CN212540420U - Semi-automatic immunofluorescence analyzer - Google Patents
Semi-automatic immunofluorescence analyzer Download PDFInfo
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- CN212540420U CN212540420U CN202020664628.2U CN202020664628U CN212540420U CN 212540420 U CN212540420 U CN 212540420U CN 202020664628 U CN202020664628 U CN 202020664628U CN 212540420 U CN212540420 U CN 212540420U
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Abstract
The utility model discloses a semi-automatic immunofluorescence analysis appearance includes: a sample module; the reagent module and the incubation module are integrated on the same platform structure and can move along a track, and the platform structure is provided with a plurality of side-by-side groove positions and a plurality of rows of holes; a reagent card is arranged in each slot position to form an incubation module with a plurality of incubation positions, and a plurality of hole positions are arranged in each row of holes so that the reagent module can be inserted into at least one TIP head and one reagent tube; the sampling and sample adding module can move along the track; a detection module that moves along the track to perform immunofluorescence detection on different reagent cards. The utility model discloses with reagent module and incubation module integration on same platform structure, sample application of sample module can follow the track and accomplish the sample application of sample action with the displacement of less degree, has shortened the time of sample application of sample, and sample application of sample module is along the rail mobility simultaneously, conveniently carries out automated control, improves the efficiency of sample application of sample, eliminates the influence of manual operation sample application of sample to testing result stability.
Description
Technical Field
The utility model relates to a medical instrument check out test set technical field, more specifically says, the utility model relates to a semi-automatic immunofluorescence analysis appearance.
Background
Most of the existing semi-automatic fluorescence immunoassay analyzers in the current market are of a single-channel structure, a plurality of items cannot be tested simultaneously, and the detection efficiency is not high; and the sampling and sample dropping work is mostly finished manually, the manual participation is too much, the operation requirement is high, the stability of manual operation cannot be ensured, and the precision and the stability of the detection result are influenced.
Most of the existing multi-channel fluorescence immunoassay analyzers are full-automatic instruments, the requirements on the used sample amount are large, the instrument is large in size and high in price, and the use cost of general medical institutions is too high.
Therefore, it is highly desirable to design a semi-automatic immunofluorescence analyzer to improve the detection efficiency and avoid the influence of manual operation on the detection result.
SUMMERY OF THE UTILITY MODEL
It is an object of the present invention to address at least the above-mentioned deficiencies and to provide at least the advantages which will be explained later.
Another object of the utility model is to integrate reagent module and incubation module in order to shorten the time raise the efficiency of sample application.
The utility model discloses a another purpose is that the automatic sample application that realizes of sample application module is sampled in the design, eliminates manual operation to the influence of testing result.
To achieve these objects and other advantages in accordance with the purpose of the invention, the present invention provides a semi-automatic immunofluorescence analyzer, wherein, includes:
a sample module for placing a sample;
the reagent module and the incubation module are integrated on the same platform structure, a plurality of side-by-side groove positions and a plurality of rows of holes are formed in the platform structure, and each groove position corresponds to one row of holes; each slot is internally provided with a reagent card to form an incubation module with a plurality of incubation positions, and the row of holes are provided with a plurality of hole positions so that the reagent module can be inserted into at least one TIP head and one reagent tube;
the sampling and sample-adding module can move between the sample module and the platform structure along a track, and a sampling gun is arranged on the sampling and sample-adding module and is allowed to be matched with the TIP head to finish sampling and sample-adding actions;
a detection module that moves along the track to perform immunofluorescence detection on different reagent cards.
Among the above-mentioned technical scheme, reagent module and incubation module integration are structural at same platform, and sample application module can be followed the track and accomplished sample application action with the displacement of less degree, has shortened the time of sample application, and sample application module is along track movement simultaneously, conveniently carries out automated control, improves the efficiency of sample application, eliminates the influence of manual operation sample application to testing result stability.
Meanwhile, the incubation module is provided with a plurality of incubation positions, and the detection module can move along the track, so that a plurality of item detections can be carried out.
Preferably, in the semi-automatic immunofluorescence analyzer, the sample module includes:
the bottom of the test tube rack is matched with the track, a plurality of test tube holes are formed in the test tube rack, and test tubes loaded with samples can be rotatably placed in the test tube holes;
a scanner for scanning a label on a test tube;
liftable test tube drive arrangement, it includes driving motor and fitting piece, the bottom of fitting piece is provided with inward toper sunken, and the toper is sunken more and more to inner radius less, when test tube drive arrangement descends, the toper is sunken to be cooperated with the test tube, driving motor drive fitting piece rotates and rotates through friction drive test tube.
