JP5865713B2 - Automatic analyzer - Google Patents

Description

  Embodiments described herein relate generally to an automatic analyzer that analyzes components contained in a liquid.

  The automatic analyzer is intended for biochemical test items, and irradiates light to a reaction container that contains a mixed solution of a test sample and a reagent for each test item. And the change of the color tone which arises by reaction in a liquid mixture is measured by detecting the light which permeate | transmitted the liquid mixture, and the density | concentration and enzyme activity of various components in a test sample are calculated | required. On the other hand, an immune serum test apparatus is used for many immune serum test items. And, for example, the change in aggregation due to the antigen-antibody reaction between one of the antigen or antibody immobilized on latex particles contained in the reagent of the latex agglutination method and the other as an immune serum test item component contained in the test sample, Measurement is performed by detecting scattered light scattered in the mixed liquid.

  Recently, efficiency and cost reduction in inspection are required, and it is desired that many inspection items can be inspected with as few analyzers as possible. Under such circumstances, immune serum test items have been analyzed using an automatic analyzer that can process many items at high speed.

JP-A-11-108830

  However, in the automatic analyzer, when the change in aggregation is measured by detecting light transmitted through the mixed solution, scattered light scattered by the aggregated scatterer is also detected. And at high absorbance, there is a problem that the influence of scattered light becomes large, the amount of change in absorbance per unit concentration is reduced, and measurement accuracy in a high concentration region where the absorbance is high is lowered.

  The embodiment has been made to solve the above-described problems, and an object thereof is to provide an automatic analyzer capable of improving measurement accuracy in a high concentration region.

In order to achieve the above object, the automatic analyzer according to the embodiment irradiates light to a reaction container containing a dispensed test sample and reagent mixed solution, and detects light transmitted through the mixed solution. In the automatic analyzer including a photometric unit that performs measurement, the reaction container has a plurality of planes that are in contact with the mixed solution, and a surface on which light irradiated from the photometric unit is incident is formed in a concave shape. The surface from which the light incident from the concave surface and transmitted through the mixed liquid is emitted is formed in a convex shape .

The block diagram which shows the structure of the automatic analyzer which concerns on embodiment. The perspective view which shows the structure of the analysis part which concerns on embodiment. The figure which shows an example of a structure of the photometry part which concerns on embodiment. Sectional drawing which shows an example of a structure of the reaction container which concerns on embodiment. Sectional drawing which shows the other example of a structure of the reaction container which concerns on embodiment. Sectional drawing which shows the other example of a structure of the reaction container which concerns on embodiment.

  Hereinafter, embodiments will be described with reference to the drawings.

  FIG. 1 is a block diagram illustrating a configuration of an automatic analyzer according to the embodiment. The automatic analyzer 100 dispenses a standard sample or test sample and a reagent, measures the mixed solution to generate standard data or test data, and each analysis unit in the analysis unit 24. An analysis control unit 25 that performs driving and control, and a data processing unit 30 that processes standard data and test data generated by the analysis unit 24 to generate calibration data and analysis data are provided.

  The automatic analyzer 100 also includes an output unit 40 that prints out and displays the calibration data and analysis data generated by the data processing unit 30, an operation unit 50 that inputs various command signals, and the analysis control unit 25. A data processing unit 30 and a system control unit 51 that controls the output unit 40 in an integrated manner.

  FIG. 2 is a perspective view showing the configuration of the analysis unit 24. The analysis unit 24 includes a sample container 17 that stores a sample such as a standard sample or a test sample, and a sample disk 5 that holds the sample container 17. Further, for example, a reagent container 6 that contains a reagent that contains a component that reacts with a component of each inspection item included in the sample, for example, a first reagent and a first reagent of a two reagent system, and a reagent container 1 that keeps the reagent container 6 cool. And a reagent rack 1a for rotatably holding the reagent container 6 stored in the reagent storage 1. In addition, a reagent container 7 that stores a second reagent that is paired with a first reagent in a two-reagent system, a reagent container 2 that keeps the reagent container 7 cold, and a reagent container 7 that is stored in the reagent container 2 can be rotated. And a reagent rack 2a for holding. In addition, a plurality of reaction vessels 3 arranged on the circumference and a reaction disk 4 for rotatably holding the reaction vessel 3 are provided.

