阅读说明：本技术 一种自动微流控样品处理设备及其控制方法 (Automatic microfluidic sample processing equipment and control method thereof ) 是由 颜菁 朱海龟 于 2019-08-19 设计创作，主要内容包括：本发明公开了一种自动微流控样品处理设备及其自动控制方法,其能够实现对微流控样品的自动处理。一种自动微流控样品处理设备,包括：机械臂,其具有用于装载芯片夹具的枪头；负压吸液装置,包括负压电机；升降装置,包括升降电机；平移装置,包括平移电机；及控制器；控制器,用于向平移电机发出运行控制信号,以使平移电机运行而将枪头移动至芯片夹具或试剂上方；控制器,还用于向升降电机发出运行控制信号,以使升降电机运行而将枪头下移而装载芯片夹具或插入试剂中,或将枪头上移而脱离试剂；控制器,还用于向负压电机发出运行控制信号,以使负压电机运行而向枪头的气流通道提供吸液的负压或排液的正压。(The invention discloses automatic microfluidic sample processing equipment and an automatic control method thereof, which can realize automatic processing of microfluidic samples. An automated microfluidic sample processing device comprising: a robot arm having a head for loading a chip gripper; the negative pressure liquid suction device comprises a negative pressure motor; the lifting device comprises a lifting motor; the translation device comprises a translation motor; and a controller; the controller is used for sending an operation control signal to the translation motor so as to enable the translation motor to operate and move the gun head to the position above the chip clamp or the reagent; the controller is also used for sending an operation control signal to the lifting motor so as to enable the lifting motor to operate to move the gun head downwards to load the chip clamp or insert the gun head into the reagent, or move the gun head upwards to separate from the reagent; and the controller is also used for sending an operation control signal to the negative pressure motor so as to enable the negative pressure motor to operate and provide liquid suction negative pressure or liquid discharge positive pressure for the airflow channel of the gun head.)

1. An automated microfluidic sample processing apparatus, comprising:

a tray device for accommodating reagents and chip holders with microfluidic chips mounted thereon;

the mechanical arm is provided with a gun head for loading the chip clamp, and an airflow channel for communicating an inner cavity of the chip clamp is formed in the gun head;

the negative pressure liquid suction device is used for providing air pressure for the airflow channel of the gun head and comprises a negative pressure motor;

the lifting device is used for driving the gun head to lift so as to load the chip clamp or enable the chip clamp to be inserted into or separated from the reagent, and the lifting device comprises a lifting motor;

the translation device is used for driving the gun head to move above the chip clamp or above the reagent, and comprises a translation motor; and

a controller;

the tray device is positioned below the mechanical arm, and the mechanical arm is arranged on the translation device and connected with the lifting device; the controller is used for sending an operation control signal to the translation motor so as to enable the translation motor to operate and move the gun head to the position above the chip clamp or the reagent; the controller is also used for sending an operation control signal to the lifting motor so as to enable the lifting motor to operate to move the gun head downwards to load the chip clamp or insert the gun head into a reagent, or move the gun head upwards to separate the gun head from the reagent; the controller is also used for sending an operation control signal to the negative pressure motor so as to enable the negative pressure motor to operate and provide liquid suction negative pressure or liquid discharge positive pressure for the airflow channel of the gun head.

2. The automated microfluidic sample processing device of claim 1, wherein: the translation motor comprises an x-direction motor for driving the gun head to move along the left-right direction and a y-direction motor for driving the gun head to move along the front-back direction.

3. The automated microfluidic sample processing device of claim 2, wherein: the controller is electrically connected with the negative pressure motor, the lifting motor, the x-direction motor and the y-direction motor respectively.

4. The automated microfluidic sample processing device of claim 3, wherein: the automatic microfluidic sample processing device further comprises a power supply for supplying power to the controller, the negative pressure motor, the lifting motor, the x-direction motor and the y-direction motor.

5. The automated microfluidic sample processing device of claim 1, wherein: the automatic microfluidic sample processing equipment further comprises a fault detection device, wherein the fault detection device comprises at least one detection unit, the detection unit comprises a pair of photoelectric detection switches arranged at intervals and a blocking piece moving along with the gun head, and the blocking piece is arranged between the pair of photoelectric detection switches; the controller is electrically connected with each photoelectric detection switch, and the controller is used for sending a stop control signal to the corresponding motor to stop the movement of the gun head after any one photoelectric detection switch is triggered.

6. The automated microfluidic sample processing device of claim 5, wherein: the fault detection device further comprises a fault indicator lamp, the controller is electrically connected with the fault indicator lamp, and the controller is further used for controlling the fault indicator lamp to switch the color of light after any one photoelectric detection switch is triggered;

and/or, the fault detection device still includes audible alarm device, the controller with audible alarm device electric connection, the controller still is used for at arbitrary one after the photoelectric detection switch is triggered audible alarm device sends out the warning sound.

7. A method of controlling an automated microfluidic sample processing device according to claim 1, comprising the steps of:

moving the gun head positioned above the chip clamp downwards to load the chip clamp on the gun head;

moving the gun head loaded with the chip clamp upwards and translating the gun head to the upper part of the reagent;

moving the gun head downwards to insert the chip clamp into the reagent;

providing negative pressure for the gun head, sucking the reagent into the chip clamp, and making the reagent flow through the microfluidic chip;

moving the gun head upwards to separate from the reagent, and translating the gun head to the upper part of the waste liquid collecting hole;

the gun head is moved downwards and inserted into the waste liquid collecting hole;

and providing positive pressure to the gun head, and discharging the sucked reagent into the waste liquid collecting hole.

8. The control method according to claim 7, characterized by further comprising the steps of:

translating the gun head loaded with the chip clamp to the position above the chip recovery hole; a baffle is arranged above the chip recovery hole, the baffle shields the part of the chip recovery hole, and in the step, the gun head is specifically translated to the part of the chip recovery hole which is not shielded by the baffle;

moving the gun head downwards to insert the chip clamp into the chip recovery hole;

translating the gun head to move the chip clamp to the part of the chip recovery hole, which is shielded by the baffle plate;

and moving the gun head upwards to move the gun head out of the chip recovery hole, wherein the chip clamp is blocked by the baffle and is left in the chip recovery hole.

