JPH0126507B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to an automatic chemical analyzer.

Automatic chemical analyzers used in clinical tests, etc. mix the serum of the specimen to be analyzed (hereinafter also referred to as sample) with a reagent corresponding to the analysis item, react it, measure the light of this to determine the absorbance, and measure the absorbance in advance. This is an apparatus that automatically performs analysis by determining the concentration of a sample corresponding to the absorbance from a calibration curve determined using a reagent and a standard substance such as standard serum.

However, since the reagents generally deteriorate even when stored at a low temperature of 2 to 8°C, a calibration curve must be prepared using standard serum at certain time intervals.

However, conventionally, such a calibration curve has to be created every day, and standard serum is expensive and denatures even when stored in the refrigerator, so it must be prepared immediately before use, which is labor-intensive and economical. It was becoming a burden.

The present invention has been made based on the above circumstances, and it is possible to create a calibration curve based on the temporal deterioration characteristics of a reagent determined in advance under certain conditions, thereby reducing the labor required for calibrating the device. The object of the present invention is to provide an automatic chemical analyzer that can reduce the economic burden.

First, the principle of determining a calibration curve based on the deterioration of a reagent over time determined under certain conditions will be explained. In general, if the storage temperature of a reagent changes, the deterioration characteristics, i.e., the absorbance of the reagent (hereinafter also referred to as the reagent blank value) or the reaction characteristics of the reagent will change, so the storage temperature of the reagent is kept at a constant low temperature (hereinafter referred to as the storage temperature). There is. Furthermore, in order to proceed with the chemical reaction between the reagent and the sample during analysis in the photometry section, the reagent is maintained at a predetermined reaction temperature. Based on these conditions, for example, if the time-dependent change in reaction with respect to a standard serum with a concentration of the component to be measured C ₁ is expressed as a change in absorbance, a reaction curve l ₁ shown in FIG. 1 can be obtained. Furthermore, if the prepared reagent is stored at the storage temperature T for ₁ hour and then the reaction is allowed to proceed at the same reaction temperature as described above, the reaction curve _l2 shown in FIG. 1 can be obtained. Absorbance B shown in Figure 1
is the reagent blank value, and the absorbance B + ΔB ₁ is T ₁
This is the reagent blank value when it is stored at a constant temperature for a period of time, and the absorbance M is the absorbance after reacting the standard serum with a concentration of C ₁ , which is made by mixing the reagents used in the preparation, for t ₁ hour. M+ΔM ₁ is the absorbance after reacting a standard serum with a measurement component concentration C ₁ after being stored for T ₁ hour for t ₁ hour. From these reaction curves l ₁ and l ₂ , as shown in FIG. 2, a calibration curve L ₁ at the time of reagent preparation and a calibration curve L ₂ after storage for T ₁ hour from the time of reagent preparation are determined. The calibration curve L ₁ can be expressed by the following equation (1), and the calibration curve L ₂ can be expressed by the following equation (2).

X _{= C 1 /M-B(E-B)...(1 )} , and E is the measured absorbance.) As is clear from equations (1) and (2) above, this value is calculated every 12 hours, for example, after a certain period of time has elapsed since the time of reagent preparation. Change in absorbance of reagent (hereinafter also referred to as change in absorbance of reagent)
By determining in advance ΔB ₁ … _o and the absorbance increase/decrease of a standard substance such as standard serum (hereinafter also referred to as standard serum absorbance increase/decrease) made by mixing the same reagent, 4M ₁ … _o can be calculated. A calibration curve can be created based on this and the elapsed time from the time of reagent preparation.
Furthermore, if the reagent absorbance increase/decrease ΔB ₁ ... _o and the standard serum absorbance increase/decrease ΔM _{1 ...} ) and the elapsed time from the time of preparation, a calibration curve can be created.
As is clear from the above explanation of the principle, the reagent absorbance increase/decrease ΔB ₁ ... _o or the standard serum absorbance increase/decrease ΔM ₁ ... _o for a plurality of reagents is determined in advance under certain conditions over time, The purpose is to create a calibration curve using one or both of these and the elapsed time from the time of reagent preparation.

