KR100343753B1 - Instrument for determining Bilirubin concentration and Hemoglobin content - Google Patents

Abstract

The present invention relates to a bilirubin concentration and a hemoglobin content measuring device, wherein a sample insert hole is provided in which a cell holder 10 into which a capillary tube 11 containing a sample solution is coupled and separated and a sample container 20 containing blood are formed. A device body, a lamp 100 installed inside the device body to emit a light source, a condenser lens 110 for condensing a light source emitted from the lamp 100, and condensed by the condenser lens 110 A heat insulating filter 200 for transmitting the light source to the sample liquid contained in the capillary tube 11, a main half mirror 120 and an auxiliary half mirror 130 for dividing the wavelength passing through the sample liquid into two parts; Through the half-mirror 120 and the auxiliary half-miller 130, the two-component solar component passes only the dominant wavelength filter having a wavelength of 455 nm, and only the wavelength having a monochromatic component of 575 nm. Negative wavelength pass filter 220 and wave The amount of light transmitted through the hemoglobin pass filter 230, the dominant wavelength pass filter 210, the sub-wave pass filter 220, and the hemoglobin pass filter 230, the field passing only the wavelength of 530nm monochromatic component current. Light passing through the hemoglobin pass filter 230 at the light receiving device 300 for converting the light into a light source, the amplifier 400 for amplifying the current converted by the light receiving device 300, and the sub-wavelength amplified by the amplifier 400. Switch that switches the wavelength of the control switch 910 according to the amount of light passed through the dominant wavelength filter 210 and the control switch 910 according to the cell holder 10 and the sample container 20 installed in the sample insertion opening 900 and the voltage difference between the maximum wavelength, the negative wavelength, and the maximum value of hemoglobin amplified by the amplifier 400 by the control switch 910 having a contact point defined by the switching switch 900 through the log converter 500. Recognize the dominant wavelength filter 210 and the sub-wave filter 220 And a control unit 600 for comparing and analyzing the wavelength values of the monochromatic components read by the hemoglobin pass filter 230, and converting the analog signal by the A / D converter 700 into the wavelength values compared and analyzed by the control unit 600. Consists of a display unit 800 that converts and displays a signal and measures the concentration of bilirubin in the blood and the content of hemoglobin in the bile, and the presence of jaundice, anemia and anemia. Of the hemoglobin containing the concentration of bilirubin or red blood cells in the blood by placing the bilirubin test cell holder 10 or the hemoglobin test sample container 20 at the sample insertion hole formed in the device body. By accurately measuring the amount, it is possible to perform appropriate treatment according to jaundice value and hemoglobin content.

Description

Instrument for determining Bilirubin concentration and Hemoglobin content

The present invention relates to a measuring device for checking the presence of jaundice, anemia and anemia in the blood by measuring the concentration of bilirubin (red pigment in the bile) and the content of hemoglobin in the blood. Indirectly measures the amount of bilirubin in the blood by measuring the concentration change of the plasma color, which is changed according to the amount of bilirubin contained in the blood, and the amount of bilirubin measured by the photometer is displayed as a numerical value through the display. At the same time, the content of hemoglobin contained in the red blood cells of the blood is indirectly measured by a photometer so that the amount of bilirubin measured by the photometer can be easily expressed numerically through a display unit. It relates to a content measuring instrument.

In general, blood contains bilirubin, which is produced by the reduction of hemoglobin and biliberdin, which are the pigment proteins that carry oxygen in red blood cells.

However, if the blood contains an excessive amount of bilirubin, such as hemolytic anemia and jaundice, as well as disorders such as hepatitis, rabies.

In addition, when the amount of hemoglobin contained in the red blood cells in the blood is low, the red blood cells are destroyed and symptoms such as hemolytic anemia appear, as well as the black blood that turns the blood dark brown and the skin or nails become black. Is caught.

Therefore, when the test subject appears, the blood of the test subject is collected and the bilirubin level is measured by measuring the bilirubin level by measuring the concentration of bilirubin, thereby performing appropriate treatment according to the jaundice component. Of course, the amount of hemoglobin contained in the red blood cells in the blood is examined by using a hemoglobin content measuring device to perform treatment accordingly.