9. The control method according to claim 8, wherein the chip recovery hole is a long hole or a kidney-shaped hole.

10. A method of controlling according to claim 7, wherein the step of translating the lance tip comprises moving the lance tip in a side-to-side direction and/or moving the lance tip in a fore-and-aft direction.

Technical Field

The invention belongs to the technical field of biological detection, and relates to automatic microfluidic sample processing equipment and a control method thereof.

Background

Microfluidic technology is an important method for sorting and analyzing cells or biomolecules, such as capturing Circulating Tumor Cells (CTCs), and has the advantages of simple operation and low amount of required antibodies. The microfluidic chip is a core component of the microfluidic technology, is provided with a micro-channel and is attached with a specific antibody, and is used for intercepting and capturing target cells or biomolecules of a sample flowing through the microfluidic chip. These captured cells or biomolecules often require a series of post-treatments for analysis, such as washing, primary or secondary antibody treatment, staining, and the like. At present, most of the treatments are carried out manually, the operation is complex and inconvenient, the efficiency is low, and the automation degree is low.

Disclosure of Invention

The invention aims to provide an automatic microfluidic sample processing device and an automatic control method thereof, which can realize automatic processing of microfluidic samples.

In order to achieve the purpose, the invention adopts a technical scheme that:

an automated microfluidic sample processing device comprising:

a tray device for accommodating reagents and chip holders with microfluidic chips mounted thereon;

the mechanical arm is provided with a gun head for loading the chip clamp, and an airflow channel for communicating an inner cavity of the chip clamp is formed in the gun head;

the negative pressure liquid suction device is used for providing air pressure for the airflow channel of the gun head and comprises a negative pressure motor;

the lifting device is used for driving the gun head to lift so as to load the chip clamp or enable the chip clamp to be inserted into or separated from the reagent, and the lifting device comprises a lifting motor;

the translation device is used for driving the gun head to move above the chip clamp or above the reagent, and comprises a translation motor; and

a controller;

the tray device is positioned below the mechanical arm, and the mechanical arm is arranged on the translation device and connected with the lifting device; the controller is used for sending an operation control signal to the translation motor so as to enable the translation motor to operate and move the gun head to the position above the chip clamp or the reagent; the controller is also used for sending an operation control signal to the lifting motor so as to enable the lifting motor to operate to move the gun head downwards to load the chip clamp or insert the gun head into a reagent, or move the gun head upwards to separate the gun head from the reagent; the controller is also used for sending an operation control signal to the negative pressure motor so as to enable the negative pressure motor to operate and provide liquid suction negative pressure or liquid discharge positive pressure for the airflow channel of the gun head.

Preferably, the translation motor comprises an x-direction motor for driving the lance head to move in the left-right direction and a y-direction motor for driving the lance head to move in the front-back direction.

More preferably, the controller is electrically connected to the negative pressure motor, the lifting motor, the x-direction motor, and the y-direction motor, respectively.

Further, the automatic microfluidic sample processing device further comprises a power supply for supplying power to the controller, the negative pressure motor, the lifting motor, the x-direction motor and the y-direction motor.

Preferably, the automatic microfluidic sample processing device further comprises a fault detection device, wherein the fault detection device comprises at least one detection unit, the detection unit comprises a pair of photoelectric detection switches arranged at intervals and a blocking piece moving along with the gun head, and the blocking piece is arranged between the pair of photoelectric detection switches; the controller is electrically connected with each photoelectric detection switch, and the controller is used for sending a stop control signal to the corresponding motor to stop the movement of the gun head after any one photoelectric detection switch is triggered.

More preferably, the fault detection device further comprises a fault indicator light, the controller is electrically connected with the fault indicator light, and the controller is further configured to control the fault indicator light to switch the light color after any one of the photoelectric detection switches is triggered;

and/or, the fault detection device still includes audible alarm device, the controller with audible alarm device electric connection, the controller still is used for at arbitrary one after the photoelectric detection switch is triggered audible alarm device sends out the warning sound.

Preferably, one or more reagent boxes arranged in parallel in the left-right direction are installed in the tray device, each reagent box comprises a box body, and a waste liquid collecting hole for inserting the chip clamp and storing waste liquid and one or more reagent holes for storing reagents are formed in the box body; the chip clamp comprises a body and a flow guide pipe for sucking and discharging liquid, wherein the body is provided with an inner cavity for mounting the microfluidic chip, and the flow guide pipe extends downwards from the body and is communicated with the inner cavity; the body is provided with a barrel part for inserting the gun head.

In one embodiment, the tray device is provided with one or more mounting grooves arranged side by side in the left-right direction, and each mounting groove is provided with one reagent kit.

More preferably, the tray device includes a bottom plate and an upper plate fixedly disposed on the bottom plate, the upper plate includes a left and right extending portion and a plurality of front and rear extending portions extending forward from the left and right extending portion, the plurality of front and rear extending portions are disposed in parallel and at intervals along a left and right direction, and the mounting groove with an open front side and an open upper side is formed between any two adjacent front and rear extending portions.

Furthermore, each front and back extension part is provided with a slot extending along the front and back direction, the slots on two adjacent front and back extension parts are arranged oppositely, and the left and right side edges of the reagent kit are inserted into the two corresponding slots.

More preferably, the box body is further provided with a chip recovery hole for recovering the chip clamp, the tray device further comprises a baffle, and a part of the chip recovery hole is located right below the baffle and is shielded by the baffle.

Further, the chip recovery hole is a long hole or a waist-shaped hole extending in the front-back direction.

In an embodiment, the mechanical arm further includes a housing and a lifting rod movably disposed through the housing in an up-down direction, the lifting rod is hollow, an upper end of the lifting rod is disposed at a joint for communicating the negative pressure liquid suction device, and the gun head is fixedly disposed at a lower end of the lifting rod.

Preferably, the lifting device includes a lifting rotary shaft assembly driven by the lifting motor to rotate, one or more turns of teeth are formed on an outer circumferential surface of the lifting rotary shaft assembly, the lifting rod has a rack portion extending in an up-down direction, and the rack portion and the teeth on the lifting rotary shaft assembly are engaged with each other.

