KR102393593B1 - Fluorescence reader for measuring immunoassay strip - Google Patents

Abstract

The present invention has a simple structure, so it can be manufactured in a compact size, and it is possible to acquire fluorescence image information obtained in a two-dimensional area of the result window area of an immunodiagnostic strip or LFA strip and analyze it to effectively analyze the results of a diagnostic sensor. An object of the present invention is to provide a fluorescent reader for measuring a diagnostic strip.
In order to achieve the above object, the present invention provides a fluorescence reader for measuring an in vitro diagnostic strip for measuring the fluorescence characteristics of the in vitro diagnostic strip, comprising: a body having a space formed therein; a camera module inserted into and coupled to the upper part of the body; a light source module located inside the upper end of the body; a processor configured to be separated from the body and electrically connected to the camera module; and an in vitro diagnostic strip inserted into the body, wherein the light source module excites light to the in vitro diagnostic strip, the camera module captures fluorescence excited by the excitation light and outputs a signal, and the photographing signal is processed by the processor.

Description

Fluorescence reader for measuring immunoassay strip

The present invention relates to a fluorescent reader for measuring in vitro diagnostic strips, and more particularly, to a fluorescent reader for measuring in vitro diagnostic strips that can be implemented in a compact size.

A device for examining or examining the presence of a single or multiple substances in a liquid sample, for example, a urine or blood sample, is referred to as a diagnostic kit. Specifically, the modern diagnostic business field is being integrated into one point-of-care testing (POCT). Point-of-care inspection (POCT) refers to equipment that can be used by the general public without specialized knowledge as an inspection performed outside of a centralized laboratory. Currently, the diagnostic field is expanding from hospitals to on-site and personal areas.

In particular, rapid diagnostic kits, represented by immunochromatographic analysis, are used to identify diseases or identify changes in the health and medical field, and qualitatively and quantitatively test trace analytes in various fields such as food and biological processing fields and environmental fields. It is developed in a simple way. In the health care field, the scope of application is expanding, such as pregnancy, ovulation, infectious diseases, drug abuse, acute myocardial infarction, and cancer.

One of the diagnostic kits described above includes the LFA-type diagnostic strip disclosed in Korean Patent Publication No. 2015-0053386.

The diagnostic strip disclosed in the patent includes an elongated rectangular support made of an adhesive plastic material, and a sample pad, a conjugate pad, a signal detecting pad, and an absorption pad, which are disposed approximately sequentially from one side to the other on the support. made including

Here, the detection antibody polymerized with the labeling material is accumulated in a dry state on the conjugation pad in advance, and when the sample moves through the sample pad to the conjugate pad, the conjugate is dissolved and reacts with the analyte in the liquid phase. Such a reaction occurs when the sample solution moves according to the fluid flow caused by capillary action, and an immune binder is formed between the conjugate and the analyte (antigen) by sandwich bonding. This immune conjugate moves to the signal detection pad on the top of the membrane and is captured by the immobilized capture antibody that reacts specifically with the analyte, causing a reaction proportional to the analyte concentration. Depending on the degree of such a reaction, the color of the reaction region existing in the signal detection pad is changed, and the user diagnoses by checking the change in color as described above. The change in color may be visually recognized or the magnitude of the fluorescence signal generated in proportion to the degree of the reaction may be measured with a camera or the like. The analyte that has passed through the reaction region passes through the control region to confirm that a normal lateral flow assay (LFA) has been performed, and the analyte is absorbed into the absorbent pad.

In particular, the strip disclosed in this patent induces an electrochemical reaction using an electrochemical luminescent material and an inculator or luminescence inducing material reacting thereto, and then optically measures the light generated by the electrochemical reaction. It is proposed to perform diagnosis in the form of

The reader has the advantage of being able to measure various characteristics of the strip, but has a structurally complicated disadvantage including the transport device.

