CN115856328A - Sample analysis device - Google Patents

Abstract

A sample analysis apparatus, wherein the controller is further configured to generate a reagent tray interface configured to display and update reagent information for the reagent tray and a reagent loading and unloading interface configured to display and update reagent information for the reagent loading and unloading mechanism; the controller is further configured to control the display unit to display the reagent tray interface and/or the reagent loading/unloading interface, where the reagent tray interface and the reagent loading/unloading interface are not displayed on the same display screen at the same time. According to the invention, the reagent information is divided into the reagent disk interface and the reagent loading and unloading interface on the two interfaces according to the specific hardware structure, and the two interfaces are not displayed on the same display picture at the same time, so that the reagent information is richer in logical sense and hierarchical sense, and is very convenient for a user to check.

Description

Sample analysis device

Technical Field

The invention relates to the field of in-vitro diagnosis, in particular to a sample analysis device.

Background

A sample analyzer, such as a biochemical analyzer, an immunological analyzer, a cell analyzer, and the like, is a device for analyzing and measuring a sample, and generally measures a chemical component, a concentration, and the like in a sample by adding a reagent to the sample and then reacting the sample with the reagent in a predetermined manner.

As the test continues, consumables such as reagents are consumed, so that the sample analyzer needs to be replaced and replenished with reagents, and generally, the user is assisted to replace and replenish the reagents through related display interfaces, which are used for the user to view reagent information, even for the user to operate the sample analyzer, how to arrange and plan the relationship between the display interfaces and the specific displayed content, and are very important for the user to perform operations such as replacing and replenishing the reagents.

Disclosure of Invention

The present invention provides a sample analyzer, which will be described in detail below.

According to a first aspect, there is provided in an embodiment a sample analysis device comprising:

a sample section for supplying a sample to be measured;

the reagent component comprises a reagent disk, a reagent loading and unloading mechanism and a conveying mechanism; the reagent tray comprises a plurality of reagent sites for carrying reagent containers, the reagent tray being for scheduling the carried reagent containers; the reagent loading and unloading mechanism comprises a plurality of reagent positions for bearing reagent containers, and is used for scheduling the borne reagent containers; the transport mechanism is used for transporting the reagent container between the reagent disk and the reagent loading and unloading mechanism; the transport mechanism is used for transporting the reagent containers to be loaded from the reagent loading and unloading mechanism to the reagent tray and transporting the reagent containers to be unloaded from the reagent tray to the reagent loading and unloading mechanism;

a reagent dispensing unit configured to dispense a reagent in a reagent container carried by the reagent disk;

a reaction component for receiving the sample to be measured provided by the sample component and the reagent dispensed by the reagent dispensing component to prepare a sample;

a measuring unit for measuring the sample

A display section;

a controller for controlling the sample unit, the reagent dispensing unit, the reaction unit, the measurement unit, and the display unit;

wherein:

the controller is also used for acquiring reagent information of the reagent disk and reagent information of the reagent loading and unloading mechanism;

the controller is further used for generating a reagent disk interface and a reagent loading and unloading interface, wherein the reagent disk interface is used for displaying and updating the reagent information of the reagent disk, and the reagent loading and unloading interface is used for displaying and updating the reagent information of the reagent loading and unloading mechanism;

the controller is further configured to control the display unit to display the reagent disk interface and/or the reagent loading/unloading interface, where the reagent disk interface and the reagent loading/unloading interface are not displayed in the same display screen at the same time. The sample analysis device of claim 1, wherein the reagent tray interface has a reagent tray label control, and the reagent off-load interface has a reagent off-load label control;

in response to clicking the reagent disk label control, the controller controls the display component to switch to displaying the reagent disk interface;

and responding to clicking of the reagent loading and unloading label control, and controlling the display component to be switched to display the reagent loading and unloading interface by the controller.

In one embodiment, the display component comprises a first sub-display and a second sub-display; the first sub-display screen is used for displaying the reagent tray interface, and the second sub-display screen is used for displaying the reagent loading and unloading interface.

In one embodiment, the reagent loading and unloading interface further displays a pictogram of the reagent loading and unloading mechanism;

when the pictograph of the reagent loading and unloading mechanism moves, the reagent loading and unloading mechanism can correspondingly move along with the pictograph of the reagent loading and unloading mechanism; and/or when the reagent loading and unloading mechanism moves, the pictogram of the reagent loading and unloading mechanism can correspondingly move along with the reagent loading and unloading mechanism.

In one embodiment, when the reagent loading and unloading mechanism receives a motion signal triggered by a user to move, the pictogram of the reagent loading and unloading mechanism moves correspondingly along with the reagent loading and unloading mechanism.

In one embodiment, when the pictogram of the reagent loading and unloading mechanism receives a motion signal triggered by a user, the reagent loading and unloading mechanism moves correspondingly along with the pictogram thereof.

In one embodiment, the reagent loading and unloading mechanism is provided with a cover capable of opening and closing; when the cover is opened, the reagent loading and unloading mechanism forms an operation area for a user to operate, the display part correspondingly displays the operation area and the reagent position in the operation area on the pictogram of the reagent loading and unloading mechanism, and the operation area on the pictogram of the reagent loading and unloading mechanism is displayed in a mode different from other areas on the pictogram.

In one embodiment, in the reagent loading and unloading interface, the reagent positions on the reagent loading and unloading mechanism are associated with the displayed reagent information of the reagent loading and unloading mechanism through a pictogram of the reagent loading and unloading mechanism, wherein the display component displays the reagent information of the reagent loading and unloading mechanism in an array, the array comprises array elements with the same number as the reagent positions of the reagent loading and unloading mechanism, the array elements are independent from each other, and each array element corresponds to one reagent position of the reagent loading and unloading mechanism; each array element is a display area and is used for displaying reagent information of a corresponding reagent position, and the reagent information at least comprises reagent allowance information and reagent position information; and/or the presence of a gas in the gas,

the display part displays the reagent information of the reagent disk in an array in the reagent disk interface, the reagent information of the reagent disk comprises the reagent residual amount information of each test item, the array comprises a plurality of mutually independent array elements, and each array element is a display area and is used for displaying the reagent residual amount information of one test item.

In one embodiment, the controller acquires total remaining reagent amount information, controls the display unit to display the total remaining reagent amount information resident on the reagent loading/unloading interface, and controls the display unit to display the total remaining reagent amount information resident on the reagent disk interface.