More preferably, the lifting rotating shaft assembly includes a lifting rotating shaft driven by the lifting motor to rotate and one or more gears rotating with the lifting rotating shaft, the gears are provided with polygonal holes, and the lifting rotating shaft is inserted into the polygonal holes and can allow the gears to horizontally move relative to the lifting rotating shaft.

Further, the gear is fixedly arranged in the shell.

In one embodiment, the negative pressure liquid suction device comprises a piston driven by the negative pressure motor to reciprocate linearly and a piston shell provided with a gas cavity, and the piston is inserted in the gas cavity of the piston shell.

More preferably, the negative pressure imbibition device further comprises an air duct, one end of the air duct is fixedly connected to the piston shell and is communicated with the air cavity, and the other end of the air duct is fixedly connected to the mechanical arm.

In one embodiment, the translation device comprises an x-direction component for driving the mechanical arm to move along the left-right direction and a y-direction component for driving the mechanical arm to move along the front-back direction.

More preferably, the mechanical arm is arranged on the x-direction component, the x-direction component is arranged on the y-direction component, and the y-direction component is arranged on the frame.

Further, x includes mounting panel and the lead screw that extends along left right direction to the subassembly, the lead screw can set up in around self axial lead rotation on the mounting panel, x rotates to motor drive lead screw, the lead screw wear to locate in the arm and with the arm passes through threaded connection.

Furthermore, y to the subassembly including along the slide rail that the fore-and-aft direction extends and set up slidable in slider on the slide rail, the slide rail is fixed set up in the frame, x to the subassembly set up in on the slider, y passes through synchronous belt drive mechanism to the motor and drives the slider slip.

The invention adopts another technical scheme that:

a method of controlling an automated microfluidic sample processing device as described above, comprising the steps of:

moving the gun head positioned above the chip clamp downwards to load the chip clamp on the gun head;

moving the gun head loaded with the chip clamp upwards and translating the gun head to the upper part of the reagent;

moving the gun head downwards to insert the chip clamp into the reagent;

providing negative pressure for the gun head, sucking the reagent into the chip clamp, and making the reagent flow through the microfluidic chip;

moving the gun head upwards to separate from the reagent, and translating the gun head to the upper part of the waste liquid collecting hole;

the gun head is moved downwards and inserted into the waste liquid collecting hole;

and providing positive pressure to the gun head, and discharging the sucked reagent into the waste liquid collecting hole.

Preferably, the control method further includes the steps of:

translating the gun head loaded with the chip clamp to the position above the chip recovery hole; a baffle is arranged above the chip recovery hole, the baffle shields the part of the chip recovery hole, and in the step, the gun head is specifically translated to the part of the chip recovery hole which is not shielded by the baffle;

moving the gun head downwards to insert the chip clamp into the chip recovery hole;

translating the gun head to move the chip clamp to the part of the chip recovery hole, which is shielded by the baffle plate;

and moving the gun head upwards to move the gun head out of the chip recovery hole, wherein the chip clamp is blocked by the baffle and is left in the chip recovery hole.

More preferably, the chip recovery hole is a long hole or a kidney-shaped hole.

Preferably, the step of translating the lance tip comprises moving the lance tip in a side-to-side direction and/or moving the lance tip in a front-to-rear direction.

Compared with the prior art, the invention has the following advantages by adopting the scheme:

the automatic microfluidic sample processing equipment integrates the functions of cell or biomolecule capture, fixation, cleaning, antibody incubation, dyeing and the like, automatically realizes a series of processing on the microfluidic sample, reduces manual intervention, has high automation degree and improves processing efficiency.

Drawings

In order to more clearly illustrate the technical solution of the present invention, the drawings needed to be used in the description of the embodiments will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings based on the drawings without creative efforts.

Fig. 1 is a schematic perspective view of an automated microfluidic sample processing device according to an embodiment;

fig. 2a is a schematic diagram of the internal structure of an automated microfluidic sample processing device according to an embodiment, with part of the housing not shown;

FIG. 2b is an enlarged view of a portion of FIG. 2a at A;

fig. 2c is a control block diagram of an automated microfluidic sample processing device according to an embodiment;

fig. 3 is a top view of an automated microfluidic sample processing device according to an embodiment, with a portion of the housing not shown;

fig. 4 is a front view of a microfluidic sample processing device according to an embodiment, with a partial housing not shown;

FIGS. 5, 6, and 7 are perspective views of tray devices, respectively, with portions of the upper plate and the baffle of FIG. 7 not shown;

FIG. 8 is a schematic perspective view of a robotic arm;

FIG. 9 is a schematic view of a single robotic arm;

FIG. 10 is a schematic view of a single robotic arm, with the housing not shown;

FIG. 11 is a partial cross-sectional view of the robotic arm, lifting device and translation device;

FIG. 12 is a cross-sectional view of the negative pressure wicking apparatus.

In the above-described figures of the drawings,

1. a frame; 10. a housing; 101. a door; 11. a controller; 12. a power source; 13. a filter;

2. a kit; 20. a box body; 21. a waste liquid collection well; 22. a stationary liquid port; 23. a buffer liquid hole; 24. a first primary antibody pore; 25. a second primary antibody pore; 26. a second antibody hole; 27. a staining solution well; 28. a chip recovery hole;

3. a chip clamp; 30. a body; 31. a flow guide pipe; 32. a barrel portion;

4. a tray device; 40. mounting grooves; 41. a base plate; 42. an upper plate; 421. a left and right extension portion; 422. front and rear extensions; 423. a slot; 424. positioning the projection; 43. a baffle plate;

5. a mechanical arm; 50. a housing; 51. a gun head; 511. a first flange; 512. a second flange; 52. a lifting rod; 521 a rack portion; 53. a joint;

6. a negative pressure imbibition device; 61. a negative pressure motor; 611. pushing the plate; 62. a piston; 63. a piston housing; 631. a gas chamber; 64. A photoelectric detection switch; 65. a baffle plate;

7. a lifting device; 71. a lifting rotating shaft; 72. a gear; 721. a square hole; 73. a lifting motor;

8. a translation device; 81. mounting a plate; 811. a guide rail; 82. an x-direction motor; 83. a lead screw; 84. a y-direction motor; 85. a synchronous belt transmission mechanism; 86. a slide rail; 87. a slider;

9. a fault detection device; 91. a first photoelectric detection switch; 92. a first baffle plate; 93. a second photoelectric detection switch; 94. A second baffle plate; 95. a third photoelectric detection switch; 96. and a fault indicator lamp.