Herein, the conventional bilirubin concentration measuring device includes a device main body having a sample insertion hole provided with a cell holder for coupling and separating a capillary tube containing a sample liquid, a lamp installed inside the device main body to emit a light source, and from the lamp A condenser lens for condensing the emitted light source, an insulating filter for transmitting the light source condensed by the condenser lens to the sample liquid contained in the capillary tube, a half mirror for dividing the wavelength passing through the sample liquid into two, and the half mirror The main wavelength filter and the sub-pass filter for passing the two-component photovoltaic component through only the main wavelength of 455 nm monochromatic component and the sub-wavelength of 575 nm monochromatic component, respectively, A light receiving element for converting the amount of light transmitted through the pass filter into a current, an amplifier for amplifying the current converted in the light receiving element, and a phase A control unit for recognizing the voltage difference between the amplified main wavelength and the sub-wavelength amplified by the preamplifier through a log converter and comparing and analyzing the wavelength values of the monochromatic components read by the main wavelength filter and the sub-wavelength filter, and the comparative analysis by the controller And a display unit for converting an analog signal into a digital signal and displaying the wavelength value by an A / D converter.

Such a conventional bilirubin concentration meter operates the power switch of the device so that the electric energy is supplied to the lamp, and then emits the lamp, and then inserts the sample container containing the sample liquid into the sample insertion hole formed in the device body, The light source of the lamp emitted by the light is collected by the condenser lens and transmitted through the sample liquid contained in the sample container while the heat is blocked by the adiabatic filter.

The light source passing through the sample liquid is divided into half wavelengths by the half-mirror, the dominant wavelength having a wavelength of 455 nm and the sub-wavelength having a wavelength of 575 nm.

On the other hand, as described above, the 455nm monochromatic component of the divided wavelength passes through the dominant wavelength pass filter that passes only the 455nm monochromatic component, and the monochromatic component passed through the dominant wavelength pass filter passes through the sample liquid contained in the capillary tube. The wavelength value of the monochromatic component obtained by the reaction is changed into a current by the light receiving element, and the wavelength value of the solar component changed into a current by the light receiving element is amplified by the amplifier.

In addition, the monochromatic component having a wavelength of 575 nm passes through the sub-wavelength filter passing only the monochromatic component of 575 nm, and the monochromatic component passing through the sub-wave pass filter reacts while passing through the sample liquid contained in the capillary tube. The wavelength value of is changed into a current by the light receiving element, and the wavelength value of the monochromatic component changed into a current by the light receiving element is amplified by the amplifier.

As described above, the wavelength value of the monochromatic component amplified by the amplifier is recognized by the controller through a log converter to compare and analyze the wavelength values of the monochromatic component read by each of the dominant wavelength filter and the sub-wavelength filter. In this wavelength value, the analog signal is converted into a digital signal by an A / D converter.

The digital signal converted by the A / D converter displays a comparatively analyzed wavelength value of the monochromatic component read by the sub-wavelength filter and the sub-wavelength filter through the display unit.

On the other hand, the wavelength value of the solar component amplified by the amplifier is recognized by the control unit through a log converter to compare and analyze the wavelength values of the monochromatic components read by each of the dominant wavelength pass filter and the sub-wave pass filter. If the measured wavelength value is too high or lower than the reference value set on the display of the equipment, the alarm judge determines the presence of an alarm and then displays it on the display.

As described above, the presence or absence of jaundice is determined according to the numerical value indicated on the display unit, and the treatment appropriate to the numerical value of the jaundice shown on the display unit is performed.

However, such a conventional bilirubin concentration meter has a maximum absorbance of bilirubin at 455 nm, where the hemoglobin absorbance is the same as at 575 nm, and the bilirubin absorbance at 575 nm maintains straightness, thus canceling absorbance of 455 nm and pure bilirubin In order to measure the amount of hemoglobin contained in the blood, the amount of hemoglobin contained in the red blood cells in the blood is measured by using a separate hemoglobin content measuring instrument and the treatment accordingly. By doing so, there is a problem that requires a long inspection period, as well as a large inspection cost.

