KR102566752B1 - Microplate fluorescence measurement device with improved light source - Google Patents

Abstract

A microplate fluorescence measuring device is a device that measures the type and concentration of a substance by measuring fluorescence generated by selectively irradiating a microplate with light of various wavelengths in order to measure the components of various substances. However, in order to variously select light wavelengths for measurement, many types of filters must be provided and used while replacing them. As shown in FIG. 2, a commonly used method for this purpose is to fix an optical filter to a rotating wheel and select an optical wavelength by rotating the wheel.
The measuring device configured in this way has no problem when used in a stationary place such as a laboratory, but is inevitably vulnerable to vibration and shock when used in a vehicle or ship. The invention of the present application is a concave mirror to solve this problem; and a light source module provided inside the circumference of the concave mirror at regular intervals around the circumference of the concave mirror so that a plurality of single wavelength light sources having different wavelengths may be irradiated in parallel to the concave mirror along the circumference of the circumference of the concave mirror. It consists of, providing a microplate fluorescence measurement device characterized in that to position the light inlet of the optical fiber bundle at the focal point of the concave mirror so that the light of the improved light source at the focal point of the concave mirror can be incident to the optical fiber bundle do.
According to the above configuration of the present invention, a microplate fluorescence measurement device that supplies light of various wavelengths without the configuration of a rotating optical filter wheel provided in the light source unit is provided.

Description

Microplate fluorescence measuring device with improved light source{.}

The present invention relates to a device for measuring the fluorescence characteristics of a material in a microplate well. More specifically, it relates to a complex measuring device that measures all of fluorescence, absorption and phosphorescence.

As a prior art prior to the filing of the present application, an invention related to a fluorescence scanning optical device is disclosed (see FIG. 4). In this technology, light is supplied from the top and bottom of the microplate well and supplied from the material in the microplate well. A technique for measuring fluorescence generated by the light through a filter is disclosed.

As another prior art, a technology related to a light source device for microplates has been disclosed (see FIG. 5). In this technology, each pH, O2 concentration, CO2 concentration, etc. A technology for a light source device that simultaneously radiates uniform light to each well of a microplate to obtain information is disclosed. In this technology, a light source plate having a cavity formed therein and including a plurality of through holes formed in an area corresponding to each well of the microplate, a cap extending into the through hole and widening in the inside direction of the light source plate, and It is a technology that includes a side light source attached to at least one side of the light source plate and uniformizes each light emitted through each of the plurality of through holes.

US Registered Patent Publication US 6,316,774 B1 Republic of Korea Patent Registration No. 10-0942438

The basic structure of the microplate fluorescence meter prior to the invention of the present application is shown in FIG. 4. For fluorescence measurements, an optional optical filter in two parts is required. One is a light source unit, and one is a measurement unit. The light source wavelength selection filter of the light source unit has a well formed on the surface of the microplate, a small groove for loading a sample for measuring a drug or material such as bio or food. In this well, light is irradiated by selecting a wavelength according to the type of material to be measured so that the irradiated light and the material to be measured react to generate fluorescence. In order to measure this, fluorescence of a wavelength band different from the wavelength of the irradiated light is generated. In order to measure only this fluorescence, a measurement light wavelength selection filter is required to block the passage of other light and pass only the light of the wavelength corresponding to the fluorescence to be measured. do.

In order to irradiate and measure light by selecting wavelengths of various materials for various purposes, it is essential to have many types of filters. In order to satisfy this purpose, as shown in FIG. 2, an optical filter is fixed to a rotating wheel to select a wavelength. Although this device has no problem when used in a stationary place such as a laboratory, it is inevitably vulnerable to vibration and shock when used in a vehicle or ship. The present invention is intended to provide a microplate fluorescence measurement device with an improved light source unit capable of selectively providing various lights required for fluorescence measurement without such a rotating optical filter wheel.

In order to solve the above problems, the following problem solving means are provided.

In the microplate fluorescence measurement device,

Improved light source

concave mirror; and

A light source module provided at regular intervals around the circumference of the circumference of the concave mirror to the inside of the circumference of the concave mirror so that a plurality of single wavelength light sources having different wavelengths may be irradiated in parallel to the concave mirror along the circumference of the circumference of the concave mirror consists of

A light inlet of the optical fiber bundle is positioned at the focal point of the concave mirror so that the light of the improved light source can be incident to the optical fiber bundle at the focal point of the concave mirror.

In addition, in the control method of the improved light source using the microplate fluorescence measuring device,

a single wavelength light source selection step of selecting one of a plurality of single wavelength light sources constituting the light source module according to the type of material to be measured; and

a light source operation step of operating the selected single wavelength light source for measurement; and

Provided is an improved light source control method using a microplate fluorescence measuring device, comprising a fluorescence measurement step of measuring fluorescence generated by the operation of the single wavelength light source.