Detailed Description

Preferred embodiments of the present invention will be described in detail below with reference to the accompanying drawings so that the advantages and features of the invention may be more readily understood by those skilled in the art. It should be noted that the description of the embodiments is provided to help understanding of the present invention, but the present invention is not limited thereto.

Fig. 1 to 11 show an automated microfluidic sample processing device. Referring to fig. 1 to 11, the microfluidic sample processing apparatus mainly includes a tray device 4, a mechanical arm 5, a negative pressure liquid suction device 6, a lifting device 7, and a translation device 8, where the tray device 4, the mechanical arm 5, the negative pressure liquid suction device 6, and the translation device 8 are all disposed on a rack 1 of the microfluidic sample processing apparatus, a housing 10 is covered on the periphery of the rack 1, and all the devices are covered in the housing 10. Wherein, the tray device 4 is used for accommodating reagents and a chip clamp 3 provided with a microfluidic chip; the mechanical arm 5 is provided with a gun head 51 used for loading the chip clamp 3, and an airflow channel used for communicating the inner cavity of the chip clamp 3 is formed in the gun head 51; the negative pressure liquid suction device 6 is used for providing air pressure for an air flow channel of the gun head 51; the lifting device 7 is used for driving the gun head 51 to lift so as to load the chip clamp 3 or enable the chip clamp 3 to be inserted into or separated from a reagent; the translation device 8 is used for driving the gun head 51 to move above the chip clamp 3 or move above the reagent. The tray device 4 is positioned below the mechanical arm 5, and the mechanical arm 5 is arranged on the translation device 8 and connected with the lifting device 7. Specifically, one or more reagent kits 2 are installed on the tray device 4, chip clamps 3 are stored in the reagent kits 2, and the microfluidic chip is installed in the chip clamps 3 and fixed through the chip clamps 3. As shown in fig. 1, a door 101 is provided on the housing 10, the door 101 is slidably provided in the vertical direction, the door 101 is provided to face the tray unit 4, and when the door 101 is slid upward, the tray unit 4 is exposed, and the reagent cartridge 2 can be easily mounted or replaced.

In this embodiment, a plurality of reagent cartridges 2 arranged side by side in the left-right direction are mounted on the tray device 4 (as shown in fig. 3, four reagent cartridges 2 can be mounted on the tray device 4 at a time). Referring to fig. 5, the kit 21 includes a case 20, and the case 20 is provided with a waste liquid collecting hole 21 for inserting the chip holder 3 and storing waste liquid, one or more reagent holes for storing reagents, and a chip recycling hole 28 for recycling the chip holder 3. The reagent wells specifically include a fixative well 22 for holding fixative, a buffer well 23 for holding buffer, a primary antibody well for holding a primary antibody, a secondary antibody well 26 for holding a secondary antibody, and a staining solution well 27 for holding staining solution. Wherein, the primary antibody hole specifically comprises a first primary antibody hole 24 for storing a first primary antibody and a second primary antibody hole 25 for storing a second primary antibody. Waste liquid collecting hole 21 and chip recovery hole 28 are stepped holes having an upper aperture larger than a lower aperture, respectively, to fit the shape of chip holder 3, facilitating insertion of chip holder 3. The chip recovery holes 28 are long holes or waist-shaped holes, and the length direction of the chip recovery holes 28 is consistent with the length direction of the box body 20. In the reagent kit 21, the reagent and the chip holder 3 are used in the reagent kit 21 at one time; can process a plurality of steps such as liquid transferring, sorting, waste liquid and the like; internal operation and small pollution risk. Moreover, the reagent kit 21 is designed integrally, and reagents in reagent holes are stored separately without mixing, so that the reagent kit is suitable for different use concentrations in different steps and can be suitable for long-term storage. The reagent storage section and the reagent kit 21 are of an integral structure, so that the reagent is stored more stably and is more stable in operation. The waste liquid collecting hole 21 in the reagent kit 21 is not only the mounting position of the chip holder 3 but also the waste liquid disposal position, which saves the reagent kit 21 space and does not require an operator to prepare a container for collecting waste liquid.

The waste liquid collecting hole 21 and the chip recovery hole 28 are respectively located on the front end and the rear end of the box body 20, the fixing liquid hole 22, the buffer liquid hole 23 and the primary antibody hole are sequentially arranged between the waste liquid collecting hole 21 and the chip recovery hole 28, and the secondary antibody hole 26 and the dyeing liquid hole 27 are arranged between the primary antibody hole and the chip recovery hole 28 in a left-right parallel mode. That is, the waste liquid collecting well 21, the fixing liquid well 22, the buffer liquid well 23, the primary antibody well, the secondary antibody well 26, the staining liquid well 27, and the chip recovering well 28 are arranged in this order at intervals along the longitudinal direction (i.e., the front-rear direction) of the cartridge 20. In this embodiment, the waste liquid collecting hole 21 is used for storing samples (such as blood, urine, interstitial fluid, spinal fluid, and other body fluids), reagents, and the like discharged from the microfluidic chip; the stationary liquid hole 22 is filled with stationary liquid; PBS buffer is stored in the buffer hole 23; a primary antibody A is stored in the first primary antibody hole 24, and a primary antibody B is stored in the second primary antibody hole 25; the secondary antibody hole 26 stores secondary antibody; DAPI staining solution is stored in the staining solution well 27.

