CN220730026U - Surface plasmon resonance imaging detection system - Google Patents

Abstract

The utility model provides a surface plasmon resonance imaging detection system, which belongs to the technical field of surface plasmon resonance imaging, and comprises a liquid storage area, a multi-path selection valve, a continuous flow pump, a liquid dispenser, a mechanical arm, a sample storage area, an overflow cleaning area and an optical detection area; the multiple selectable interfaces of the multi-way selection valve are connected with the liquid storage area, the public interface of the multi-way selection valve is connected with the continuous flow pump, one side of the continuous flow pump is connected with the liquid separator, and the liquid separator is connected with one end of the mechanical arm; the sample storage area, the overflow cleaning area and the optical detection area are arranged on one side of the mechanical arm. The sample overflows from the periphery of the sampling needle after flowing out, compared with an incubation method, the sample detected by the system can flow, so that the detection effect is better, and compared with the traditional directional flowing device manufacturing process of microfluid, the system is simple to manufacture.

Description

Surface plasmon resonance imaging detection system

Technical Field

The utility model belongs to the technical field of surface plasmon resonance imaging, and particularly relates to a surface plasmon resonance imaging detection system.

Background

The SPR phenomenon is a phenomenon in which light is reflected by a metal thin film layer, and the intensity of the reflected light is significantly attenuated by resonance at a specific incident angle. The SPR sensor is a technology for measuring the refractive index of a liquid sample above a metal film layer by utilizing the SPR phenomenon, and the SPR biosensor can be used for detecting biochemical reaction because the adsorption of surface substances is approximately proportional to the change of the refractive index in the biochemical reaction process. There are four detection principles of wavelength detection, angle detection, intensity detection and phase detection in SPR detection.

The detection method can be divided into nanosphere detection, prism coupling detection, optical fiber coupling detection and grating coupling detection.

Among the four detection methods, the two methods of nanosphere detection and optical fiber coupling detection belong to different technical routes and are not overlapped with the detection technology.

In the existing prism coupling SPR and grating coupling SPR technologies, the sample delivery method is mainly a cavity type surface micro-fluidic structure or a direct incubation method.

The chamber-type surface microfluid is characterized in that a microfluid area with an inlet and an outlet is created on the surface of a sensor by a certain material shaping method. The sample is taken from the storage area into the integrated microfluidic channel inlet and then from the integrated microfluidic channel outlet into the sensor surface microfluidic inlet to the outlet in a single specific direction defined by the fluidic structure.

Direct incubation, i.e. prefabricating the vessel wall above the sensor surface and adding the sample to be measured directly to the vessel formed by the sensor and the vessel wall.

On this basis, an automated sampler is required as long as it is an automated detection device.

The mechanical structure of the chamber-type surface microfluidics is relatively complex to fabricate, is difficult to process, and requires integrated microfluidic support to accomplish sample delivery to the sensor. The complex control of the integrated microfluidic is required to avoid contact of different liquids in the continuous line of the sampling system, the complex pump valve structure in the integrated microfluidic has greater risk of aging and failure, is easily affected by corrosive or adhesive samples, and the cleaning process is tedious and time-consuming.

In the SPR detection process, the sample must circulate at a certain speed to fully contact and react with the surface of the sensor and be detected, and the incubation method has poor detection effect and less application because the sample does not circulate.

Disclosure of Invention

The utility model provides a surface plasmon resonance imaging detection system aiming at the problems in the prior art, and aims to solve the technical problems of simple structure, low processing difficulty and capability of enabling a sample to circulate on a detection chip.

In order to solve the technical problems, the utility model provides a surface plasmon resonance imaging detection system, which comprises a liquid storage area, a multi-path selection valve, a continuous flow pump, a liquid dispenser, a mechanical arm, a sample storage area, an overflow cleaning area and an optical detection area;

the multiple selectable interfaces of the multi-way selection valve are connected with the liquid storage area, the public interface of the multi-way selection valve is connected with the continuous flow pump, one side of the continuous flow pump is connected with the liquid separator, and the liquid separator is connected with one end of the mechanical arm;

the sample storage area, the overflow cleaning area and the optical detection area are arranged on one side of the mechanical arm.

