JP2003021593A - Specimen examination device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a specimen examination device, capable of rapidly and accurately analyzing large number of specimens or a very small amount of a specimen. SOLUTION: Tubular daughter specimen vessels 6 housing the specimens are held on a conveying rack 4. The light emitting part 21, arranged above the daughter specimen vessels 6 emits examination light downwardly and the examination light incident on the daughter specimen serum 30, in each of the daughter specimen vessels 6 from above transmits through the serum downwardly. The transmitted light passes through each of the light transmission holes 10, formed on the conveying rack 4 to be detected by a transmitted light detection part 8, arranged under the conveying rack 4. The light irradiation part 2 and the transmitted light detection part 8 can change over a measurement wavelength to one or more kinds of measurement wavelengths, and by changing over the measurement wavelength in a time-shared manner, the daughter specimen serum 30 is successively measured, on the basis of a plurality of measurement wavelengths different from each other.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a sample testing device, and more particularly to a device having a function of optically analyzing a test substance such as chyle in a blood sample.

[0002]

2. Description of the Related Art A test for analyzing serum in blood is the most frequently used technique in the field of specimen test for testing the health condition and allergic constitution of a subject. In the analysis of this serum, the serum is separated from the collected blood by centrifugation, and the serum is dispensed for each analysis item to prepare a child sample. Then, the child sample is analyzed by the analyzer. At this time, it is known that an error occurs in the test result when hemolyzed hemoglobin, bilirubin, and chyle, which are so-called interfering substances, are present in the serum. Therefore, it is necessary to check the presence or absence of these interfering substances, their concentrations, etc. and reflect them in the analysis result before the sample is applied to the analyzer.

Conventionally, the process before the analysis was visually performed by an examiner, but the process speed is limited, and it is difficult to rapidly process a large amount of samples such as a mass examination.
Further, in the visual inspection, it is difficult to ensure the objectivity and quantitativeness of the determination level because the inspector may be affected by the physical condition and environment even if the same inspector is used.

From such a problem, Japanese Patent Laid-Open No. 7-28081
Japanese Patent Laid-Open No. 4 (1994) proposes a sample inspection system that automatically makes a determination in analysis pretreatment, not visually. The technique disclosed therein carries out an optical measurement from the side of a blood collection tube containing the centrifuged original serum.

[0005]

However, a vacuum blood collection tube in which the original serum is put and a sub-sample container into which the original serum is dispensed and subdivided have a label such as a bar code for identifying the sample in a hospital or a hospital. Since it is created and attached at an inspection center, there is a problem that optical measurement from the side is often difficult. Also in the prior art, considering this point,
A method is disclosed in which the serum is transferred to a separate container without a bar code label and the measurement is performed from the side. In such a method, an extra dispensing operation for transfer is required and another container is required, which causes a problem that the processing speed becomes slow and the inspection cost increases.

In many cases, the amount of the sub-sample is small, and the height of the sub-sample in the sub-sample container is very small, which may make it difficult to measure the optical transmittance from the side surface.

Further, the rack for transporting the sample container is
There is one that holds a plurality of sample containers upright in a two-dimensional array. In that case, there are a plurality of sample containers on the optical path of the inspection light from the side, and the measurement for each sample container is performed. It may not be possible to do so.

The present invention has been made to solve the above problems, and an object of the present invention is to provide a sample inspection apparatus capable of analyzing a large number of samples or a small amount of samples quickly and accurately.

[0009]

The above objects are achieved by the present invention described in (1) to (10) below.

(1) A light irradiator for vertically injecting a test light into a sample contained in a columnar sample container, a transmitted light detector for detecting transmitted light from the sample, and a transmitted light detector based on the transmitted light. In the sample inspection device having an analysis unit for analyzing the sample, the transmitted light detection unit and the light irradiation unit can switch the measurement wavelength to a plurality of types, and by switching the measurement wavelength in a time division manner. A sample inspection apparatus, wherein the sample is measured at a plurality of different measurement wavelengths.