The sample can deposit or the layering at the in-process that stews, sets up the sample that test tube drive arrangement can mix in the test tube, improves sample detection's accuracy. During the use, detection item, personal information etc. in the label on the scanner scanning test tube, test tube drive arrangement descends and makes the sunken and test tube cooperation of fitting piece, because sunken radius is more and more little, therefore test tube drive arrangement descends more, and the fitting piece is inseparabler with the test tube cooperation, and test tube drive arrangement descends behind the certain distance (this distance can preset), and driving motor drive fitting piece rotates, and the fitting piece passes through frictional force and drives the test tube rotation for the sample mixing.
Preferably, in the semi-automatic immunofluorescence analyzer, the platform structure is formed by splicing or integrally molding a first plate and a second plate;
the groove position is arranged on the second plate, and the row holes are arranged on the first plate; the second plate is a metal heat conducting plate;
a Peltier temperature control device is arranged below the second plate and used for controlling the temperature in the slot position.
The slot position forms the incubation module after inserting the reagent card, and the incubation module needs suitable temperature, and peltier temperature control device can provide suitable temperature environment.
Preferably, in the semi-automatic immunofluorescence analyzer, the peltier temperature control device includes:
a Peltier patch attached below the second plate;
a heat conducting plate attached below the Peltier; the heat dissipation can be promoted, and the heat conduction and the heat dissipation are more uniform.
The fan is arranged below the heat conducting plate and used for blowing air and dissipating heat;
a temperature sensor disposed within the slot;
and the single chip microcomputer is connected with the temperature sensor, the Peltier and the fan.
Preferably, in the semi-automatic immunofluorescence analyzer, in the sampling and sample-adding module, a sampling gun is vertically arranged and matched with a rail to move up and down;
the diameter of the lower end of the sampling gun is continuously reduced to form a gun mouth, the gun mouth is sleeved with the TIP head, and the sampling gun is of a hollow structure and is communicated with the pump body;
be provided with liquid response module on the sample gun in order to prevent that the sample gun from inhaling empty.
When the sampling and sample-adding device is used, the sampling and sample-adding module transversely moves to the upper side of the TIP head along the track, then the sampling gun vertically moves downwards along the track to be sleeved with the TIP head, the sampling gun moves downwards to be tighter than the TIP head sleeve, the sampling gun moves downwards by a certain depth, so that the matching degree of the sampling gun and the TIP head is just proper, and the sampling and sample-adding process is not easy to drop, leak gas or leak liquid. The sampling gun finishes the suction of a sample or a reagent through the suction of the pump body so as to achieve the purpose of sampling and sample adding.
The principle of the liquid induction module is as follows: when the different media of sampling gun suction, required suction is different, and the load of the pump body is also different, and liquid response module and pump body coupling, through the electric current or the voltage change that detect the pump body, and then judge whether the sampling gun inhales the air or inhales liquid, consequently can judge whether the sampling gun inhales the sky. If the air is sucked, the instrument can be set to give out corresponding alarms and prompts. The liquid induction module can improve the accuracy of the sample suction.
Preferably, in the semi-automatic immunofluorescence analyzer, the sampling and sample-adding module further comprises a hole pricking gun, and the hole pricking gun is vertically arranged on the sampling and sample-adding module in a vertically movable manner.
Preferably, the semi-automatic immunofluorescence analyzer further comprises a TIP removal head module, the TIP removal head module comprises a first hole and a second hole which are arranged on the same plate, the aperture of the first hole is set to allow the TIP head to pass through, the aperture of the second hole is set to disallow the TIP head to pass through, the first hole is communicated with the second hole, after sampling and sample adding are completed, the sampling gun is inserted into the first hole and is transversely moved to the second hole and then is drawn out, and the TIP head is clamped by the second hole to complete separation of the sampling gun and the TIP head.
During the use, sample application of sample module is along track lateral shifting to first hole top, and the vertical downstream of sampling gun inserts first hole, then sample application of sample module lateral shifting makes in sampling gun lateral shifting to the second hole, then the sampling gun moves up to take out from the second hole, and the TIP head is blocked and then separates with the sampling gun because can't pass through the second hole, and the TIP head that breaks away from drops in the TIP head collection box.
