CN112014570A

CN112014570A - High-speed C reaction protein analyzer

Info

Publication number: CN112014570A
Application number: CN202010840515.8A
Authority: CN
Inventors: 宋晓峰; 余强华; 胡培丽
Original assignee: Jinhuake Biotechnology Hebei Co ltd
Current assignee: Jinhuake Biotechnology Hebei Co ltd
Priority date: 2020-08-20
Filing date: 2020-08-20
Publication date: 2020-12-01

Abstract

The invention provides a high-speed C-reactive protein analyzer. In the technical scheme, a screw rod mechanism is used for bearing the lifting table, and the lifting table is driven to move longitudinally by the driving of a first motor; the rotating shaft is driven to rotate by the second motor, the rotating arm is sleeved on the rotating shaft through the mounting ring and is fixed by the jackscrew, so that the rotating arm can rotate under the driving of the second motor; a sample adding pipe is arranged at the tail end of the rotating arm, and the sample adding pipe is driven by a liquid pump to suck and release a sample; based on the structure, the automatic sample adding function can be realized. On this basis, utilize step motor drive carousel rotatory, set up the cell frame on the carousel, the reaction tube is the annular and pegs graft on the cell frame, based on step motor's drive action, makes the reaction tube pass through application of sample mechanism below one by one to accomplish the application of sample action. On the basis, an infrared detector can be further introduced to monitor the liquid level condition in the sample adding pipe so as to avoid the phenomenon of adding missing.

Description

High-speed C reaction protein analyzer

Technical Field

The invention relates to the technical field of medical detection, in particular to a high-speed C-reactive protein analyzer.

Background

C-reactive protein (CRP) refers to a number of proteins that rise sharply in the plasma (acute proteins) when the body is infected or tissue damaged. CRP can activate complement and enhance phagocytosis of phagocyte to play an opsonizing role, thereby eliminating pathogenic microorganism and damaged, necrotic and apoptotic histiocyte invading the body, and playing an important protective role in the natural immune process of the body.

CRP is not only a non-specific inflammation marker, but also directly participates in cardiovascular diseases such as inflammation and atherosclerosis, and is the most powerful predictor and risk factor for cardiovascular diseases. The interaction of CRP with complement Clq and FcTR allows it to exhibit a number of biological activities, including host defense against infection, phagocytosis and regulation of inflammatory responses, etc. The combination of the antigen and damaged cells, apoptotic cells and nuclear antigens plays an important role in autoimmune diseases

CRP assays are of great clinical significance.

(1) After the attack of various diseases such as acute inflammation, tissue injury, myocardial infarction, surgical trauma, radiation injury and the like, the disease rapidly rises for hours and has the potential of increasing by times. When the pathological changes are improved, the pathological changes are quickly reduced to normal, and the increasing amplitude of the pathological changes is positively correlated with the infection degree. CRP of a patient after the operation is increased, CRP level is reduced after 7-10 days of the operation, if CRP is not reduced or increased again, infection or thromboembolism possibly occurs.

(2) CRP has close correlation with other inflammatory factors such as total leukocyte count, erythrocyte sedimentation rate and polymorphonuclear leukocytes. And positively correlated with WBCs. Plays a positive role in inflammatory reaction and endows the human body with nonspecific resistance. The patient can rise earlier than WBC at the onset of disease, and can recover to normal quickly, so the sensitivity is extremely high.

(3) Helping to distinguish the type of respiratory infection. CRP can be used for differential diagnosis of bacterial and viral infections: elevation of CRP levels upon bacterial infection; when the virus is infected, CRP is not increased or slightly increased, so that CRP value can help doctors to distinguish types of respiratory tract infection and give medicines and treatment in a targeted mode.

(4) The CRP of malignant tumor patients is increased, such as the joint detection of CRP and AFP, can be used for the differential diagnosis of liver cancer and liver benign diseases, and can be used for the judgment of liver cancer curative effect and prognosis. CRP increased before surgery and decreased after surgery, and its response was not affected by radiotherapy, chemotherapy, and corticoid treatment, which helps to assess tumor progression.

(5) The severity of acute pancreatitis was assessed and when CRP was higher than 250mg/L, extensive necrotizing pancreatitis was suggested.

(6) The CRP can be measured by hypersensitivity latex enhancement method, and the sensitivity of measurement can be improved, and the method can be used for predicting coronary heart disease and myocardial infarction risk.

The C-reactive protein analyzer is an immunoassay analyzer which detects the concentration of C-reactive protein in blood by adopting an immune scattering turbidimetry method or a colloidal gold method. At present, a semi-quantitative analyzer based on a colloidal gold method generally needs manual sample adding, so that the degree of automation is low, the operation is complex, and the detection efficiency is low.

Disclosure of Invention

The invention aims to provide a high-speed C-reactive protein analyzer aiming at the technical defects of the prior art, and aims to solve the technical problem that the conventional C-reactive protein analyzer cannot automatically sample.