(2) The sample inspection apparatus according to (1) above, wherein the switching of the measurement wavelength is performed by changing the wavelength characteristic of at least one of the transmitted light detection unit and the light irradiation unit.

(3) Based on the transmitted light, a light irradiator for vertically injecting the inspection light into the specimen contained in the columnar specimen container, a transmitted light detector for detecting the transmitted light from the specimen, and the transmitted light. And an analysis unit that analyzes the sample, wherein the light irradiation unit irradiates inspection light including light of a plurality of wavelengths, and the transmitted light detection unit is included in the transmitted light. Discriminate and detect light of multiple wavelengths,
A specimen inspection apparatus, which simultaneously measures the specimen at a plurality of different measurement wavelengths.

(4) The transmitted light detecting section has a light discriminating means for spectrally dividing the transmitted light by wavelength, and the specimen for spectroscopically detecting the transmitted light by the optical discriminating means. Inspection device.

(5) The sample inspection apparatus according to any one of (1) to (4), wherein the analysis unit obtains the concentration of the test substance contained in the sample based on the transmitted light.

(6) In the above (5), the analysis section has an absorbance determination means for determining the absorbance of the test substance based on the transmitted light and a concentration determination means for determining the concentration based on the absorbance. Sample inspection apparatus described.

(7) The sample testing apparatus according to (6), wherein the concentration determining means has a conversion table showing a relationship between the absorbance and the concentration.

(8) The sample inspection apparatus according to any one of (1) to (7) above, which analyzes a plurality of test substances contained in the sample based on the measurement results at the plurality of measurement wavelengths.

(9) The specimen testing apparatus according to (8), wherein the plurality of test substances include hemolyzed hemoglobin, chyle, or bilirubin.

(10) A plurality of the sample containers are arranged in parallel on a transport rack, and the transport rack is configured to allow light to pass through in the vertical direction of the position where the sample containers are arranged,
The sample inspection apparatus according to any one of (1) to (9), wherein the light irradiation unit and the transmitted light detection unit are arranged to face each other with the sample container and the transport rack interposed therebetween.

[0020]

BEST MODE FOR CARRYING OUT THE INVENTION Next, a sample test apparatus (blood test apparatus) according to an embodiment of the present invention will be described with reference to the drawings. This device measures the concentration of the hemolytic hemoglobin, bilirubin, and chyle that are interfering substances that may be contained in the serum, by examining the serum sample dispensed in the test tube-shaped sample container 6 (sample container). To do.

In this apparatus, when the transport rack 4 is transported to the position where the optical measurement section is provided, the transport rack 4 causes the optical measurement section to pitch the test tube holes for holding the sub-sample containers 6, that is, The sub-sample containers 6 are relatively moved (pitch feed) by the arrangement pitch of the sub-sample containers 6, and the sub-sample containers 6 arranged on the transport rack 4 are sequentially scanned. FIG. 1 is a cross-sectional view of the optical measurement unit on a plane along the scanning direction.
The optical measurement unit includes a light irradiation unit 2 for injecting test light onto the sub-sample serum (sample) 30 and a transmitted light detection unit 8 for detecting transmitted light obtained by transmitting the test light through the sub-sample serum 30. Become. This device observes transmitted light and determines the concentration of the test substance based on the change in the transmitted light compared with the inspection light.

The characteristic of this apparatus is that the inspection light is incident on the specimen along the vertical direction. In the example shown in FIG.
Sub-sample container 6 in which light irradiation unit 2 stands on transport rack 4
Is arranged above and emits inspection light downward. The transmitted light detection unit 8 is arranged below the transport rack 4 and detects light from above. That is, the sub-sample serum 30 is contained in a vertically elongated sub-sample container 6 such as a test tube,
The inspection light is vertically transmitted through the child sample serum 30. The transmission direction may be from top to bottom or from bottom to top. When the sub-sample container 6 has a columnar shape, the top surface and the bottom surface thereof are generally openings or have a small area, so that they are not used for labeling or the like and can easily be configured to transmit light. Further, the irradiation position of the inspection light and the observation position of the transmitted light are basically determined by the horizontal cross-section opening of the sub-sample container 6 regardless of the amount of the sub-sample serum 30, and it is not necessary to adjust the observation position according to the sample amount. is there. On the bottom surface of the transport rack 4, a light transmission hole 10 capable of transmitting light is provided at a position where the sub-sample container 6 stands. The light transmission hole 10 is formed of an opening or a transparent member.