Referring to fig. 8, the chip holder 3 includes a body 30 and a flow guide tube 31 for sucking and discharging liquid, the microfluidic chip is mounted in the inner cavity of the body 30, and the flow guide tube 31 extends downward from the body 30 and communicates with the inner cavity. The body 30 has a cylindrical portion 32 formed at an upper portion thereof, into which a lower end portion of the robot arm 5 is inserted. The barrel portion 32 is hollow and in communication with the interior of the body 30. The body 30 of the chip clamp 3 can store a sample, the flow guide pipe 31 at the lower part can discharge waste liquid and absorb reagent, the waste liquid flowing through the microfluidic chip is guided and the reagent is absorbed to flow through the microfluidic chip for incubation or cleaning, and the like, so that the microfluidic chip can capture target cells or biomolecules in the sample conveniently and absorb or discharge the reagent conveniently.

The automatic microfluidic sample treatment device has a waste liquid collection state, a chip recovery state and a liquid transfer state. When the automatic microfluidic sample processing device is in a waste liquid collecting state, the chip holder 3 is inserted into the waste liquid collecting hole 21 of the reagent cartridge 21, the body 30 thereof is positioned at the upper part of the stepped hole, and the flow guide tube 31 is inserted into the lower part of the stepped hole, as shown in fig. 5 to 7 where the leftmost chip holder 3 is positioned. When the microfluidic sample processing device is in a chip recovery state, the chip holders 3 are inserted into the chip recovery holes 28 of the reagent kit 21, the body 30 thereof is positioned at the upper part of the stepped hole, and the flow guide tube 31 is inserted into the lower part of the stepped hole, as shown in fig. 5 to 7 where the middle two chip holders 3 are positioned. When the microfluidic sample processing device is in a pipetting state, the chip holder 3 is detached from the waste liquid collecting well 21, the chip holder 3 is positioned above one of the reagent wells, and the flow guide tube 31 is inserted into the reagent well.

Specifically, as shown in fig. 5 to 7, the tray device 4 is provided with a plurality of mounting grooves 40 arranged side by side in the left-right direction, and one reagent cartridge 2 is inserted into each mounting groove 40. In this embodiment, the tray device 4 includes a bottom plate 41 fixedly disposed on the frame 1 and an upper plate 42 fixedly disposed on the bottom plate 41, the upper plate 42 includes a left and right extending portion 421 and a plurality of front and rear extending portions 422 extending forward from the left and right extending portion 421, the plurality of front and rear extending portions 422 are disposed side by side and at intervals in the left and right direction, and the mounting groove 40 having an open front side and an open upper side is formed between any two adjacent front and rear extending portions 422, respectively. Each front and rear extension 422 is provided with a slot 423 extending in the front and rear direction, the slots 423 of two adjacent front and rear extensions 422 are arranged oppositely, and the left and right edges of the reagent kit 2 are inserted into the two corresponding slots 423. The upper plate 42 is formed by stacking an upper plate and a lower plate, and the insertion groove 423 is formed between the upper plate and the lower plate.

The upper plate 42 is provided with a positioning mechanism for positioning the reagent cartridge 2. In this embodiment, as shown in fig. 7, the positioning mechanism includes an upwardly extending positioning projection 424 formed on the upper plate 42, and the reagent cartridge is provided with a downwardly facing recess. When the reagent kit is installed in place, the positioning protrusions 424 are inserted into the concave portions of the reagent kit, and the reagent kit is fixed in the installation grooves 40 by matching with the insertion grooves 423 on the two sides, so that the reagent kit is prevented from shaking. When mounting, the left and right side edges of the reagent cartridge 2 are inserted into the insertion grooves 423 at both sides, and are pushed in from the front side of the mounting groove 40 until being caught on the positioning projections 424.

Further, the tray device 4 further includes a baffle 43, and a part of the chip recovery hole is located directly below the baffle 43. The baffle 43 is fixedly arranged on the bottom plate 41 or the rack 1, and the baffle 43 is positioned above the upper plate 42 and partially covers the chip recovery holes 28 of the reagent kit below, so as to prevent the chip clamps 3 from separating from the chip recovery holes 28. When the microfluidic sample processing device is in the waste liquid collecting state, the chip holder 3 is slidably inserted in the chip recovery hole 28 in the front-rear direction. When the microfluidic chip is recovered, the chip holder 3 is inserted downward into the chip recovery hole 28 from the front end of the chip recovery hole 28 (as shown in fig. 5 to 7 where the second chip holder 3 is located on the left side), and then moved along the chip recovery hole 28 to the rear end thereof (as shown in fig. 5 to 7 where the third chip holder 3 is located on the left side), and is confined in the chip recovery hole 28 by the stopper 43, thereby detaching the chip holder 3 from the robot arm 5.

In this embodiment, the number of the robot arms 5 is plural, and four robot arms are illustrated in fig. 8. The plurality of robot arms 5 are arranged side by side in the left-right direction and respectively correspond to the plurality of reagent cartridges 2 below one by one. As shown in fig. 8 to 11, each robot arm 5 includes a housing 50, a lifting rod 52 vertically movably inserted in the housing 50, a gun head 51 provided at a lower end of the lifting rod 52, and a joint 53 provided at an upper end of the lifting rod 52. The connector 53 is used for communicating with the connector 53 of the negative pressure liquid suction device 6, the lifting rod 52 is arranged in a hollow mode, and air pressure for sucking liquid or discharging liquid is provided for the gun head 51 through the negative pressure liquid suction device 6.

As shown in fig. 9, the lance tip 51 comprises a body 30, a first flange 511 and a second flange 512 extending outwardly from an outer surface of a lower portion of the body 30, the first flange 511 being located a distance above the second flange 512, and the first flange 511 having an outer diameter smaller than that of the second flange 512. The lower end of the lance head 51 is substantially gourd-shaped, and when the lance head is inserted into the barrel portion 32 of the chip holder 3, the connection is firm, and the chip holder 3 is prevented from falling from the lance head 51.