Preferably, the semi-automatic immunofluorescence analyzer further comprises:
a display module disposed on a housing of the semi-automatic immunoassay analyzer;
a button assembly disposed on a housing of the semi-automatic immunoassay analyzer;
and the control module is connected with the display module, the sampling and sample adding module, the detection module, the sample module and the Peltier temperature control device.
The display module can display various information such as operation information, detection project information, detection analysis result information and the like; the button subassembly can carry out work operation control and selection, horizontal and longitudinal movement that control module can control sample application of sample module, reciprocating and the sample application of sample action of sampling rifle, can control detection module and carry out fluorescence immunoassay and analysis, can show the detection and analysis result on the display module or save storage module, control module can control the test tube drive arrangement in the sample module and go up and down and driving motor's operation, can also control peltier temperature regulating device's operation.
Preferably, semi-automatic immunofluorescence analysis appearance in, control module control test tube drive arrangement goes up and down to make fitting piece and test tube contact to control driving motor drive test tube and rotate so that the sample mixing:
when the sampling gun is downwards sleeved with the TIP head, the control module controls the sampling gun to downwards probe along the track for a fixed depth and then stops, so that the sampling gun is prevented from being excessively sleeved with the TIP head;
the control module is connected with the liquid sensing module and the pump body and controls the pump body to suck according to signals of the liquid sensing module. When the liquid sensing module senses that the sampling gun sucks liquid, the control module controls the pump body to operate to finish sample suction, and when the liquid sensing module senses that the sampling gun sucks the air, the control module controls the pump body to stop sample suction.
The utility model discloses at least, include following beneficial effect:
the integration of the reagent module and the incubation module shortens the sampling and sample adding time and improves the sampling and sample adding efficiency; the design of the sampling and sample adding module enables the semi-automatic instrument to realize sample adding and sampling automation, thereby eliminating the influence of manual operation on the stability of a detection result; in addition, the sampling and sample adding module is internally provided with a pressure sensor, so that the sampling and sample adding precision is improved, the sampling and sample adding stability is ensured, and the stability of a detection result is also ensured; and the detection module can move to allow the items with the reaction time to be detected in time, so that a plurality of items can be detected simultaneously.
Additional advantages, objects, and features of the invention will be set forth in part in the description which follows and in part will become apparent to those having ordinary skill in the art upon examination of the following or may be learned from practice of the invention.
Drawings
FIG. 1 is a schematic view of a three-dimensional structure of a semi-automatic immunofluorescence analyzer of the present invention in one direction;
FIG. 2 is a schematic view of the other direction of the semi-automatic immunofluorescence analyzer of the present invention;
fig. 3 is a schematic view of a vertical cross-section structure of the platform structure of the present invention;
FIG. 4 is a schematic structural view of the TIP removing head module of the present invention;
fig. 5 is a schematic structural diagram of the fitting piece and the test tube of the present invention.
Detailed Description
The present invention is further described in detail below with reference to examples so that those skilled in the art can implement the invention with reference to the description.
As shown in fig. 1 to 5, a semi-automatic immunofluorescence analyzer, comprising:
a sample block 1 for placing a sample;
the reagent module and the incubation module are integrated on the same platform structure 4, a plurality of parallel slot positions 15 and a plurality of rows of holes 6 are arranged on the platform structure 4, and each slot position 15 corresponds to one row of holes; each slot 15 houses a reagent card 5 to form an incubation module with a plurality of incubation positions, the array of holes being provided with a plurality of holes to enable the reagent module to be inserted into at least one TIP head 7 and one reagent tube 6;
the sampling and sample-adding module 8 can move between the sample module 1 and the platform structure 4 along a track, a sampling gun 9 is arranged on the sampling and sample-adding module 8, and the sampling gun 9 is allowed to be matched with the TIP head to finish sampling and sample-adding actions; generally, a sampling gun has a function of sucking and discharging a liquid, and sucks the liquid at the time of sampling and discharges the liquid at the time of sampling. The analyzer is internally provided with a corresponding track, and the sampling and sample adding module is matched with the track and moves to a corresponding position along the track when being driven.
A detection module 11 that moves along the track to perform immunofluorescence detection on different reagent cards 5. The analyzer is also provided with a track matched with the detection module 11, so that the detection module 11 can move along the track to perform immunofluorescence detection on the reagent cards in different slots.