With such a configuration, it is possible to analyze a plurality of sub-sample serums 30 respectively held in sub-sample containers 6 while standing on the transport rack 4. By relatively moving the light irradiation unit 2 and the transmitted light detection unit 8 and the transport rack 4, the transmitted light for the plurality of subsample serums 30 held on the transport rack 4 is measured. In the present invention, since the light is transmitted in the vertical direction, the transport rack 4
Even when the sub-sample containers 6 are arranged in a two-dimensional array (matrix), the transmission of light is not blocked by the other sub-sample containers 6.

The light irradiator 2 is an LED (Light Emission D
iode) 20, a lens 22, irises 24 and 26, and a lens 28. The light from the LED 20 passes through the lens 22, the irises 24 and 26, and the lens 28 in this order, and is focused vertically downward. The focused inspection light passes through the upper opening of the sub-sample container 6 standing on the transport rack 4, and the sub-sample serum 3 contained in the sub-sample container 6
It is incident on 0, passes through the subsample serum 30 and the bottom surface of the subsample container 6, and is output as transmitted light. Transmitted light detector 8
Is the scanner plate 40, the lens 42, the filter 4
4 and a photodetector 46. The photodetector 46 is collimated by the scanner plate 40 and the lens 4
The transmitted light focused at 2 enters. The filter 44 selectively transmits a specific wavelength range of transmitted light.

In this apparatus, analysis is performed at four types of wavelengths in order to measure the concentrations of the above three types of interfering substances. The light irradiation unit 2 and the transmitted light detection unit 8 can switch the measurement wavelength among these four types of wavelengths. And the light irradiation unit 2
The transmitted light detection unit 8 switches the measurement wavelength for one sub-sample serum 30 in a time division manner, and sequentially performs measurement at four types of measurement wavelengths. When the measurement with one of the four subsample serums 30 is completed, the transport rack 4 is pitch-fed, and the subsample serum 30 in the next subsample container 6 is similarly measured. By repeating such an operation, the sub-sample serums 30 in the sub-sample containers 6 held in the transport rack 4 respectively receive measurements on these four wavelengths, and receive light signals for each of the four measurement wavelengths. Is obtained for each child sample serum 30.

The measurement wavelengths of the light irradiation unit 2 and the transmitted light detection unit 8 are switched by changing the wavelength characteristics of the light irradiation unit 2. This can be realized by the following configuration, for example. The LED 20 has four built-in LED chips that generate lights of different wavelengths,
As a result, the light irradiation unit 2 changes the wavelength of the inspection light to be irradiated to 4
The type can be switched. By switching the wavelength of the inspection light, the light irradiation unit 2 and the transmitted light detection unit 8 can switch the measurement wavelength.

Further, the switching of the measurement wavelengths of the light irradiation section 2 and the transmitted light detecting section 8 may be performed by changing the wavelength characteristic of the transmitted light detecting section 8. This can be realized by the following configuration, for example. LED20 is
It is composed of a white LED that emits white light, and the light irradiation unit 2 emits white inspection light. The filter 44 has a configuration in which four filters having different wavelength ranges to be transmitted are connected to each other, and the wavelength ranges to be transmitted are different depending on respective portions thereof. This filter 44
The transmitted light detector 8 allows four regions having different transmission wavelength regions to be selectively positioned on the optical axis of the inspection light.
It is provided to be movable. Of the white inspection light that has passed through the subsample serum 30, only the light in the specific wavelength region that has passed through the filter 44 is detected by the photodetector 46.
By moving the filter 44 to switch the wavelength range transmitted through the filter 44 and switch the wavelength of the light incident on the photodetector 46, the light irradiation section 2 and the transmitted light detection section 8 are selected.
Can switch the measurement wavelength. In this case, instead of the LED 20, another white light source such as a halogen lamp may be used.