The present invention has been devised to overcome the disadvantages of the prior art as described above. It has a simple structure and can be manufactured in a compact size, and obtains fluorescence image information obtained in a two-dimensional area of the result window area of an immunodiagnostic strip or LFA strip. An object of the present invention is to provide a fluorescence reader for in vitro diagnostic strip measurement that can effectively analyze the result of a diagnostic sensor by analyzing it.

In order to achieve the above object, the present invention provides a fluorescence reader for measuring an in vitro diagnostic strip for measuring fluorescence characteristics of the in vitro diagnostic strip, comprising: a body having a space formed therein; a camera module inserted into and coupled to the upper part of the body; a light source module located inside the upper end of the body; a processor configured to be separated from the body and electrically connected to the camera module; and an in vitro diagnostic strip inserted into the body, wherein the light source module excites light to the in vitro diagnostic strip, the camera module captures fluorescence excited by the excitation light and outputs a signal, and the photographing signal is processed by the processor.

Preferably, the camera module comprises: a camera casing; BPF disposed on the inlet side of the casing; a first lens group disposed on the BPF; an imaging device disposed on an upper end of the first lens group; and a connection part formed on the camera casing.

More preferably, it characterized in that it further comprises a second lens group disposed on the upper end of the first lens group and a diaphragm disposed on the upper end of the second lens group.

Preferably, the light source module is characterized in that the plurality of LEDs disposed around the camera module inside the upper end of the body.

More preferably, the LEDs are plural, and the brightness is overlapped so that the intensity of the light source in the result window area is constant.

Preferably, the upper end of the body is characterized in that it further comprises a horizontal module for alarming by sensing the level of the body.

Preferably, the electrical connection to the processor by the connection unit is a ground line, a power line, a switch line for LED operation, a trigger line for controlling the operation of the imaging device, and a data line for transmitting image information output from the imaging device It is characterized in that it includes.

The fluorescent reader for in vitro diagnostic strip measurement according to the present invention is characterized in that a reader body including a camera module and a processor for processing information on the camera module are separately configured, and the body and the processor are only electrically connected, so that the main body is compact. It has a manufacturable effect. In addition, since it is configured to include a plurality of lens groups, it is possible to obtain a high-resolution video image, so that high-resolution and quick operation can be performed.

1 is a block diagram of a fluorescent reader according to the present invention;
Figure 2 is a block diagram of the strip shown in Figure 1,
Figure 3 is a block diagram of the body shown in Figure 1,
Figure 4 is a cross-sectional view of the camera module shown in Figure 1,
5 is a block diagram of the light source module shown in FIG. 1;
Figure 6 is a plan view of Figure 5,
7 is a block diagram of the horizontal module shown in FIG.

Hereinafter, preferred embodiments according to the present invention will be described in detail with reference to the accompanying drawings.

As shown in FIG. 1 , the fluorescent reader 100 according to the present invention includes a base plate 10 , a body 20 seated on the base plate 10 , and a camera module 40 installed on the body 20 . ), a light source module 60 disposed inside the body 20 , and a processor 90 for processing a signal output from the camera module 40 .

The fluorescence reader 100 is configured to detect the fluorescence characteristics of the strip 100 in a state in which the strip 200 shown in FIG. 2 is inserted.

Here, the strip 200 is an immunodiagnostic sheet strip, specifically, a strip in the form of an immunodiagnostic chip, such as a microchannel, in addition to the LFA strip.

And externally, the casing 210 of a rectangular parallelepiped having a low height, the inlet 220 for putting a liquid sample in the upper part of the casing 210, and the result window 230 in which the inputted sample is diffused and then the reaction with the internal material appears. is comprised of

On the other hand, the base plate 10 of the fluorescent reader 100 is configured in the form of a flat plate, coupled to the lower end of the body 20 serves to support the body (20).

Grooves to which the body 20 can be coupled are formed at the upper end, and can be implemented in any coupling structure capable of coupling with the body 20 .

And the body 20 is configured to include a container part 21 and a cover part 27, as shown in FIG. 3, and the container part 21 has a relatively narrow lower end 22 in a box shape. ) and the lower end 22, while positioned at the upper end, is configured to include a box-shaped upper end 23 having a relatively large width.

