JP3356517B2 - Singlet oxygen analyzer - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an apparatus for measuring singlet oxygen by detecting near-infrared luminescence generated by singlet oxygen excited by irradiation with a laser having an ultraviolet wavelength.

[0002]

2. Description of the Related Art Singlet oxygen, superoxide, hydroxyl radical, hydrogen peroxide and the like are known as active oxygen. Among them, singlet oxygen has recently been produced due to lipid peroxidation, light damage and aging. It has been shown to play an important role in various reactions that occur in the body.

Hitherto, as a method for detecting singlet oxygen in a biological system or a solution system, a chemical detection method using a chemical reaction and a spectroscopic detection method for detecting luminescence due to molecular transition have been used.

[0004] The former chemical detection method is to add a chemical substance such as 2,2,6,6-tetramethylpiperidine or cholesterol which specifically reacts with singlet oxygen and measure the amount of the product, or An inhibitor of the effect of singlet oxygen,
For example, NaN ₃ , β-carotene, diphenylisobenzofuran, diazobicyclooctane and enhancer (D ₂ O)
To observe the change in the reaction.

[0005] The latter method of spectroscopic detection is a method of spectroscopically measuring the luminescence when the excited singlet oxygen molecule transitions to the ground state. The method of observing luminescence in the visible region due to luminescence and the method of observing near-infrared luminescence due to single-molecule transition.

[0006] Spectroscopic detection methods are more direct and more reliable than chemical methods, without affecting the system itself, and the method is the most direct excited singlet oxygen. It is considered a method for detecting molecules. However, the transition from the singlet to the triplet of the oxygen molecule is spin forbidden and orbital symmetry forbidden, and the accompanying light emission is extremely weak, so it has been said that there is a problem in terms of detection sensitivity.
It has been reported that excited singlet oxygen molecules have been detected along with the development of a detector with high sensitivity in the near infrared region.

On the other hand, as the excitation light source, any light source can be used in principle as long as it has a capability of generating light having a wavelength that is absorbed by the substance to be measured. Due to obstacles such as insufficient light quantity and difficulty in condensing due to incoherence,
Effective excitation was difficult.

Therefore, in recent years, it has various excellent characteristics such as monochromaticity, directivity, light condensing property, and high energy property, and has been applied to a wide range of fields such as photochemotherapy, and is being put to practical use. It has been studied to use a laser as an excitation light source.

[0009]

However, conventionally,
Since the laser used as the excitation light source was limited to the wavelength in the visible region, only the compounds having an absorption wavelength in the visible region were targeted for the measurement sample used for detecting singlet oxygen.

As a result, many compounds which have an absorption wavelength only in the ultraviolet wavelength region or have a very low absorbance in the ultraviolet region as compared with those in the visible region are used in pharmaceuticals, cosmetics, foods, and the like. Cannot be measured,
Furthermore, despite the fact that attention has been paid to the effects of ultraviolet rays on living organisms and the relationship between ultraviolet rays and active oxygen, conventional devices could not be applied to studies involving ultraviolet rays.

[0011]

Means for Solving the Problems In order to solve the above-mentioned problems, the present inventors have determined with high sensitivity the near-infrared emission of excited singlet oxygen molecules generated using a laser in the ultraviolet wavelength region as an excitation light source. A practical singlet oxygen measuring device has been put to practical use, and the present invention has been completed.

That is, the present invention provides a light source unit that oscillates a laser in the ultraviolet region, a modulation unit that modulates the intensity of the laser oscillated from the light source unit, irradiation of a sample solution, and irradiation of intensity-modulated laser light. Sample section with a flow cell that receives light, a spectroscope that selectively splits near-infrared light emitted from the flow cell by laser irradiation, a detection section that has a split near-infrared light emission detector, and output from the detector Is a singlet oximeter that includes an amplifier that amplifies the signal and an amplifying / recording unit including a display unit that displays a processing result of the amplified output signal.

[0013]

BRIEF DESCRIPTION OF THE DRAWINGS FIG.
The present invention will be further described. In FIG. 1, reference numeral 1 denotes a light source unit.
The light source section may be any one that continuously oscillates laser light in an ultraviolet wavelength range, and examples thereof include an argon laser and a helium-cadmium laser.