The measurement wavelengths of the light irradiation unit 2 and the transmitted light detection unit 8 may be switched by changing the wavelength characteristics of both the light irradiation unit 2 and the transmitted light detection unit 8.

As described above, according to the present invention, since it is possible to perform the measurement at a plurality of measurement wavelengths by one set of the light irradiation section 2 and the transmitted light detection section 8, the light irradiation section and the transmitted light detection section for each wavelength. It is not necessary to provide the
Can be miniaturized.

A plurality of test tube holes of the transport rack 4 are arranged in the scanning direction, that is, the relative movement direction, and
A plurality of sub-sample containers 6 are also arranged in a direction orthogonal to the scanning direction, and the sub-sample containers 6 are arranged in a two-dimensional array (matrix).
As described above, in the present apparatus, since the irradiation of the inspection light and the detection of the transmitted light are performed in the vertical direction of the sub-sample container 6, a plurality of sub-sample serums 30 arranged in a two-dimensional array in the horizontal plane.
It is possible to make individual measurements for. Figure 2
FIG. 3 is a schematic perspective view showing a transport rack and an optical measurement unit. The illustrated transport rack 4 is provided with five test tube holes along a direction orthogonal to the scanning direction. In this device, correspondingly, five sets of the same light irradiation section 2 and transmitted light detection section 8 are arranged in parallel in the direction orthogonal to the scanning direction. As a result, the measurement can be performed on the five sub-sample containers 6 at the same time, and the throughput is further improved.

FIG. 3 is a schematic block diagram of this apparatus. This device is provided with the above-mentioned light irradiation unit 2 and transmitted light detection unit 8
Besides, the light source drive circuit 50, the rack drive circuit 52, I-
V converter 54, ADC (Analog-to-Digital Converte
r) 56, analysis unit 58, dispensing amount input unit 60, output unit 62
It is configured to include. The analysis unit 58 includes a CPU (CentralP
rocessing unit) 64, a calibration curve table 66, and an optical path length table 68.

The light source drive circuit 50 is the LED of the light irradiation unit 2.
It is a circuit for driving the LED 20, and blinks the LED 20 in accordance with an instruction from the CPU 64.

The rack drive circuit 52 is a circuit for operating a drive mechanism (not shown) for moving the transport rack 4. For example, at the position of the optical measuring section, the pitch of the test tube holes, that is, the relative moving direction, is determined. Sub-sample container 6
The transport rack 4 is moved by the arrangement pitch. CPU
Reference numeral 64 gives an instruction to the rack drive circuit 52 to move the transport rack 4 in synchronism with the processing cycle of irradiating the inspection light in the optical measuring unit and detecting the transmitted light. With such a configuration, in the present embodiment, since it is possible to perform the measurement while the sub-sample container 6 is stopped with respect to the light irradiation unit 2 and the transmitted light detection unit 8, it is possible to more reliably perform the measurement.
The measurement can be performed with higher accuracy.

The IV converter 54 converts the output current signal of the photodetector 46 of the transmitted light detector 8 into a voltage signal. This voltage signal is converted into a digital signal by the ADC 56 and input to the CPU 64.

The calibration curve table 66 preliminarily measures and stores calibration curve data, which is the relationship between the concentration and the absorbance of each interfering substance to be measured. This calibration curve data is for the case where the optical path length in the sample through which the inspection light passes is a predetermined reference optical path length.

The measured absorbance depends on the actual optical path length (optical path length in the substance causing the absorption). Generally, as the amount of the sample increases, the height of the sample in the sample container increases. The height depends on the shape of the storage portion of the sample container.
In the present invention, since light is transmitted in the vertical direction, its optical path length is basically the height of the sample in the sample container, and the height of the sample in the sample container is determined from the shape of the sample container and the amount of the sample. By determining the height, the optical path length can be determined.

