JPS63106567A - Pipet apparatus having automatic nozzle tip replacing mechanism - Google Patents

Abstract

PURPOSE:To prevent the mutual mixing of a sample liquid, by making it possible to inject the sample liquid while the automatic replacement of a nozzle tip is performed with respect to a large number of reaction cells prepared and arranged. CONSTITUTION:The title apparatus consists of a nozzle tip detaching lever 19 loosely fitted around the lower end part of a shaft body 16, the holding spring 20 mounted in the shaft body 16 and always biasing the lever 19 to an upward side and the second air cylinder apparatus 21 for allowing downward moving force to act on the lever and bringing the lever 19 into engagement with the upper end of a nozzle tip 9 in an engaged state to detach the nozzle tip 9 from the lower end part of the shaft body 16. The timings of the engagement of the nozzle tip 9, the subsequent detachment thereof after a series of the suction and distribution of a sample liquid are performed and the engagement and detachment of the nozzle chip 9 further subsequently performed are taken by a microcomputer being a predetermined electronic control apparatus.

Description

Detailed Description of the Invention (Field of Application of the Invention) The present invention relates to a pipette device for automatic injection of a small amount of liquid used in a measuring device for automatically and continuously measuring a large number of analytes (sample liquids); For details, attach the bottom end of the pipette nozzle to a removable and replaceable disposable nozzle tip (
The present invention relates to a pipette device comprising a nozzle tip (hereinafter simply referred to as a nozzle tip) and having an automatic exchange mechanism that allows the nozzle tip to be exchanged for each sample to be injected.

(Background of the Invention) Generally, when detecting a trace amount of a substance in a sample liquid by immunoreaction or chemical or other biochemical methods, appropriate reagents are added to the target sample liquid.
Changes appearing in the sample liquid are detected and measured by optical means, etc., but for this purpose, skilled techniques are often required for operations such as quantifying the sample liquid and adding a constant amount of reagent.

However, such testing work is generally monotonous and tiring work, and it is difficult to handle minute amounts of sample liquid, reagents, etc. with high accuracy over a long period of time, and there is a possibility of errors due to individual differences among testing technicians. Conventionally, due to problems such as the desire to reduce as much as possible, and furthermore, the absolute number of skilled laboratory technicians is insufficient compared to the increase in the number of test subjects,
Various studies and developments have been conducted regarding automated devices for detecting and quantifying trace amounts of substances using biochemical methods.

By the way, in devices for measuring and detecting trace components in sample liquids, it is normal for the target substance to be detected to be in extremely small amounts in the sample liquid, so the automation of the device is also effective in addressing this issue. In addition, in a system that processes different sample solutions at once, the concentration ratio of the target substance to be detected between the sample solutions may be close to 1:106 (for example, α-protein In order to perform measurements with high precision and few errors, it is also required to minimize the risk of samples mixing together.

(Object of the Invention) The present invention has been made from this point of view, and its object is to provide a pipette device suitably used for quantitatively injecting a plurality of sample liquids, etc. into a large number of prepared and arranged reaction cells. It is in a place where we provide.

Another object of the present invention is to provide a pipetting device that also has a mechanism that allows the nozzle tip to be automatically replaced for each of a plurality of sample liquids.

(Summary of the Invention) The pipette device of the present invention, which has been made for this purpose, is characterized by having a lower end portion that can be externally fitted into the upper end opening of the nozzle tip, which is approximately in the shape of an inverted cone; A plunger-shaped shaft whose inside is connected to an air supply/discharge device for sucking and discharging liquid, a slider that supports this shaft so that it can move in a relatively small stroke in the vertical direction, and a slider that allows the slider to move in a large stroke in the vertical direction. a support pedestal movably supporting the slider; a large stroke drive means which interlocks and connects the slider and the support pedestal to move the slider up and down with respect to the support pedestal; and a large stroke drive means which operatively connects the slider and the shaft to the shaft. a small stroke drive means for moving the body up and down relative to the slider for fitting the nozzle chip; and a push-down blade is provided on the upper end surface of the nozzle chip externally fitted to the lower end of the shaft body so as to be operable. It has a 4JL configuration including a nozzle tip removal lever and a nozzle tip removal drive means for driving the nozzle tip removal lever.