  In addition, a sample dispensing probe 16 for dispensing the sample in the sample container 17 held on the sample disk 5 and sucking it into the reaction container 3, and a sample portion for holding the sample dispensing probe 16 movably. A note arm 10 is provided. In addition, a first reagent dispensing probe 14 for aspirating the first reagent in the reagent container 6 held in the reagent rack 1a and dispensing it into the reaction container 3 into which the sample has been dispensed, and the first reagent And a first reagent dispensing arm 8 that holds the dispensing probe 14 so as to be movable.

  Also, a second reagent dispensing probe 15 for aspirating the second reagent in the reagent container 7 held in the reagent rack 2a and dispensing it into the reaction container 3 into which the first reagent has been dispensed, A second reagent dispensing arm 9 that holds the two reagent dispensing probe 15 in a movable manner is provided. Moreover, the photometry part 13 which irradiates and measures the light to the reaction container 3 which accommodates a liquid mixture, and the reaction container washing | cleaning unit 12 which wash | cleans the inside of the reaction container 3 which completed the measurement in the photometry part 13 are provided.

  Then, the photometry unit 13 irradiates light to the reaction container 3 that rotates, and the irradiation causes the sample and the first reagent and the second reagent in the reaction container 3 to be mixed. The transmitted light is detected. Then, based on the detected signal, standard data represented by absorbance and test data are generated, and the generated standard data and test data are output to the data processing unit 30.

  The analysis control unit 25 in FIG. 1 includes a mechanism that drives each analysis unit of the analysis unit 24 and a control unit that controls the mechanism, and rotates the sample disk 5, the reagent rack 1a, and the reagent rack 2a, respectively. Further, the reaction disk 4 is rotated. Further, the sample dispensing arm 10, the first reagent dispensing arm 8, and the second reagent dispensing arm 9 are rotated and moved up and down, respectively. Further, the reaction container cleaning unit 12 is moved up and down.

  The data processing unit 30 is generated by the calculation unit 31 and the calculation unit 31 that process the standard data and test data output from the photometry unit 13 of the analysis unit 24 to generate calibration data and analysis data of each inspection item. And a data storage unit 32 for storing standard data and analysis data.

  The calculation unit 31 generates calibration data representing the relationship between the standard value and the standard data from the standard data output from the photometry unit 13 and a standard value set in advance for the standard sample of the standard data. The data is output to the output unit 40 and stored in the data storage unit 32.

  In addition, the calculation unit 31 reads out the calibration data of the inspection item corresponding to the test data output from the photometry unit 13 from the data storage unit 32, and the test data output from the photometry unit 13 using the read calibration data. From this, analysis data expressed as a concentration value or an activity value is generated. The generated analysis data is output to the output unit 40 and stored in the data storage unit 32.

  The data storage unit 32 includes a memory device such as a hard disk, and stores the calibration data output from the calculation unit 31 for each inspection item. Moreover, the analysis data of each inspection item output from the calculation unit 31 is stored for each test sample.

  The output unit 40 includes a printing unit 41 that prints out calibration data and analysis data output from the calculation unit 31 of the data processing unit 30 and a display unit 42 that displays and outputs the calibration data. The printing unit 41 includes a printer or the like, and prints calibration data and analysis data on printer paper or the like according to a preset format.

  The display unit 42 includes a monitor such as a CRT or a liquid crystal panel, and displays calibration data and analysis data. In addition, an analysis parameter setting screen for setting analysis parameters for analyzing each inspection item by the automatic analyzer 100 is displayed. Also, an inspection item setting screen for setting the inspection item to be inspected from the identification information for identifying the test sample for each test sample, the identification information such as name and ID, and the inspection item set on the analysis parameter setting screen Is displayed.

