RU2001136035A - SPECTROPHOTOMETRIC DEVICE AND METHOD FOR DETERMINING THE BLOOD Glucose Level - Google Patents

Claims (18)

1. Spectrophotometric device for determining glucose in the blood, containing means of irradiation in the near infrared region, designed to continuously divide the spectrum of infrared light in the near infrared region in the wavelength range from 0.8 to 2.5 μm, into narrow spectral regions using acousto-optical tunable filter and irradiation of the measurement object, photoelectric conversion means for receiving and photoelectric conversion of light transmitted through the measurement object, irradiation ennogo a radiation means in the near infrared or reflected them, means for determining the concentration of glucose in the blood measurement object by analyzing the absorption spectrum, obtained on the basis of the detection signals obtained by the photoelectric conversion means. 2. The spectrophotometric device according to claim 1, in which the specified means of irradiation in the near infrared region contains a light source, an acousto-optic filter with a variable oscillation frequency, to which light comes from a light source, a high-frequency vibrator for applying acoustic vibrations to an acousto-optic filter with a variable oscillation frequency , a high frequency voltage generation unit for applying a high frequency voltage to a high frequency vibrator. 3. The spectrophotometric device according to claim 2, in which the material of the acousto-optical filter with a variable frequency of oscillation is a crystalline material with birefringence. 4. The spectrophotometric device according to claim 1, wherein the photoelectric conversion means comprises an element for receiving light passing through the measurement object and generating detection signals constituting an absorption spectrum. 5. The spectrophotometric device according to claim 1, wherein the means for determining glucose concentration comprises a unit for analyzing the shape of the absorption spectrum to which detection signals from the light receiving element are supplied, and a unit for calculating glucose concentration for converting the absorption spectrum to glucose concentration. 6. The spectrophotometric device according to claim 5, in which the absorption spectrum is a blood spectrum obtained by subtracting the spectrum of the normal state from the spectrum of the hemostatic state, which is obtained using an arithmetic device similar to image processing. 7. The spectrophotometric device according to claim 5, in which the wavelengths selected in the specified range of the absorption spectrum are converted values based on at least five wavelengths per 1.44 μm, 1.94 μm and in a band of 0.8 up to 2.5 microns. 8. The spectrophotometric device according to claim 1, in which the measurement object is a part of the human body, in which the concentration of glucose in the blood should be measured. 9. The spectrophotometric device according to claim 1, in which the fixing means for the measurement object is capable of causing blood stagnation by holding under pressure the portion of the human body where the measurement is made. 10. A spectrophotometric method for determining blood glucose, namely, that the measurement object is irradiated in the near infrared region with continuous light separation in the wavelength range from 0.8 to 2.5 μm into narrow spectral regions using an acousto-optic tunable filter and photoelectric conversion of light transmitted through or reflected from the irradiated measurement object determines the glucose concentration in the blood of the measurement object by analyzing the absorption spectrum obtained from the detectors signal from the photoelectric converter. 11. The spectrophotometric method according to claim 10, in which a high-frequency voltage is applied to the high-frequency vibrator for irradiation in the near infrared region, acoustic vibrations are transmitted from the high-frequency vibrator to the acousto-optic filter, the light incident on the acousto-optic filter with a variable oscillation frequency is transmitted, and emitted light in the near infrared in the wavelength range from 0.8 to 2.5 microns. 12. The spectrophotometric method of claim 10, wherein the acousto-optic tunable filter material is a birefringent crystalline material. 13. The spectrophotometric method according to claim 10, in which for photoelectric conversion, simultaneously the light transmitted through the object of measurement or reflected by it is supplied to the light receiving element and the detection signals are supplied that make up the absorption spectrum from the light receiving element. 14. The spectrophotometric method of claim 10, in which to determine the glucose concentration, simultaneously analyze the shape of the absorption spectrum, on which the signals from the element for receiving light are supplied, and convert the absorption spectrum to glucose concentration. 15. The spectrophotometric method of claim 10, in which the absorption spectrum is a blood spectrum obtained by subtracting the spectrum of the normal state from the spectrum of the hemostatic state, carried out by the arithmetic device by the method used in image processing. 16. The spectrophotometric method of claim 10, in which the wavelengths selected in the absorption spectrum are converted values based on at least five wavelengths per 144 μm, 1.94 μm and in the band from 0.8 to 2.5 microns. 17. The spectrophotometric method of claim 10, in which the measurement object is a part of the human body, in which the concentration of glucose in the blood is measured. 18. The spectrophotometric method of claim 10, in which the measurement object is a part where there is stagnation of blood flow, which is obtained by holding the measured area of the human body under pressure.