In the present invention, the reason why the shaft body is made to move vertically (downwardly) with large strokes and small strokes as described above is to take into consideration the machining tolerance of the nozzle tip fitted to the lower end of the shaft body. This is to ensure the above-mentioned exterior fitting, that is, the fitted state, without causing damage to the nozzle tip.

The pipette device of the present invention having the above-mentioned configuration may be used by installing the device in a fixed manner so that an appropriate plate having a reaction cell can be inserted and removed therebelow, or by arranging the device in a row. The pipetting device may be used to scan the reaction cell eight times.

For each drive means in the above configuration, an appropriate type is used that is suitable for the characteristics of the device, which requires a relatively small stroke and precision in the stopping position, but generally, an air cylinder device, a pulse drive device, etc. are used. Motors, screw drives, cam mechanisms, etc. are preferably used. In particular, for the small stroke driving means that moves the shaft body up and down relative to the slider, the downward force of the shaft body when the shaft body is fitted is An air cylinder device is preferably used because it is easy to maintain the pressure at a constant level, but it is also recommended to use a shock absorber that deflects the spring when a force greater than that of the window is applied. It can be anything.

The nozzle tip that is inserted into the shaft and used for replacement can be a regular one, but depending on the amount of sample liquid to be aspirated or discharged, it is necessary to have a sufficient internal volume so that the sample liquid does not come into contact with the shaft. Needless to say, it is required to have a temperature of several μC to several mC.

INDUSTRIAL APPLICABILITY The present invention is preferably applied mainly to devices for analyzing biochemical reactions, and particularly to devices for measuring immune reactions using enzymes and the like as labels, but is not limited thereto. It is applicable to various analytical devices that require dispensing sample liquid for continuous analytical measurement.

(Embodiments of the Invention) The present invention will be described below using as an example an enzyme immunoassay device that performs measurements using a test cup filled with beads inside a reaction cell, as shown in the drawings.

The test cup mentioned above has a structure in which a plurality of beads are filled in a cup-shaped container body that opens upward, and the upper opening is sealed with a sealing foil. A cell prepared in advance to provide a reaction cell for a desired test item by immobilizing an antigen). It is also effective to use these beads by incorporating a magnetic substance so that the liquid in the reaction cell can be stirred by the action of an externally fluctuating magnetic field.

In FIG. 1, reference numeral 1 denotes a transport path for transporting the test plate 7 carrying a plurality of the test cups 8 in an array in the direction of the arrow in the figure. , the seal breakers 2. Sample liquid dispensing device 3゜B/
F separation device4. A substrate dispensing device 5 and a photometry device 6 are arranged.

Each of the above-mentioned devices, namely, seal breaker 2. sample liquid dispensing device 3. B/F separation device4. The substrate dispensing device 5 and the photometry device 6 first break the seal foil of the test cup, inject a predetermined amount of sample liquid into the reaction cell of the test cup whose top surface is open, and after the reaction, B /F
Injecting a substrate into the reaction cell that causes an optically detectable change due to the active action of the enzyme labeled on the antigen-antibody reaction complex, and detecting the change that occurs in the substrate. Each device is used for measurement.

The test plate 7 is provided with a large number of holes (not shown) so that a plurality of test cups 8 can be aligned and supported in a fixed position and posture as shown in FIG. By the operation of a feeding mechanism (not shown), the sheets are intermittently transported in the direction of the arrow in FIG. 1 at predetermined timing.

FIG. 2 shows a nozzle tip 9 used in the pipetting device of this example.
2 is a diagram showing an example of the preparation state in which one nozzle chip corresponds to one sample liquid, and the positional relationship between these and the reaction cell. If one row of test cups arranged horizontally in FIG. It will indicate the nozzle tip and sample liquid used for the group.