  The operation unit 50 includes input devices such as a keyboard, a mouse, a button, and a touch key panel, and performs input for setting analysis parameters for each inspection item. In addition, input is performed for setting identification information and inspection items to be inspected for each test sample.

  The system control unit 51 includes a CPU and a storage circuit, and stores input information such as analysis parameter information of each test item, identification information for each test sample, and test item information input by an operation from the operation unit 50. After being stored in the circuit, the analysis control unit 25, the data processing unit 30, and the output unit 40 are integrated to control the entire system based on the input information.

  Hereinafter, with reference to FIG. 1 thru | or FIG. 6, the structure of the photometry part 13 of the analysis part 24 and the reaction container 3 is demonstrated.

  FIG. 3 is a diagram showing the configuration of the photometry unit 13. The photometric unit 13 includes a light source 60 that emits light to irradiate the reaction vessel 3, a first slit 61 that restricts light from the light source 60, and a condensing lens that collects light that has passed through the first slit 61. 62 and a second slit 64 that narrows the light transmitted through the reaction vessel 3 that rotates and moves across the optical axis 63 of the condenser lens 62 to a predetermined range.

  The photometric unit 13 also includes a diffraction grating 65 that splits the light that has passed through the second slit 64, and a photodetector 66 that detects the spectrum dispersed by the diffraction grating 65 for each predetermined wavelength and converts it into an electrical signal. And a signal processing unit 67 that processes the detection signal from the photodetector 66 to generate standard data or test data as absorbance.

  The light source 60 is, for example, a halogen lamp, and a filament as a light source center in the case of the halogen lamp is disposed on the optical axis 63. The first slit 61 is disposed between the light source 60 and the condenser lens 62, and an opening through which light from the light source 60 passes is located on the optical axis 63. Further, the condenser lens 62 is disposed between the reaction vessel 3 and the first slit 61 at the photometric position Pt that rotates and moves by the rotation of the reaction disk 4 and crosses the optical axis 63.

  The second slit 64 is disposed between the reaction vessel 3 at the photometric position Pt and the diffraction grating 65, and an opening through which light from the reaction vessel 3 passes is located on the optical axis 63. Then, the light transmitted through the reaction vessel 3 is narrowed down so that it falls within the effective range of the diffraction grating 65. In addition, the diffraction grating 65 separates the light incident through the second slit 64 in a predetermined direction for each wavelength.

  The photodetector 66 includes a plurality of light receiving elements that detect light of a plurality of wavelengths set in advance among the light of each wavelength from the diffraction grating 65, and the plurality of wavelengths separated by the diffraction grating 65 for each wavelength. Light is detected and converted into an electrical signal, and the converted electrical signal is output to the signal processing unit 67 as a detection signal. Further, the signal processing unit 67 amplifies and analog-digital converts each detection signal output from the photodetector 66, generates standard data expressed by absorbance and test data, and outputs the data to the data processing unit 30. .

  FIG. 4 is a cross-sectional view showing an example of the configuration of the reaction vessel 3. The reaction container 3 includes a sample dispensing probe 16, a sample discharged from the first and second reagent dispensing probes 14 and 15, and a reaction container main body 70 containing a mixed solution of the first and second reagents, A first lens 71 that converts the optical path of the light from the photometry unit 13 provided in the reaction vessel main body 70 and a second light that condenses the light transmitted through the mixed solution in the reaction vessel main body 70 provided in the reaction vessel main body 70. Lens 72.

  The reaction container main body 70 is excellent in the transmittance of light irradiated from the light source 60, and is resistant to chemicals such as a sample, a first reagent, a second reagent, and an acidic cleaning solution and an alkaline cleaning solution used in the reaction container cleaning unit 12 of the analysis unit 24. For example, it is formed of a plastic material having excellent properties, and the inside has a quadrangular prism shape constituted by a plane. And the sample discharged from the opening part provided in the upper part, a 1st reagent, and a 2nd reagent are accommodated.

