JP4727349B2 - Oxygen detector composition - Google Patents

Description

  The present invention relates to a method for detecting the presence or absence of oxygen or oxygen concentration in an oxygen-free package by luminescence, and a detection agent composition comprising a luminescent substance whose luminescence intensity and lifetime can be quenched by oxygen. .

  Conventionally, oxygen detector compositions using variable organic dyes that change color reversibly by oxidation-reduction have been proposed. For example, solid oxygen detectors composed of thiazine dyes, azine dyes, oxazine dyes and other organic pigments and reducing agents are disclosed (Patent Documents 1 and 2). Also known is an oxygen indicator ink composition in which a thiazine dye or the like, a reducing saccharide, and an alkaline substance are dissolved or dispersed in a resin solution (Patent Document 3). Commercially available tablet-type oxygen detector (for example, trade name: Ageless Eye, manufactured by Mitsubishi Gas Chemical Co., Ltd.) and an oxygen detector coated with an ink composition having an oxygen detection function (trade name: Paper Eye, Mitsubishi Gas Chemical ( Co., Ltd.) is a functional product that simply shows a color change that the oxygen concentration in the transparent packaging container is less than 0.1% by volume, and is an oxygen scavenger (for example, trade name: Ageless). , Manufactured by Mitsubishi Gas Chemical Co., Ltd.) to maintain the freshness of food and the quality of medical drugs.

However, conventional oxygen detectors have insufficient light resistance and storage stability of variable organic dyes, which may cause fading or discoloration under light irradiation, and brown or discoloration at high temperatures. Since the function may be deteriorated, in order to maintain a vivid color for a long period of time, there is a disadvantage that it must be stored under light shielding and at a low temperature. Furthermore, conventional oxygen detectors have the disadvantage that they must be stored under oxygen-free conditions because the reducing agent, which is an essential component, is oxidized in the air.
In recent years, an oxygen detection agent composition (Patent Document 4) and an oxygen detection ink composition (Patent Document 5), in which light resistance and storage stability are greatly improved by inserting an organic dye between layers of a layered silicate, It has been developed. However, there remains a problem that oxygen detectors using these layered silicates must be stored under oxygen-free conditions to avoid oxidation of the reducing agent.

  On the other hand, an optical oxygen detector composition and apparatus that do not use a reducing agent have been proposed (Patent Document 6). The principle of oxygen detection is based on the fact that fluorescence and phosphorescence emitted by molecules excited by absorption of light are quenched by oxygen molecules, and disclosed metal porphyrins with platinum or palladium as the central metal as luminescent materials. Yes. In addition, synthetic resins such as polymethyl methacrylate, polyvinyl chloride, polystyrene, polycarbonate, polytetrafluoroethylene, and silicone rubber are disclosed as carrier materials containing a luminescent material. However, the oxygen detector composition described above also has a drawback that the light resistance and storage stability of the metalloporphyrin are insufficient.

JP-A-53-117495 Japanese Patent Laid-Open No. 53-120493 JP 56-84772 A JP 2004-45365 A JP 2004-323740 A Japanese Patent Publication No. 6-43963

  An object of the present invention is to solve the above-mentioned problems in the prior art and to provide a chemically and photochemically stable oxygen detector composition and a method of detecting oxygen in an oxygen-free package using the same. .

That is, the present invention includes a detection agent using a luminescent substance whose luminescence intensity and lifetime are quenched by oxygen in an oxygen-free package, and the detection agent is irradiated with visible light or ultraviolet light from the outside. A detection agent composition for use in a method for detecting oxygen by detecting a luminescent state, wherein the luminescent substance is a complex in which a luminescent organic compound is inserted between layers of a layered silicate. The oxygen detector composition.
In the present invention, the luminescent organic compound is a cationic metalloporphyrin, the luminescent organic compound is a cationic metalloporphyrin having palladium or platinum as a central metal, the layered silicate Is an oxygen detector composition which is a layered silicate selected from the smectite group.
Further, the present invention provides a method for detecting oxygen in an oxygen-free package, wherein the oxygen-free package includes a detection agent using a luminescent substance whose luminescence intensity and lifetime are quenched by oxygen, A method for detecting oxygen in an oxygen-free package, wherein the agent is irradiated with visible light or ultraviolet light from the outside to detect a light emission state.