Reference numeral 11 denotes a nozzle chip stand, which is provided with a nozzle chip insertion support hole 11a and a sample liquid filling cup insertion support hole ttb so as to support the nozzle chip 9 and the sample liquid filling cup 10 in the illustrated state. There is.

3 and 4 show the pipette device of this example, and a slider (sliding base) is provided on the front surface of the support pedestal 12.
13 is assembled to be movable up and down, and a lower power transmission bin 13a on the side of the swinging arm 1 is attached to the support frame.
By reciprocatingly engaging the cam groove 14b of No. 4, the swinging arm 14 is provided to move up and down with the vibration force within a certain angular range. 14a is a central axis of swing of the swing arm 14. The swing arm 14 swings between the lower limit position shown by the solid line in the figure and the lower limit position shown by the phantom line in the figure by transmission of driving force from a pulse motor (not shown), etc. It is designed to move up and down. Note that a first air cylinder device 18 is fixed to the upper part of the slider 13 for lowering a shaft body 15, which will be described later.

Reference numeral 15 denotes a shaft body support bracket, and numeral 16 denotes a shaft body.These are integrated, and the shaft body support bracket 16 is an engagement portion that can slide vertically between the front surface of the slider 13. By having this, relative movement of a small stroke can be performed in the vertical direction. Reference numeral 13b denotes a guide bin protruding from the slider to constitute this engaging portion, and 15b denotes a vertically elongated guide hole formed in the shaft support bracket 15 to constitute this engaging portion. . Note that 15a is a connecting portion with the piston rod 18a of the air cylinder device 18, which is formed as the upper end portion of the shaft support bracket 15.

Since the shaft body 16 described above is integrated with the shaft body support bracket 15, the vertical movement (large stroke) of the slider 13 and the vertical movement (small stroke) by the first air cylinder device 18 can cause Two steps of vertical movement are performed.

Reference numeral 17 denotes an air pipe, which is attached to the shaft body 16 so as to pass through it in the vertical direction, and its upper end is connected to an air supply/discharge device (not shown), and its lower end is connected to the shaft body 1.
The nozzle tip 9 is fitted into the lower end of the nozzle tip 9 so as to face the inside of the nozzle tip 9.

With the above configuration, the shaft body 16 having the air pipe 17 is first moved by a large stroke of the slider 13 to bring its lower end close to the nozzle chip prepared below, and then by the first process, by the cylinder device 18. The small stroke makes it possible to securely fit the lower end portion without damaging the nozzle tip 9.

Next, the mechanism for removing the nozzle tip 9 used will be explained. This mechanism of this example consists of a nozzle tip removal lever 1 loosely fitted around the lower end of the shaft body 16.
9, a hold spring 20 that is built into the shaft body 16 and normally biases the sleeve 19a that is integral with the nozzle tip removal lever 19 upward, and a downward force for the nozzle tip removal lever 19. and a second air cylinder device 21 that engages the lever 19 with the upper end of the fitted nozzle tip and removes the nozzle tip from the lower end of the shaft body 16. Note that 19b is the lever 19 for removing the nozzle tip.
This is a guide bar that guides the vertical movement.

Furthermore, the timing for operating each of the above drive devices, that is, the fitting of the nozzle tip, then the removal of the nozzle tip after a series of suction and discharge (dispensing) of the sample liquid,
Further, the timing of the subsequent insertion/removal of the nozzle tip can be controlled using a predetermined electronic control device, -a2, in particular, a microcomputer.

FIG. 5 shows another embodiment of the device of the present invention.

In the example shown in FIG. 5, the support pedestal 12 is supported movably in the axial direction of the guide rods by a pair of guide rods 31 and 32 provided on the frame 30, and the sample suction is carried out by a moving device (not shown). It is designed so that 8 injections are made at each position for one dispensing.