In one embodiment, the reagent loading and unloading mechanism is provided with a cover capable of opening and closing; when the cover is changed from the closed state to the open state, the display component is switched to display the reagent loading and unloading interface, and when the cover is changed from the open state to the closed state, the display component is switched to display the reagent disk interface.

According to the sample analysis device of the embodiment, the reagent information is divided into the reagent disk interface and the reagent loading and unloading interface on the two interfaces according to the specific hardware structure, and the reagent disk interface and the reagent loading and unloading interface are not displayed on the same display screen at the same time when the two interfaces are displayed, so that the reagent information is richer in logical sense and layering sense, and the user can conveniently check the reagent information.

Drawings

FIG. 1 is a schematic diagram of a sample analyzer according to an embodiment;

FIGS. 2 (a) and 2 (b) are schematic views of the lid of the reagent disk of an embodiment being opened and closed, respectively;

FIGS. 3 (a) and 3 (b) are two schematic views of a reagent disk, respectively;

FIG. 4 is a schematic view of a reagent disk of an embodiment;

FIG. 5 is a schematic diagram of the structure of a reagent pack of an embodiment;

FIG. 6 is a schematic diagram of the structure of a reagent member according to one embodiment;

FIG. 7 is a schematic view of a reagent loading and unloading mechanism according to an embodiment;

FIG. 8 is a schematic view of a reagent loading and unloading mechanism according to an embodiment;

FIG. 9 is a schematic structural view of a reagent loading/unloading mechanism according to an embodiment;

FIG. 10 is a schematic structural view of a reagent loading/unloading mechanism according to an embodiment;

FIG. 11 is a schematic structural view of a reagent loading/unloading mechanism according to an embodiment;

FIG. 12 is a schematic diagram of the structure of a reagent pack of an embodiment;

FIG. 13 is a schematic diagram of the structure of a reagent member of one embodiment;

FIG. 14 is a schematic diagram of the structure of a reagent member of one embodiment;

FIG. 15 is a schematic diagram of the structure of a reagent pack of an embodiment;

FIG. 16 is a schematic view of a reagent disk interface according to one embodiment;

FIG. 17 is a schematic view of a reagent disk interface according to one embodiment;

FIG. 18 is a schematic view of a reagent loading/unloading interface according to an embodiment;

FIGS. 19 (a) and 19 (b) are schematic views of a reagent disk interface and a reagent loading/unloading interface, respectively;

FIG. 20 is a schematic view of a sample analyzer according to an embodiment;

FIG. 21 is a diagram illustrating a screen displayed by the display assembly having a first display area and a second display area, according to one embodiment;

fig. 22 is a flowchart of a reagent information display method of a sample analysis apparatus according to an embodiment.

Detailed Description

The present invention will be described in further detail with reference to the following detailed description and accompanying drawings. Wherein like elements in different embodiments have been given like element numbers associated therewith. In the following description, numerous details are set forth in order to provide a better understanding of the present application. However, one skilled in the art will readily recognize that some of the features may be omitted or replaced with other elements, materials, methods in different instances. In some instances, certain operations related to the present application have not been shown or described in detail in order to avoid obscuring the core of the present application from excessive description, and it is not necessary for those skilled in the art to describe these operations in detail, so that they may be fully understood from the description in the specification and the general knowledge in the art.

Furthermore, the features, operations, or characteristics described in the specification may be combined in any suitable manner to form various embodiments. Also, the various steps or actions in the method descriptions may be transposed or transposed in order, as will be apparent to one of ordinary skill in the art. Thus, the various sequences in the specification and drawings are for the purpose of describing certain embodiments only and are not intended to imply a required sequence unless otherwise indicated where such sequence must be followed.

The numbering of the components as such, e.g., "first", "second", etc., is used herein only to distinguish the objects as described, and does not have any sequential or technical meaning. The term "connected" and "coupled" as used herein includes both direct and indirect connections (couplings), unless otherwise specified.

In some embodiments of the present invention, a sample analysis device is provided. Referring to fig. 1, a sample analysis apparatus in some embodiments includes a sample part 100, a reagent part 200, a reagent dispensing part 300, a reaction part 400, a measurement part 500, a controller 600, and a display part 700; wherein: the sample part 100 is used for supplying a sample to be measured; the reagent component 200 comprises a reagent site for carrying reagent containers, the reagent component 200 for scheduling the carried reagent containers; the reagent dispensing unit 300 is used for dispensing a reagent in a reagent container, for example, sucking the reagent from the reagent unit 200 and dispensing the reagent into the reaction unit 400; the reaction unit 400 is adapted to receive a sample to be measured provided from the sample unit 100 and a reagent dispensed by the reagent dispensing unit 300 to prepare a sample; the measuring unit 500 measures a sample; the controller 600 controls the sample unit 100, the reagent unit 200, the reagent dispensing unit 300, the reaction unit 400, the measurement unit 500, and the display unit 700 displays contents, screens, and the like.

The reagent part 200 will be described in detail below.

As described above, the reagent unit 200 has a plurality of reagent sites for carrying reagent containers or reagents. In some embodiments, the reagent component 200 can provide cooling or other functions to the reagent carried, such as maintaining a temperature between 2 and 16 degrees Celsius, thereby ensuring the activity of the reagent. Specifically, the reagent component 200 is used to maintain its internal temperature within the range required by the instructions for use of the reagent. In order to ensure the cooling effect, the reagent part 200 may be a closed structure, for example, the reagent part 200 may be provided with a cover capable of being opened and closed to realize heat preservation. The reagent unit 200 may have a reagent presence detector for detecting whether or not a reagent container is loaded on the reagent site.

In some embodiments, the reagent member 200 may be a disk-like structure or a linear structure. For example, the reagent component 200 in some embodiments includes a reagent disk 210. Reagent dish 210 is the setting of discoid structure, can rotate and drive its reagent that bears and rotate. By the rotation of the reagent disk 210, the reagent can be transferred to the reagent aspirating position for the reagent dispensing unit 300 to aspirate. The reagent disk 210 may have a lid 211 that can be opened and closed, and when the lid 211 is opened, a user can put or take a reagent into or out of the reagent disk 210. For example, fig. 2 (a) and 2 (b) are schematic diagrams of the reagent disk 210 when the cover 211 is opened (the cover 211 is in an open state) and when the cover 211 is closed (the cover 211 is in a closed state).