As shown in fig. 3, 4, 10 and 11, the lifting device 7 includes a lifting shaft assembly driven by a lifting power mechanism to rotate, one or more circles of teeth are formed on an outer circumferential surface of the lifting shaft assembly, the lifting rod 52 has a rack portion 521 extending in the up-down direction, and the rack portion 521 and the teeth on the lifting shaft assembly are engaged with each other. Specifically, the lifting power mechanism is a lifting motor 73, the lifting rotating shaft assembly includes a lifting rotating shaft 71 driven by the lifting motor 73 to rotate and one or more gears 72 rotating along with the lifting rotating shaft 71, a polygonal hole is formed in the gear 72, and the lifting rotating shaft 71 is inserted into the polygonal hole and can allow the gear 72 to horizontally move relative to the lifting rotating shaft 71. The gear 72 is fixedly disposed within the housing 50. The number of the gears 72 corresponds to the number of the mechanical arms 5, that is, one gear 72 is fixedly arranged in the housing 50 of each mechanical arm 5. As shown in fig. 11, the polygonal hole is specifically a square hole 721, the cross section of the lifting spindle 71 is square, the lifting spindle 71 extends in the left-right direction and sequentially passes through the square holes 721 of the gears 72 in the plurality of robot arms 5, and when the lifting spindle 71 rotates, the gears 72 are driven to rotate, and the lifting rod 52 is driven to move up and down under the coordination of the gear rack. Meanwhile, when the robot arm 5 is subjected to a force applied to the left or right by the translation device 8, the gear 72 can be allowed to slide on the lifting rotating shaft 71, so that the robot arm 5 can move in the left-right direction by the translation device 8.

Referring to fig. 3, 4 and 11, the translation device 8 includes an x-direction component for driving the robot arm 5 to move in the left-right direction and a y-direction component for driving the robot arm 5 to move in the front-back direction, wherein the robot arm 5 is disposed on the x-direction component, the x-direction component is disposed on the y-direction component, and the y-direction component is disposed on the frame 1. Specifically, the x-direction component includes a mounting plate 81 and a lead screw 83 extending in the left-right direction, the lead screw 83 is rotatably disposed on the mounting plate 81 around its axis, and the lead screw 83 is inserted into the mechanical arm 5 and is connected to the mechanical arm 5 through a thread. A guide rail 811 extending in the left-right direction is fixedly provided on the mounting plate 81, and each robot arm 5 is slidably provided on the guide rail 811 in the left-right direction, and specifically, the housing 50 of the robot arm 5 is connected to the guide rail 811 in a sliding fit. The x-direction assembly also includes an x-direction motor 82 for driving the lead screw 83 to rotate. The screw 83 is parallel to the lifting shaft 71, the screw 83 is located above the lifting shaft 71, the screw 83 passes through the upper portion of the robot arm 5, and the lifting shaft 71 passes through the lower portion of the robot arm 5. The y-direction component comprises a slide rail 86 extending along the front-back direction and a slide block 87 slidably arranged on the slide rail 86, the slide rail 86 is fixedly arranged on the rack 1, and the mounting plate 81 of the x-direction component is fixedly arranged on the slide block 87. The y-direction assembly further comprises a y-direction motor 84 and a synchronous belt transmission mechanism 85 driven by the y-direction motor 84, and the synchronous belt transmission mechanism 85 is connected with the sliding block 87.

Referring to fig. 2b and 12, the vacuum liquid suction device 6 includes a piston 62 driven by a vacuum motor 61 to reciprocate in a straight line, and a piston housing 63 provided with a gas chamber 631, wherein the piston housing 63 is fixedly disposed on a mounting plate 81, and the piston 62 is movably inserted into the gas chamber 631 of the piston housing 63. The vacuum imbibing device 6 further includes an air duct (not shown), one end of the air duct is fixedly connected to the piston housing 63 and is communicated with the air chamber 631, and the other end of the air duct is fixedly connected to the mechanical arm 5. In this embodiment, the number of the pistons 62, the number of the gas cavities 631 and the number of the gas ducts correspond to the number of the mechanical arms 5. That is, a plurality of independent gas chambers 631 are formed in the piston housing 63, a piston 62 is slidably disposed in each gas chamber 631, and when the negative pressure motor 61 drives the piston 62 to reciprocate, the gas pressure in the gas chamber 631 and the gun head 51 communicated with the gas chamber 631 through the gas guide tube changes, so that the reagent can be sucked or discharged. The negative pressure liquid suction device 6 utilizes the principle of the piston 62 to generate pressure to control suction or discharge liquid in a closed state, the piston 62 moves backwards to generate negative pressure when the head is under the liquid level so as to achieve the purpose of sucking the liquid, and conversely, when liquid exists in the gun head 51, the piston 62 moves forwards to generate positive pressure so as to discharge the liquid. The front end of the piston 62 is provided with a rubber pad, and the sealing performance is improved through the rubber pad.

Referring to fig. 2c, the automated microfluidic sample processing device further comprises a controller 11 and a power supply 12 for powering the controller 11 and the motors. The controller 11 and the negative pressure motor 61, the lifting motor 73, the x-direction motor 82 and the y-direction motor 84 are respectively and electrically connected through conducting wires to respectively transmit control signals to the motors, and the power source 12 and the controller 11, the negative pressure motor 61, the lifting motor 73, the x-direction motor 82 and the y-direction motor 84 are respectively and electrically connected through conducting wires to supply power. The power supply 12 is a switching power supply and is connected to the commercial power through a filter 13. MCU, specifically STM32 is selected for use by controller 11. And a controller 11 for sending an operation control signal to the x-direction motor 82 and/or the y-direction motor 84 so that the x-direction motor 82 and/or the y-direction motor 84 operate to move the gun head 51 above the chip holder 3 or the reagent. The controller 11 is further configured to send an operation control signal to the lift motor 73, so that the lift motor 73 operates to move the gun head 51 downward to load the chip holder 3 or insert the chip holder into the reagent, or move the gun head 51 upward to separate the gun head from the reagent. The controller 11 is further configured to send an operation control signal to the negative pressure motor 61, so that the negative pressure motor 61 operates to provide suction negative pressure or discharge positive pressure to the airflow channel of the gun head 51.

