KR20230171671A - Micro Plate Reader with Mixer - Google Patents

Abstract

As microplate readers become automated and robotic, large amounts of samples are stored in loading containers and measured automatically. Various measurement techniques are used for measurement, with fluorescence and spectroscopy as the basic measurement methods. However, when stacked in the loading container for such a long period of time, even if the loading container is moved and shaken, the biomaterial to be measured may adhere to the wall of the microplate and measurement may not be possible, or the signal may not be output accurately, which is a problem. there is. The invention of this application is to solve this problem,
light source; and a light source wavelength selection filter for selecting light used to generate fluorescence among the light from the light source. and an optical splitter that transmits the light passing through the light source wavelength selection filter to the microplate. and a measurement light filter for selecting and measuring only fluorescence of a selected wavelength among the fluorescence when the sample in the microplate reacts with the light distributed from the optical splitter to generate fluorescence. And a microplate reader equipped with a fluorescence detector 1 for quantifying the amount of components contained in the sample by measuring the intensity of fluorescence passing through the measurement light filter, a microplate that generates fluorescence by reacting with the light. A mixing function is provided to prevent the measurement signal from being reduced or not measured due to the sample being attached to the wall of the sample well of the microplate by installing an ultrasonic oscillator at the bottom of the position and operating the ultrasonic oscillator before and during measurement. A microplate reader is provided.
By the above-mentioned configuration of the invention of the present application, even when measuring a sample on a microplate containing a sample stored in a microplate container for a long period of time, it is prevented from normal measurement due to the sample being attached to the wall or bottom of the microplate. There is an effect.

Description

Micro plate reader with mixing function {Micro Plate Reader with Mixer}

The present application relates to a microplate reader. More specifically, the goal is to solve the problem of poor measurement due to the material being measured being fixed to the wall of the microplate during measurement.

A microplate reader has been disclosed as prior art prior to the application of the present invention. The microplate reader of this technology has a light transmitting part placed on one side of the microplate and corresponding to one well of the microplate, and a light transmitting part placed on the opposite side of the light transmitting part across the microplate and corresponding to one well of the microplate. It is characterized by comprising a light receiving unit and a plurality of light receiving paths disposed between the light receiving unit and the microplate and guiding the light emitted from the light transmitting unit and passing through the sample received in the well to the light receiving unit.

Another prior art discloses a method and system for fluorescence detection. This technology targets multiplexed fluorescence detection, including time-resolved fluorescence (TRF) detection. The combination of spectral and temporal differences in fluorescence emission and spectral differences here is used to enhance the ability to separate signals in assays from multiple fluorescent labels. Other classes of labels can be used, including upconversion phosphors and lanthanide chelates and transition metal chelates. The method can be implemented with optical plate readers, including cartridge-based multi-mode readers.

Japanese Patent Publication No. 6807071 Japanese Patent Publication No. 7038158

In the present invention, the microplate reader is automated and robotized, storing a large amount of samples in a loading container and automatically measuring them. Various measurement techniques are used for measurement, with fluorescence and spectroscopy as the basic measurement methods. However, when stacked in the loading container for such a long period of time, even if the loading container is moved and shaken, the biomaterial to be measured may adhere to the wall of the microplate and measurement may not be possible, or the signal may not be output accurately, which is a problem. It is becoming. The invention of this application seeks to solve this problem.

In order to solve the above problems,

light source; and

a light source wavelength selection filter for selecting light used to generate fluorescence among the light from the light source; and

An optical splitter that transmits the light passing through the light source wavelength selection filter to the microplate; and

When the sample in the microplate reacts with the light distributed from the optical splitter to generate fluorescence, a measurement light filter for selecting and measuring only fluorescence of a selected wavelength among the fluorescence; and

In the microplate reader equipped with a fluorescence detector 1 for quantifying the amount of components contained in the sample by measuring the intensity of fluorescence passing through the measurement light filter,

An ultrasonic oscillator is provided at the bottom of the microplate position that reacts with the light and generates fluorescence. By operating the ultrasonic oscillator before and during measurement, the sample is attached to the wall of the sample well of the microplate, resulting in a small measurement signal or no measurement. We provide a microplate reader with a mixing function that prevents mixing.

In addition, a microplate reader with a mixing function is provided, characterized in that a microplate container loaded with samples for measurement is further provided inside or outside one side of the microplate reader with a mixing function.

In addition, a microplate reader with a mixing function is provided, which prevents deterioration of the microplate samples by supplying a microplate cover from a microplate feeder to the microplate coming out of the microplate container.

In addition, the microplate container is provided with a microplate reader with a mixing function, which continuously supplies carbon dioxide and/or nitrogen gas to create an environment in which the sample does not deteriorate.

Due to the configuration of the invention as described above, the present application prevents normal measurement from occurring due to the sample being attached to the wall or bottom of the microplate when measuring a sample on a microplate containing a sample stored in a microflake container for a long period of time. It works.

1 is a microplate reader before the application of the present invention.
Figure 2 is a microplate reader with a mixing function according to the invention of the present application.
Figure 3 shows an ultrasonic vibrator and a fine-toothed rail for transferring microplates to a microplate reader with a mixing function according to the invention of this application.