In some specific examples, the reagent disk 210 may include at least one circle of reagent track 212 capable of rotating, the reagent track 212 includes a plurality of reagent sites 210a for carrying reagents, and the reagent track 212 rotates to move reagent containers on the reagent sites 210a thereof — for example, fig. 3 (a) and 3 (b) are two examples. In some embodiments, the reagent disk 210 includes multiple turns of reagent tracks 212, each reagent track 212 being capable of independent rotation. Fig. 3 (a) shows an example in which the reagent disk 210 has one turn of the reagent track 212, and fig. 3 (b) shows an example in which the reagent disk 210 has two turns of the reagent track 212 that can rotate independently. The reagent rail 212 can rotate and drive the reagent container carried by the reagent rail to transfer, so that the reagent container is rotated to a reagent sucking position, and the reagent dispensing component 300 sucks the reagent and dispenses the reagent to the reaction part 400. The reagent disk 210 is further described below with reference to the drawings.

Referring to fig. 3 (a), in some embodiments, the reagent tray 210 includes a circle of reagent tracks 212, and the reagent sites 210a can be used for placing reagent cups 215, a reagent container, the reagent cups 215 each include one or more cavities for containing reagents required by the project test, and a reagent is placed in one of the cavities; the reagent disk 210 includes a corresponding drive assembly for driving the reagent rail 212 to rotate, and the drive assembly drives the reagent rail 212 to rotate, so as to rotate the cavity of the reagent cup 91 containing the reagent required by the project to the corresponding reagent sucking position. In one example, each of the reagent cups 91 includes at least a first cavity 215a for carrying a first reagent and a second cavity 215b for carrying a second reagent, for example, the reagent cup 215 includes at least a first cavity 215a for carrying a mixed reagent (not referred to as R1) and a second cavity 215b for carrying a trigger reagent (not referred to as R2); the reagent disk 210 comprises a first reagent absorption position and a second reagent absorption position different from the first reagent absorption position, and the reagent track 212 is driven to rotate so as to drive the reagent cup 215 to rotate, so that the first cavity 215a of the reagent cup 215 is rotated to the first reagent absorption position; the reagent track 212 is driven to rotate the reagent cup 215, so as to rotate the second cavity 215b to the second reagent sucking position. It is understood that the first and second blotting sites are within the scope of the blotting sites herein.

Referring to FIG. 3 (b), in some embodiments, the reagent disk 210 includes two independently rotatable reagent tracks 212, such as the inner and outer reagent tracks 212 and 212 shown in the figure. An outer ring of reagent tracks 212, the reagent site 210a of which can be used to carry a first reagent container; the outer reagent track 212, reagent site 210a, may be used to carry a second reagent container. The reagent disk 210 includes a corresponding drive assembly for driving the rotation of the outer ring of reagent tracks 212, the drive assembly driving the outer ring of reagent tracks 212 to rotate and bring the first reagent container into rotation to rotate the first reagent container to the first reagent uptake position; the reagent disk 210 further includes a corresponding drive assembly for driving the rotation of the inner ring of reagent tracks 212, which drives the inner ring of reagent tracks 212 to rotate and to rotate the second reagent container to the second reagent aspirating position. It is to be understood that the first reagent container and the second reagent container herein are both within the scope of the reagent container herein.

In the above description, two structures of the reagent disk 210 are described, for example, fig. 2 (a) is an example of placing the reagent cup 215, fig. 2 (b) is an example of implementing the reagent disk 210 by a plurality of tracks capable of rotating independently, and it will be understood by those skilled in the art that the reagent disk 210 may also be implemented by a plurality of tracks capable of rotating independently, and at least one reagent site 210a on one track or each track may be used for placing the reagent cup 215, for example, fig. 4 is an example, and both the reagent site 210a on the inner track 212 and the reagent site 210a on the outer track 212 may be used for placing the reagent cup 215. By placing all the types of reagents required for one test item in the same reagent sipper 215, the management of the reagents can be facilitated. Of course, in other embodiments, the inner ring of the reagent track 212 may be used to place consumables such as syringe and diluent, and the outer ring of the reagent track 212 may be used to place the main reagents for testing, such as the mixed reagent and the trigger reagent mentioned above.

The reagent disk 210 is one, which can be separately provided outside the reaction part 400. In other embodiments, there may be more than one reagent disk 210, for example, there may be two reagent disks 210. In some examples where the reagent tray 210 has two, one reagent tray 210 may be used to exclusively carry the mixed reagent R1 and another reagent tray 210 may be used to exclusively carry the trigger reagent R2.

The above are some of the descriptions of the reagent disk 210. The reagent disk 210 may rotate and dispense the corresponding reagent required for the test item to the reagent pipetting module 300 to the corresponding reagent pipetting site by rotating during the operation cycle, for example, the first reagent is dispensed to the first reagent pipetting site, and the second reagent is dispensed to the second reagent pipetting site.

The reagent tray 210 needs to receive reagent to replenish reagent consumed during testing, and to unload reagent or discard, for example, an empty reagent container. In some examples, a user may add reagent to the reagent tray 210 through the cover 211 of the reagent tray 210 and remove reagent containers to be unloaded from the reagent tray 210.

To enable online real-time reagent loading, the reagent component 200 in other embodiments may include, in addition to the reagent disk 210, a reagent loading and unloading mechanism 250 and a transport mechanism 290; in these embodiments, the reagent disk 210 may retain its cover 211 or may be constructed such that its cover 211 is removed.

Referring to fig. 5 and 6, fig. 5 is a perspective view of the reagent disk 210, the reagent loading/unloading mechanism 250, and the transport mechanism 290 with a partial housing removed, and fig. 6 is a plan view of the reagent disk 210, the reagent loading/unloading mechanism 250, and the transport mechanism 290 with a partial housing removed. The reagent unloading and loading mechanism 250 may interact with the reagent disk 210, for example, for real-time reagent loading, and/or real-time reagent unloading (including unloading of reagent containers that still have reagent remaining, unloading of empty reagent containers, etc.); for example, in some embodiments, the reagent loading and unloading mechanism 250 is used to store reagent containers to be loaded, or to store or discard unloaded reagent containers. The transport mechanism 290 transports the reagent pack between the reagent disk 210 and the reagent loading/unloading mechanism 250; for example, in some embodiments, the transport mechanism 290 is used to transport a reagent container to be loaded from the reagent load and unload mechanism 250 to the reagent tray 210, or to transport a reagent container to be unloaded from the reagent tray 210 to the reagent load and unload mechanism 250.