  The present invention provides a chemically and photochemically stable oxygen detector composition and a method for detecting oxygen in an oxygen-free package using the detector composition. The present invention has extremely high utility value in the field of oxygen-free storage such as food preservation and quality maintenance of medical drugs.

First, the oxygen detector composition of the present invention is composed of a composite in which a luminescent organic compound is inserted between layered silicate layers.
The light-emitting organic compound used in the present invention is a carbon compound that is excited by ultraviolet light or visible light and emits fluorescence or phosphorescence in an oxygen-free atmosphere, and includes an organometallic compound having a metal-carbon bond in the molecule. . Examples of the organic compound of the present invention include polycyclic aromatic hydrocarbons such as pyrene, transition metal complexes such as ruthenium or osmium and rhodium, and metal porphyrins having platinum or palladium as a central metal. In particular, a metal porphyrin having platinum or palladium as a central metal is preferable because phosphorescence is observed even at room temperature. Moreover, it is desirable that the organic compound that emits light in the absence of oxygen used in the present invention is a cationic that easily forms a complex with the layered silicate.

  The layered silicate used in the present invention has a layered structure in which atoms (including ions; the same applies hereinafter) groups are arranged on a plane to form a sheet structure, and the sheet structure repeats in a direction perpendicular to the plane. It has a silicate. In addition, an inorganic material comprising a layer in which a tetrahedral sheet composed of silicon atoms, aluminum atoms and oxygen atoms and an octahedral sheet composed of aluminum atoms, magnesium atoms, oxygen atoms and hydrogen atoms are combined one-to-one or two-to-one. It is a layered compound. Further, the tetrahedral sheet may contain iron atoms in addition to the above atoms, and the octahedral sheet may contain iron atoms, or chromium atoms, manganese atoms, nickel atoms, and lithium atoms. In addition to water molecules, cations such as potassium ions, sodium ions, calcium ions or the like can be present as exchangeable cations between the layers of the layered compound.

  The type of layered silicate used in the present invention is preferably a smectite group, and examples thereof include layered silicates belonging to a natural smectite group such as montmorillonite and beidellite, saponite, hectorite, and saconite. In addition, a layered silicate belonging to the smectite group synthesized hydrothermally using an inorganic compound as a starting material can also be used. Among them, a preferred layered silicate is synthetic saponite.

  The conditions for charging the oxygen detector composition of the present invention are as follows. The luminescent organic compound is 0.001 to 10 parts by weight, preferably 0.01 to 1 part by weight per 1 part by weight of the layered silicate.

  The oxygen detector composition of the present invention can be obtained by mixing an aqueous dispersion of a layered silicate and an aqueous solution in which a luminescent organic compound is dissolved. Further, the mixed liquid is separated from water by filtration or centrifugation, and dried to obtain a thin film or a lump solid. In addition, a solid layered silicate and a solid or liquid luminescent organic compound can be similarly obtained as a solid by mixing them using a mortar or the like. At this time, a small amount of a solvent such as water or alcohol may be added as necessary.

  The fact that the light-emitting organic compound of the present invention is inserted between the layers of the layered silicate means that the interlayer distance is increased by X-ray analysis or the light-emitting organic compound is adsorbed on the surface of the layered silicate layer. It can be confirmed by the shift of the maximum absorption wavelength by. In particular, when tetravalent cationic porphyrin is used as the luminescent organic compound, the molecular structure is strongly planarized by adsorption, and a long wavelength shift with a maximum absorption wavelength is observed.

  The oxygen detector composition of the present invention can be present in the oxygen-free package by various methods. Since the present oxygen detector composition itself becomes a solid pigment, it can be used as it is or after being formed into a film or the like. Or it can disperse | distribute to other solids, or can be mixed with other solids, and can be set as the oxygen detection body which has a tablet type | mold, a sheet form, a film form, and another shape. In addition, as a pigment for oxygen detection ink, it can be mixed with a solvent, a binder, or the like to form an oxygen detection ink, and this oxygen detection ink can be applied on paper or plastic tape or the like as a character, figure, pattern, or the like. By printing or the like, it is possible to obtain an oxygen detector that indicates the presence or absence of oxygen or the oxygen concentration by light emission. Furthermore, by printing the oxygen detection ink on the inner surface of the gas barrier container or on the surface of the oxygen scavenger as characters, figures, patterns, etc., the presence or absence of oxygen in the container or the oxygen concentration is emitted from the outside. I can know.