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

the high-speed C reaction protein analyzer comprises a sample adding mechanism and a bearing mechanism, wherein the sample adding mechanism is arranged on the side of the bearing mechanism;

the sample adding mechanism comprises a bottom plate, a lead screw, a first motor, a first belt, a bevel gear, a lead screw nut, a lifting platform, a second motor, a rotating shaft, a rotating arm, a mounting ring, a sample adding pipe, a liquid pump and a jackscrew, wherein the bottom plate is connected with the lead screw through a bearing, the first motor is in transmission connection with the lead screw through the first belt and the bevel gear, the lead screw nut is screwed on the lead screw, the lead screw nut is fixedly connected with the lifting platform, the lifting platform is fixedly connected with the second motor, and the second motor is in transmission connection with the rotating shaft; the rotating arm is provided with a mounting ring which is sleeved on the rotating shaft, the jackscrew is connected on the mounting ring, the jackscrew penetrates through the mounting ring and is jacked on the rotating shaft, the rotating arm is connected with a sample adding pipe, and the sample adding pipe is connected with a liquid pump;

the bearing mechanism comprises a substrate, a rotary table, a third motor, a gear, a tank frame and a reaction tube, wherein the rotary table is arranged on the substrate, the third motor is fixedly connected to the substrate and is in transmission connection with the gear, a gear ring is arranged on the periphery of the rotary table, and the gear is meshed with the gear ring; the turntable is fixedly connected with a groove frame, and the groove frame is inserted with a reaction tube.

Preferably, the reaction tube further comprises an infrared detector fixedly connected to the substrate, and the infrared detector is positioned on the side of the reaction tube.

Preferably, the sample addition tube is positioned above the reaction tube.

Preferably, the third motor is a stepping motor.

Preferably, the groove frame is annular, a plurality of cylindrical blind holes are formed in the upper end of the groove frame, a spongy cushion is fixedly connected to the bottom end of each blind hole, the reaction tubes are inserted into the blind holes, and the spongy cushion is supported at the bottom ends of the reaction tubes.

The invention provides a high-speed C-reactive protein analyzer. In the technical scheme, a screw rod mechanism is used for bearing the lifting table, and the lifting table is driven to move longitudinally by the driving of a first motor; the rotating shaft is driven to rotate by the second motor, the rotating arm is sleeved on the rotating shaft through the mounting ring and is fixed by the jackscrew, so that the rotating arm can rotate under the driving of the second motor; a sample adding pipe is arranged at the tail end of the rotating arm, and the sample adding pipe is driven by a liquid pump to suck and release a sample; based on the structure, the automatic sample adding function can be realized. On this basis, utilize step motor drive carousel rotatory, set up the cell frame on the carousel, the reaction tube is the annular and pegs graft on the cell frame, based on step motor's drive action, makes the reaction tube pass through application of sample mechanism below one by one to accomplish the application of sample action. On the basis, an infrared detector can be further introduced to monitor the liquid level condition in the sample adding pipe so as to avoid the phenomenon of adding missing. The invention can effectively improve the detection efficiency and reduce the experimental operation amount, and has outstanding technical advantages.

Drawings

FIG. 1 is a front view of a sample application mechanism according to the present invention;

FIG. 2 is a perspective view of a pivot arm and its upper assembly in accordance with the present invention;

FIG. 3 is a perspective view of a load bearing mechanism of the present invention;

in the figure:

1. bottom plate 2, lead screw 3, first motor 4, first belt

5. Bevel gear 6, lead screw nut 7, elevating platform 8, second motor

9. Rotating shaft 10, rotating arm 11, mounting ring 12 and sample adding pipe

13. Liquid pump 14, jackscrew 15, base plate 16, carousel

17. Third motor 18, gear 19, groove frame 20 and reaction tube

21. An infrared detector.

Detailed Description

Hereinafter, specific embodiments of the present invention will be described in detail. Well-known structures or functions may not be described in detail in the following embodiments in order to avoid unnecessarily obscuring the details. Approximating language, as used herein in the following examples, may be applied to identify quantitative representations that could permissibly vary in number without resulting in a change in the basic function. Unless defined otherwise, technical and scientific terms used in the following examples have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs.