Further, the liquid storage area comprises a plurality of accommodating chambers, and the accommodating chambers are independent from each other.

Further, the continuous flow pump comprises two liquid interfaces, one of which is connected with the multi-way selection valve and the other of which is connected with the liquid separator.

Further, the knockout includes knockout body and a plurality of sample needle, and the upper portion of knockout body is connected with continuous flow pump, and the below of knockout body is connected with the sample needle.

Further, the sampling needle is of a long tube type structure.

Further, the overflow cleaning zone includes a plurality of cleaning tanks.

Further, the cleaning tank is a blind hole.

Further, the optical detection area comprises a detection groove partition plate, a detection chip and an SPR optical sensor, the bottom of the detection groove partition plate is attached to the detection chip, and the SPR optical sensor is arranged below the detection chip.

Further, a plurality of detection groove partitions are formed therebetween.

Further, the SPR optical sensor comprises a prism, an imaging device and a light source, wherein the prism is arranged below the detection chip, the imaging device is arranged on one side of the prism, and the light source is arranged on the other side of the prism.

Further, overflow collectors are arranged above the overflow cleaning area and the optical detection area.

According to the surface plasmon resonance imaging detection system, a sample can overflow from the periphery after flowing out of the sampling needle, so that the detection effect is good, and compared with the manufacturing process of a device for directional flow of the traditional microfluid, the system is simple to manufacture; the area for optical detection in the SPR optical sensor is the projection of the sample inlet on the SPR optical sensor along the liquid flow direction, namely the area right below the sample inlet; the whole reaction process is that the sample only contacts with the sampling needle of the liquid dispenser, and no other fluid components are needed, so that the pollution of the sample is avoided; compared with incubation type detection, in the detection process, the surface liquid of the SPR optical sensor can circulate according to a set flow rate; high throughput detection is achieved by using a method in which multiple sampling pins are connected in parallel.

The utility model provides a surface plasmon resonance imaging detection system, which uses an automatic sampler composed of a liquid dispenser and a mechanical arm to realize the direct sample delivery to an SPR optical sensor of an optical detection area; the flowing direction of the sample on the detection chip is that the sample overflows from the periphery of the sampling needle after flowing out, compared with an incubation method, the sample can flow by using the method, so that the detection effect is better, and compared with the manufacturing process of a device for directional flow of the traditional microfluid, the system is simple to manufacture; the SPR optical sensor micro-fluid has only one liquid inlet and outlet, namely a detection groove, the manufacturing process is simple, and the traditional micro-fluid generally has two inlets and outlets, and the manufacturing process is complex.

Drawings

Fig. 1 is a schematic structural diagram of a surface plasmon resonance imaging detection system of the present utility model.

1. A liquid storage area; 2. a multiple-way selection valve; 3. a continuous flow pump; 4. a knockout; 41. a knockout body; 42. a sampling needle; 5. a mechanical arm; 6. a sample storage area; 7. an overflow cleaning zone; 71. a cleaning tank; 8. an optical detection zone; 81. a detection groove; 82. detecting a groove partition plate; 83. a detection chip; 84. SPR optical sensor; 841. a prism; 842. an imaging device; 843. a light source.

Detailed Description

For the purpose of making the objects, technical solutions and advantages of the embodiments of the present utility model more apparent, the technical solutions of the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present utility model, and it is apparent that the described embodiments are some embodiments of the present utility model, but not all embodiments. All other embodiments, based on the embodiments of the utility model, which are apparent to those of ordinary skill in the art without inventive faculty, are intended to be within the scope of the utility model.