  The first lens 71 is located between the condensing lens 62 of the photometry unit 13 and the mixed liquid in the reaction container main body 70 at the photometric position Pt of the reaction container 3, and the light from the condensing lens 62 is transmitted to the reaction container main body 70. It is a lens that converts the inside of the liquid mixture into an optical path that becomes parallel light traveling straight in parallel. This lens is, for example, a plano-concave lens formed on one side wall in the vicinity of the lower end of the reaction vessel main body 70 with the outer wall surface on which light from the condenser lens 62 is incident as a concave surface and the inner wall surface in contact with the mixed solution as a flat surface. is there.

  The first lens 71 has a linear axis 73 orthogonal to the side wall on one side of the reaction vessel main body 70 and the other side wall facing the side wall as an optical axis, and the axis 73 is the optical axis 63 of the photometry unit 13. At the photometric position Pt that coincides with the focal point of the condenser lens 62. Then, the light from the condensing lens 62 is refracted and converted into an optical path that becomes parallel light that goes straight in parallel with the shaft 73 in the mixed liquid in the reaction container main body 70.

  Thus, by providing the 1st lens 71, the light from the condensing lens 62 can be converted into parallel light, and can be irradiated to a liquid mixture. As a result, when the change in aggregation in the liquid mixture is measured using transmitted light, only the light parallel to the axis 73 and the scattered light close to parallel can be guided to the photodetector 66, which is unnecessary. Since detection of scattered light can be suppressed, it is possible to improve measurement accuracy in a high concentration region where the absorbance is high.

  Since the first lens 71 is provided in the reaction vessel main body 70, the distance between the condenser lens 62 and the first lens 71 can be increased as compared with the case where the first lens 71 is provided in the photometry unit 13. The beam width of parallel light can be narrowed without reducing the luminous flux irradiated to the liquid mixture. Thereby, when measuring the change in aggregation in the mixed solution using transmitted light, it is possible to suppress the detection of unnecessary scattered light and reduce the amount of the mixed solution in the reaction vessel main body 70, which is high. It is possible to improve the measurement accuracy of the high concentration region that becomes the absorbance, and to reduce the amount of each liquid of the sample, the first reagent, and the second reagent that are discharged into the reaction container main body 70.

  In addition, by providing the first lens 71 in the reaction vessel main body 70, it is not necessary to dispose the first lens 71 in the case where the photometry unit 13 is provided separately from the reaction vessel main body 70. Can be achieved.

  The second lens 72 has a shaft 73 formed on the other side wall in the vicinity of the lower end of the reaction vessel main body 70 having a flat inner wall surface in contact with the mixed liquid and a convex outer wall surface from which light transmitted through the mixed liquid is emitted. Is a plano-convex lens with the optical axis as the optical axis. At the photometric position Pt, the parallel light transmitted through the mixed liquid in the reaction vessel main body 70 is focused on the second slit 64 opening in the photometric unit 13 or on the optical axis 63 in the vicinity of this opening.

  In this way, by providing the second lens 72 and condensing the light that has passed through the mixed liquid, it is possible to reduce the decrease in the light flux detected by the photodetector 66, and thus the transmitted light is used for aggregation. It is possible to improve the measurement accuracy in a high concentration region where the absorbance is high when measuring the change in the above.

  In addition, by providing the second lens 72 in the reaction vessel main body 70, it is not necessary to dispose the second lens 72 in the case where it is provided in the photometry unit 13, so that the photometry unit 13 can be reduced in size. Can be achieved.

  In addition, the first and second lenses 71 and 72 are plano-concave lenses and plano-convex lenses, and the plane of the plano-concave lens and plano-convex lens is formed in the same plane as the inner surface of the reaction vessel main body 70, thereby When the inside of the reaction vessel main body 70 is washed by the reaction vessel washing unit 12, it is possible to easily discharge the mixed liquid and prevent the residue.