An object of the present invention, in order to solve the problems as described above, the device body is formed with a sample holder is provided with a cell holder and a sample holder containing blood and the capillary tube is coupled and separated containing the sample liquid, and the inside of the device body A lamp installed at the light source, a light condensing lens for condensing the light source emitted from the lamp, a light condensing light source collected from the light condensing lens, and a heat insulating filter allowing the sample liquid contained in the capillary tube to pass through the sample liquid. The main half-mirror and the sub-half miller which split one wavelength, and the main wave pass filter and the wavelength through which the solar component divided through the main half-mirror and the sub-half mirror only pass the dominant wavelength of 455 nm monochromatic component A sub-wave pass filter for passing only a wavelength of 575 nm monochromatic component and a hemoglobin pass filter for passing only a wavelength of 530 nm monochromatic component, A light receiving element for converting the amount of light transmitted through the dominant wavelength filter, the sub-pass filter and the hemoglobin pass filter into a current, an amplifier for amplifying the current converted in the light-receiving element, and a sub-wavelength amplified by the amplifier A switching switch for converting the amount of light passing through the hemoglobin pass filter and the light passing through the dominant wavelength pass filter into a cell holder and a sample passage of the control switch according to a cell holder installed at the sample insertion port, and comparing the wavelength values; The monochromatic component read from the dominant pass filter, the sub pass filter, and the hemoglobin pass filter by recognizing the voltage difference between the main wavelength, the sub wavelength, and the maximum value of the hemoglobin amplified by the amplifier by the control switch whose contact is defined by the switch. And a control unit for comparing and analyzing the wavelength values of the A and D converters. It consists of a display unit for converting and displaying an analog signal into a digital signal. By measuring the concentration of bilirubin (red pigment in the bile) and the content of hemoglobin in the blood, the presence of jaundice, anemia and black blood disease When the abnormality is examined, the bilirubin test cell holder or the hemoglobin test sample container is installed at the sample insertion hole formed in the main body of the device to accurately measure the concentration of bilirubin and the amount of hemoglobin contained in the red blood cells in the blood. The present invention provides a bilirubin concentration and a hemoglobin content measuring instrument that enables proper treatment according to jaundice value and hemoglobin content.

1 is a circuit diagram of a bilirubin concentration and hemoglobin content measuring instrument according to the present invention

Explanation of symbols on the main parts of the drawings

10 cell holder 11 capillary tube

20: sample container 100: lamp

110: condenser lens 120: Zhu half mirror

130: auxiliary half-miller 200: insulation filter

210: dominant wavelength filter 220: sub-wavelength filter

230: hemoglobin pass filter 300: light receiving element

400: amplifier 500: log converter

600: control unit 700: A / D converter

800: display unit 900: switching switch

910: control switch log converter

Hereinafter, the technical configuration of the present invention with reference to the accompanying drawings in detail.

As shown in FIG. 1, the bilirubin concentration and hemoglobin content measuring device includes a cell holder 10 to which a capillary tube 11 containing a sample solution is coupled and separated, and a sample container 20 containing blood. A device body having a sample insertion hole provided therein, a lamp 100 installed inside the device body to emit a light source, a condenser lens 110 to condense a light source emitted from the lamp 100, and the condenser lens A heat insulating filter 200 for transmitting the light source collected at 110 to the sample liquid contained in the capillary tube 11, and a main half mirror 120 and an auxiliary half mirror for dividing the wavelength passing through the sample liquid. 130), and a main wavelength pass filter 210 which passes only the dominant wavelength having a monochromatic wavelength of 455 nm through the solar component divided into two parts through the main half miller 120 and the auxiliary half miller 130, and the wavelength of 575 nm. Negative wavelengths that pass only wavelengths that are monochromatic The hemoglobin pass filter 230 which passes only the overfilter 220 and the wavelength having a monochromatic component of 530 nm, and the dominant wavelength pass filter 210, the sub-wave pass filter 220, and the hemoglobin pass filter 230. Hemoglobin pass filter in the light receiving element 300 for converting the amount of transmitted light into the current, the amplifier 400 for amplifying the current converted in the light receiving element 300, and the sub-wavelength amplified by the amplifier 400 The amount of light passing through the 230 and the light passing through the dominant wavelength pass filter 210 are converted into the wavelength of the control switch 910 according to the cell holder 10 and the sample passage 20 installed at the sample insertion opening. The voltage difference between the maximum wavelength, the negative wavelength, and the maximum value of the hemoglobin amplified by the switching switch 900 and the control switch 910 whose contact is determined by the switching switch 900, and the amplifier 400 is compared. Recognized through the log converter 500 and the negative wavelength filter 210 and the negative A / D converter 700 compares the wavelength value of the monochromatic component read by the long pass filter 220 and the hemoglobin pass filter 230 with the wavelength value analyzed by the control unit 600. And a display unit 800 for converting and displaying an analog signal into a digital signal.

