KR102522512B1 - filter-wheel free multi-wavelength fluorescence simultaneous detection system using a time-division light source device and a space-division imaging sensor - Google Patents

Abstract

A filter-wheel-free multi-wavelength fluorescence simultaneous detection system using a time-division light source device and a space-division imaging sensor includes a multi-wavelength light source unit, a focusing optic unit, a space division unit, and an imaging optic unit. The multi-wavelength light source unit outputs light of different wavelengths, the focusing optical unit focuses the light of different wavelengths and transmits them to the same fluorescence area, and the spatial dividing unit spatially divides the fluorescence transmitted from the fluorescence area according to the wavelength area, The imaging optical unit separates and outputs the spatially divided fluorescence from each other. According to this configuration, since light sources of different wavelengths are irradiated to the same fluorescence area, and the detected fluorescence is spatially divided and imaged in different areas, the volume and cost of the device are reduced, while fluorescence of multiple wavelengths is simultaneously emitted. be able to detect.

Description

Filter-wheel free multi-wavelength fluorescence simultaneous detection system using a time-division light source device and a space-division imaging sensor}

The present invention relates to a technique related to the simultaneous detection of multi-wavelength fluorescence, and more particularly, in measuring fluorescence generated from biochemicals, various types of fluorescence can be smoothly measured, and at the same time, miniaturization of the device and improvement in economic feasibility can be achieved. It relates to a multi-wavelength fluorescence detection system that enables

In order to measure fluorescence generated from biochemical substances, first, excitation light is provided to give energy to the fluorescent substances. Since there are separate wavelength bands of excitation light with high excitation efficiency for various fluorescent materials, in order to smoothly measure a specific fluorescent material, excitation of a wavelength range suitable for the fluorescent material is maximized to maximize the amount of fluorescence generated by the fluorescent material. light will be used.

According to this principle, several types of excitation light are used for multiple fluorescence detection, and these excitation lights should not affect each other in fluorescence detection. Therefore, the multi-channel fluorescence measurement system is formed to supply excitation light of different wavelength bands suitable for various types of fluorescent materials for each fluorescent material.

In order to realize such a function, a white light source containing light of all wavelength bands is usually used as a basic light source, but a plurality of band-pass filters that selectively pass only light of the wavelength range suitable for each fluorescent material are installed on the filter wheel. Then, by rotating the filter wheel, a band pass filter suitable for the fluorescent substance to be measured is selected to generate excitation light.

In addition, in the case of a light receiving unit that detects fluorescence, a plurality of band pass filters that pass only specific wavelengths are installed on the filter wheel, and the filter wheel is rotated to select a band pass filter suitable for the fluorescence substance to be detected to measure the amount of fluorescence. do. In this process, a dichroic beam splitter is typically used to minimize background interference caused by excitation light.

However, a conventional fluorescence detection device requires a measurement channel including a band pass filter, a dichroic beam splitter, a light source, and a light receiving sensor in order to detect fluorescence in a specific wavelength range. Channels are required, which unduly increases device volume and cost.

In addition, in order to measure the fluorescence of different wavelength bands, it is necessary to perform measurement with one measurement channel optimized for a specific wavelength band, move it to another measurement channel optimized for another specific wavelength band, and measure again. This process In addition, the risk of measurement error due to the difference in the degree of response according to the time delay also increases.

KR 101953864 B1

The present invention has been made to solve the above-mentioned conventional problems, and an object of the present invention is to provide a system capable of simultaneously detecting fluorescence of multiple wavelengths while reducing the volume and cost of the device.

To achieve the above object, a multi-wavelength fluorescence simultaneous detection system according to the present invention includes a multi-wavelength light source unit, a focusing optical unit, a spatial division unit, and an imaging optical unit. The multi-wavelength light source unit outputs light of different wavelengths, the focusing optical unit focuses the light of different wavelengths and transmits them to the same fluorescence area, and the spatial dividing unit spatially divides the fluorescence transmitted from the fluorescence area according to the wavelength area, The imaging optical unit separates and outputs the spatially divided fluorescence from each other.

According to this configuration, since light sources of different wavelengths are irradiated to the same fluorescence area, and the detected fluorescence is spatially divided and imaged in different areas, the volume and cost of the device are reduced, while fluorescence of multiple wavelengths is simultaneously emitted. be able to detect.

In this case, the image sensor unit may further include an image sensor unit configured to detect the light transmitted from the imaging optical unit in different regions according to wavelength regions. According to this configuration, it is possible to distinguish a wavelength region according to a physical region detected by the image sensor unit.

