the ultraviolet reflecting agent is added to the base material, this does not prevent the membrane from being made, and as a result sufficient blocking of the ultraviolet rays can be achieved.

Effect of the Invention

In accordance with this invention having the above arrangement, since the electric potential fluctuation of the inner electrode due to the ultraviolet rays can be restrained, it is possible to conduct the analysis with high accuracy.

BEST MODES OF EMBODYING THE INVENTION

One embodiment of this invention will be explained with reference to drawings.

A liquid membrane type Na+/K+electrode1in accordance with this embodiment is a hybrid type wherein an ion-selective electrode and a reference electrode are integrated for measuring a concentration of a sodium ion and a concentration of a potassium ion in, for example, urine, and as shown inFIG. 1˜3, comprises a body2made of a resin, an arithmetic processing part (not shown in drawings) such as a micro computer incorporated in the body2, a display/operation part3formed on an upper surface of the body2, a power source part4formed adjacent to the display/operation part3and an electrode part5made of a synthetic resin and formed in a water-proof structure.

Lead parts21A,22A,23A24A, and25A of a flat-type sensor7, to be described later, and a connecting part63that is connected to a circuit substrate62having the arithmetic processing part are provided inside of the body2. The circuit substrate62is connected to and supported by a case.

The display/operation part3comprises a display part31and an operation part32that operates various buttons such as a power button32a, a correction button32band a hold button32c. The power source part4comprises button batteries41,42.

The electrode part5comprises a tubular part6whose one end opens to make it possible to house the power source part4and a flat-type sensor7that is continuously arranged at the other end of the tubular part6. The electrode part5is configured so that it can be integrally connected with the body2by being mounted on the body2so as to cover the power source part4or so that it can be separated from the body2.

The flat-type sensor7is, as shown inFIG. 2andFIG. 3, made of a material such as polyethylene terephthalate having electrical insulation, and comprises substrates11,12, and13each of which is laminated. A part of each substrate11,12, and13is formed in a shape of an arc. The third substrate13positioned as the top layer and the second substrate12positioned as the middle layer have the same shape (in a plane view), and the arc part of the first substrate11positioned as the lower layer is the same as that of the second substrate12and the third substrate13, and other side of the first substrate11is longer than that of the second substrate12and the third substrate13. In addition, a detected liquid holder74is arranged to surround a peripheral border of the third substrate13.

Conductive parts21,22,23,24, and25are formed on an upper surface of the first substrate11by silk-screen printing, for example, Ag paste after providing a predetermined pretreatment, and a circular through bore81is formed on the first substrate11. The conductive parts21,22,23,24, and25are processed as follows. First, a distal end of the conductive part21located at one of the outer sides is covered with AgCl and a circular inner electrode26of a Na+electrode71is formed, and a distal end of the conductive part22located at an inner side of the conductive part21is also covered with AgCl and a circular inner electrode27of a K+electrode72is formed. In addition, a distal end of the conductive part25located at the other outer side is also covered with AgCl and an inner electrode28of a reference electrode73having an elongated shape located at one of the side end parts of the substrate11is formed. Furthermore, a temperature compensating element29such as a thermistor is arranged over a distal end of the conductive part23and a distal end of the conductive part24, wherein the conductive parts23and24are located at an inner side. The other ends of each conductive part21,22,23,24, and25constitute lead parts21A,22A,23A,24A, and25A respectively.

The second substrate12is provided with a through bore82that is arranged at a position corresponding to the through bore81and that has the same diameter as that of the through bore81and through bores83and84, each of which is formed at a position corresponding to each of the inner electrode26and inner electrode27and whose diameters are a little larger than those of the through bores81and82, and a rectangular through bore85that is formed at a position corresponding to the temperature compensating element29and whose size is generally the same as that of the temperature compensating element29. Furthermore, an elongated cutout86is formed at a side end part corresponding to the inner electrode28of the reference electrode73.

The third substrate13is provided with a through bore87that is arranged at a position corresponding to the through bores81and82and that has the same diameter as that of the through bores81and82, through bores88and89, each of which is formed at a position corresponding to each of the through bore83and the through bore84and whose diameter is a little larger than that of the through bores83and84, and a rectangular through bore91that is formed at a position corresponding to the through bore85and whose size is generally the same as that of the through bore85. Furthermore, a cutout92whose size is the same as that of the cutout86is formed at a position corresponding to the cutout86.

A liquid junction17of the reference electrode73composed of a porous body made of polyethylene is inserted into the through bores81,82, and87, each of which is formed at the corresponding position of each of the substrates11,12, and13respectively. The liquid junction17is mounted in a state that the upper surface of the liquid junction17is generally flush with an upper surface of the third substrate13positioned as the top layer.

A gelled internal solution14ais mounted on the through bore83formed on the second substrate12and a gelled internal solution14bis mounted on the through bore84on the second substrate12. The gelled internal solution14ais formed into a disk shape and made of a pH buffer solution containing CaCl2to which a sodium ion is added and to which a gelatinizing agent and a gel evaporation retardant are further added. The gelled internal solution14bis formed into a disk shape and made of a pH buffer solution containing CaCl2to which a potassium ion is added and to which a gelatinizing agent and a gel evaporation retardant are further added. A Cl−concentration of the internal solution is adjusted to 0.1M˜the saturated concentration. The gelled internal solution14ais mounted inside of the through bore83in a state that an upper surface of the gelled internal solution14aprojects a little from an upper surface of the second substrate12, and makes contact with the inner electrode26formed on an upper surface of the first substrate11through the through bore83. The gelled internal solution14bis mounted inside of the through bore84in a state that an upper surface of the gelled internal solution14bprojects a little from an upper surface of the second substrate12, and makes contact with the inner electrode27formed on the upper surface of the first substrate11through the through bore84.

