The present application claims priority from Japanese application Ser. No. 2007-37309 filed on Feb. 19, 2007, the content of which is hereby incorporated by reference into this application.
1. Field of the Invention
The present invention relates to an automatic analyzer and automatic analyzing method which carries out qualitative and quantitative analyses of biological or chemical samples such as blood and urine and more particularly to an automatic analyzer with a mixing device.
2. Description of the Related Art
It is known that conventional chemical or biochemical analyzers use a reaction liquid obtained by mixing a sample such as serum with a desired reagent as an object of analysis and measures its absorbance. This kind of analyzer is comprised of a mechanism for providing a sample and a reagent into a reaction chamber or cuvette, a mechanism for mixing a sample and a reagent in a reaction chamber, a mechanism for analyzing physical properties of a sample which is reacting or has finished reaction, and so on.
A major technical problem in analyzers is reduction of the required quantities of sample and reagent for analysis. One reason for this is that as the number of test items increases, the quantity of sample available for one test item decreases. For example, in blood tests of infants, the quantity of blood sample available for analysis is very small. In addition, from the viewpoint of cost, there is demand for reduction of the quantity of reagent used in analysis. Because there is the growing tendency that advanced analysis techniques are introduced and expensive reagents are widely used.
As the quantities of sample and reagent used for analysis were decreased, the size of reaction chambers was reduced. However, this has posed a new problem. For example, when the reaction liquid is mixed mechanically by a spatula or the like, the ratio of reaction liquid taken out or the ratio of rinse fluid taken in becomes larger, which affects the analysis result. One solution to this problem related to mixing is a non-contact mixing device using ultrasonic waves as described in JP-A No. 2003-35715. However, in this case, for the sample and reagent which are injected into a reaction chamber, their mixture ratio varies depending on the type of test, or test item. So the quantity of liquid to be measured in the chamber is different and complicated control work is needed for efficient mixing.
The technique described in JP-A No. 2003-35715 uses a plurality of ultrasonic oscillators provided at different heights so that mixing efficiency does not deteriorate even when the liquid level of liquid to be mixed varies. In this case, complicated control work is needed to determine which oscillator should be activated according to the liquid level. Also it is desirable to adjust the intensity of oscillation depending on the properties of the liquid to be mixed (viscosity, etc). Not only in non-contact ultrasonic mixing but also in mechanical mixing with a spatula, a smaller quantity of liquid to be mixed makes it more difficult to ensure uniformity in mixing.
An object of the present invention is to provide an automatic analyzer and analyzing method having a mixing device with a simple structure which is able to mix liquids uniformly regardless of the quantity of sample and liquid properties.
In order to achieve the above object, the present invention provides an automatic analyzer as summarized below.
The automatic analyzer includes a liquid adding device for adding a conditioning liquid into a reaction chamber, wherein the predetermined quantity of liquid is prepared in each reaction chamber before the mixing.
The reaction chamber is a container in which a sample and a reagent are mixed to react with each other. The reaction liquid in the reaction chamber is analyzed qualitatively and quantitatively by an optical method (measurement of change in absorbance, etc). For the mixing device, various mixing methods are available. For example, a spatula is moved for mixing or the outside of the reaction chamber is irradiated with ultrasonic waves to agitate the liquid by acoustic radiation pressure. The conditioning liquid may be a diluent or physiological saline as used for dilution of a sample or any other special liquid that adjusts the properties of liquid to be mixed (viscosity, surface tension, etc). In automatic analyzers, the quantity of reagent is several times as much as the quantity of sample and the properties of liquid to be mixed largely depends on those of the reagent. Therefore, the properties of the conditioning liquid are optimized depending on those of the reagent and the properties of liquid to be mixed become almost identical regardless of test item.
Therefore, according to the present invention, there is provided an automatic analyzer which assures uniformity in mixing effects regardless of sample quantity and test item and thus produces analysis results with high repeatability.