The automatic chemical analyzer of the present invention will be explained below with reference to the drawings.

FIG. 3 is a schematic explanatory diagram of a discrete type automatic chemical analyzer which is an embodiment of the present invention. In the figure, 1 is a reagent tray in which reagent containers 1a containing various reagents are housed and the reagents are kept at a constant low temperature by an electronic cooling element (not shown), and 2 is a reagent tray containing reagent containers 1a containing various reagents. This is a sample tray in which a sample container 2a containing a sample such as serum (hereinafter referred to as sample) is housed, and each container is connected to the arrow E shown in the figure through an appropriate means.
It is possible to reciprocate in the F direction. A nozzle block 3 is provided above these so as to be movable back and forth along a pair of guide rails 4.
The nozzle block 3 is provided with one sampling nozzle 3a and two reagent nozzles 3b movable up and down. A sampling pump 5 and a reagent pump 6 are disposed near the nozzle block 3, and these pump the sample in the sample container 2a and the reagent in the reagent container 1a to the sampling nozzle 3a and the reagent nozzle 3b. It is designed to be sucked in a fixed amount. and the guide rail 4
A plurality of reaction vessels 7 into which the aspirated sample and reagent are dispensed are intermittently rotated in the direction G shown in the third figure, and while these reaction vessels 7 are maintained at a constant temperature, A reaction tank 8 is arranged in which the dispensed reagent reacts with the sample. A suction nozzle 10 is provided at the right end of the reaction tank 8 for sucking the sample and reagent dispensed into the reactor 7 and reacted via a suction pump 9. The photometric section 11 is connected to a photometric section 11 for photometric measurement. Note that the photometry section 11 and the reaction tank 8 are maintained at a constant reaction temperature by a constant temperature bath 12. Further, the photometry section 11 has a built-in light source 11a and a detector 11b, and an A/D converter for converting the electrical signal from the detector 11b.
A D converter 13, a CPU 14 for inputting outputs from the A/D converter, etc., and an operation panel 15 equipped with a numeric keypad (not shown) for inputting various data to the CPU 14 are provided. Here said
The functions of the CPU 14 will be explained. First, a predetermined calibration curve is created depending on the analysis item. In addition, the reagent absorbance increase/decrease ΔB ₁ ... _o and the standard serum absorbance are calculated over time under certain conditions (reagent holding temperature and reaction temperature) for the plurality of reagents stored in the reagent tray 1. The increase/decrease ΔM ₁ ... _o is stored in the storage device in the CPU 14,
Depending on the elapsed time from the time of preparation of these reagents, the predetermined increases and decreases ΔB ₁ ... _o and ΔM ₁ ... _o are read out from the storage device, the calibration curve is automatically created, and the concentration of the sample can be calculated. It's becoming like that. Note that the constant conditions regarding the holding temperature and reaction temperature are faithfully reproduced by controlling an electronic cooling element (not shown) provided in the reagent tray 1 and a constant temperature bath 12 by the CPU 14.
In this embodiment, the calibration curve creation means for creating a calibration curve based on the change in absorbance of a reagent over time determined in advance under certain conditions is implemented by the CPU.
It has 14 built-in functions.