In addition, an image processing unit may further include processing data detected by the image sensor unit according to preset regions. According to this configuration, it is possible to perform image processing that is separated and distinguished for each wavelength region.

In addition, it may include a light source control unit that performs frequency and time division control of light from the multi-wavelength light source unit. According to this configuration, it is possible to secure various fluorescent images by controlling the frequency and time division of a plurality of outputable lights.

In addition, the image analysis unit may further include an image analysis unit that analyzes the images processed by the image processing unit according to preset regions. According to this configuration, it is possible to analyze images using images obtained for different wavelengths.

In addition, it may further include an image output unit for outputting a combination or synthesis of each processed image according to a preset region. According to this configuration, it is possible to secure a more effective video by changing the shape of the video output as needed.

In addition, the multi-wavelength light source unit may include a plurality of white light sources and filters of different wavelength regions respectively corresponding to the white light sources, and may include a plurality of light sources of different wavelength regions.

According to the present invention, since light sources of different wavelengths are irradiated to the same fluorescence area, and the detected fluorescence is spatially divided and imaged in different areas, the volume and cost of the device are reduced, while fluorescence of multiple wavelengths is simultaneously detected. You can do it.

In addition, a wavelength region can be distinguished according to a physical region detected by the image sensor unit.

In addition, it is possible to perform image processing that is divided by wavelength region.

In addition, by controlling the frequency and time division of a plurality of outputable lights, it is possible to secure various fluorescence images.

In addition, it is possible to analyze images using images obtained for different wavelengths.

In addition, it is possible to secure a more effective image by changing the shape of the image output as needed.

1 is a schematic block diagram of a filter-wheel-free multi-wavelength fluorescence simultaneous detection system using a time-division light source device and a space-division imaging sensor according to an embodiment of the present invention.
2 is a view showing a state of use of the simultaneous multi-wavelength fluorescence detection system of FIG. 1;
3 and 4 are diagrams illustrating an actual implementation example of the multi-wavelength light source unit 110 shown in FIG. 2 .
5 is a diagram illustrating a spatial division multiplexing module of a spatial division unit;
FIG. 6 is a diagram separately illustrating each side of the spatial division multiplexing module of FIG. 5;
FIG. 7 is a view for explaining a detection process performed in the filter-wheel-free multi-wavelength fluorescence simultaneous detection system using the time-division light source device and the space-division imaging sensor of FIG. 1;

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

1 is a schematic block diagram of a filter-wheel free multi-wavelength fluorescence simultaneous detection system using a time-division light source device and a space-division imaging sensor according to an embodiment of the present invention, and FIG. 2 is a multi-wavelength fluorescence simultaneous detection system of FIG. 1 It is a drawing showing the state of use of

1, the multi-wavelength fluorescence simultaneous detection system includes a multi-wavelength light source unit 110, a focusing optical unit 120, a spatial division unit 130, an imaging optical unit 140, an image sensor unit 150, and an image processing unit 160. ), a light source controller 170, an image analysis unit 180, and an image output unit 190.

The multi-wavelength light source unit 110 outputs light of different wavelengths. In this case, the multi-wavelength light source unit 110 may include a plurality of white light sources and filters of different wavelength regions respectively corresponding to the white light sources, or may include a plurality of light sources of different wavelength regions.

3 and 4 are diagrams illustrating examples of actual implementation of the multi-wavelength light source unit of FIG. 2 . 3 shows an example in which a multi-wavelength light source is implemented using a white light LED and a multi-wavelength filter, and FIG. 4 shows an example in which a multi-wavelength light source is implemented using a multi-wavelength LED. 3 and 4, it can be confirmed that the multi-wavelength light source unit 110 further includes a lens.

The focusing optical unit 120 focuses light of different wavelengths and transfers them to the same fluorescence region, and the space division unit 130 spatially divides the fluorescence transmitted from the fluorescence region according to the wavelength region.

FIG. 5 is a diagram showing a space division multiplexing module of a space division unit, and FIG. 6 is a view showing each side of the space division multiplexing module of FIG. 5 in isolation. As shown in FIG. 5 , the space dividing unit 130 may be manufactured in a modular form and combined in an array form. In addition, as shown in FIG. 6, it can be seen that the light incident through one opening on the side of the light source is divided by wavelength on the image side and output through different openings.

The imaging optical unit 140 separates and outputs the spatially divided fluorescence from each other. According to this configuration, since light sources of different wavelengths are irradiated to the same fluorescence area, and the detected fluorescence is spatially divided and imaged in different areas, the volume and cost of the device are reduced, while fluorescence of multiple wavelengths is simultaneously emitted. be able to detect.