The invention will be more particularly described with reference to the accompanying drawings, in which:
Next, a preferred embodiment of the present invention will be described referring to the accompanying drawings.
The automatic analyzer according to this embodiment is mainly composed of a sample disk 1, a reagent disk 2, a reaction disk 3, a reaction bath 4, a sampling mechanism 5, a pipetting mechanism 6, a mixing mechanism 7, a photometric mechanism 8, a rinsing mechanism 9, and a controller 40. The controller 40 further includes a display unit 10, an input unit 11, a memory 12, and a control unit 13.
Referring to
In the reagent disk 2, plural reagent bottles 18a, which contain reagents to be mixed with samples for reaction, and conditioning liquid bottles 18b are arranged and fixed on the circumference of a circular disk 19 which is surrounded by a temperature-controlled cold storage 20. The circular disk 19 is rotated in the circumferential direction in a way that it can be repositioned by a ordinary drive mechanism composed of a motor, a rotary shaft and so on (not shown).
The reaction disk 3, equipped with plural reaction chamber holders 22 provided as a hole in the reaction disk 3 which hold reaction chambers 21 for samples and reagents, is circumferentially rotated and stopped repeatedly in a cycle by a drive mechanism 23 to transport the reaction chambers 21 intermittently.
The reaction bath 4 is provided along the excursion of movement of the reaction chambers 21. The reaction bath 4 serves as an incubation bath which uses, for example, a temperature-controlled liquid to control the reaction liquid in a reaction chamber 21 to a given temperature in order to accelerate chemical or biochemical reaction between the sample and reagent. The reaction chambers 21 move inside the reaction bath 4.
The sampling mechanism 5 includes a probe 24, an arm 26 fitted to a support shaft 25 and a drive mechanism (not shown). The drive mechanism is provided for the movement of the probe 24 between the sample disk 1 and the reaction disk 3 with the support shaft 25 as the center of rotation. According to a predetermined sequence, The sampling mechanism 5 supplies a sample in a sample container 16 transported to a predetermined position by rotation of the sample disk 1, to a reaction chamber 21.
Similarly, the pipetting mechanism 6 includes a probe 27, an arm 29 fitted to a support shaft 28 and a drive mechanism(not shown). The drive mechanism enables the movement of the probe 27 between the reagent disk 2 and the reaction disk 3 with the support shaft 28 which operates as the center of rotation. According to a predetermined sequence, the pipetting mechanism 6 supplies a reagent in a reagent bottle 18a or a conditioning liquid in a conditioning liquid bottle 18b to a reaction chamber 21. The reagent bottle 18a or conditioning liquid bottle 18b is transported to a predetermining position by rotation of the reagent disk 2. The sample containers 16 and reagent bottles 18a contain different types of samples and reagents respectively and as much sample and reagent as needed are supplied to a reaction chamber 21. Likewise, the conditioning liquid bottles 18b contain different types of conditioning liquids and as much conditioning liquid as needed is supplied to the reaction chamber 21.
Referring to
As shown in
Referring to
Then as it arrives at the mixing position and stops, at least one of the piezoelectric elements 30, which depend on the quantity and properties of the liquid for reaction, is oscillated at a prescribed frequency by the piezoelectric element driver 14. Oscillating waves generated by the oscillated piezoelectric elements 30 are transmitted as sonic waves in the temperature-controlled water in the reaction bath 4 and reach the sample and reagent in the reaction chamber 21. The transmitted oscillating waves cause swirls, which stimulate movement of the sample and mix the sample and the reagent.
Looking back to
Again referring to the controller 40 of
The automatic analyzer according to this embodiment further includes a syringe and a pump as components and all these components are controlled by the control unit 13.
The operation of the automatic analyzer will be described next.