The technical scheme is characterized in that: reagent module and incubation module integration are structural at same platform, and sample application module can be followed the track and accomplished sample application action with the displacement of less degree, has shortened the time of sample application, and sample application module is along the orbital motion simultaneously, conveniently carries out automated control, improves the efficiency of sample application, eliminates the influence of manual operation sample application to testing result stability.
Meanwhile, the incubation module is provided with a plurality of incubation positions, and the detection module can move along the track, so that a plurality of item detections can be carried out.
Further, the sample block 1 includes:
the bottom of the test tube rack is matched with the track, a plurality of test tube holes are formed in the test tube rack, and the test tubes 2 loaded with samples can be rotatably placed in the test tube holes;
a scanner for scanning the label on the test tube 2;
liftable test tube drive arrangement 3, it includes driving motor and fitting piece 22, the bottom of fitting piece 22 is provided with inward toper sunken, and sunken more to inner radius less, when test tube drive arrangement 3 descends along rail movement, sunken and test tube 2 cooperation, driving motor drive fitting piece 22 rotates and drives test tube 2 through friction and rotates.
During the use, detection item, personal information etc. in the label on the scanner scanning test tube, test tube drive arrangement descends and makes the sunken and test tube cooperation of fitting piece, because sunken radius is more and more little, therefore test tube drive arrangement descends more, and the fitting piece is inseparabler with the test tube cooperation, and test tube drive arrangement descends behind the certain distance (this distance can preset), and driving motor drive fitting piece rotates, and the fitting piece passes through frictional force and drives the test tube rotation for the sample mixing.
Further, as shown in fig. 3, the platform structure 4 is formed by splicing or integrally forming a first plate 13 and a second plate 14;
the slot position 15 is arranged on the second plate 14, and the row holes are arranged on the first plate 13; the second plate 14 is a metal heat conducting plate;
a peltier temperature control device is arranged below the second plate 14 to control the temperature in the slot.
The slot position 15 forms an incubation module after being inserted into the reagent card 5, the incubation module needs a proper temperature, and the Peltier temperature control device can provide a proper temperature environment.
Further, the peltier temperature control device comprises:
a peltier 16 affixed under said second plate 14;
a heat conducting plate 17 attached under the peltier 16; the heat dissipation can be promoted, and the heat conduction and the heat dissipation are more uniform.
A fan 18 arranged below the heat conducting plate 17 for blowing air and dissipating heat;
a temperature sensor disposed within the slot 15;
and the single chip microcomputer is connected with the temperature sensor, the Peltier and the fan.
The single chip microcomputer controls the fan and the Peltier to operate according to the temperature signal of the temperature sensor, and therefore the groove position is kept at a proper temperature.
Further, in the sampling and sample-adding module 8, a sampling gun 9 is vertically arranged and matched with the rail to move up and down;
the diameter of the lower end of the sampling gun 9 is continuously reduced to form a gun mouth, the gun mouth is sleeved with the TIP head, the sampling gun is of a hollow structure and is communicated with a pump body, and the pump body pumps to enable the sampling gun to suck or discharge liquid;
and a pressure sensor is arranged on the sampling gun 9 and used for sensing the sleeving pressure of the sampling gun and the TIP head.
Be provided with liquid response module on the sample gun in order to prevent that the sample gun from inhaling empty.
When the sampling and sample-adding device is used, the sampling and sample-adding module transversely moves to the upper side of the TIP head along the track, then the sampling gun vertically moves downwards along the track to be sleeved with the TIP head, the sampling gun moves downwards to be tighter than the TIP head sleeve, the sampling gun moves downwards by a certain depth, so that the matching degree of the sampling gun and the TIP head is just proper, and the sampling and sample-adding process is not easy to drop, leak gas or leak liquid. The sampling gun finishes the suction of a sample or a reagent through the suction of the pump body so as to achieve the purpose of sampling and sample adding.
When the different media of sampling gun suction, required suction is different, and the load of the pump body is also different, and liquid response module and pump body coupling, through the electric current or the voltage change that detect the pump body, and then judge whether the sampling gun inhales the air or inhales liquid, consequently can judge whether the sampling gun inhales the sky. If the air is sucked, the instrument can be set to give out corresponding alarms and prompts.