Example 1

A high-speed C-reactive protein analyzer is shown in figures 1-3 and comprises a sample adding mechanism and a bearing mechanism, wherein the sample adding mechanism is arranged on the side of the bearing mechanism;

the sample adding mechanism comprises a bottom plate 1, a lead screw 2, a first motor 3, a first belt 4, a bevel gear 5, a lead screw nut 6, a lifting table 7, a second motor 8, a rotating shaft 9, a rotating arm 10, a mounting ring 11, a sample adding pipe 12, a liquid pump 13 and a jackscrew 14, wherein the lead screw 2 is connected to the bottom plate 1 through a bearing, the first motor 3 is in transmission connection with the lead screw 2 through the first belt 4 and the bevel gear 5, the lead screw nut 6 is screwed on the lead screw 2, the lead screw nut 6 is fixedly connected with the lifting table 7, the second motor 8 is fixedly connected to the lifting table 7, and the second motor 8 is in transmission connection with the rotating shaft 9; the rotating arm 10 is provided with a mounting ring 11, the mounting ring 11 is sleeved on the rotating shaft 9, a jackscrew 14 is connected on the mounting ring 11 through a screw, the jackscrew 14 penetrates through the mounting ring 11 and is pressed on the rotating shaft 9, the rotating arm 10 is connected with a sample adding pipe 12, and the sample adding pipe 12 is connected with a liquid pump 13;

the bearing mechanism comprises a substrate 15, a turntable 16, a third motor 17, a gear 18, a groove frame 19 and a reaction tube 20, wherein the turntable 16 is arranged on the substrate 15, the third motor 17 is fixedly connected to the substrate 15, the third motor 17 is in transmission connection with the gear 18, a gear ring is arranged on the periphery of the turntable 16, and the gear 18 is meshed with the gear ring; the turntable 16 is fixedly connected with a groove frame 19, and a reaction tube 20 is inserted on the groove frame 19.

Example 2

Meanwhile, the device also comprises an infrared detector 21, wherein the infrared detector 21 is fixedly connected to the substrate 15, and the infrared detector 21 is positioned on the side of the reaction tube 20. The sample addition tube 12 is located above the reaction tube 20. The third motor 17 is a stepping motor. The groove frame 19 is annular, has seted up a plurality of columniform blind holes in the upper end of groove frame 19 the bottom fixedly connected with foam-rubber cushion of blind hole, reaction tube 20 pegs graft in the blind hole, the foam-rubber cushion bearing is in reaction tube 20 bottom.

The embodiments of the present invention have been described in detail, but the description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention. Any modification, equivalent replacement, and improvement made within the scope of the application of the present invention should be included in the protection scope of the present invention.

Claims

1. The high-speed C reaction protein analyzer is characterized by comprising a sample adding mechanism and a bearing mechanism, wherein the sample adding mechanism is arranged on the side of the bearing mechanism;

the sample adding mechanism comprises a bottom plate (1), a lead screw (2), a first motor (3), a first belt (4), a bevel gear (5), a lead screw nut (6), a lifting platform (7), a second motor (8), a rotating shaft (9), a rotating arm (10), a mounting ring (11), a sample adding pipe (12), a liquid pump (13) and a jackscrew (14), wherein the lead screw (2) is connected to the bottom plate (1) through a bearing, the first motor (3) is in transmission connection with the lead screw (2) through the first belt (4) and the bevel gear (5), the lead screw nut (6) is screwed to the lead screw (2), the lead screw nut (6) is fixedly connected with the lifting platform (7), the second motor (8) is fixedly connected to the lifting platform (7), and the second motor (8) is in transmission connection with the rotating shaft (9); the rotary arm (10) is provided with a mounting ring (11), the mounting ring (11) is sleeved on the rotating shaft (9), a top wire (14) is connected on the mounting ring (11), the top wire (14) penetrates through the mounting ring (11) and is pressed on the rotating shaft (9), the rotary arm (10) is connected with a sample adding pipe (12), and the sample adding pipe (12) is connected with a liquid pump (13);

the bearing mechanism comprises a substrate (15), a turntable (16), a third motor (17), a gear (18), a groove frame (19) and a reaction tube (20), wherein the turntable (16) is arranged on the substrate (15), the third motor (17) is fixedly connected to the substrate (15), the third motor (17) is in transmission connection with the gear (18), a gear ring is arranged on the periphery of the turntable (16), and the gear (18) is meshed with the gear ring; the turntable (16) is fixedly connected with a groove frame (19), and the groove frame (19) is spliced with a reaction tube (20).

2. The high-speed C-reactive protein analyzer according to claim 1, further comprising an infrared detector (21), wherein the infrared detector (21) is fixedly connected to the substrate (15), and the infrared detector (21) is located at the side of the reaction tube (20).

3. The high speed C-reactive protein analyzer of claim 1, wherein the sample application tube (12) is positioned above the reaction tube (20).

4. The high speed C-reactive protein analyzer of claim 1, wherein the third motor (17) is a stepper motor.

5. The high-speed C-reactive protein analyzer according to claim 1, wherein the tank rack (19) is annular, the upper end of the tank rack (19) is provided with a plurality of cylindrical blind holes, the bottom ends of the blind holes are fixedly connected with sponge pads, the reaction tubes (20) are inserted into the blind holes, and the sponge pads are supported at the bottom ends of the reaction tubes (20).