First, the reaction chamber 21 rinsed by the rinsing mechanism 9 is transported to the sample injection position by rotation of the reaction disk 3. And then a sample container 16 with a sample in it is transported to the sampling position by rotation of the sample disk 1. Similarly the reagent disk 2 transports a required reagent bottle 18a to the pipetting position.
Then, the sampling mechanism 5 is activated to inject a sample from the sample container 16 transported to the sampling position into the reaction chamber 21 transported to the sample injection position using the probe 24. The reaction chamber 21 with the injected sample in it is transported to the reagent injection position and a reagent is injected from the sample bottle 18a transported to the pipetting position on the reagent disk 2, into the reaction chamber 21 transported to the reagent injection position, by the pipetting mechanism 6.
Then, the reaction chamber 21 is transported to the conditioning liquid injection position. Meanwhile, the reagent disk 2 transports a required conditioning liquid bottle 18b to the pipetting position and as the reaction chamber 21 arrives at the conditioning liquid injection position, a conditioning liquid is injected from the conditioning liquid bottle 18b into the reaction chamber 21 transported to the conditioning liquid injection position, by the pipetting mechanism 6.
The reaction chamber 21, which now contains the injected sample, reagent and conditioning liquid, is transported to the mixing position where they are mixed by the mixing mechanism 7.
The absorbance of the reaction liquid thus mixed is measured by the photometric mechanism 8 while the reaction chamber 21 is passing between the light source and the photometer. This measurement cycle is made several times and after finishing all measurement cycles, the reaction chamber 21 is rinsed by the rinsing mechanism 9.
A series of steps as mentioned above are taken for each reaction chamber 21 so that the automatic analyzer makes analysis according to this embodiment.
The characteristics of this embodiment will be explained below.
This embodiment is characterized in that a conditioning liquid is injected in addition to the sample and reagent before the reaction chamber 21 arrives at the mixing position and thus the quantity and properties of liquid for reaction are controlled within prescribed ranges.
For the above characteristics, the analyzer takes the following preparations under the control of the control unit 13:
The first preparation is made, for example, by entry of the type of conditioning liquid suitable for each test item as a parameter through the input unit 11. Alternatively, it is also possible that a look-up table of conditioning liquid types suitable for different test items as shown in
For the second preparation, the injection quantity is determined, for example, by subtracting the sum of the quantities of sample and reagent from the target quantity of liquid as shown in
In the control unit 13, an output of the conditioning liquid volume calculating means 131 and the output of a reserved conditioning liquid detecting means 132 are compared in a comparing means 132 and the result is inputted in a output means 134. Then the output means send a analyzing start command to the analyzer when the volume of the reserved conditioning liquid in the bottle 18b satisfy the needed volume. When the volume of the reserved conditioning liquid is less than the needed volume, The output means 134 send an analyzing inhibiting command to the analyzer.
When the volume of reserved conditioning liquid is less than needed after the analyzing is started, a alarm adding means 135 add a alarm information to the analyzing result.
These process is performed by the sequence program processed in the control unit 13. And special hard logic circuit may also utilized instead.
Properties of the liquid for reaction such as viscosity and wettability are controlled within ranges suitable for solution mixing by injection of a conditioning liquid.
After the above two preparations are made, finally the conditioning liquid is injected in the reaction cuvette 21 to adjust the quantity and properties of liquid for reaction so that the required quantities of sample and reagent can be decreased without extremely reducing the size of the reaction chamber 21.
In other words, the required quantities of sample and reagent can be decreased without the possibility of encountering a new technical problem which might arise with reaction chamber size reduction.
In addition, since the quantity and properties of the liquid for reaction are controlled within prescribed ranges, the mixing mechanism 7 can be simplified.
In other words, the need for complicated control work involved in dealing with different liquid quantities and properties for different test items is eliminated and also the number of electrodes 32 can be decreased, which means that the mixing mechanism 7 can be simplified.
Number | Date | Country | Kind |
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2007-037309 | Feb 2007 | JP | national |