Thus, the following detailed description of the embodiments of the utility model, as presented in the figures, is not intended to limit the scope of the utility model, as claimed, but is merely representative of selected embodiments of the utility model. All other embodiments, based on the embodiments of the utility model, which are apparent to those of ordinary skill in the art without inventive faculty, are intended to be within the scope of the utility model.

It should be noted that: like reference numerals and letters denote like items in the following figures, and thus once an item is defined in one figure, no further definition or explanation thereof is necessary in the following figures.

In the present utility model, unless explicitly specified and limited otherwise, the terms "mounted," "connected," "secured," and the like are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally formed; can be directly connected or indirectly connected through an intermediate medium, and can be communicated with the inside of two elements or the interaction relationship of the two elements. The specific meaning of the above terms in the present utility model can be understood by those of ordinary skill in the art according to the specific circumstances.

For a better understanding of the objects, structures and functions of the present utility model, a surface plasmon resonance imaging detection system according to the present utility model will be described in further detail with reference to the accompanying drawings.

Example 1:

as shown in fig. 1, the surface plasmon resonance imaging detection system of the utility model comprises a liquid storage area 1, a multi-path selection valve 2, a continuous flow pump 3, a liquid dispenser 4, a mechanical arm 5, a sample storage area 6, an overflow cleaning area 7 and an optical detection area 8;

the multiple selectable interfaces of the multi-way selection valve 2 are connected with the liquid storage area 1, the public interface of the multi-way selection valve 2 is connected with the continuous flow pump 3, one side of the continuous flow pump 3 is connected with the liquid separator 4, and the liquid separator 4 is connected with one end of the mechanical arm 5;

the sample storage area 6, the overflow cleaning area 7 and the optical detection area 8 are arranged on one side of the robot arm 5.

Example 2:

as shown in fig. 1, the surface plasmon resonance imaging detection system of the utility model comprises a liquid storage area 1, a multi-path selection valve 2, a continuous flow pump 3, a liquid dispenser 4, a mechanical arm 5, a sample storage area 6, an overflow cleaning area 7 and an optical detection area 8;

the multiple selectable interfaces of the multi-way selection valve 2 are connected with the liquid storage area 1, the public interface of the multi-way selection valve 2 is connected with the continuous flow pump 3, one side of the continuous flow pump 3 is connected with the liquid separator 4, and the liquid separator 4 is connected with one end of the mechanical arm 5;

the sample storage area 6, the overflow cleaning area 7 and the optical detection area 8 are arranged on one side of the robot arm 5.

The present embodiment is different from the first embodiment in that:

the liquid storage area 1 comprises a plurality of accommodating chambers, each accommodating chamber comprises a waste liquid accommodating chamber and a plurality of buffer liquid accommodating chambers, the plurality of accommodating chambers are mutually independent and respectively accommodate different liquids, the plurality of accommodating chambers are connected with the selectable interfaces of the multi-way selection valve 2 through fluid pipelines, and the multi-way selection valve 2 can select different liquids to be conveyed into the liquid separator 4.

The multiple-way selector valve 2 comprises a common interface (COM) and a plurality of selectable interfaces, each of which connects to a different housing, the common interface connecting to the continuous flow pump 3. The multiplexing valve 2 is able to choose to connect different selectable interfaces with a common interface.

The continuous flow pump 3 comprises two liquid interfaces, one is connected with the multi-way selector valve 2, the other is connected with the liquid distributor 4, and the control system can control the flow speed and the direction of the continuous flow pump 3 to realize accurate fluid control.

The dispenser 4 can divide the fluid into multiple paths of fluid with the same flow rate and pressure according to the requirement, the dispenser 4 comprises a dispenser body 41 and a plurality of sampling needles 42, the upper part of the dispenser body 41 is connected with the continuous flow pump 3, the lower part of the dispenser body 41 is connected with the sampling needles 42, the sampling needles 42 are of long tube type structures, and the sampling needles 42 can circulate liquid and store a certain amount of liquid samples for transfer in the liquid transfer process.