Reference numeral 33 denotes a rotating shaft whose one end is connected to a pulse motor 34 , and the cam groove 14 b of the swinging arm (cam) 14 fixed non-rotatably to the rotating shaft 33 is connected to the protrusion 1 of the slider 13 .
3 a, the slider 13 rotates by engaging with the long groove.
can be moved up and down. Reference numeral 15 denotes a support bracket for the shaft body 16, which is inserted into a groove 13c formed on the front surface of the slider 13 and is slidably supported in the vertical direction. A fixed air cylinder device 18 is provided to provide a relative vertical movement of a small stroke to the slider. 15 and further in this example,
A nozzle tip removal lever 37 is attached to the lower part of this support bracket 15 so as to be swingable about a shaft 36,
This is used normally to remove the nozzle tip. Reference numeral 38 denotes a shaft loose fitting hole formed in the nozzle chip removal lever 37, and the nozzle chip 9 is removed when the lower surface of the periphery of the hole 38 engages with the upper end surface of the nozzle chip 9. ing.

The other configurations are substantially the same as in the previous embodiment.

(Effects of the Invention) According to the pipette device of the present invention having the above configuration, a large number of 4! Sample liquids can be injected into prepared reaction cells while automatically exchanging nozzle tips, so multiple sample liquids can be injected quantitatively into a given reaction cell without causing samples to mix with each other. This has the effect of greatly reducing the possibility of measurement errors occurring for each sample.

Further, according to the bed device of the present invention, since it has a machine groove for automatically replacing the nozzle tip used for each of a plurality of sample liquids, it is possible to suitably configure a device that automates analysis and measurement. can be obtained, and its usefulness is extremely great.

[Brief explanation of the drawing]

Figure 1 of the drawings shows an overview of the configuration of an enzyme immunoassay device incorporating a nozzle device according to the present invention - an example, and Figure 2 shows the relationship between a test plate carrying a test cup and a pipette device, etc. A perspective view, FIG. 3 is a front view of the pipette device, and FIG. 4 is a side view of the pipette device. FIG. 5 is a perspective view of an apparatus showing another embodiment of the invention. 2: Seal breaker 3: Sample liquid dispensing device 4: B/F separation device 5: Substrate dispensing device 6: Photometer 7: Test plate 8/test cup 9
: Nozzle tip 10: Sample liquid filling cup 11, Nozzle chip stand 11a: Nozzle chip insertion support hole 11b: Sample liquid filling cup insertion support hole 12: Support frame 13 Varnish slider 13a: Lower power transmission pin 13b;
Guide pin 13C: Groove 14: Swing arm 14a: Swing center shaft 14b: Cam groove 15: Shaft support bracket 15a: Air cylinder connecting portion 15b = Guide elongated hole -...1 6
: Offer Body 17: Air pipe 18: First air cylinder device 19; Nozzle tip removal lever 19a; Sleeve 19b, guide bar 20, two hold springs 21: Second (for nozzle tip removal) air cylinder device 30: Frame 31. 32 Ni guide rod 33; Rotation @ 34: Valse motor 35: Leaf spring 36: Shaft 37: Nozzle removal lever 38: Free fit hole Fig. 2

Claims (1)

[Claims] A plunger-shaped shaft body having a lower end portion that can be externally fitted to the upper end opening of the nozzle chip having a substantially inverted conical shape, and the inside of which is connected to an air supply/discharge device for sucking and discharging liquid, and this shaft body. a slider that supports the slider so as to be able to move relative to each other in a small stroke in the vertical direction; a support pedestal that supports the slider so that it can move in a large stroke in the vertical direction; a large stroke driving means for vertically moving the slider, a small stroke driving means for interlockingly connecting the slider and the shaft and moving the shaft vertically relative to the slider for fitting the nozzle chip; A nozzle chip removal lever is provided on the upper end surface of the nozzle chip externally fitted to the lower end so that a pressing blade can act, and a nozzle chip removal drive means for driving the nozzle chip removal lever. Pipette device with automatic nozzle tip exchange mechanism