In some embodiments, in order to interact with the reagent loading and unloading mechanism 250, the reagent disk 210 further includes a reagent container access 231 and a power door 233 provided in the reagent container access 231 in an openable and closable manner; when the power door 233 is in the open state, the transport mechanism 290 can be allowed to transport the reagent container from the reagent loading and unloading mechanism 250 to the reagent disk 210 through the reagent container entrance 231, or the transport mechanism 290 can transport the reagent container from the reagent disk 210 to the reagent loading and unloading mechanism 250 through the reagent container entrance 231; at other times, the power door 233 may remain closed, thereby ensuring that the reagent disk 210 has less heat loss and ensures its cooling effect. That is, the power door 233 is opened when a reagent vessel is taken in or put out from the reagent disk 210, and is closed at other times. Other structures and examples of the reagent disk 210 are described in detail above and will not be described further herein.

In some embodiments, the reagent un-loading mechanism 250 is used to store reagent containers to be loaded and/or to receive unloaded reagent containers for subsequent storage or disposal. In some embodiments, the reagent unloading mechanism 250 is provided with a plurality of reagent stations including a storage location for storing reagent containers to be loaded or unloaded and a discard location for discarding reagent containers to be discarded, such as empty reagent containers unloaded from the reagent tray 210. There are various implementations of the reagent loading and unloading mechanism 250, which are described in detail below.

Referring to fig. 7, in some embodiments, the reagent loading/unloading mechanism 250 includes a base 251 and a storage portion 260. The storage unit 260 is used for storing or receiving a reagent container. In some embodiments, the storage portion 260 may be fixedly disposed on the base 251, that is, the storage portion 260 is fixed, for example, fig. 7 is an example. In other embodiments, the storage unit 260 may be movably disposed on the base 251, for example, the reagent loading/unloading mechanism 250 further includes a driving unit 252, and the driving unit 252 is configured to drive the storage unit 260 to move, for example, rotate or linearly move, relative to the base 251 — for example, fig. 8 is an example in which the storage unit 260 can rotate relative to the base 251, and fig. 10 is an example in which the storage unit 260 can linearly move relative to the base 251.

The storage unit 260 may be movable relative to the base 251 or may be stationary. The shape of the storage portion 260 may be a disk-shaped structure or a rectangular shape.

For example, in some embodiments, the storage portion 260 is a disk-shaped structure. Fig. 7 and 8 both show examples in which the storage portion 260 has a disk-shaped structure. The disk-shaped surface of the storage part 260 is provided with the above-mentioned plurality of reagent stations, which, as mentioned above, comprise a storage location 262 for storing reagent containers to be loaded or unloaded and a disposal location 263 for receiving reagent containers to be disposed of, which are unloaded from the reagent disk 210. The number of storage bits 262 is one or more, preferably the number of storage bits 262 is plural; similarly, the number of the discarding bits 263 is one or more, preferably, the number of the discarding bits 263 is one — for example, ten are stored bits 262 in fig. 7 and 8, and the discarding bits 263 is an example. In some embodiments, each reagent site of the reservoir 260 is annularly disposed about the disk-shaped center of the reservoir 260. In the case where the storage unit 260 is movable (e.g., rotatable) relative to the base 251, when the storage unit 260 is rotated, each reagent site on the storage unit is also rotated.

As another example, in some embodiments, the storage portion 260 is rectangular-such as is the case with FIGS. 9 and 10. The rectangular surface of the storage section 260 is provided with a plurality of reagent stations as mentioned above, which similarly include a storage bit 262 for storing reagent containers to be loaded or unloaded and a discard bit 263 for receiving reagent containers to be discarded unloaded from the reagent disk 210. The number of storage bits 262 is one or more, preferably the number of storage bits 262 is plural; similarly, the number of discarded bits 263 is one or more, preferably, the number of discarded bits 263 is one — for example, in fig. 9 and 10, the stored bits 262 are seven, and the discarded bits 263 is an example. In some embodiments, the reagent sites of the storage portion are arranged in a row.

The user can place a reagent container to be loaded into the storage location 262 of the storage section 260 and can also take out an unloaded reagent container from the storage location 262, while a reagent container to be discarded, e.g., an empty reagent container depleted of reagent, is transported from the reagent disk 210 to the discard location 263 of the storage section 260 to effect the discard process of the reagent container. In some embodiments, referring to FIG. 11, the discard bit 263 may be connected to the waste bin 265 via a passageway 264, and reagent containers received by the discard bit 263 are discarded to the waste bin 265 via the passageway 264. The waste bin 265 may receive information such as expired reagent containers, empty reagent containers, etc. In the instance where the storage portion 260 is movable relative to the base 251, the channel 264 is capable of moving with the disposal location 263 as the storage portion 260 is moved, e.g., in embodiments where the storage portion 260 is rotatable relative to the base 251, the channel 264 is configured to rotate with the disposal location 263; in embodiments where the storage portion 260 moves linearly relative to the base 251, the channel 264 is configured to move linearly with the disposal site 263. In embodiments where the channel 264 is movable with the disposal site 263, this facilitates placement and functional multiplexing of the waste bin 265 within the sample analysis device, e.g., the waste bin 265 may be used to receive discarded reagent containers and may also be used to receive used reaction cups.

In some embodiments, the reagent loading and unloading mechanism 250 further comprises a lid (not shown) for allowing a user to access the reagent or reagent container, for example, when the lid of the reagent loading and unloading mechanism 250 is opened, the user can remove the reagent from the reagent loading and unloading mechanism 250 or insert the reagent into the reagent loading and unloading mechanism 250.

The reagent loading/unloading mechanism 250 is described above, and the transport mechanism 290 will be described below.

The transport mechanism 290 transports the reagent container between the reagent disk 210 and the reagent loading/unloading mechanism 250. For example, the transport mechanism 290 is used to transport reagent containers to be loaded from the storage locations of the reagent load and unload mechanism 250 to the reagent disk 210 and/or to transport reagent containers to be unloaded from the reagent disk 210 to the storage locations of the reagent load and unload mechanism 250. There are a variety of implementations of transport mechanism 290.