The robotic arm 5 is capable of moving the dispenser 4 to a sample storage area 6, an overflow wash area 7 and an optical detection area 8.

And a sample storage area 6 for storing a sample to be detected.

The overflow cleaning zone 7 comprises a plurality of vertically placed cleaning tanks 71, the cleaning tanks 71 being blind holes, and when the liquid in the sampling needle 42 of the liquid dispenser 4 flows into the blind holes and overflows from the gap between the sampling needle 42 and the blind holes, the liquid flows through the blind holes and the outer wall of the sampling needle 42, thereby realizing the function of cleaning the sampling needle 42.

The optical detection area 8 comprises a detection groove partition board 82, a detection chip 83 and an SPR optical sensor 84, the SPR optical sensor 84 comprises a prism 841, an imaging device 842 and a light source 843, the bottom of the detection groove partition board 82 is attached to the detection chip 83, a detection groove 81 is formed among the detection groove partition boards 82, a prism 841 is arranged below the detection chip 83, one side of the prism 841 is provided with the imaging device 842, and the other side of the prism 841 is provided with the light source 843. During sample injection, SPR optical sensor 84 is capable of detecting the reaction process in real time.

Overflow collectors are arranged above the overflow cleaning area 7 and the optical detection area 8: consists of a pipeline and a peristaltic pump which independently operates independently of the micro-fluidic system, and the overflowed liquid is recovered as waste liquid when the overflow detection groove 81 or the blind hole exists in the optical detection 8 area or the overflow cleaning area 7.

The continuous flow pump 3 is a prior art, and here refers to a fluid pump of a single structure or a composite structure capable of operating continuously without an upper limit of pumping volume theory during operation in any given direction by controlling the operation of pumping fluid in different directions.

The working process of the surface plasmon resonance imaging detection system of the embodiment is as follows:

the user prepares the liquid in the liquid storage area 1 as required, prepares the sample to be detected in the sample storage area 6, and prepares the SPR optical sensor 84 in the optical detection area 8.

The mechanical arm 5 drives the liquid distributor 4 to move to the overflow cleaning area 7.

The multi-path selection valve 2 selects the buffer solution which moves to the liquid storage area 1 and has the cleaning function, the continuous flow pump 3 pumps the buffer solution to the overflow cleaning area 7 towards the direction of the liquid separator 4, the buffer solution overflows from the opening of the cleaning tank 71, and the overflowed buffer solution is collected as waste liquid by the overflow collector.

The mechanical arm 5 drives the liquid separator 4 to move to the optical detection area 8, the multi-path selection valve 2 selects the buffer liquid which moves to the liquid storage area 1 and has a cleaning function, the continuous flow pump 3 pumps the buffer liquid to the optical detection area 8 towards the liquid separator 4, the buffer liquid overflows from the upper part of the detection groove 81, and the overflowed buffer liquid is collected by the overflow collector as waste liquid, so that the cleaning and zero-resetting calibration of the optical detection area 8 are completed.

The robotic arm 5 moves the dispenser 4 to the sample storage area 6.

The multi-way selector valve 2 is connected to the waste liquid container, and the continuous flow pump 3 pumps the sample to the sample volume set by the user in the direction of the multi-way selector valve 2, and at this time, the sample is sucked and temporarily stored in the sampling needle 42 of the dispenser 4.

The mechanical arm 5 drives the liquid dispenser 4 to optically detect the region 8.