  In the present invention, a detection agent using a luminescent substance whose luminescence intensity and lifetime are quenched by oxygen is present in the oxygen-free package, and the detection agent is irradiated with visible light or ultraviolet light from the outside. The method for detecting oxygen in an oxygen-free package is characterized by detecting the light emission state.

The oxygen-free package of the present invention includes vacuum packaging, inert gas replacement packaging such as nitrogen, oxygen scavenger packaging, and other oxygen-free packaging, such as food preservation and medical product quality maintenance, etc. There are preservation of goods and various other things.
These oxygen-free packaging materials are made of a material having an oxygen impermeability or a low oxygen permeability, and the most general one is an oxygen gas barrier plastics film.

In the present invention, the oxygen detector in the oxygen-free package is irradiated with visible light or ultraviolet light from the outside to detect luminescence. From this point, it is essential that at least the oxygen detection agent can be seen through from the outside, and it is essential that the irradiation light and luminescence be efficiently transmitted.
The most versatile oxygen-free packaging material is plastics, and many of them have a large absorption band in the near ultraviolet region even though they are transparent to visible light. From this aspect, the luminescent organic compound used in the detection agent is preferably one having an absorption wavelength on the longer wavelength side than this wavelength, and
It is usually preferable that the luminescence wavelength is also in the visible light range, and it is necessary to consider the relationship with the packaging material to be used.

  When the method of the present invention requires light irradiation and a certain amount of quantitative detection of luminescence, a device including a light receiving and emitting element is required. However, since it is an optical method and its response speed is high, it demonstrates its power when it is necessary to inspect and detect a large number of articles at a high speed. It has extremely high utility value in the field of oxygen-free storage such as quality maintenance.

Hereinafter, the present invention will be described in more detail by way of examples.
Example 1
Synthetic saponite (trade name: Smecton SA, manufactured by Kunimine Kogyo Co., Ltd.) 1.0 gL- ¹ aqueous dispersion 1.0 mL of a layered silicate, 2.0 × 10 ⁻⁴ M tetrakis (1-methyl) -Pyridinium-4-yl) porphyrinato palladium (hereinafter, cationic palladium porphyrin) 62.5 μL was mixed with stirring. Dioxane (200 μL) was mixed with the resulting aqueous complex solution and gently stirred. The obtained complex solution was filtered under reduced pressure using a membrane filter having a pore size of 0.1 μm. The obtained filtrate was completely colorless and transparent, and the complex and the cationic palladium porphyrin did not pass through the filter at all. The vacuum filtration was completed before the membrane filter was completely dried. After completion of filtration, the filtrate on the membrane filter was pressure-bonded onto a micro slide glass. By carefully peeling the membrane filter, a transparent and uniform composite film of cationic palladium porphyrin and synthetic saponite on glass was obtained.

The obtained composite film was measured for the absorption spectrum by an ordinary transmission method using an ultraviolet-visible spectrophotometer. The maximum absorption wavelength of the cationic palladium porphyrin in the aqueous solution was 417 nm, but the maximum absorption wavelength in the composite film was 470 nm. That is, it was shown that the cationic palladium porphyrin was inserted between the layers of the layered silicate.
The obtained composite film was put into a normal quartz fluorescent cell, and a sample was set at 45 degrees with respect to the excitation light incident angle by a fluorescence spectrophotometer, and an emission spectrum was measured. The excitation wavelength was set at 470 nm. A 520 nm cut filter was installed in the optical path on the detector side. The atmosphere in the quartz cell was under air, nitrogen gas, and oxygen gas, and the emission spectrum was measured in each case. Here, the luminescence emitted by the cationic palladium porphyrin is phosphorescence. FIG. 1 shows phosphorescence spectra of the composite film under air gas, nitrogen gas, and oxygen gas. Compared with nitrogen, the phosphorescence intensity decreased significantly under air. Moreover, the phosphorescence intensity further decreased under oxygen. That is, the obtained composite film of cationic palladium porphyrin and synthetic saponite functioned as an oxygen detector composition.