Further, sample application module 8 still includes prick hole rifle 10, prick the same vertical ground that can reciprocate of hole rifle 10 and set up on sample application module, prick the hole rifle and reciprocate when being driven and be used for pricking the membrane of sealing on reagent pipe or the test tube, avoid TIP and the contact of membrane of sealing, reduce the contaminated risk of TIP.
Further, as shown in fig. 4, the TIP removing head module 19 is further included, the TIP removing head module 19 includes a first hole 20 and a second hole 21 which are arranged on the same plate, the hole diameter of the first hole 20 is set to allow the TIP head to pass through, the hole diameter of the second hole 21 is set to not allow the TIP head to pass through, the first hole 20 and the second hole 21 are communicated, after sampling and sample adding are completed, the sampling gun is inserted into the first hole 20 and is transversely moved to the second hole 21 to be drawn out, and the TIP head is clamped by the second hole 21 to complete separation of the sampling gun and the TIP head.
During the use, sample application of sample module is along track lateral shifting to first hole top, and the vertical downstream of sampling gun inserts first hole, then sample application of sample module lateral shifting makes in sampling gun lateral shifting to the second hole, then the sampling gun moves up to take out from the second hole, and the TIP head is blocked and then separates with the sampling gun because can't pass through the second hole, and the TIP head that breaks away from drops in TIP head collection box 12.
Further, still include:
a display module disposed on a housing of the semi-automatic immunoassay analyzer;
a button assembly disposed on a housing of the semi-automatic immunoassay analyzer;
and the control module is connected with the display module, the sampling and sample adding module, the detection module, the sample module and the Peltier temperature control device.
The display module can display various information such as operation information, detection project information, detection analysis result information, error prompt information and the like; the button subassembly can carry out work operation control and selection, horizontal and longitudinal movement that control module can control sample application of sample module, reciprocating and the sample application of sample action of sampling rifle, can control detection module and carry out fluorescence immunoassay and analysis, can show the detection and analysis result on the display module or save storage module, control module can control the test tube drive arrangement in the sample module and go up and down and driving motor's operation, can also control peltier temperature regulating device's operation.
Further, control module control test tube drive arrangement goes up and down to make fitting piece and test tube contact to control driving motor drive test tube and rotate so that the sample mixing:
when the sampling gun is downwards sleeved with the TIP head, the control module controls the sampling gun to downwards probe along the track for a fixed depth and then stops;
the control module is connected with the liquid sensing module and the pump body and controls the pump body to suck according to signals of the liquid sensing module. When the liquid sensing module senses that the sampling gun sucks liquid, the control module controls the pump body to operate to finish sample suction, and when the liquid sensing module senses that the sampling gun sucks the air, the control module controls the pump body to stop sample suction.
The utility model discloses a use as follows: after the system is started and initialized, an operator puts test tubes loaded with samples into a test tube rack, then pushes the test tube rack into the sample position in the instrument along a track, simultaneously puts consumables such as reagents of related detection items, sampling TIP heads and the like into corresponding positions, inserts an ID chip (stores basic information of each item, such as batch numbers, validity periods, standard curves and the like), connects the ID chip with a control module, and clicks a start button. The instrument starts to automatically identify whether the test items correspond to the required conditions one by one, prompts an operator to perform related operations on the display screen when the conditions are not met, and starts to test after the conditions are met. The test action was: the sample module carries out sample rotation mixing, and the rifle that takes a sample reaches reagent module installation disposable TIP head simultaneously, and the rifle that takes a sample of installing the TIP head moves to the sample module and absorbs the certain sample volume of each project. Then the sampling gun moves to the reagent module to drop the sample into the buffer solution test tube, the sample is subjected to throughput and uniform mixing for multiple times, a certain amount of uniformly mixed liquid is sucked, all the mixed liquid is discharged to the sample dropping port corresponding to the reagent card, and the reaction time is calculated. And after the reaction time is met, scanning immunofluorescence detection is carried out on the reagent card through the detection module, and after the data is subjected to spectrum recognition, the data is sent to the control module for data analysis and data processing, and then the detection result is displayed on a screen. And finally, printing the related information together through a self-contained printer or transmitting the related information to a connected computer for printing.
While embodiments of the invention have been disclosed above, it is not intended to be limited to the applications listed in the specification and the examples. It can be applicable to various and be fit for the utility model discloses a field completely. Additional modifications will readily occur to those skilled in the art.