That is, in this apparatus, the actual optical path length depends on the dispensing amount subdivided into the sub-sample container 6 and the shape of the sub-sample container 6. The optical path length table 68 is a table that stores this relationship. FIG. 4 is a graph showing an example of the relationship between the dispensing amount and the optical path length in the sample, which is stored in the optical path length table 68, and is a graph when the sub-sample container 6 is a test tube having an inner diameter of 10 mm. . An optical path length table 68 is prepared in advance in the analysis unit 58 according to the child sample container 6 used. On the other hand, the information on the dispensing amount of each sub-sample container 6 is
The dispensing amount input unit 60 acquires from the dispensing device and inputs it to the CPU 64. The CPU 64 reads from the optical path length table 68 the optical path length corresponding to the dispensed quantity obtained from the dispensed quantity input unit 60.

The output unit 62 has a function of numerically displaying the concentration of the interfering substance calculated by the CPU 64, and an alarm output when the concentration exceeds a predetermined abnormality determination threshold value.

Next, the operation of this apparatus will be described. When the rack drive circuit 52 detects with the sensor that the leading portion of the transport rack 4 moved by the transport means has been transported to the position where the light irradiation unit 2 and the transmitted light detection unit 8 are vertically opposed to each other, The transport rack 4 is step-driven (pitch feed) for each array pitch of the test tube holes in the transport direction. By this step drive, the sub-sample container 6 held in each test tube hole is sequentially moved between the light irradiation unit 2 and the transmitted light detection unit 8, and the transmitted light intensity is measured. As described above, the measurement results of the transmitted light with respect to each of the four types of measurement wavelengths are obtained for each child sample serum 30, and the CPU 64 handles these four measurement results as one set of data.

The CPU 64 calculates the absorbance A at each measurement wavelength from the measurement result of the transmitted light. Generally, the absorbance A is A≡log, where I _{0 is} the intensity of incident light and I is the intensity of transmitted light.
It is calculated by ₁₀ (I ₀ / I).

Next, the CPU 64 searches the calibration curve table 66 by using the calculated absorbance as a key and acquires the concentration data stored in the table. This concentration data is obtained for each of the three interfering substances hemolyzed hemoglobin, bilirubin and chyle.

Since the density data stored in the calibration curve table 66 is for a predetermined reference optical path length,
The CPU 64 converts this concentration data into data according to the actual optical path length in the sample. The CPU 64 reads out the data of the sample to be processed from the dispensing amount data obtained from the dispensing device. Then, the optical path length table 68 is searched by using the dispensed amount as a key, and the actual optical path length according to the used sub-sample container 6 is acquired and the above conversion is performed.

For example, the Lambert-Beer law of A = εcd is known as a relation between the absorbance A and the thickness d of the absorption layer. Here, ε is the molecular extinction coefficient, and c is the concentration. Based on such a rule, the CPU 64 converts the density data at the reference optical path length into the actual density according to the actual optical path length.

FIG. 5 is a cross-sectional view of an optical measuring section on a plane along the scanning direction in another embodiment of the sample testing apparatus of the present invention. Hereinafter, other embodiments of the sample testing apparatus of the present invention will be described with reference to this figure, but the description will focus on the differences from the above-described embodiments, and description of similar items will be omitted.

In the present embodiment, the light irradiating section 2 irradiates one irradiation light having a mixture of plural wavelengths. That is, the light irradiator 2 irradiates the inspection light including lights of a plurality of wavelengths. Then, the transmitted light detection unit 8 discriminates and detects light of a plurality of wavelengths from the light transmitted through the subsample serum 30. Thereby, measurement is performed at a plurality of (four) different measurement wavelengths at the same time. The details will be described below.

The light irradiation section 2 includes a white light source 21 and a lens 2
2, an iris 24 and 26, and a lens 28, and emits white inspection light including lights of a plurality of wavelengths. The white light source 21 may be any one such as a white LED or a halogen lamp.