The vacuum imbibing device 6 also includes a piston detection mechanism for monitoring the displacement of the piston 62. In this embodiment, as shown in fig. 2b, the piston detection mechanism includes a photo detection switch 64 fixedly disposed on the piston housing 63 and a blocking piece 65 moving synchronously with the piston 62, when the piston 62 moves to the maximum setting displacement, the blocking piece 65 moves to the photo detection switch position 64, and the photo detection switch 64 is triggered to send out a detection signal. The photoelectric detection switch 64 of the piston detection mechanism is electrically connected with the controller 11 through a lead, the negative pressure motor 61 is electrically connected with the controller 11 through a lead, when the photoelectric detection switch 64 is triggered, a detection signal is sent, the controller 11 receives the detection signal and sends a control signal for stopping the operation to the negative pressure motor 61, the negative pressure motor 61 stops the operation in response to the control signal, and the piston 62 stops moving. Specifically, the negative pressure motor 61 is mounted on the piston housing 63, a motor shaft of the negative pressure motor 61 is connected with a push plate 611 and drives the push plate 611 to reciprocate linearly, the plurality of pistons 62 are all fixedly disposed on the push plate 611 and are driven by the push plate 611 to move synchronously, and the blocking piece 65 is fixedly disposed on the push plate 611.

The automated microfluidic sample processing device further comprises a failure detection means 9. The failure detection device 9 comprises at least one detection unit, the detection unit comprises a pair of photoelectric detection switches arranged at intervals and a blocking piece moving along with the gun head 51, and the blocking piece is arranged between the pair of photoelectric detection switches. The baffle is a metal baffle. Specifically, in this embodiment, the number of the detecting units is three, and the detecting units are respectively the first detecting unit, the second detecting unit and the third detecting unit. The first detection unit is used for detecting the moving distance of the gun head 51 along the up-down direction, the second detection unit is used for detecting the moving distance of the gun head 51 along the left-right direction, and the third detection unit is used for detecting the moving distance of the gun head 51 along the front-back direction. As shown in fig. 8, the first detecting unit includes a pair of first photoelectric detecting switches 91 and a first blocking piece 92, the pair of first photoelectric detecting switches 91 are disposed near the mechanical arms 5, and are specifically fixedly disposed on the housing 50 of one of the mechanical arms 5, the first photoelectric detecting switches and the housing 50 are disposed along the vertical direction and have a first interval, the first interval is greater than the maximum set stroke of the lifting rod 52 moving along the vertical direction, and the first blocking piece 92 is fixedly connected to the lifting rod 52 and is located between the pair of first photoelectric detecting switches 91. As shown in fig. 3, the second detecting unit includes a pair of second photoelectric detection switches 93 and a second blocking piece 94, the pair of second photoelectric detection switches 93 is disposed near the robot arm 5, and is specifically and fixedly disposed at a position of the mounting plate 81 near the robot arm 5, the pair of second photoelectric detection switches 93 is disposed along the left-right direction and has a second interval, the second interval is greater than a maximum set stroke of the robot arm 5 moving along the left-right direction, and the second blocking piece 94 is fixedly connected to one of the robot arms 5 (specifically, the housing 50 of the robot arm 5) and is located between the pair of second photoelectric detection switches 93. Referring to fig. 2b and fig. 3, the third detecting unit includes a pair of third photoelectric detecting switches 95 and a third blocking piece (not shown in the figure), the pair of third photoelectric detecting switches 95 are fixedly disposed at a position of the rack 1 close to the sliding block 87, specifically, at a side of the sliding rail 86, and are disposed along the front-back direction and have a third interval, the third interval is greater than a maximum set stroke of the mechanical arm 5 moving along the front-back direction, and the third blocking piece is fixedly connected to the sliding block 87 and is located between the pair of third photoelectric detecting switches 95.

The controller 11 is electrically connected to each of the photo-detection switches, and the controller 11 is configured to control the mechanical arm 5 to stop moving after any one of the photo-detection switches is triggered. The fault detection device 9 further comprises a fault indicator lamp 96, the controller 11 is electrically connected with the fault indicator lamp 96, and the controller 11 is further configured to control the fault indicator lamp 96 to switch the light color after any one of the photoelectric detection switches is triggered. Specifically, the controller 11 is electrically connected to the pair of first photoelectric detection switches 91, the pair of second photoelectric detection switches 93, and the pair of third photoelectric detection switches 95 through wires, and the controller 11 is also electrically connected to the lift motor 73, the x-direction motor 82, and the y-direction motor 84 through wires. When the mechanical arm 5 moves in the up-down direction beyond the maximum set displacement, the first blocking piece 92 moves to a certain first photoelectric detection switch 91 to trigger the first photoelectric detection switch 91 to send out a fault signal, the controller 11 receives the fault signal and then sends out first control signals for stopping operation to the lifting motor 73, the x-direction motor 82 and the y-direction motor 84, meanwhile, the controller 11 also sends out a second control signal for switching the indication color to the fault indicator lamp 96, the lifting motor 73, the x-direction motor 82 and the y-direction motor 84 stop operating in response to the first control signals, and the color of the fault indicator lamp 96 is changed from green to red in response to the second control signals. As shown in fig. 1, the fault indicator light 96 is specifically disposed on the housing 10, and includes an elongated LED light; when the microfluidic sample processing device is operating normally, the fault indicator light 96 is displayed green in color; when the movement of the mechanical arm 5 in any direction exceeds the maximum set stroke, it is determined that the microfluidic sample processing device is in failure, each motor stops operating, the mechanical arm 5 stops moving, and the failure indicator lamp 96 is displayed in red. Avoiding damage to the sample and to the machine itself by incorrect operation of the robotic arm 5.

The detection principle of the photoelectric detection switch adopted in the embodiment is as follows: after the separation blade moves to the photoelectric detection position, the detection light of the photoelectric detection switch is shielded, so that the photoelectric detection switch is triggered. The photoelectric detection switch is typically an infrared detection switch, and the infrared detection switch is triggered when the blocking piece blocks infrared rays emitted by the infrared detection switch.

In other embodiments, the fault detection device 9 further comprises an audible alarm device, the controller 11 is electrically connected to the audible alarm device, and the controller 11 is further configured to control the audible alarm device to emit an alarm sound after any one of the photoelectric detection switches is triggered.

In the fault detection device 9, a small distance is arranged between the normal operation range of the mechanical arm 5 and the photoelectric detection switch, so that the probability of mistakenly triggering the photoelectric detection switch is greatly reduced. Once the mechanical arm 5 breaks down, the blocking piece reaches the position of the photoelectric detection switch, the mechanical arm 5 stops moving immediately, and the safety of the machine is effectively improved. The operation is simple, and the fault reaction is visual.