Claims (8)
1. A semi-automatic immunofluorescence analyzer, comprising:
a sample module for placing a sample;
the reagent module and the incubation module are integrated on the same platform structure, a plurality of side-by-side groove positions and a plurality of rows of holes are formed in the platform structure, and each groove position corresponds to one row of holes; each slot is internally provided with a reagent card to form an incubation module with a plurality of incubation positions, and the row of holes are provided with a plurality of hole positions so that the reagent module can be inserted into at least one TIP head and one reagent tube;
the sampling and sample-adding module moves between the sample module and the platform structure along the track, a sampling gun is arranged on the sampling and sample-adding module, and the sampling gun is allowed to be matched with the TIP head to finish sampling and sample-adding actions;
a detection module that moves along the track to perform immunofluorescence detection on different reagent cards.
2. The semi-automatic immunofluorescence analyzer of claim 1, wherein the sample module comprises:
the bottom of the test tube rack is matched with the track, a plurality of test tube holes are formed in the test tube rack, and test tubes loaded with samples can be rotatably placed in the test tube holes;
a scanner for scanning a label on a test tube;
liftable test tube drive arrangement, it includes driving motor and fitting piece, the bottom of fitting piece is provided with inward toper sunken, and the toper is sunken more and more to inner radius less, when test tube drive arrangement descends, the toper is sunken to be cooperated with the test tube, driving motor drive fitting piece rotates and rotates through friction drive test tube.
3. The semi-automatic immunofluorescence analyzer of claim 2, wherein the platform structure is formed by a first plate and a second plate that are spliced or integrally formed;
the groove position is arranged on the second plate, and the row holes are arranged on the first plate; the second plate is a metal heat conducting plate;
a Peltier temperature control device is arranged below the second plate and used for controlling the temperature in the slot position.
4. The semi-automatic immunofluorescence analyzer of claim 3, wherein the Peltier temperature control device comprises:
a Peltier patch attached below the second plate;
a heat conducting plate attached below the Peltier;
the fan is arranged below the heat conducting plate and used for blowing air and dissipating heat;
a temperature sensor disposed within the slot;
and the single chip microcomputer is connected with the temperature sensor, the Peltier and the fan.
5. The semi-automatic immunofluorescence analyzer of claim 4, wherein in the sample application module, a sampling gun is vertically disposed and cooperates with a rail to move up and down;
the diameter of the lower end of the sampling gun is continuously reduced to form a gun mouth, the gun mouth is sleeved with the TIP head, and the sampling gun is of a hollow structure and is communicated with the pump body;
be provided with liquid response module on the sample gun in order to prevent that the sample gun from inhaling empty.
6. The semi-automatic immunofluorescence analyzer of claim 5, wherein the sample and application module further comprises a pricking gun, and the pricking gun is also vertically and vertically movably disposed on the sample and application module.
7. The semi-automatic immunofluorescence analyzer of claim 6, further comprising a TIP removal block, the TIP removal block comprising a first hole and a second hole disposed on the same block, the first hole having an aperture configured to allow the TIP to pass through, the second hole having an aperture configured to not allow the TIP to pass through, the first hole and the second hole being in communication.
8. The semi-automatic immunofluorescence analyzer of claim 7, further comprising:
a display module disposed on a housing of the semi-automatic immunoassay analyzer;
a button assembly disposed on a housing of the semi-automatic immunoassay analyzer;
and the control module is connected with the display module, the sampling and sample adding module, the detection module, the sample module and the Peltier temperature control device.
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Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN111487402A (en) * | 2020-04-27 | 2020-08-04 | 巴迪泰(广西)生物科技有限公司 | Semi-automatic immunofluorescence analyzer |
CN114813300A (en) * | 2022-06-24 | 2022-07-29 | 普迈德(北京)科技有限公司 | Blood sample diluting device and diluting method for immunoassay detection equipment |
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2020
- 2020-04-27 CN CN202020664628.2U patent/CN212540420U/en active Active
Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN111487402A (en) * | 2020-04-27 | 2020-08-04 | 巴迪泰(广西)生物科技有限公司 | Semi-automatic immunofluorescence analyzer |
CN111487402B (en) * | 2020-04-27 | 2024-08-27 | 巴迪泰(广西)生物科技有限公司 | Semi-automatic immunofluorescence analyzer |
CN114813300A (en) * | 2022-06-24 | 2022-07-29 | 普迈德(北京)科技有限公司 | Blood sample diluting device and diluting method for immunoassay detection equipment |
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