Referring to fig. 12 and 13, for example, in some embodiments, the transport mechanism 450 includes a two-dimensional movement mechanism 251 and a reagent container gripping portion 259; the two-dimensional moving mechanism 251 is capable of driving the reagent container gripping section 259 to perform one-dimensional movement (e.g., up and down directions of the paper plane in fig. 12) between the reagent disk 210 and the storage section 260, and driving the reagent container gripping section 259 to perform up and down movements (e.g., a direction perpendicular to the paper plane in fig. 12); the reagent container gripping section 259 is used to grip and drop a reagent container. In an example in which the transport mechanism 250 is capable of one-dimensional movement in the planar direction and vertical direction, the reagent loading/unloading mechanism 250 may be configured such that the storage unit 260 is capable of moving relative to the base 251.

For another example, referring to fig. 14, the transport mechanism 450 includes a three-dimensional moving mechanism 253 and a reagent container gripping section 259; the three-dimensional movement mechanism 253 can drive the reagent container gripping section 259 to move in three-dimensional directions; the reagent container catching unit 259 is used to catch and drop reagent containers. In an example in which the transport mechanism 250 is capable of three-dimensional movement, the reagent loading/unloading mechanism 250 may be configured such that the storage unit 260 is stationary.

The above description is of the reagent disk 210, the reagent loading and unloading mechanism 250, and the transport mechanism 290. The reagent disk 210, the reagent loading/unloading mechanism 250, and the transport mechanism 290 according to the present invention cooperate with each other, so that a test flow can be performed without interrupting the test flow when reagent is loaded or unloaded. For example, a user places a reagent container to be loaded on the storage location 262 on the storage portion 260, and the transport mechanism 290 transports the reagent container to be loaded from the storage location 262 on the storage portion 260 to the reagent tray 210 at an appropriate time, so that real-time reagent loading is realized without interrupting a test flow; likewise, the transport mechanism 290 transports the reagent containers to be unloaded from the reagent disk 210 to the storage location 462 on the storage section 460 at an appropriate timing for the user to take out, which does not affect and interrupt the normal test flow of the reagent disk 210; likewise, the transport mechanism 290 transports the reagent pack to be discarded from the reagent disk 210 to the discard position 263 on the storage portion 260 at an appropriate timing for the discarding process, which does not affect and interrupt the normal test flow of the reagent disk 210.

In some embodiments, the sample analysis device further includes a scanning portion 270, such as is illustrated in FIG. 15. The reagent container may be provided with a label, and the scanner 270 reads label information of the reagent container by sensing the label. The label of the reagent container stores the reagent information of the corresponding reagent, and the reagent information or the label information at least comprises the reagent type, the reagent allowance and the like, and also comprises the information of the type of the reagent container, the production date, the quality guarantee period, the batch number, the serial number, the bottle opening date, a plurality of calibration curves and the like. Therefore, in some embodiments, the scanner 270 is configured to read reagent information of the reagent container by sensing label information of the reagent container in the reagent loading/unloading mechanism 260. In some embodiments, the scanner 270 is also used to write information into the label of the reagent container. The scanning section 270 may be an RFID reader, and the label of the reagent container may be an RFID label. The scanner 270 assists in completing the information management function of the reagent.

The above are some of the descriptions of the sample analyzing apparatus.

To facilitate understanding and replacement of reagents, etc., in some embodiments, the display assembly 700 is used to display a reagent interface; wherein the reagent interface displays a pictogram of reagent component 200; in some embodiments, the reagent interface also displays and updates reagent information, such as reagent balance information, e.g., reagent location information, etc., of the reagent component 200.

In some embodiments, when the reagent component 200 receives a motion signal triggered by a user to move, the pictogram of the reagent component 200 follows the corresponding motion of the reagent component 200.

In some embodiments, when the pictogram of the reagent component 200 receives a motion signal triggered by the user to move, the reagent component 200 follows its pictogram to move accordingly.

In some embodiments, the reagent interface may be a reagent disk interface, the pictogram of the reagent component 200 is a pictogram of the reagent disk 210, and the reagent information of the reagent component 200 is reagent information of the reagent disk 210, so that the reagent disk interface displays the pictogram of the reagent disk 210 and the reagent disk interface also displays and updates the reagent information of the reagent disk 210, as shown in fig. 16, for example. In some embodiments, when the reagent disk 210 receives a movement signal rotation triggered by a user, the pictogram of the reagent disk 210 rotates following the reagent disk 210. In some embodiments, when the pictogram of the reagent disk 210 receives a movement signal rotation triggered by a user, the reagent disk 210 rotates following its pictogram.

In the embodiment where the reagent disk 210 has the openable and closable cover 211, when the cover 211 is changed from the closed state to the open state, the display part 700 is switched to display the reagent disk interface, which is very convenient for the user to use, and saves the step and time for the user to manually switch to the reagent disk interface.

In the embodiment where the reagent disk 210 has the openable and closable cover 211, when the cover 211 is opened, the reagent disk 210 forms an operation area for a user to operate, the display part 700 correspondingly displays the operation area and the reagent level in the operation area on the pictogram of the reagent disk 210, and the operation area on the pictogram of the reagent disk 210 is displayed in a manner different from other areas on the pictogram, for example, fig. 16 is a schematic diagram of the operation area formed after the cover 211 is opened, the operation area is displayed in white, and the other areas are displayed in gray.

In embodiments where the reagent disk 210 has a lid 211 that can be opened and closed, when the lid 211 is opened, the reagent disk 210 forms an operating area for a user to operate, the number of reagent sites in the operating area is N, for example 4, and the reagent disk 210 may have a key assembly-physical or virtual-that is configured to signal movement when triggered by the user to cause the reagent disk to rotate N reagent sites.

In some embodiments, the display unit 700 displays the reagent information of the reagent disk 210 in an array in the reagent disk interface, the reagent information of the reagent disk 210 including the reagent remaining amount information of each test item, the array including a plurality of mutually independent array elements, each array element being a display area for displaying the reagent remaining amount information of one test item, for example, fig. 17 is an example.

In some specific embodiments, the reagent interface may be a reagent loading/unloading interface, the pictogram of the reagent component 200 is a pictogram of the reagent loading/unloading mechanism 250, and the reagent information of the reagent component 200 is reagent information of the reagent loading/unloading mechanism 250, so that the reagent loading/unloading interface displays the pictogram of the reagent loading/unloading mechanism 250, and the reagent loading/unloading interface also displays and updates the reagent information of the reagent loading/unloading mechanism 250, as shown in fig. 18, for example. In some embodiments, upon movement of the reagent loading and unloading mechanism 250, for example upon receiving a user-triggered movement signal, the pictogram of the reagent loading and unloading mechanism 250 can follow the corresponding movement of the reagent loading and unloading mechanism. In some embodiments, upon movement of the pictogram of the reagent loading and unloading mechanism 250, such as upon receiving a movement signal triggered by a user, the reagent loading and unloading mechanism 250 is able to follow the pictogram of the reagent loading and unloading mechanism 250.