In addition, in the control method of the improved light source using the microplate fluorescence measuring device,

a multi-selection step of selecting two or more single wavelength light sources from among a plurality of single wavelength light sources constituting the light source module according to the type of material to be measured; and

Multi-light source operation step of simultaneously operating a plurality of selected single-wavelength light sources for measurement; and

Provided is an improved light source control method using a microplate fluorescence measuring device, comprising a fluorescence measurement step of measuring fluorescence generated by the operation of the plurality of single wavelength light sources.

In addition, in the control method of the improved light source using the microplate fluorescence measuring device,

a multi-selection step of selecting two or more single wavelength light sources from among a plurality of single wavelength light sources constituting the light source module according to the type of material to be measured; and

a sequential multi-light source operation step of operating the selected plurality of single-wavelength light sources in a set order for measurement; and

Provided is an improved light source control method using a microplate fluorescence measurement device, comprising a fluorescence sequential measurement step of sequentially measuring fluorescence generated sequentially by the sequential operation of the plurality of single wavelength light sources.

The invention of the present application is a microplate fluorescence having the effect of increasing the measurement speed, lowering the failure rate, and lowering the production cost by configuring a single LED light of various wavelengths without the configuration of the rotating optical filter wheel provided in the light source unit according to the above configuration. Provide a measurement reader.

In addition, in the past, only one filter for selecting light from one light source could be used, so only light of a single wavelength passing through the selected filter could be used for fluorescence measurement. By turning on sequentially, instantaneous measurement using light of various wavelengths is possible.

In particular, a new fluorescence measurement method can be developed by using excitation light in multiple steps, from light having a long frequency wavelength to light having a short wavelength frequency.

1 is a conceptual explanatory diagram of a measuring device of a general microplate fluorescence measuring device.
2 is a conceptual diagram illustrating the operation of a conventional rotary wheel filter.
3 is a conceptual diagram of the structure of the improved light source of the present application.
4 is a configuration diagram of a microplate fluorescence measurement device prior to filing of the present invention.
5 is a description of a light source for multi-measurement prior to the filing of the present invention.

The operation and effect of the invention of the present application will be described using drawings as follows.

1 is a conceptual explanatory diagram of a measuring device of a general microplate fluorescence measuring device. Of the light emitted from the light source, only the light required for fluorescence measurement passes through the light source wavelength selection filter that selects the light to irradiate the sample provided in the microplate well, and only the light required for fluorescence measurement passes through the filter and passes through the set optical path. The wells of the microplate with the measurement sample are irradiated. The irradiated light reacts with the measurement sample to generate fluorescence. At this time, since the irradiated light and the light generated from the measurement sample are mixed, an optical filter (light pass filter) is used again in order to measure only the fluorescence generated from the measurement sample in the mixed light. At this time, too, a rotary filter wheel is often used to select light of various wavelengths.

In this way, only the light generated by the fluorescence is passed through, and the amount of light by the fluorescence is measured in a photodiode or PMT sensor to calculate the type and concentration of the substance.

2 is a conceptual diagram illustrating the operation of a conventional rotary wheel filter. The basic concept is the same, although the type and number of optical filters vary depending on the measurement method and object. An optical filter or an optical filter is positioned by rotation on an optical path through which light passes, and an optical filter is selected and placed to be used for measurement.

3 is a conceptual diagram of the configuration of the improved light source of the present application. The principle of this improved light source uses two basic principles. One uses the principle of an optical mirror, and the other is the principle of fluorescence measurement. First of all, explaining the principle of fluorescence measurement, it is necessary to irradiate light that is good for fluorescence from light emitted from a light source, but fluorescence occurs without necessarily irradiating light with a wavelength that matches 100%. Therefore, since there is no need to use exactly matched light as a light source, fluorescence of the material to be measured can be measured by selecting and using a plurality of single lights as the most suitable light source. In addition, since two or more lights can be independently controlled in the present invention, unlike the existing methods, various light irradiation measurement techniques that could not be used in the past can be used by controlling the light sources simultaneously or quickly. .

Second, according to the optical measurement principle, when a concave mirror having a circular curved surface is fixed vertically to the ground, incident light incident horizontally to the ground converges at a focal point of the concave mirror. Therefore, when a plurality of independent lights are installed on the circumferential surface of the concave mirror and the light is horizontally incident on the concave mirror, they all gather at the focal point of the concave mirror.

If the light incident part of the optical fiber bundle (optical fiber bundle) is placed at the focal point, light can be used from the other side of the optical fiber bundle. An improved light source capable of performing the same function as filtering the light emitted from the light source was created by controlling light of different wavelengths located on the circumferential surface of the concave mirror using this property.

4 is a schematic configuration diagram of a microplate fluorescence measurement device prior to filing of the present invention. The principle is that when the light generated from the light source on the upper left is selected and transmitted through the light source wavelength selection filter, the transmitted light is incident on an optical fiber and used for measurement in a microplate or the like to be measured.

5 is a description of a light source for multi-measurement prior to the filing of the present invention. This technique relates to a conventional technique for supplying a side light source to the outside with a constant size of the light source.