If necessary, the container part 21 can be implemented in a simple rectangular box shape without distinction between the upper part 23 and the lower part 22 .

On the other hand, an insertion hole 24 into which the strip 200 is inserted is formed on the side surface of the body 20 , and a guide 25 for guiding the arrangement of the strip 200 is formed inside the insertion hole 24 .

The guide 25 is composed of a 'C'-shaped sidewall in contact with three sides of the strip 200, and guides the strip 200 so that it is always disposed at the same position.

A cover part 27 is coupled to the upper end of the container part 21 and serves to close the space inside the container part 21 .

In addition, the camera module 40 and the light source module 60, which are main components for detecting the fluorescence characteristics of the inserted strip 200, are mounted on the cover part 27 .

As shown in FIG. 4 , the camera module 40 is mounted through the cover part 27 , and includes a camera casing 41 , a band pass filter (BPF) 42 , a first lens group 43 , and a first lens group 43 . It is configured to include a two-lens group 44 , an aperture 45 , an image pickup device 46 , and a connection unit 47 .

The camera casing 41 may be manufactured in various shapes as a configuration for fixing and protecting components disposed therein.

In addition, if necessary, the second lens group 44 and the diaphragm 45 may be omitted and implemented using only a single lens group.

It is preferable that the lens groups 43 and 44 have optical axes coincident with each other, and the optical axes are arranged to coincide with the center of the result window 230 in the strip 200 .

In particular, the fluorescence reader 100 according to the present invention is configured to detect fluorescence characteristics emitted from the strip 200 by excitation light. Since it is a configuration that measures only the brightness of fluorescence even if some of the focus is out of focus, it can be implemented with a single lens group. Since image distortion can be corrected, high measurement quality is possible.

A CCD or CMOS type device is used as the imaging device 46 , and an image signal obtained through the imaging device is output to the outside through the connection unit 47 .

In addition, the imaging device 46 starts photographing through a separate control line, obtains a fluorescent image signal through exposure time control, and is output to the outside through the connection unit 47 .

The diaphragm 45 may be configured as a manual type, but when configured as an automatic type in which an iris value is adjusted through a separate control line, the control line is connected to the outside through a connection part 47 .

On the other hand, the light source module 60 is disposed on the outer part of the camera module 40 in the cover part 27 .

As shown in FIG. 5 , the light source module 60 includes a plurality of LEDs 61 arranged so that the light source faces the result window 230 without interference in the optical axis of the camera module 40 . is composed

Here, as shown in FIG. 6 , a plurality of the LEDs 61 are preferably arranged in each direction with the camera module 40 as the center, and if necessary, they are arranged horizontally or vertically so that the brightness signal due to overlap is made uniform. It can be implemented so that

Power of the LED 61 is supplied through the connection part 47 .

Accordingly, the connection unit 47 requires ground, power, a switch line for LED operation, a trigger line for controlling the operation of the imaging device, and a data line output from the imaging device 46 .

Of course, it is also possible to control the operation of the LED 61 and the start of the operation of the imaging device 46 with one trigger line.

On the other hand, the processor 90 is configured to include a separate cable coupled to the connection part 47 , controls the operation of the entire fluorescent reader 100 , and processes the signal output to the image pickup device 46 , It plays the role of outputting to the screen. The fluorescence response of the strip 200 can be confirmed by the signal processing.

Of course, the operation of the LED 61 is also controlled. That is, the processor 90 supplies all the power required by the fluorescent reader 100 , and also outputs a control signal for operation, and processes the obtained image signal to image it.

The connection part 47 can be implemented in the form of a USB, and can also be implemented as a port for asynchronous communication if necessary.

Meanwhile, as shown in FIG. 7 , the cover part 27 may include a horizontal module 70 .

The horizontal module 70 includes a horizontal sensor 71 , a processing unit 72 , and an alarm unit 73 .