In FIG. 1, reference numeral 2 denotes a modulator, which modulates the intensity of the continuous laser light into pulsed light.
The intensity modulation in this modulation section is performed by an acousto-optic modulator 7 that performs intensity modulation of light by amplitude modulation of ultrasonic waves. The acousto-optic modulator may use, for example, a reference signal of the amplifier 14 described later and generate pulsed light having the same cycle as the phase of this signal.

Further, in FIG. 1, reference numeral 3 denotes a sample section, which is preferably provided with a flow cell 8 made of quartz. The flow cell is preferably provided with a sample circulation pump 9 for circulating a sample solution, and further provided with a blowing port 10 for bubbling oxygen gas.

In FIG. 1, reference numeral 4 denotes a detection unit, which focuses (condenses) near-infrared light emitted from the flow cell of the sample unit by a lens 11 and the like, splits the light by a spectroscope 12, and Convert to electrical signals. Note that the sample section 3 and the detection section 4 need to be dark boxes 17.

In FIG. 1, reference numeral 5 denotes an amplifying / recording unit, which is an amplifier 14 for amplifying an electric signal of the detecting unit, a recorder 16 for recording / displaying an emission spectrum, and for synchronizing and driving the recorder and the spectroscope. Wavelength configuration device 15
It has.

The measurement of singlet oxygen using the above-described apparatus of the present invention is performed as follows.

First, a laser beam in the ultraviolet region is oscillated by an excitation light source, and the laser beam is intensity-modulated. Then, the laser beam is irradiated on a sample solution in a flow cell in a sample section. As an excitation light source, an argon laser is preferably used, and intensity of a laser (light in the ultraviolet region) of 140 to 400 nm oscillated from the light source is preferably modulated by an acousto-optic modulator.

During the measurement, it is desirable to circulate the sample solution in the flow cell using a pump or the like, so that the effect of discoloration of the sample due to light irradiation can be prevented, and the gas is discharged during the measurement. It also allows you to breathe.

In addition, it is preferable to bubble high-purity oxygen gas into the sample solution to saturate the dissolved oxygen at the time of detection, thereby increasing the probability of energy transfer occurring, and increasing the detection sensitivity. Increase.

In the detection of the light emission of the sample solution irradiated with the laser light as described above, for example, the light emission is first focused (condensed) by a lens, and then the visible light is removed by a visible light cut filter.

Next, after selecting a wavelength through a spectroscope,
Light of the selected wavelength is received by a Ge-detector cooled with liquid nitrogen, and converted into an electric signal.

The electric signal thus converted is amplified by, for example, a lock-in amplifier and recorded on a recorder tuned to a spectroscope. The presence or amount of singlet oxygen can be measured.

Next, an example of singlet oxygen measurement using the apparatus of the present invention configured as described above will be described.

Test Example [Measurement Apparatus] A singlet oxygen measurement apparatus was constructed as follows. (1) Light source unit: Argon laser (Innova 70-4) manufactured by Coherent (2) Intensity modulation unit: IntraActio
n) Acousto-optic modulator (ASM-702-8, ME-70) (3) Flow cell: quartz flow cell (cell length 3m)
m; capacity 0.18ml)

(4) Circulation pump and bubbling device: Peristaltic pump TST manufactured by Iwaki Glass Co., Ltd.
-100 High-pressure oxygen gas cylinder (5) Visible light filter, spectroscope and detector: colored glass filter (IR-80) JASCO spectrometer (CT-10, slit width 2 mm) Applied Detector Ge
-Detector (Model 403 HS; liquid nitrogen cooling) (6) Amplifier EG & G Princeton Applied Research (EG
& G Princeton Applied Research) lock-in amplifier (Model 124A, 116)

[Measurement Method] As a measurement sample, a 20 μM solution of hematoporphyrin, for which it was extremely difficult to measure singlet oxygen, because the emission intensity in the visible wavelength region was weak, was used. This hematoporphyrin solution was circulated in the flow cell at a rate of 20 ml / min. In addition, high-purity oxygen gas was introduced into the flow cell at 2000 ml / mi.
I blew it with n.

The cell was irradiated with a laser having a wavelength of 350 to 365 nm (the maximum absorption wavelength of hematoporphyrin). When the emission spectrum in the near infrared region generated by this irradiation was examined, it was confirmed that there was a peak at 1268 nm (FIG. 2). This peak is associated with the transition of the excited singlet oxygen molecule.