In the embodiment where the reagent loading and unloading mechanism 250 has an openable and closable lid, when the lid is changed from the closed state to the open state, the display unit 700 switches to display the reagent loading and unloading interface, which is very convenient for the user to use, and saves the step and time for the user to manually switch to the reagent loading and unloading interface.

In the embodiment where the reagent loading and unloading mechanism 250 has a lid that can be opened and closed, when the lid is opened, the reagent loading and unloading mechanism 250 forms an operation area for a user to operate, the display unit 700 displays the operation area and the reagent level in the operation area on the pictogram of the reagent loading and unloading mechanism 250, and the operation area on the pictogram of the reagent loading and unloading mechanism 250 is displayed differently from other areas on the pictogram, for example, fig. 18 is a schematic diagram of the operation area formed after the lid is opened, and the operation area is displayed in white and the other areas are displayed in gray.

In embodiments where the reagent loading and unloading mechanism 250 has a lid that can be opened and closed, the reagent loading and unloading mechanism 250 forms an operating area for operation by a user when the lid is opened, and the reagent sites in the operating area are N, e.g., 4, reagent sites, e.g., numbered 01, 02, 03, and 04 in the figures, and the reagent loading and unloading mechanism 250 may have a key assembly, physical or virtual, that is configured to signal movement when triggered by a user to cause the reagent loading and unloading mechanism 250 to rotate N reagent sites.

In some embodiments, the reagent loading and unloading interface associates the reagent sites on the reagent loading and unloading mechanism 250 with the displayed reagent information of the reagent loading and unloading mechanism 250 through a pictogram of the reagent loading and unloading mechanism 250, wherein the display unit 700 displays the reagent information of the reagent loading and unloading mechanism 250 in an array, the array includes the same number of array elements as the reagent sites of the reagent loading and unloading mechanism 250, each array element is independent of each other and corresponds to one reagent site of the reagent loading and unloading mechanism 250; each array element is a display area and is used for displaying the reagent information of the corresponding reagent position; the reagent information includes at least reagent remaining amount information, reagent position information, and the like.

In some embodiments with a reagent load/unload interface, a reagent disk interface may also be present, which displays and updates reagent information for the reagent disk 210. Further, the reagent disk interface also displays a pictogram of the reagent disk 210, and associates the reagent site on the reagent disk 210 with the displayed reagent information of the reagent disk 210 through the pictogram of the reagent disk 210.

In embodiments where the sample analysis device includes a reagent disk 210 and a reagent load mechanism 250, the sample analysis device may have a reagent disk interface and a reagent load interface; in some embodiments, the reagent disk interface is used to display and update reagent information of the reagent disk 210, and the reagent loading and unloading interface is used to display and update reagent information of the reagent loading and unloading mechanism 250; the reagent disk interface and the reagent loading/unloading interface may be generated by the controller 600, and the reagent information of the reagent disk 210 and the reagent information of the reagent loading/unloading mechanism 250 may be acquired by the controller 600.

In some embodiments, controller 600 controls display component 700 to switch to displaying the reagent loading and unloading interface when the first interface switching condition is satisfied. In some embodiments, the first interface switch condition comprises any one or more of:

(1) The reagent loading/unloading mechanism 250 has a lid that can be opened and closed; when the cover is changed from the closed state to the open state, the controller 600 controls the display part 700 to switch to the display reagent loading and unloading interface;

(2) When it is determined that the reagent sites of the reagent loading and unloading mechanism 250 all carry reagent containers to be unloaded (i.e., reagent containers unloaded from the reagent disk 210) according to the acquired reagent information of the reagent loading and unloading mechanism 250, the controller 600 controls the display unit 700 to switch to display a reagent loading and unloading interface;

(3) When it is determined that the remaining amount of the reagent for the test item is insufficient, the controller 600 controls the display unit 700 to switch to the display reagent loading/unloading interface.

In some embodiments, when the second interface switching condition is satisfied, the controller 600 controls the display part 700 to switch to display the reagent disk interface. In some embodiments, the second interface switching condition comprises any one or more of:

(1) The reagent loading/unloading mechanism 250 has an openable/closable lid, and when the lid is changed from an open state to a closed state, the controller 600 controls the display unit 700 to switch to display the reagent disk interface;

(2) The reagent loading/unloading mechanism 250 has an openable/closable lid and a scanning unit 270 for scanning the reagent container, and when the lid is changed from an open state to a closed state and the scanning unit 270 has successfully scanned, the controller 600 controls the display unit 700 to switch to display the reagent disk interface.

In some embodiments, the switching may be between a reagent disk interface and a reagent loading/unloading interface. In some embodiments, the controller 600 controls the display unit 700 to switch between the reagent loading/unloading interface and the reagent disk interface according to a preset interface switching condition. In some embodiments, the interface switching condition comprises any one or more of:

(1) The reagent loading/unloading mechanism 250 has an openable/closable lid, and when the lid is changed from a closed state to an open state, the controller 600 controls the display member 700 to switch from the reagent disk interface to the reagent loading/unloading interface;

(2) The reagent loading/unloading mechanism 250 has an openable/closable lid, and when the lid is changed from an open state to a closed state, the controller 600 controls the display member 700 to switch from the reagent loading/unloading interface to the reagent disk interface;

(3) The reagent loading/unloading mechanism 250 has an openable/closable lid and a scanning unit 270 for scanning the reagent container, and when the lid is changed from a closed state to an open state, the controller 600 controls the display member 700 to switch from the reagent disk interface to the reagent loading/unloading interface;

(4) The reagent loading and unloading mechanism 250 has an openable and closable lid and a scanning unit 270 for scanning the reagent container, and when the lid is changed from an open state to a closed state and the scanning unit 270 scans successfully, the controller 600 controls the display member 700 to switch from the reagent loading and unloading interface to the reagent disk interface;

(5) When it is determined that all the reagent sites of the reagent loading and unloading mechanism 250 carry the reagent containers to be unloaded (i.e., the reagent containers unloaded from the reagent disk 210) according to the acquired reagent information of the reagent loading and unloading mechanism 250, the controller 600 controls the display part 700 to switch from the reagent disk interface to the reagent loading and unloading interface;

(6) When it is determined that the remaining amount of the reagent for the test item is insufficient, the controller 600 controls the display unit 700 to switch from the reagent disk interface to the reagent loading/unloading interface.