Next, the operation of the automatic chemical analyzer constructed in this way will be explained. First, instruction data corresponding to the analysis item is transmitted via the operation panel 15.
The input to the CPU 14 causes the reagent tray 1 and sample tray 2 to move in the directions of the third arrows E and F, and connects the reagent nozzle 3b of the nozzle block 3 via the reagent pump 6 and sampling pump 5. Reagents and samples corresponding to the analysis items are sucked into the sampling nozzle 3a, and the sucked reagents and samples are dispensed into the reaction container 7 in the reaction tank 8 to proceed with the reaction. The reacted reagent and sample are then transferred to the suction nozzle 10.
is attracted to the photometry section 11 through the light source 11a.
The transmitted data is detected by the detector 11b, and the photometric data is sent to the CPU via the A/D converter 13.
14. Then, the reagent absorbance increase/decrease ΔB ₁ … _o and the standard serum absorbance increase/decrease ΔM ₁ … _o , which correspond to the used reagent and correspond to the elapsed time from the time of preparation of the used reagent, are read out from the storage device. Based on this, calculations as shown in equation (2) above are performed to automatically create a calibration curve and calculate the concentration of the sample. In this way, in the apparatus shown in this example, a calibration curve is automatically created based on the elapsed time from the time of reagent preparation, which significantly reduces the labor and economic burden required for calibrating the apparatus. Furthermore, highly accurate analysis can be guaranteed.

In the above example, a case was explained in which the reagents were kept constant at a constant low temperature using an electronic cooling element installed in the reagent tray. It is also possible to remove the reagents and make them available for use.

Furthermore, the above example describes a case where both the reagent absorbance increase/decrease ΔB ₁ ... _o and the standard serum absorbance increase/decrease ΔM ₁ ... _o are determined over time, and a calibration curve is created based on both of them. However, the invention is not limited to this. For example, only the standard serum absorbance increase/decrease ΔM ₁ ... _o is determined in advance, and the reagent absorbance increase/decrease ΔB ₁ ... _o is determined by the operator at regular intervals using a normal method. It is also possible to perform a calibration curve based on both of these. In particular, by doing so, it is possible to check for an abnormality even if the temperature of the cold box storing the reagent increases due to a power outage or the like and the absorbance of the reagent changes unexpectedly over time. Also, if there is a drift in the device itself,
By measuring reagent blank values, it is possible to create a more accurate calibration curve.

Furthermore, depending on the reagent, only the absorbance of the reagent itself changes, and the reaction power may not deteriorate. In this case, it is also possible to create a calibration curve by storing only the reagent absorbance increase/decrease ΔB ₁ ... _o in the CPU.

Furthermore, in the above embodiment, the case where a calibration curve is automatically created has been described, but when applied to an apparatus that measures light using a spectrophotometer, the second
As shown in the figure, prepare a diagram in advance that depicts a calibration curve that changes over time, and analyze the sample using the calibration curve that corresponds to the elapsed time from the time of reagent preparation to the time of analysis in the diagram. It is also possible to do so. In addition, the absorbance of the reagent and the factor value (ratio F of the absorbance x of the standard substance and its concentration value y)
When using a spectrophotometer that can store a calibration curve by inputting By inputting the absorbance and factor values of the reagent corresponding to the elapsed time from 1 to 2 into the spectrophotometer, a properly prepared calibration curve can be easily stored and analyzed.

As is clear from the above explanation, with the automatic chemical analyzer of the present invention, it is possible to create a calibration curve based on the deterioration characteristics over time of reagents determined in advance under certain conditions. This method has excellent effects such as being able to reduce the labor and economic burden required for calibrating the device.

[Brief explanation of drawings]

FIG. 1 is an explanatory diagram showing a reaction curve, FIG. 2 is an explanatory diagram showing a calibration curve, and FIG. 3 is a schematic explanatory diagram of a discrete type automatic chemical analyzer which is an embodiment of the present invention. 1... Reagent tray, 2... Sample tray, 8... Reaction tank, 11... Photometry section, 14... CPU.

Claims (1)

[Claims] 1. In an automatic chemical analyzer that analyzes a sample to be analyzed based on the absorbance obtained by mixing and reacting a reagent with the sample to be analyzed and a calibration curve corresponding to the analysis item, A calibration curve creation means is provided for creating a calibration curve based on changes in the properties of the reagent over time determined under certain conditions, and based on the calibration curve creation means and the elapsed time from the time of adjustment of the reagent. An automatic chemical analyzer characterized in that it is possible to create a calibration curve.