Next, when the concentration of hematoporphyrin was changed and the emission intensity at 1268 nm was examined, it was recognized that the concentration was almost linear at a low concentration (FIG. 3).

[0031]

In the past, even if a laser in the ultraviolet wavelength range was irradiated, the near-infrared emission of excited singlet oxygen was weak and it was difficult to detect it. The modulation enables the near-infrared light emission to be enhanced and detected.

Therefore, (1) the measurement of the amount of singlet oxygen produced from a compound having an absorption wavelength only in the ultraviolet wavelength region,
(2) High-sensitivity measurement of singlet oxygen in compounds having a larger absorption wavelength in the ultraviolet wavelength region than in the visible wavelength region, (3) Relationship between ultraviolet and singlet oxygen, (4) Ultraviolet and single effects on biological systems It can be applied as a means for knowing the influence of oxygen.

[0033]

As described above, according to the singlet oxygen measuring apparatus of the present invention, since the excitation light in the ultraviolet wavelength region is irradiated, the singlet oxygen measuring device has absorption only in the ultraviolet wavelength region where measurement was impossible up to now. Singlet oxygen of the compound can be measured. In addition, singlet oxygen of the compound, which has extremely low absorption in the visible wavelength region as compared with that in the ultraviolet wavelength region and is extremely difficult to measure, can be measured with high sensitivity.

Furthermore, it is very useful in knowing the relationship between ultraviolet rays and singlet oxygen and the effects of ultraviolet rays and singlet oxygen on living systems.

[Brief description of the drawings]

FIG. 1 is a drawing showing a singlet oxygen measuring device of the present invention.

FIG. 2 is a drawing showing an emission spectrum of a hematoporphyrin solution in a near infrared region.

FIG. 3 is a drawing showing the relationship between the concentration of a hematoporphyrin solution and the emission intensity.

[Explanation of symbols]

 1: Light source 11: Lens 2: Modulator 12: Spectroscope 3: Sample 13: Detector 4: Detector 14: Amplifier 5: Amplifier / Recorder 15: Wavelength component device 6: Laser oscillator 16: Recorder 7: Acousto-optic modulator 17: Dark box 8: Flow cell 9: Sample circulation pump 10: Oxygen gas inlet

──────────────────────────────────────────────────続 き Continuation of front page (72) Inventor Akemi Kasa 3-2-2 Funato, Abiko-shi, Chiba (56) References JP-A-5-273130 (JP, A) JP-A-5-34290 (JP, A) Japanese Translation of International Publication No. 3-500817 (JP, A) Yasutoshi Muto et al., Measurement of lipid peroxide in vivo by ultra-low light emission and research on its clinical significance, Research Fund for Metabolic Disorders, 11th Collection 1984, Japan, December 7, 1984, PAGE. 148-157 Akasa Kasa et al., Production of Singlet Oxygen and Peroxidation of Skin Epidermis by Porphyrin from Propionibacterium acnes, Journal of Japan Cosmetic Science, Japan, May 25, 1995, Vol. 19 / NO. 1, PAGE. 1-6 (58) Field surveyed (Int.Cl. ⁷ , DB name) G01N 21/62-21/74 G01N 33/48-33/98 JICST file (JOIS)

Claims (4)

(57) [Claims] 1. A light source unit for oscillating a laser in an ultraviolet region, a modulation unit for intensity-modulating a laser oscillated from the light source unit, a flow cell for circulating a sample solution and receiving irradiation with intensity-modulated laser light. Sample section equipped with a spectroscope that selectively disperses near-infrared light emitted from the flow cell by laser irradiation, a detection section that has a separated near-infrared light emission detector, and amplifies the output from the detector amplifier,
And a singlet oximeter comprising an amplifying / recording unit having a display means for displaying a processing result of the amplified output signal. 2. The singlet oximeter according to claim 1, wherein the intensity modulation is performed by an acousto-optic modulator. 3. The singlet oximeter according to claim 2, wherein the signal detected by light detection is synchronously amplified by a reference signal. 4. The singlet oxygen measuring apparatus according to claim 1, wherein the flow cell is a flow cell into which oxygen can be blown.