As described above, in embodiments where the sample analysis device includes a reagent disk 210 and a reagent loading and unloading mechanism 250, the sample analysis device may have a reagent disk interface and a reagent loading and unloading interface; in some embodiments, the reagent disk interface is used to display and update reagent information of the reagent disk 210, and the reagent loading and unloading interface is used to display and update reagent information of the reagent loading and unloading mechanism 250; the reagent disk interface and the reagent loading/unloading interface may be generated by the controller 600, and the reagent information of the reagent disk 210 and the reagent information of the reagent loading/unloading mechanism 250 may be acquired by the controller 600.

In some embodiments, the controller 600 is configured to control the display unit 700 to display a reagent disk interface and/or a reagent loading/unloading interface, wherein the reagent disk interface and the reagent loading/unloading interface are not displayed in the same display screen at the same time.

In some embodiments, the reagent disk interface has a reagent disk label control a, the reagent off-load interface has a reagent off-load label control b; in response to clicking the reagent disk label control a, the controller 600 controls the display unit 700 to switch to display the reagent disk interface, for example, fig. 19 (a) is an example, and a label named "reagent disk" in the figure is the reagent disk label control a; in response to clicking on the reagent unloading label control b, the controller 600 controls the display unit 700 to switch to display a reagent unloading interface, for example, fig. 19 (b) is an example, and a label named "loading tray" is the reagent unloading label control b.

In some embodiments, referring to fig. 20, the display unit 700 includes a first sub-display 710 and a second sub-display 720; the first sub-display screen 710 is used for displaying a reagent tray interface, and the second sub-display screen 720 is used for displaying a reagent loading and unloading interface.

In some embodiments, the controller 600 obtains reagent information including at least total reagent balance information; the controller 600 controls the display unit 700 to always display the total remaining reagent amount information on the reagent loading/unloading interface and/or the reagent disk interface. A more complete and detailed description is provided below.

In some embodiments, the controller 600 is configured to obtain reagent information of the reagent disk 210 and reagent information of the reagent loading and unloading mechanism 250, and calculate total consumable remaining amount information, where the total consumable remaining amount information includes a sum of remaining amount information of consumables of the same type, for example, the total consumable remaining amount information at least includes the total reagent remaining amount information; the controller 600 is further configured to generate a reagent disk interface and a reagent loading/unloading interface, wherein the reagent disk interface is configured to display and update the reagent information of the reagent disk 210, and the reagent loading/unloading interface is configured to display and update the reagent information of the reagent loading/unloading mechanism 250; the controller 600 is further configured to control the display unit 700 to display a reagent disk interface and/or a reagent loading/unloading interface; when the display part 700 displays the interface of the reagent disk, the total consumable balance information is also displayed at the same time, and the total consumable balance information is positioned in the interface of the reagent disk or outside the interface of the reagent disk; when the display part 700 displays the reagent loading and unloading interface, the total consumable balance information is also displayed at the same time, and the total consumable balance information is located in the reagent loading and unloading interface or outside the reagent loading and unloading interface.

Referring to fig. 21, in some embodiments, the display part 700 has a first display area c and a second display area d on the same screen, where the first display area c is used for displaying one of the reagent disk interface and the reagent loading/unloading interface, and the second display area d is used for displaying the total consumable remaining amount information. The first display area c is used for selecting one of the reagent disk interface and the reagent loading/unloading interface for display, and may be selected by the reagent disk label control a and the reagent loading/unloading label control b, for example, fig. 19 (a) and 19 (b) are the examples, or may be intelligently switched by the first interface switching condition, the second interface switching condition, the interface switching condition, or the like, which is not described herein again. In other embodiments, the reagent disk interface includes a first sub-display area and a second sub-display area, the first sub-display area is used for displaying reagent information of the reagent disk, and the second sub-display area is used for displaying the total consumable remaining amount information; similarly, the reagent loading/unloading interface includes a third sub-display area for displaying reagent information of the reagent loading/unloading mechanism and a fourth sub-display area for displaying the total remaining consumable material amount information. In an embodiment where the display part 700 includes the first sub-display 710 and the second sub-display 720, the first sub-display 710 is used to display a reagent disk interface, and when the first sub-display 710 displays the reagent disk interface, the total consumable balance information is also displayed at the same time; the second sub-display screen 720 is used for displaying the reagent loading and unloading interface, and when the second sub-display screen 720 displays the reagent loading and unloading interface, the total material consumption allowance information is also displayed at the same time.

Referring to fig. 22, some embodiments further provide a reagent information display method of a sample analyzer, where the sample analyzer may be the sample analyzer according to any of the embodiments of the present application, and the reagent information display method includes the following steps:

step S100: a reagent loading and unloading interface and a reagent disk interface are provided.

Step S110: reagent information of the reagent disk and the reagent loading and unloading mechanism is acquired.

Step S120: and displaying a reagent loading and unloading interface and/or a reagent disk interface, wherein the reagent loading and unloading interface displays a pictogram of the reagent loading and unloading mechanism and reagent information of the reagent loading and unloading mechanism, and the reagent disk interface displays the reagent information of the reagent disk.

Step S130: when the reagent loading and unloading mechanism receives a motion signal triggered by a user to move, the pictogram of the reagent loading and unloading mechanism correspondingly moves along with the reagent loading and unloading mechanism.

Step S140: when the reagent of the reagent loading and unloading mechanism changes, the reagent information of the reagent loading and unloading mechanism displayed on the reagent loading and unloading interface is updated.

Step S150: and updating the reagent information of the reagent disk displayed on the reagent disk interface when the reagent of the reagent disk changes.

Reference is made herein to various exemplary embodiments. However, those skilled in the art will recognize that changes and modifications may be made to the exemplary embodiments without departing from the scope hereof. For example, the various operational steps, as well as the components used to perform the operational steps, may be implemented in differing ways depending upon the particular application or consideration of any number of cost functions associated with operation of the system (e.g., one or more steps may be deleted, modified or incorporated into other steps).