In the present invention configured as described above, when measuring bilirubin, the blood of the bilirubin test subject is collected, and the sample liquid necessary for the jaundice measurement is collected by a blood separator and then placed in the capillary tube (11).

A device body in which a sample holder into which a cell holder 10 into which a sample solution containing capillary tube 11 is coupled and separated, and a sample container 20 containing blood are formed, and which are installed inside the device body to emit a light source The condenser 100, the condenser lens 110 condensing the light source emitted from the lamp 100, and the condensed light source from the condenser lens 110 to the sample liquid contained in the capillary tube 11.

The capillary tube 11 containing the sample liquid as described above is inserted into the cell holder 10 installed at the sample insertion hole.

When the capillary tube 11 is fixedly inserted into the cell holder 10, the lamp 100 is emitted by operating a power switch of the device so that electric energy is supplied to the lamp 100.

The light source of the lamp 100 emitted by the electric energy is collected by the condenser lens 110.

The light source of the lamp 100 collected by the condenser lens 110 is transmitted to the sample liquid contained in the capillary tube 11 by the adiabatic filter 200.

The light source passing through the sample liquid is divided into half wavelengths by the half-mirror with a 455 nm monochromatic component and a wavelength of 575 nm monochromatic component.

On the other hand, the divided wavelength as described above, the monochromatic component passes through the dominant wavelength filter 210 passing only the monochromatic component of 455nm, the monochromatic component passed through the dominant wavelength pass filter 210 is the capillary tube (11) The wavelength value of the monochromatic component obtained by reacting while passing through the sample liquid contained in the sample is changed into a current by the light receiving element 300, and the wavelength value of the solar component changed into a current by the light receiving element 300 is the amplifier 400. Is amplified through.

In addition, the wavelength of the monochromatic component having a wavelength of 575 nm passes through the auxiliary wavelength passing filter, and the monochromatic component passing through the auxiliary wavelength passing filter passes through the sample liquid contained in the capillary tube 11 to react with the wavelength of the monochromatic component. The wavelength value of the monochromatic component changed into a current by the light receiving element 300 and changed into a current by the light receiving element 300 is amplified by the amplifier 400.

As described above, the wavelength value of the monochromatic component amplified by the amplifier 400 is recognized by the control unit 600 through the log converter 500, and the monochromatic component read by each dominant wavelength filter 210 and the auxiliary wavelength filter. Compare and analyze the wavelength value of the analog signal, the analog signal is converted into a digital signal by the A / D converter 700.

The digital signal converted by the A / D converter 700 displays a comparatively analyzed wavelength value of the monochromatic component read by each of the auxiliary wavelength filter and the dominant wavelength filter 210 through the display unit 800.

On the other hand, the wavelength value of the monochromatic component amplified by the amplifier 400 is recognized by the control unit 600 through the log converter 500 and the monochromatic component read by each of the auxiliary wavelength filter and the dominant wavelength filter 210. As a result of the comparative analysis of the wavelength value, when the comparatively analyzed wavelength value is too high or lower than the reference value set in the display unit 800 of the device, the presence or absence of an alarm is determined by an alarm determiner and then displayed on the display unit 800. .

As described above, the presence or absence of jaundice may be determined according to the numerical value displayed on the display unit 800, and treatment appropriate to the numerical value of the jaundice displayed on the display unit 800 may be performed.

In addition, at the time of measuring the content of hemoglobin contained in the red blood cells of blood, the blood of the hemoglobin test subject is sampled and put into the sample container 20.

When the sample container 20 containing the sample liquid is inserted into the sample insertion hole as described above, the switching switch 900 detects this and changes the contact point of the control switch 910.