  As shown in FIG. 5, the reaction container body 70 a is flat on one side and the other outer surface of the reaction container body 70, and the reaction container body 70 a is flat on one side plane on which light from the condenser lens 62 is incident. A first lens 71a which is a plano-concave lens with the side closely arranged, and a second lens 72a which is a plano-convex lens with the plane side closely arranged on the other side plane of the reaction vessel main body 70a from which the light transmitted through the mixed solution is emitted. You may make it implement using the reaction container 3a comprised by these. As a result, as in the case of the reaction vessel 3, the measurement accuracy of the high concentration region where the absorbance is high is improved, and the liquids of the sample, the first reagent, and the second reagent to be discharged into the reaction vessel main body 70 are improved. The amount can be reduced. Further, the photometric unit 13 can be downsized.

  In addition, as shown in FIG. 6, a reaction vessel provided with openings in a region where the first lens 71 is formed on one side wall of the reaction vessel main body 70 and a region where the second lens 72 is formed on the other side wall. The main body 70b, the first lens 71a disposed so that the opening on one side wall of the reaction vessel main body 70b is flush with the inner surface of the reaction vessel main body 70b, and the reaction vessel main body 70b The opening of the side wall may be sealed, and the reaction may be performed using the reaction vessel 3b configured by the second lens 72a arranged so that the plane side is flush with the inner surface of the reaction vessel main body 70b. . As a result, as in the case of the reaction vessel 3, the measurement accuracy of the high concentration region where the absorbance is high is improved, and the liquids of the sample, the first reagent, and the second reagent to be discharged into the reaction vessel main body 70 are improved. The amount can be reduced. Further, the photometric unit 13 can be downsized.

  Furthermore, the reaction vessel main body 70b of the reaction vessel 3b shown in FIG. 6 may be formed from a black material. Moreover, you may make it implement by covering the outer surface of each reaction container main body 70 and 70b with black materials, such as black coating. Moreover, you may make it implement by covering parts other than the 1st and 2nd lenses 71a and 72a of reaction container main body 70a outer surface with black materials, such as black coating. As a result, it is possible to further suppress the detection of unnecessary scattered light when measuring the change in aggregation in the liquid mixture using transmitted light, thereby improving the measurement accuracy in the high concentration region where the absorbance is high. be able to.

  Furthermore, by covering the surfaces of the first and second lenses 71, 71a, 71b, 72, 72a, 72b with an antireflection film, the first and second lenses 71, 71a, 71b, 72, 72a are covered. , 72b can be measured without reducing the energy of light.

  According to the embodiment described above, by providing the first lens 71, it is possible to convert the light from the condenser lens 62 into parallel light and irradiate the mixed liquid in the reaction container main body 70. As a result, it is possible to suppress the detection of unnecessary scattered light when measuring the change in aggregation in the liquid mixture using transmitted light, so that the measurement accuracy in a high concentration region with high absorbance can be improved. Can do.

  Further, by providing the first lens 71 in the reaction vessel main body 70, the beam width of the parallel light is narrowed without lowering the luminous flux irradiating the mixed liquid as compared with the case where the first lens 71 is provided in the photometry unit 13. be able to. As a result, it is possible to suppress the detection of unnecessary scattered light when measuring the change in aggregation in the liquid mixture using transmitted light, and to reduce the amount of liquid mixture in the reaction vessel main body 70. As a result, the measurement accuracy in the high concentration region can be improved, and the amount of each liquid of the sample, the first reagent, and the second reagent to be discharged into the reaction container main body 70 can be reduced.

  In addition, by providing the first lens 71 in the reaction vessel main body 70, it is not necessary to dispose the first lens 71 in the case where the photometry unit 13 is provided separately from the reaction vessel main body 70. Can be achieved.