Example 2
The emission spectrum of a composite membrane of cationic palladium porphyrin and synthetic saponite was measured in a water vapor saturated atmosphere. The composite film obtained in Example 1 was put into a normal quartz fluorescent cell, and a sample was set at 45 degrees with respect to the excitation light incident angle by a fluorescence spectrophotometer, and the emission spectrum was measured. The excitation wavelength was set at 470 nm. A 520 nm cut filter was installed in the optical path on the detector side. The atmosphere in the quartz cell was under air, nitrogen gas, and oxygen gas, and the emission spectrum was measured in each case. At that time, gas was introduced into the quartz cell via water. As a result, the gas is almost saturated with water vapor. FIG. 2 shows phosphorescence spectra of the composite film under air, nitrogen gas, and oxygen gas. Compared with nitrogen, the phosphorescence intensity decreased significantly under air. Moreover, the phosphorescence intensity further decreased under oxygen. That is, the obtained composite film functioned as an oxygen detector composition even under water saturation.

Example 3
The light resistance of the composite film of cationic palladium porphyrin and synthetic saponite was evaluated. The composite film obtained in Example 1 was put into a normal quartz fluorescent cell, and a sample was set at 45 degrees with respect to the excitation light incident angle by a fluorescence spectrophotometer, and the emission spectrum was measured. The excitation wavelength was set at 470 nm. A 520 nm cut filter was installed in the optical path on the detector side. The atmosphere in the quartz cell was steam saturated nitrogen, and the emission spectrum was measured 100 times repeatedly. No decrease in emission intensity was observed after 100 measurements.

Example 4
The durability of the composite membrane of cationic palladium porphyrin and synthetic saponite to water was evaluated. The operation of filling the quartz cell containing the composite film obtained in Example 1 with water and drying was repeated, and the absorption spectrum was measured. As a result, the composite membrane was extremely stable against immersion in water, and the cationic palladium porphyrin always maintained an equivalent absorption spectrum. Despite being water-soluble, the cationic palladium porphyrin molecule was stably present in the composite membrane and did not dissolve in water at all.

Example 5
The transparent and uniform cationic platinum porphyrin was carried out in exactly the same manner as in Example 1 except that the cationic palladium porphyrin was replaced with the cationic platinum porphyrin tetrakis (1-methyl-pyridinium-4-yl) porphyrinatoplatinium. And a composite film of synthetic saponite was obtained. As a result of measuring the phosphorescence intensity of this composite film in the same manner as in Example 1, the phosphorescence intensity was dependent on the oxygen concentration. That is, the obtained composite film of cationic platinum porphyrin and synthetic saponite also functioned as an oxygen detector composition.

FIG. 1 is an emission spectrum of a composite film of cationic palladium porphyrin and synthetic saponite. In the figure, the vertical axis represents emission intensity (arbitrary unit), and the horizontal axis represents wavelength (nm). As shown in the figure, the spectra are under nitrogen, air, and oxygen. FIG. 2 is an emission spectrum of a composite film of cationic palladium porphyrin and synthetic saponite in a steam saturated atmosphere. In the figure, the vertical axis represents emission intensity (arbitrary unit), and the horizontal axis represents wavelength (nm). As shown in each figure, the spectra are under nitrogen, air, and oxygen saturated with water vapor.

Claims (3)

A detection agent using a luminescent substance whose luminescence intensity and lifetime is quenched by oxygen is present in an oxygen-free package, and the detection state is detected by irradiating the detection agent with visible light or ultraviolet light from the outside. A detection agent composition for use in a method for detecting oxygen, wherein the luminescent material is a complex in which a cationic metalloporphyrin is inserted between layers of a layered silicate and has excellent water resistance oxygen detecting agent composition. The oxygen detector composition according to claim 1, wherein the layered silicate is a layered silicate selected from the smectite group. In the method for detecting oxygen in an oxygen-free package, a detection agent using a luminescent material whose luminescence intensity and lifetime are quenched by oxygen is present in the oxygen-free package, and visible light is externally applied to the detection agent. Or a method for detecting oxygen in an oxygen-free package by irradiating ultraviolet light, wherein the luminescent material is a composite in which cationic palladium porphyrin is inserted between layers of a layered silicate A method for detecting oxygen in an oxygen-free packaging body, characterized by being a body .

Images