The composition of the invention for showing the operational effects of the invention of the present application as described above is as follows.

In the microplate fluorescence measurement device,

Improved light source

concave mirror; and

A light source module provided at regular intervals around the circumference of the circumference of the concave mirror to the inside of the circumference of the concave mirror so that a plurality of single wavelength light sources having different wavelengths may be irradiated in parallel to the concave mirror along the circumference of the circumference of the concave mirror consists of

Provided is a microplate fluorescence measurement device characterized in that the optical entrance of the optical fiber bundle is located at the focal point of the concave mirror so that the light of the improved light source can be incident to the optical fiber bundle at the focal point of the concave mirror.

In addition, in the control method of the improved light source using the microplate fluorescence measuring device,

a single wavelength light source selection step of selecting one of a plurality of single wavelength light sources constituting the light source module according to the type of material to be measured; and

a light source operation step of operating the selected single wavelength light source for measurement; and

Provided is an improved light source control method using a microplate fluorescence measuring device, comprising a fluorescence measurement step of measuring fluorescence generated by the operation of the single wavelength light source.

In addition, in the control method of the improved light source using the microplate fluorescence measuring device,

a multi-selection step of selecting two or more single wavelength light sources from among a plurality of single wavelength light sources constituting the light source module according to the type of material to be measured; and

Multi-light source operation step of simultaneously operating a plurality of selected single-wavelength light sources for measurement; and

Provided is an improved light source control method using a microplate fluorescence measuring device, comprising a fluorescence measurement step of measuring fluorescence generated by the operation of the plurality of single wavelength light sources.

In addition, in the control method of the improved light source using the microplate fluorescence measuring device,

a multi-selection step of selecting two or more single wavelength light sources from among a plurality of single wavelength light sources constituting the light source module according to the type of material to be measured; and

a sequential multi-light source operation step of operating the selected plurality of single-wavelength light sources in a set order for measurement; and

Provided is an improved light source control method using a microplate fluorescence measurement device, comprising a fluorescence sequential measurement step of sequentially measuring fluorescence generated sequentially by the sequential operation of the plurality of single wavelength light sources.

In the present application, an elliptical mirror with chromatic aberration corrected may be used as the concave mirror in order to solve chromatic aberration caused by a difference in light wavelengths of the light sources.

The single-wavelength light source preferably has 70% or more of the energy of the light source concentrated in the central light wavelength, but can be used if it is 50% or more. In addition, a lens for concentrating light may be further mounted on the front end of the single wavelength light source. At this time, the angle of incidence for controlling the chromatic aberration may be adjusted within a range of 1 degree from the horizontal.

100: multi-wavelength optical module
110: single wavelength light source
120: concave lens
130: optical fiber bundle

Claims (4)

concave mirror; and
A light source module provided at regular intervals around the circumference of the circumference of the concave mirror to the inside of the circumference of the concave mirror so that a plurality of single wavelength light sources having different wavelengths may be irradiated in parallel to the concave mirror along the circumference of the circumference of the concave mirror consists of
A lens for concentrating light may be further added to the front end of the single wavelength light source, and an incident angle for controlling chromatic aberration may be adjusted within a range of 1 degree from the horizontal,
Control method of an improved light source using a microplate fluorescence measurement device configured to position the light inlet of the optical fiber bundle at the focal point of the concave mirror so that the light of the improved light source at the focal point of the concave mirror can be incident to the optical fiber bundle in
a single wavelength light source selection step of selecting one of a plurality of single wavelength light sources constituting the light source module according to the type of material to be measured; and
a light source operation step of operating the selected single wavelength light source for measurement; and
An improved light source control method using a microplate fluorescence measuring device, comprising a fluorescence measurement step of measuring fluorescence generated by the operation of the single wavelength light source. delete delete concave mirror; and
A light source module provided at regular intervals around the circumference of the circumference of the concave mirror to the inside of the circumference of the concave mirror so that a plurality of single wavelength light sources having different wavelengths may be irradiated in parallel to the concave mirror along the circumference of the circumference of the concave mirror consists of
A lens for concentrating light may be further added to the front end of the single wavelength light source, and an incident angle for controlling chromatic aberration may be adjusted within a range of 1 degree from the horizontal,
Control method of an improved light source using a microplate fluorescence measurement device configured to position the light inlet of the optical fiber bundle at the focal point of the concave mirror so that the light of the improved light source at the focal point of the concave mirror can be incident to the optical fiber bundle in
a multi-selection step of selecting two or more single wavelength light sources from among a plurality of single wavelength light sources constituting the light source module according to the type of material to be measured; and
Sequential multi-light source operation step of operating the selected plurality of single-wavelength light sources in a set order for measurement; and
An improved light source control method using a microplate fluorescence measuring device, characterized in that it comprises a fluorescence sequential measurement step of sequentially measuring fluorescence generated sequentially by the sequential operation of the plurality of single wavelength light sources.