  Further, by providing the second lens 72 and condensing the light transmitted through the liquid mixture in the reaction vessel main body 70, it is possible to reduce the decrease in the light beam transmitted through the liquid mixture. Thus, it is possible to improve the measurement accuracy in a high concentration region where the absorbance is high when measuring the change in aggregation.

  In addition, by providing the second lens 72 in the reaction vessel main body 70, it is not necessary to dispose the second lens 72 in the case where it is provided in the photometry unit 13, so that the photometry unit 13 can be reduced in size. Can be achieved.

  Although several embodiments of the present invention have been described, these embodiments are presented by way of example and are not intended to limit the scope of the invention. These embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the scope of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are included in the invention described in the claims and the equivalents thereof.

3 Reaction vessel 13 Photometric unit 60 Light source 61 First slit 62 Condensing lens 63 Optical axis 64 Second slit 65 Diffraction grating 66 Photo detector 67 Signal processing unit 70 Reaction vessel main body 71 First lens 72 Second lens 73 axes

Claims (11)

In an automatic analyzer equipped with a photometric unit that irradiates light to a reaction container that contains a dispensed test sample and reagent mixed solution, and detects and measures light transmitted through the mixed solution ,
In the reaction vessel, a surface in contact with the mixed solution is configured by a plurality of flat surfaces, a surface on which light irradiated from the photometry unit is incident is formed in a concave shape, and the mixed solution is incident from the concave surface. An automatic analyzer characterized in that a surface from which transmitted light is emitted has a convex shape . The reaction vessel is
The outer wall surface of the one side wall on which the light emitted from the photometry unit is incident is the concave surface, and the inner wall surface that is in contact with the mixed liquid on the one side wall from which the incident light is emitted is a flat surface. A concave lens,
The surface of the inner wall in contact with the mixed liquid on the other side wall on which the light transmitted through the mixed liquid is incident is a plane, and the outer wall surface of the other side wall on which the incident light is emitted is the convex surface. With a plano-convex lens
The automatic analyzer according to claim 1, wherein the automatic analyzer is provided. The photometry unit has a light source that emits light and a condenser lens that condenses the light emitted from the light source,
The plano-concave lens, the light from the condenser lens, Ri lens der converting the optical path as a parallel light parallel to straight pre Symbol mixed solution,
The automatic analyzer according to claim 2 , wherein the plano-convex lens is a lens that collects parallel light transmitted through the mixed solution in a slit . The automatic analyzer according to any one of claims 1 to 3 , wherein an outer surface of the reaction vessel other than the concave surface and the convex surface is covered with a black material. Automatic analyzer according to claim 2 or claim 3 wherein the plano-concave lens and the surface of the planoconvex lens is characterized in that is covered with an antireflection material. The automatic analyzer according to claim 1, further comprising a cleaning unit that cleans the inside of the reaction vessel that has been measured by the photometric unit. The automatic analyzer according to claim 6, wherein the cleaning unit discharges the mixed solution from the reaction container. The automatic analyzer according to any one of claims 1 to 7, wherein the inside of the reaction vessel has a quadrangular prism shape. 9. The reaction container according to claim 1, wherein the reaction container is made of a plastic material that has a property of transmitting the light irradiated from the photometry unit and has chemical resistance. Automatic analyzer. The plano-concave lens has a linear axis orthogonal to the one side wall and the other side wall facing the one side wall as an optical axis, and the optical axis of the concentrating lens coincides with the optical axis of the condenser lens. 4. The automatic analyzer according to claim 3, wherein light from an optical lens is refracted and converted into an optical path that travels straight in the mixed solution parallel to the axis. The planoconvex lens has a linear axis orthogonal to the one side wall and the other side wall facing the one side wall as an optical axis, and the mixing is performed at a position where the axis coincides with the optical axis of the condenser lens. The automatic analyzer according to claim 3, wherein the parallel light transmitted through the liquid is focused on the axis.

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