The effects of the invention of this application are explained using the drawings as follows.

Figure 1 shows a microplate reader before the application of the present invention.

A dichroic optical splitter is used to send light generated from a light source to the microplate reader through an optical filter that selects the light for measurement. The light incident on the sample causes fluorescence depending on the type of material contained in the sample. The wavelength of light generated at this time differs depending on the type of material, so different measurement light filters are used depending on the material to be measured, and the light that passes through the measurement light filter is detected by a detector and detects the light contained in the sample. Measure the amount of substance.

In addition, if necessary, polarized light from the light source is supplied to the sample to generate polarized fluorescence. If this is measured with two different detectors at 90-degree angles, signals that vary depending on the protein structure can be obtained. This is shown in Figure 1.

Figure 2 shows a microplate reader with a mixing function according to the invention of this application. When microplate samples are loaded into a microplate container and measured sequentially, the measurement substance may become fixed to the wall or side of the microplate and lose its activity. To prevent this problem, measurement accuracy can be further improved by applying ultrasonic vibration from the bottom of the microplate before and during measurement to vibrate the microplate and separate the substances stuck to the wall and bottom of the microplate.

Figure 3 shows an ultrasonic vibrator and a fine-toothed rail for transferring microplates to a microplate reader with a mixing function according to the invention of this application. The fine-toothed rail is configured asymmetrically to move in the forward direction, and an ultrasonic vibrator (not shown) is provided on the lower surface where the rail is fixed, so that the microplate placed on the rail can be transferred by applying vibration to the rail. The microplate may be moved forward and backward by providing an additional rail in the opposite shape of the asymmetrical fine teeth and controlling its contact with the microplate. By moving the microplate back and forth using the ultrasonic vibration method described above, the sample inside the microplate is also vibrated along with the transfer of the microplate, so that the measurement target material in the sample becomes inactive during measurement and does not affect the measurement. is also performed together.

The composition of the invention to achieve the effects of the invention as described above is as follows.

light source; and

a light source wavelength selection filter for selecting light used to generate fluorescence among the light from the light source; and

An optical splitter that transmits the light passing through the light source wavelength selection filter to the microplate; and

When the sample in the microplate reacts with the light distributed from the optical splitter to generate fluorescence, a measurement light filter for selecting and measuring only fluorescence of a selected wavelength among the fluorescence; and

In the microplate reader equipped with a fluorescence detector 1 for quantifying the amount of components contained in the sample by measuring the intensity of fluorescence passing through the measurement light filter,

An ultrasonic oscillator is provided at the bottom of the microplate position that reacts with the light and generates fluorescence. By operating the ultrasonic oscillator before and during measurement, the sample is attached to the wall of the sample well of the microplate, resulting in a small measurement signal or no measurement. We provide a micro plate reader with a mixing function that prevents mixing.

In addition, a microplate reader with a mixing function is provided, characterized in that a microplate container loaded with samples for measurement is further provided inside or outside one side of the microplate reader with a mixing function.

In addition, a microplate reader with a mixing function is provided, which prevents deterioration of the microplate samples by supplying a microplate cover from a microplate feeder to the microplate coming out of the microplate container.

In addition, the microplate container is provided with a microplate reader with a mixing function, which continuously supplies carbon dioxide and/or nitrogen gas to create an environment in which the sample does not deteriorate.

50: Microplate
60: Microplate cover
100: Microplate reader with mixing function
110: light source
120: optical filter
130: optical splitter
140: Measurement light filter
150: Fluorescence detector 1
200: polarizer
210: Polarization splitter
220: Polarizer for fluorescence detector 1
230: Polarizer for fluorescence detector 2
240: Fluorescence detector 2
300: Microplate container
310: Microplate feeder
320: Microplate vibrator
400: Ultrasonic vibrator for mixing

Claims (4)

light source; and
a light source wavelength selection filter for selecting light used to generate fluorescence among the light from the light source; and
An optical splitter that transmits the light passing through the light source wavelength selection filter to the microplate; and
When the sample in the microplate reacts with the light distributed from the optical splitter to generate fluorescence, a measurement light filter for selecting and measuring only fluorescence of a selected wavelength among the fluorescence; and
In the microplate reader equipped with a fluorescence detector 1 for quantifying the amount of components contained in the sample by measuring the intensity of fluorescence passing through the measurement light filter,
An ultrasonic oscillator is provided at the bottom of the microplate position that reacts with the light and generates fluorescence. By operating the ultrasonic oscillator before and during measurement, the sample is attached to the wall of the sample well of the microplate, resulting in a small measurement signal or no measurement. A microplate reader with a mixing function that prevents spoilage. According to paragraph 1,
A microplate reader with a mixing function, characterized in that a microplate container loaded with samples for measurement is further provided inside or outside one side of the microplate reader with a mixing function. According to paragraph 2,
A microplate reader with a mixing function, characterized in that a microplate cover is supplied from a microplate feeder to the microplate coming out of the microplate container to prevent deterioration of the microplate sample. According to paragraph 3,
A microplate reader with a mixing function, characterized in that carbon dioxide and/or nitrogen gas, etc. are continuously supplied to the microplate container to create an environment in which the sample does not deteriorate.