The multi-path selection valve 2 is connected with a buffer solution accommodating room of the liquid storage area 1 set by a user, the continuous flow pump 3 pumps buffer solution slowly to the direction of the liquid separator 4 at a speed set by the user, when the buffer solution is pushed, a sample positioned in front of the buffer solution is slowly pumped to the bottom of the detection groove 81 under the hydraulic transmission action of the buffer solution, and the sample overflows to the periphery after being separated from the sampling needle 42; after all the samples are separated from the sampling needle 42, the continuous flow pump 3 slowly pumps the liquid towards the dispenser 4 at a speed set by a user, sucks the samples in the detection groove 81 back to the sampling needle 42 of the dispenser 4, thereby completing one detection cycle, and repeating a plurality of detection cycles according to the user setting to complete one sample detection. During the process, the signal changes of SPR optical sensor 84 are recorded for estimating the observed reaction kinetics. The hydraulic transmission function of the buffer solution avoids the volume error generated by air compression in the pushing process.

After one sample test is completed, all samples should be in the sampling needle 42 of the dispenser 4, the mechanical arm moves to the sample storage area 6, the continuous flow pump 3 pumps the liquid towards the dispenser 4, and the tested samples are recovered to the original taken position. This step is skipped if no sample recovery is required.

The multi-path selection valve 2 is connected with buffer solution set by a user, and the continuous flow pump 3 pumps the liquid to the direction of the liquid separator 4 to observe the dissociation section of the reaction process.

The continuous flow pump 3 switches the multi-path selection valve 2 according to the volume set and calculated by a user in the process of pumping liquid to the direction of the liquid separator 4, so that continuous conveying of different functional liquids to the surface of the SPR optical sensor 84 is realized, and functions such as surface regeneration of the SPR optical sensor 84 are realized.

The above description is only of the preferred embodiments of the present utility model and is not intended to limit the present utility model, but various modifications and variations can be made to the present utility model by those skilled in the art. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present utility model are included in the protection scope of the present utility model.

Claims (11)

1. The surface plasmon resonance imaging detection system is characterized by comprising a liquid storage area, a multi-path selection valve, a continuous flow pump, a liquid distributor, a mechanical arm, a sample storage area, an overflow cleaning area and an optical detection area;

the multiple selectable interfaces of the multi-way selection valve are connected with the liquid storage area, the public interface of the multi-way selection valve is connected with the continuous flow pump, one side of the continuous flow pump is connected with the liquid separator, and the liquid separator is connected with one end of the mechanical arm;

the sample storage area, the overflow cleaning area and the optical detection area are arranged on one side of the mechanical arm.

2. The surface plasmon resonance imaging detection system of claim 1 wherein the reservoir comprises a plurality of receptacles, the plurality of receptacles being independent of one another.

3. The surface plasmon resonance imaging detection system of claim 1 wherein the continuous flow pump comprises two fluid ports, one coupled with the multiplexing valve and the other coupled with the dispenser.

4. The surface plasmon resonance imaging detection system of claim 1, wherein the dispenser comprises a dispenser body and a plurality of sampling needles, the upper portion of the dispenser body being connected with the continuous flow pump, the lower portion of the dispenser body being connected with the sampling needles.

5. The surface plasmon resonance imaging detection system of claim 4 wherein the sampling needle is a long tube type structure.

6. The surface plasmon resonance imaging detection system of claim 1 wherein the overflow wash zone comprises a plurality of wash tanks.

7. The surface plasmon resonance imaging detection system of claim 6 wherein the wash tank is a blind hole.

8. The surface plasmon resonance imaging detection system of claim 1, wherein the optical detection zone comprises a detection groove partition plate, a detection chip and an SPR optical sensor, the bottom of the detection groove partition plate is attached to the detection chip, and the SPR optical sensor is arranged below the detection chip.

9. The surface plasmon resonance imaging detection system of claim 8 wherein a detection groove is formed between a plurality of detection groove partitions.

10. The surface plasmon resonance imaging detection system of claim 1 wherein the SPR optical sensor comprises a prism, an imaging device and a light source, wherein the prism is disposed below the detection chip, the imaging device is disposed on one side of the prism, and the light source is disposed on the other side of the prism.

11. The surface plasmon resonance imaging detection system of claim 1, wherein overflow collectors are disposed above both the overflow wash zone and the optical detection zone.