The present embodiment also provides a method for controlling an automated microfluidic sample processing apparatus, comprising the steps of:

moving the gun head positioned above the chip clamp downwards to load the chip clamp on the gun head;

moving the gun head loaded with the chip clamp upwards and translating the gun head to the upper part of the reagent;

moving the gun head downwards to insert the chip clamp into the reagent;

providing negative pressure for the gun head, sucking the reagent into the chip clamp, and making the reagent flow through the microfluidic chip;

moving the gun head upwards to separate from the reagent, and translating the gun head to the upper part of the waste liquid collecting hole;

the gun head is moved downwards and inserted into the waste liquid collecting hole;

providing positive pressure to the gun head, and discharging the sucked reagent into a waste liquid collecting hole; and

translating the gun head loaded with the chip clamp to be above the part (namely the front end part) of the chip recovery hole which is not shielded;

moving the gun head downwards to insert the chip clamp into the chip recovery hole;

translating the gun head to move the chip clamp to a part (namely the rear end part) of the chip recovery hole, which is shielded by the baffle plate;

and moving the gun head upwards to move the gun head out of the chip recovery hole, wherein the chip clamp is blocked by the baffle and is left in the chip recovery hole.

Wherein the step of translating the lance tip comprises moving the lance tip in a left-right direction and/or moving the lance tip in a front-rear direction.

Specifically, the working process of the microfluidic sample processing device is as follows:

1. the kit 2 is loaded into the mounting groove 40 of the tray device 4, the translation device 8 drives the mechanical arm 5 to move horizontally to enable each gun head 51 to be positioned right above the corresponding chip clamp 3, the lifting device 7 drives the mechanical arm 5 to lift so that the lower end part of each gun head 51 is inserted into the barrel part 32 of the corresponding chip clamp 3, and the chip clamp 3 is loaded on the gun head 51; at this time, the chip holder 3 is initially located in the waste liquid collecting hole 21, the sample (body fluid, such as blood, urine, tissue fluid, spinal fluid, etc.) is stored in the upper section of the chip holder 3, the robotic arm is inserted into the barrel portion 32 to carry the whole chip holder 3 to move, and when inserted, the negative pressure liquid suction device 6 provides positive pressure to push the sample into the inner cavity of the chip holder 3 to flow through the microfluidic chip for cell capture, the waste liquid flows out from the lower end flow guide tube 31 of the chip holder 3 after passing through the microfluidic chip to remain in the waste liquid collecting hole 21, and the waste liquid involved in the following operation is all recovered into the waste liquid collecting hole 21.

2. The lifting device 7 drives the mechanical arm to move upwards, and the chip clamp 3 is integrally moved out of the waste liquid collecting hole 21; the y-direction motor 84 of the translation device 8 acts to enable the mechanical arm 5 to drive the chip clamp 3 to move to the position above the fixed liquid hole 22; the lifting device 7 operates to enable the mechanical arm 5 to drive the chip clamp 3 to move downwards, the guide pipe 31 is inserted into the fixing liquid hole 22, the negative pressure liquid suction device 6 provides negative pressure to enable the guide pipe 31 to suck the fixing liquid in the fixing liquid hole 22, and the fixing liquid passes through the chip from bottom to top to fix cells captured on the chip; the y-direction motor 84 of the translation mechanism acts, the mechanical arm 5 moves back to the position above the waste liquid collecting hole 21, the negative pressure liquid suction device 6 provides positive pressure to discharge the stationary liquid to the waste liquid collecting hole 21, and waste liquid treatment is performed at the same position in the later step.

3. Arm 5 control chip anchor clamps 3 move to the top in buffer solution hole 23, and insert honeycomb duct 31 in buffer solution hole 23, absorb PBS buffer solution, wash the chip, arm 5 moves back waste liquid collection hole 21 top, and waste liquid is handled waste liquid collection hole 21, repeats 2 times.

4. The mechanical arm 5 controls the chip clamp 3 to move to the upper side of the first anti-hole 24 in sequence, the guide pipe 31 is inserted into the first anti-hole 24 to suck the first anti-A, the chip is incubated for 60 minutes for the first anti-A, the chip returns to the position of the buffer hole 23 after the waste liquid is discharged from the waste liquid collecting hole 21 and is washed for 2 times, the chip is moved to the position of the second anti-hole 25 and is incubated for 60 minutes for the first anti-B, the chip returns to the position of the buffer hole 23 after the waste liquid is discharged from the waste liquid collecting hole 21 and is washed for 2 times.

5. The translation device 8 acts to enable the mechanical arm to drive the chip clamp 3 to move to the front end of the chip recovery hole 28; the lifting device 7 acts, and the mechanical arm 5 drives the chip clamp 3 to move downwards and insert into the front end of the chip recovery hole; the y-direction motor 84 of the translation device 8 operates to enable the mechanical arm 5 to drive the chip clamp 3 to move in the chip recovery hole to the rear end of the chip recovery hole, and at the moment, part of the chip clamp 3 is positioned right below the baffle 43; the lifting device 7 moves, the mechanical arm 5 moves upwards, the chip clamp 3 is blocked by the baffle 43 and is left in the chip recovery hole, and the chip clamp 3 is separated from the gun head 51.

The microfluidic sample processing device of the embodiment integrates the functions of cell or biomolecule capture, fixation, cleaning, antibody incubation, dyeing and the like, automatically realizes a series of processing on the microfluidic sample, reduces manual intervention, has high automation degree and improves processing efficiency; the chip clamps 3 can be synchronously operated at the same time, so that parallel tests are convenient to perform, and the processing efficiency is further improved; in addition, the structure is compact, the layout is reasonable, and the space occupied by the equipment is reduced.

The above embodiments are merely illustrative of the technical ideas and features of the present invention, and are preferred embodiments, which are intended to enable those skilled in the art to understand the contents of the present invention and implement the present invention, and not to limit the scope of the present invention. All equivalent changes or modifications made according to the principles of the present invention should be covered within the protection scope of the present invention.