The image sensor unit 150 detects light transmitted from the imaging optical unit 140 in different regions according to wavelength regions. According to this configuration, it is possible to distinguish a wavelength region according to a physical region detected by the image sensor unit.

The image processing unit 160 processes data detected by the image sensor unit 150 according to preset areas. According to this configuration, it is possible to perform image processing that is separated and distinguished for each wavelength region.

The light source controller 170 performs frequency and time division control of light from the multi-wavelength light source unit 110 . According to this configuration, it is possible to secure various fluorescent images by controlling the frequency and time division of a plurality of outputable lights.

The image analyzer 180 analyzes the images processed by the image processor 160 according to preset regions. According to this configuration, it is possible to analyze images using images obtained for different wavelengths.

The image output unit 190 combines or synthesizes processed images according to preset regions and outputs the combined images. According to this configuration, it is possible to secure a more effective video by changing the shape of the video output as needed.

FIG. 7 is a diagram for explaining a detection process performed in the filter-wheel free multi-wavelength fluorescence simultaneous detection system using the time-division light source device and space-division imaging sensor of FIG. 1 .

In FIG. 8, first, a multi-wavelength light source configured in the form of an array and a focusing optical system for transmitting light to a fluorescence excitation area are obtained, and multi-wavelength excitation light is radiated to the same area through time division by wavelength.

Subsequently, the fluorescence signal excited according to the wavelength irradiated from the sample stage passes through a plurality of filters having a two-dimensional structure to make different light paths for each wavelength in the form of an array, and the multi-wavelength fluorescence signal in the array form is space-divided into a camera. is observed

By utilizing this, it is possible to implement a multi-wavelength fluorescence simultaneous detection system without a filter wheel and without a plurality of cameras, and implement a multiplexing small molecule diagnostic device without a filter wheel that can diagnose genetic diseases such as infectious diseases through the use of the present invention. this becomes possible

To this end, the present invention provides an optical device for transmitting excitation light irradiated from a multi-wavelength light source array to the same fluorescence region, time-division software and hardware capable of rapidly controlling the frequency and irradiation of a multi-wavelength light source, a multi-wavelength light source, and a multi-wavelength light source. A plurality of multi-band transmission filters that minimize light interference of a plurality of fluorescent signals emitted in response, and a three-dimensional optical path imaging optical system that separates a plurality of fluorescent signals excited in response to wavelengths by wavelength and forms an image on a camera in the form of an array. , software for analyzing the fluorescence signal for each wavelength that is spatially divided into a camera and imaged, and a microcontroller unit capable of controlling a multi-wavelength light source and an imaging system.

Although the present invention has been described by some preferred embodiments, the scope of the present invention should not be limited thereto, but should also extend to modifications or improvements of the above embodiments supported by the claims.

110: multi-wavelength light source
120: focusing optics
130: space dividing unit
140: imaging optics
150: image sensor unit
160: image processing unit
170: light source control unit
180: image analysis unit
190: video output unit

Claims (8)

a multi-wavelength light source unit outputting light of different wavelengths;
a focusing optical unit for concentrating the different wavelengths of light and passing them to the same fluorescent region;
a spatial divider for spatially dividing the fluorescence image transferred from the fluorescence region according to a wavelength region; and
A multi-wavelength fluorescence simultaneous detection system including an imaging optical unit that separates and outputs the spatially divided fluorescence images from each other,
The multi-wavelength fluorescence simultaneous detection system further comprising an image sensor unit for detecting the images transferred from the imaging optical unit in different position areas of a single image sensor according to a wavelength range.
delete The method of claim 1,
The multi-wavelength fluorescence simultaneous detection system further comprising an image processing unit for processing the data detected by the image sensor unit according to a preset area.
The method of claim 3,
The multi-wavelength fluorescence simultaneous detection system further comprising a light source controller for performing time division control with the frequency of light from the multi-wavelength light source unit.
The method of claim 4,
The multi-wavelength fluorescence simultaneous detection system further comprising an image analyzer for analyzing the image processed by the image processor according to the preset region.
The method of claim 5,
The multi-wavelength fluorescence simultaneous detection system, characterized in that it further comprises an image output unit for outputting a combined or synthesized image processed according to the preset region.
The method of claim 6,
The multi-wavelength fluorescence simultaneous detection system, characterized in that the multi-wavelength light source unit comprises a plurality of white light sources and filters of different wavelength regions respectively corresponding to the white light sources.
The method of claim 6,
The multi-wavelength fluorescence simultaneous detection system, characterized in that the multi-wavelength light source unit includes a plurality of light sources in different wavelength regions.

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