A disk shaped sodium ion-sensitive membrane15is mounted on the through bore88formed on the third substrate13and the sodium ion-sensitive membrane15makes contact with the gelled internal solution14aand is fixed to the third substrate13in a state that an upper surface of the gelled internal solution14ais generally flush with the upper surface of the third substrate13. A disk shaped potassium ion-sensitive membrane16is mounted on the through bore89formed on the third substrate13and the potassium ion-sensitive membrane16makes contact with the gelled internal solution14band is fixed to the third substrate13in a state that the upper surface of the gelled internal solution14bis generally flush with the upper surface of the third substrate13. The sodium ion-sensitive membrane15faces in close proximity to the inner electrode26through the gelled internal solution14a. The potassium ion-sensitive membrane16faces in close proximity to the inner electrode27through the gelled internal solution14b.

The solid sodium ion-sensitive membrane15is formed with a procedure of adding a plasticizer, Bis(12-crown-4) as a sodium ionophore, and isoindolinone yellow as an ultraviolet ray absorber to polyvinyl chloride (PVC), dissolving the polyvinyl chloride to which the plasticizer, Bis(12-crown-4) and isoindolinone yellow are added with an organic solvent such as tetrahydrofuran (THF), filling the dissolved polyvinyl chloride into the through bore88by means of potting or an ink jet printing method, and heating so as to evaporate the organic solvent.

The potassium ion-sensitive membrane16is formed by the same method as that of the sodium ion-sensitive membrane15except for using Bis(benzo-15-crown-5) as a potassium ionophore.

A gelled internal solution14cof the reference electrode73is arranged from below the first substrate11locating at the lowest layer to the upside of the third substrate13locating at the top layer in a case61continuously arranged to the tubular part6. The gelled internal solution14cis so filled that an upper part and a lower part of the gelled internal solution14care in communication through a gap between a side part, in the internal electrode28side of the reference electrode73, of the substrates11,12and13and the case61, and the gelled internal solution14cmakes contact with a surface of the inner electrode28of the reference electrode73and the lower end part of the liquid junction17. The gelled internal solution14cof the reference electrode73is an internal solution comprising an NH4Cl aqueous solution of concentration 0.1M˜the saturated concentration to which a gelling agent and a gel evaporation retardant are added.

In accordance with the liquid membrane type Na+/K+electrode1of this embodiment having the above-mentioned arrangement, even though polyvinyl chloride, having a high permeability to ultraviolet rays, is used as the base material of the liquid membrane type ion-sensitive membranes15and16, since isoindolinone yellow that is mixed with the ion-sensitive membranes15and16absorbs the ultraviolet rays, it is possible to prevent the ultraviolet rays irradiating the inner electrodes26and27comprising the Ag/AgCl electrode arranged to face the ion-sensitive membranes15and16respectively. As a result, it is possible to restrain an electric potential fluctuation of the inner electrodes26and27due to the ultraviolet rays so that a highly accurate analysis can be conducted.

The present claimed invention is not limited to the above-mentioned embodiment, and a part or all of the above-mentioned embodiment or the modified embodiment can be combined without departing from a spirit of this invention.

EMBODIMENT

The present claimed invention will be explained in further detail with reference to the embodiment, however, this invention is not limited to the embodiment alone.

Five examples of liquid membrane type Na+/K+electrode (composite type) of the above-mentioned embodiment of the present claimed invention were manufactured wherein isoindolinone yellow (DA4446 manufactured by Dainichiseika Color & Chemicals Mfg. Co., Ltd.) is mixed with a sodium ion-sensitive membrane and a potassium ion-sensitive membrane, and five comparative examples, whose specification is the same as that of the present claimed invention except that isoindolinone yellow is not mixed with the sodium ion-sensitive membrane and the potassium ion-sensitive membrane, were manufactured.

A drop of CaCl2aqueous solution containing sodium ions and potassium ions is placed on each ion-sensitive membrane of the obtained liquid membrane type Na+/K+electrode and the generated electric voltage under the direct sunlight (61 kLux) in outdoors or in a light shielded state are respectively measured. The results are shown in Table 1 and Table 2. A tolerated value for electric potential fluctuation is 0±3 mV.

Based on the results shown in Table 1 and Table 2, some of the comparative examples show an influence from the ultraviolet rays of over 20 mV in the negative direction, corresponding to a change equal to or more than twice (corresponding to a change of −18 mV in electric potential) the ion concentration. Correspondingly, the influence from the ultraviolet rays for this invention is within ±0.2 mV, which is sufficiently less than the tolerated value for electric potential fluctuation, and there is no need to consider the influence from the ultraviolet rays when a measurement is conducted. Accordingly, based on this examination it becomes clear that the electric potential fluctuation is effectively restrained by mixing the ultraviolet ray absorbent with the ion-sensitive membrane, thereby enabling a highly accurate analysis to be conducted.

EXPLANATION OF REFERENCE CHARACTERS