The transmitted light detecting section 8 includes a scanner plate 40.
And a lens 42, a light discriminating means 45, and a photodetector 47. The light discriminating means 45 is composed of, for example, a diffraction grating. The light discriminating means 45 is not limited to the diffraction grating, and may be another type of optical element such as a mirror, a half mirror, or a prism. Further, the photodetector 47 is composed of, for example, a photodiode array, and a plurality of (4
The light can be detected in one channel.

The light transmitted through the sub-sample serum 30 is spectrally separated by the light discriminating means 45, and the plurality of spectrally separated lights are individually incident on the respective channels of the photodetector 47. As a result, the photodetector 47 detects light of different wavelengths in the four channels, and simultaneously performs measurement at four types of measurement wavelengths.

As described above, in the present embodiment, the measurement at a plurality of measurement wavelengths can be performed simultaneously, so that the measurement time can be shortened. Therefore, the inspection work can be performed more quickly, and the inspection for a large number of specimens can be performed in a shorter time.

In this embodiment, the light irradiation section may emit a plurality of wavelengths as separate irradiation light. That is, a plurality of light sources having different wavelengths may be provided in the light irradiating section, and the light from these light sources may be emitted as one light combined by an optical element such as a mirror, a half mirror or a prism. Further, the transmitted light detecting section may be provided with a plurality of photodetectors, and the respective transmitted lights spectrally separated by the wavelength by the light discriminating means may be detected by different photodetectors.

Although the sample testing apparatus of the present invention has been described above with reference to the illustrated embodiment, the present invention is not limited to this, and each unit constituting the sample testing apparatus can exhibit the same function. It can be replaced with an arbitrary configuration.

A plurality of sets of the light irradiation section and the transmitted light detection section may be arranged in parallel in the relative movement direction of the sample container (transport rack). In this case, assuming that four sets of light irradiation units and transmitted light detection unit sample containers are arranged in parallel in the relative movement direction of the sample containers, the sample containers (transport rack)
Are relatively moved by 4 pitches of the arrangement pitch of the sample containers. In this case, the light irradiation section and the transmitted light detection section are
Further, a plurality of sets may be arranged side by side in a direction orthogonal to the relative movement direction and in a matrix form as a whole.

The sample container is not limited to the cylindrical test tube shape having a rounded bottom as shown in the figure, but may be any shape such as a rectangular parallelepiped shape or a prismatic shape having a vertically long column shape. It may be one.

When a plurality of sets of light irradiating parts and passing light detecting parts are arranged in a matrix, they may be arranged such that the rows are arranged every other row like a honeycomb. It can be anything.

[0055]

According to the sample inspection apparatus of the present invention, since the inspection light is incident in the vertical direction, even if a label is affixed to the side surface of the sample container or a large number of sample containers are arranged in parallel, they are transmitted. Light can be measured, and the sample can be easily analyzed using the transmitted light. Further, even if the amount of the sample contained in the sample container is small, it is easy to make the test light incident on the sample, and in this respect, the effect of facilitating the analysis of the sample can be obtained.

Further, since it is possible to perform the measurement at a plurality of measurement wavelengths with one set of the light irradiation section and the transmitted light detection section, it is possible to perform the measurement with particularly high efficiency (throughput),
The inspection work can be speeded up. In addition, the device can be simplified and downsized.

[Brief description of drawings]

FIG. 1 is a cross-sectional view of an optical measurement unit on a plane along a scan direction.

FIG. 2 is a schematic perspective view showing a transport rack and an optical measurement unit.

FIG. 3 is a schematic block configuration diagram of a sample testing device according to an embodiment of the present invention.

FIG. 4 is a graph showing an example of a relationship between a dispensing amount and an optical path length in a sample, which is stored in an optical path length table.

FIG. 5 is a cross-sectional view of an optical measurement unit on a plane along the scanning direction in another embodiment of the sample testing apparatus of the present invention.