In general, the strip 200 should be horizontally arranged for a uniform reaction. At this time, if the fluorescence processor 100 is not horizontally arranged, there is a risk of a measurement error. Therefore, in the horizontal module 70 , when the value of the horizontal sensor 71 is out of a certain range, the processing unit 72 sends the alarm unit. (73) is operated to generate an alarm. In this case, the alarm unit 73 may be an LED or a sound output device.

In addition, the horizontal module 70 is configured to operate using the power supplied through the connection part (47).

On the other hand, the present invention synchronizes the operation of the camera module 40 and the operation of the light source module 60 to measure only the fluorescence signal after the light source signal is turned off by controlling fluorescence through time-resolved fluorescence measurement (TRF) control. It can be driven in such a way as to improve the measurement sensitivity.

In addition, when the overall magnification is adjusted by the combination of the lens groups 43 and 44, a fluorescence image result that can be optimized for the size of the two-dimensional area region that needs analysis displayed in the result window 230 of the strip 200 is obtained. And it has the advantage of being able to analyze it effectively.

That is, in the present invention, even in the case of the strip 200 including the result window 230 of a narrow area, the present invention uses a plurality of lens groups 43 and 44 to optically enlarge the image, so that a high-resolution fluorescence image is obtained. can be obtained, and since the obtained high-resolution fluorescence image is used, high-resolution analysis is possible.

In the above, the present invention has been illustrated and described with respect to specific preferred embodiments, but the present invention is not limited to these embodiments, and those of ordinary skill in the art to which the present invention pertains in the claims. It includes all of the various types of embodiments that can be implemented within the scope that does not depart from the technical spirit.

10: base plate 20: body
21: container part 22: lower part
23: upper part 24: insertion hole
25: guide 27: cover part
40: camera module 41: casing
42: BPF 43: first lens group
44: second lens group 45: aperture
46: image pickup device 47: connector
60: light source module 61: LED
70: horizontal module 71: horizontal sensor
72: processing unit 73: alarm unit
90: processor 100: fluorescence reader
200: strip 210: casing
220: inlet 230: result window

Claims (7)

A fluorescence reader for measuring an in vitro diagnostic strip for measuring the fluorescence characteristic of the in vitro diagnostic strip,
a body including a container part having a space formed therein, and a cover part coupled to an upper end of the container part;
a camera module inserted into and coupled to the upper end of the body through the cover portion of the body;
a light source module located inside the upper end of the body;
a processor configured to be separated from the body and electrically connected to the camera module; and
an in vitro diagnostic strip inserted into the body;
the light source module excites light to the in vitro diagnostic strip, the camera module captures fluorescence excited by the excitation light to output a signal, and the processor processes the captured signal;
The light source module includes a plurality of LEDs disposed in a circumferential direction of an area in which the camera module is disposed in the cover part of the body,
The plurality of LEDs overlap the brightness so that the intensity of the light source is constant in the result window area,
The body includes an insertion hole through which the in vitro diagnostic strip is inserted on a side surface of the lower end;
The inside of the insertion hole includes a guide for guiding the arrangement by contacting three sides of the in vitro diagnostic strip. The method according to claim 1, wherein the camera module comprises:
camera casing;
BPF (Band Pass Filter) disposed on the inlet side of the casing;
a first lens group disposed on the BPF;
an imaging device disposed on an upper end of the first lens group; and
A fluorescence reader for measuring an in vitro diagnostic strip, characterized in that it includes a connection part formed on the camera casing.
The fluorescence reader for measuring an in vitro diagnostic strip according to claim 2, further comprising a second lens group disposed on an upper end of the first lens group and an iris disposed on an upper end of the second lens group.
delete delete The fluorescence reader for measuring an in vitro diagnostic strip according to claim 1, further comprising a horizontal module at the upper end of the body for detecting and alarming the level of the body.
The method according to claim 2, wherein the electrical connection to the processor by the connection unit is a ground line, a power line, a switch line for LED operation, a trigger line for controlling the operation of the image pickup device, and data for transmitting image information output from the image pickup device Fluorescent reader for in vitro diagnostic strip measurement, characterized in that it includes a line.

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