When the contact point is changed by the control switch 910, the light source of the lamp 100 collected by the condenser lens 110 is transmitted to the sample liquid contained in the sample container 20 by the adiabatic filter 200, and the sample The light source passing through the liquid is divided into a main wavelength of 455 nm of monochromatic component and a hemoglobin wavelength of 530 nm of monochromatic component by the main half miller 120 and the auxiliary half miller 130 to pass the main wavelength filter 210. And the hemoglobin pass filter 230 is changed into a current by the light receiving element 300, respectively, and the wavelength value of the solar component changed into a current by the light receiving element 300 is amplified through the amplifier 400, respectively. After the log converter 500 is recognized by the control unit 600 to compare and analyze the wavelength values of the monochromatic components read by each of the dominant wavelength filter 210 and the hemoglobin pass filter 230, the comparative analyzed wavelength Value is analog signal by A / D converter 700 It is converted into a digital signal.

The digital signal converted by the A / D converter 700 displays the comparatively analyzed wavelength values of the monochromatic components read by the sub-wave filter 220 and the hemoglobin pass filter 230 through the display unit 800.

On the other hand, the wavelength value of the monochromatic component amplified by the amplifier 400 is recognized by the control unit 600 through the log converter 500 and the wavelength of the monochromatic component read by each of the auxiliary wavelength filter and the hemoglobin pass filter 230. As a result of the comparative analysis, when the comparatively analyzed wavelength value is too high or lower than the reference value set in the display unit 800 of the device, the presence or absence of an alarm is determined by the alarm determiner and then displayed on the display unit 800.

As described above, the degree of hemolytic anemia such as erythrocytes being destroyed may be measured according to the numerical value displayed on the display unit 800, and the treatment suitable for the hemoglobin level displayed on the display unit 800 may be performed.

Therefore, the present invention, by measuring the concentration of bilirubin (Bilirubin: red pigment contained in the bile) and the content of hemoglobin (Hemoglobin) in the blood, when the presence of jaundice and anemia and abnormality of the black blood cells, By installing the bilirubin test cell holder 10 or the hemoglobin test sample container 20 at the sample inlet, the display unit 800 accurately measures the concentration of bilirubin or the amount of hemoglobin contained in the red blood cells in the blood. It is a very useful invention that has the effect of performing a suitable treatment depending on the numerical value and the content of hemoglobin.

Claims (1)

A device body in which a sample holder into which a cell holder 10 into which a sample solution containing capillary tube 11 is coupled and separated, and a sample container 20 containing blood are formed, and which are installed inside the device body to emit a light source The lamp 100, the condenser lens 110 condensing the light source emitted from the lamp 100, and the light source condensed by the condenser lens 110 are transmitted to the sample liquid contained in the capillary tube 11. Dividing through the adiabatic filter 200, the main half miller 120 and the auxiliary half miller 130 so that the wavelength passing through the sample liquid is divided into two, and the main half miller 120 and the auxiliary half miller 130 The wavelength bandpass filter 210 for passing the photovoltaic component only to the dominant wavelength of 455 nm and the wavelength bandpass filter 220 for passing only the wavelength of 575 nm to the monochromatic component and the wavelength component of 530 nm. Hemoglobin pass filter 230 that passes only the phosphorus wavelength, and A light receiving element 300 for converting the amount of light transmitted through the dominant wavelength filter 210, the sub-wave pass filter 220, and the hemoglobin pass filter 230 into a current, and is converted in the light receiving element 300 The amplifier 400 for amplifying the current, and the amount of light passing through the hemoglobin pass filter 230 and the light passing through the dominant wavelength pass filter 210 at the sub-wave length amplified by the amplifier 400 are installed at the sample insertion port. A switch switch 900 for converting the contact point of the control switch 910 according to the cell holder 10 and the sample container 20 to compare the wavelength value, and a control switch having a contact point defined by the switch switch 900 ( Recognizing the voltage difference between the main wavelength, the sub-wavelength and the hemoglobin maximum value amplified by the amplifier 400 by the 910 through the log converter 500, the main wavelength filter 210 and the sub-wave filter 220 and hemoglobin Comparative analysis of the wavelength values of the monochromatic components read by the pass filter 230 The fisherman 600 and the display unit 800 for converting the analog signal into a digital signal by the A / D converter 700, the wavelength value compared and analyzed by the control unit 600 and the bilirubin characterized in that Concentration and content of hemoglobin.