[Explanation of symbols]

2 Light irradiation part 4 Transport rack 6 child sample containers 8 Transmitted light detector 10 Light transmission hole 20 LED 21 White light source 22 lens 24 Iris 26 Iris 28 lenses 30 child specimen serum 40 scanner plate 42 lens 44 Filter 45 Light discrimination means 46 Photodetector 47 Photodetector 50 Light source drive circuit 52 Rack drive circuit 54 IV converter 56 ADC 58 Analysis Department 60 dispensing amount input section 62 Output section 64 CPU 66 Calibration curve table 68 Optical path length table

─────────────────────────────────────────────────── ─── Continued Front Page (51) Int.Cl. ⁷ Identification Code FI Theme Coat (Reference) G01N 33/72 G01N 33/72 Z 35/04 35/04 H (72) Inventor Junichi Kawanabe Mitaka, Tokyo 6-22-1, Ichi Municipal Aloka Co., Ltd. (72) Inventor Go Ono 6-22-1, Mure, Mitaka City, Tokyo F-term (reference) in Aroka Co., Ltd. 2G045 DA51 DA53 DA80 FA11 GC10 HA09 2G058 AA05 CB15 CF12 GA03 GA08 GD00 GD02 2G059 AA01 AA06 BB13 DD12 EE01 EE11 GG02 GG03 GG10 HH02 JJ02 JJ05 JJ06 JJ11 JJ13 MM01

Claims (10)

[Claims] 1. A light irradiator for vertically injecting inspection light into a sample housed in a columnar sample container, a transmitted light detector for detecting transmitted light from the sample, and a transmitted light detector based on the transmitted light. A sample inspection device having an analysis unit for analyzing the sample, wherein the transmitted light detection unit and the light irradiation unit can switch the measurement wavelength to a plurality of types, by switching the measurement wavelength in a time division manner, A sample inspection apparatus, which performs measurement on the sample at a plurality of different measurement wavelengths. 2. The sample inspection apparatus according to claim 1, wherein the switching of the measurement wavelength is performed by changing a wavelength characteristic of at least one of the transmitted light detection unit and the light irradiation unit. 3. A light irradiating section for vertically injecting inspection light onto a sample contained in a columnar sample container, a transmitted light detecting section for detecting transmitted light from the sample, and a transmitted light detecting section based on the transmitted light. A sample inspection apparatus having an analysis unit for analyzing the sample, wherein the light irradiation unit irradiates inspection light containing light of a plurality of wavelengths, and the transmitted light detection unit includes a plurality of contained in the transmitted light. The sample inspection apparatus is characterized by discriminating and detecting light having a wavelength of, and simultaneously measuring the sample at a plurality of different measurement wavelengths. 4. The sample inspection apparatus according to claim 3, wherein the transmitted light detection unit has a light discriminating unit that disperses the transmitted light according to wavelengths, and the transmitted light is spectroscopically detected by the light discriminating unit. . 5. The sample inspection apparatus according to claim 1, wherein the analysis unit obtains the concentration of the test substance contained in the sample based on the transmitted light. 6. The analysis unit according to claim 5, further comprising: an absorbance determination unit that determines an absorbance of the test substance based on the transmitted light; and a concentration determination unit that determines the concentration based on the absorbance. Specimen inspection device. 7. The sample testing apparatus according to claim 6, wherein the concentration determining unit has a conversion table representing a relationship between the absorbance and the concentration. 8. The sample inspection apparatus according to claim 1, wherein a plurality of test substances contained in the sample are analyzed based on the measurement results at the plurality of measurement wavelengths. 9. The sample inspection apparatus according to claim 8, wherein the plurality of test substances include hemolyzed hemoglobin, chyle, or bilirubin. 10. A plurality of the sample containers are arranged in parallel on a transport rack, and the transport rack is configured to allow light to pass through in the vertical direction of the position where the sample container is arranged. 10. The sample inspection apparatus according to claim 1, wherein the transmitted light detection units are arranged to face each other with the sample container and the transport rack sandwiched therebetween.