While the principles herein have been illustrated in various embodiments, many modifications of structure, arrangement, proportions, elements, materials, and components particularly adapted to specific environments and operative requirements may be employed without departing from the principles and scope of the present disclosure. The above modifications and other changes or modifications are intended to be included within the scope of this document.

The foregoing detailed description has been described with reference to various embodiments. However, one of ordinary skill in the art would recognize that various modifications and changes can be made without departing from the scope of the present disclosure. Accordingly, the disclosure is to be considered in an illustrative and not a restrictive sense, and all such modifications are intended to be included within the scope thereof. Also, advantages, other advantages, and solutions to problems have been described above with regard to various embodiments. However, the benefits, advantages, solutions to problems, and any element(s) that may cause any element(s) to occur or become more pronounced are not to be construed as a critical, required, or essential feature or element of any or all the claims. As used herein, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, system, article, or apparatus. Furthermore, the term "coupled," and any other variation thereof, as used herein, refers to a physical connection, an electrical connection, a magnetic connection, an optical connection, a communicative connection, a functional connection, and/or any other connection.

Those skilled in the art will recognize that many changes may be made to the details of the above-described embodiments without departing from the underlying principles of the invention. The scope of the invention should, therefore, be determined only by the following claims.

Claims (10)

1. A sample analysis device, comprising:

a sample part for supplying a sample to be measured;

the reagent component comprises a reagent disk, a reagent loading and unloading mechanism and a conveying mechanism; the reagent tray comprises a plurality of reagent sites for carrying reagent containers, the reagent tray being for scheduling the carried reagent containers; the reagent loading and unloading mechanism comprises a plurality of reagent positions for bearing reagent containers, and is used for scheduling the borne reagent containers; the transport mechanism is used for transporting the reagent container between the reagent disk and the reagent loading and unloading mechanism; the transport mechanism is used for transporting the reagent containers to be loaded from the reagent loading and unloading mechanism to the reagent tray and transporting the reagent containers to be unloaded from the reagent tray to the reagent loading and unloading mechanism;

a reagent dispensing unit configured to dispense a reagent in a reagent container carried by the reagent disk;

a reaction component for receiving a sample to be measured provided by the sample component and a reagent dispensed by the reagent dispensing component to prepare a sample;

a measuring unit for measuring the sample

A display section;

a controller for controlling the sample unit, the reagent dispensing unit, the reaction unit, the measurement unit, and the display unit;

wherein:

the controller is also used for acquiring reagent information of the reagent disk and reagent information of the reagent loading and unloading mechanism;

the controller is further used for generating a reagent disk interface and a reagent loading and unloading interface, wherein the reagent disk interface is used for displaying and updating the reagent information of the reagent disk, and the reagent loading and unloading interface is used for displaying and updating the reagent information of the reagent loading and unloading mechanism;

the controller is further configured to control the display unit to display the reagent disk interface and/or the reagent loading/unloading interface, where the reagent disk interface and the reagent loading/unloading interface are not displayed in the same display screen at the same time.

2. The sample analysis device of claim 1, wherein the reagent tray interface has a reagent tray label control, and the reagent loading interface has a reagent loading label control;

in response to clicking the reagent disk label control, the controller controls the display component to switch to displaying the reagent disk interface;

and responding to the click of the reagent loading and unloading label control, and controlling the display component to be switched to display the reagent loading and unloading interface by the controller.

3. The sample analysis device of claim 1, wherein the display component comprises a first sub-display and a second sub-display; the first sub-display screen is used for displaying the reagent tray interface, and the second sub-display screen is used for displaying the reagent loading and unloading interface.

4. The sample analyzer of any of claims 1-3, wherein the reagent loading/unloading interface further displays a pictogram of the reagent loading/unloading mechanism;

when the pictograph of the reagent loading and unloading mechanism moves, the reagent loading and unloading mechanism can move correspondingly along with the pictograph of the reagent loading and unloading mechanism; and/or when the reagent loading and unloading mechanism moves, the pictogram of the reagent loading and unloading mechanism can correspondingly move along with the reagent loading and unloading mechanism.

5. The sample analysis device according to claim 4, wherein when the reagent loading and unloading mechanism moves upon receiving a movement signal triggered by a user, the pictogram of the reagent loading and unloading mechanism follows the corresponding movement of the reagent loading and unloading mechanism.

6. The sample analysis device according to claim 4, wherein when the pictogram of the reagent loading and unloading mechanism receives a movement signal triggered by a user, the reagent loading and unloading mechanism follows the corresponding movement of the pictogram thereof.

7. The sample analysis device of claim 4, wherein the reagent loading and unloading mechanism has an openable and closable lid; when the cover is opened, the reagent loading and unloading mechanism forms an operation area for a user to operate, the display part correspondingly displays the operation area and the reagent position in the operation area on the pictogram of the reagent loading and unloading mechanism, and the operation area on the pictogram of the reagent loading and unloading mechanism is displayed in a mode different from other areas on the pictogram.

8. The sample analyzer of any of claims 1-3, wherein in the reagent loading/unloading interface, reagent sites on the reagent loading/unloading mechanism are associated with the displayed reagent information of the reagent loading/unloading mechanism by a pictogram of the reagent loading/unloading mechanism, wherein the display component displays the reagent information of the reagent loading/unloading mechanism in an array, the array including the same number of array elements as the number of reagent sites of the reagent loading/unloading mechanism, the array elements being independent of each other and each corresponding to one reagent site of the reagent loading/unloading mechanism; each array element is a display area and is used for displaying reagent information of a corresponding reagent position, and the reagent information at least comprises reagent allowance information and reagent position information; and/or the presence of a gas in the atmosphere,

the display part displays the reagent information of the reagent disk in an array in the reagent disk interface, the reagent information of the reagent disk comprises the reagent residual amount information of each test item, the array comprises a plurality of mutually independent array elements, and each array element is a display area and is used for displaying the reagent residual amount information of one test item.

9. The sample analyzer of any of claims 1 to 3, wherein the controller obtains total remaining reagent amount information, controls the display unit to display the total remaining reagent amount information in the reagent loading/unloading interface, and controls the display unit to display the total remaining reagent amount information in the reagent disk interface.

10. The sample analysis device according to claim 1 or 2, wherein the reagent loading and unloading mechanism has a lid that can be opened and closed; when the cover is changed from the closed state to the open state, the display component is switched to display the reagent loading and unloading interface, and when the cover is changed from the open state to the closed state, the display component is switched to display the reagent tray interface.

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