KR101758145B1 - manufacturing method of micro-beads for bioassay and micro-beads for bioassay thereby - Google Patents

Abstract

The present invention relates to a microparticle for a bioassay, comprising a first step of forming a photosensitive resin layer on a substrate, and a first mold having a positive-angle encoder pattern formed of a photosensitive resin by a mask patterning process, A second step of forming an imprinted resin layer on the first mold and fabricating a master mold having imprinted encoder patterns formed by imprinting by an imprinting process; Forming a droplet by spotting the solution; curing the droplet formed on the master mold; separating the droplet on the master mold to form microparticles having an encoder pattern on the bottom surface; And a fourth step of preparing the microparticles for the bioassay. And a micro particle for a bioassay produced by the method. Accordingly, the present invention provides a microparticle for biosensor in which a probe region and an encoder region are not separated in the same substrate but overlapped by using a mask patterning process, a spotting and an imprinting process, Which enables accurate quantification and recognition of genetic information analysis.

Description

[0001] The present invention relates to a method for producing microparticles for bioassays and microparticles for bioassays,

The present invention relates to microparticles for bioassays, and it is possible to manufacture microparticles for bioassay using a mask patterning process, a spotting process, and an imprinting process. In particular, since a probe region and an encoder region are not separated, The present invention relates to a method for producing microparticles for biosensors capable of real-time PCR and microparticles for biosensors prepared thereby.

Molecular diagnostics system is a next generation convergence technology that covers science, technology, electronics, physics, chemistry, biology, material engineering, IT and NT.

In particular, a biochip, which is one of the typical fields of molecular diagnostic systems, has a structure in which a biomolecule probe such as DNA or protein is attached at high density on a substrate such as glass, silicon or polymer, It is used to detect the hybridization with a substance and to analyze a trace amount of sample at a very high speed.

By analyzing gene information such as gene expression and reaction patterns, gene defects, and protein distribution, it ultimately can be used not only for diagnosis and treatment of human diseases but also for new drug development and reagent diagnosis.

Such a biochip can be divided into a DNA chip or a protein chip depending on the type of probe, and can be divided into a microarray chip attached on a solid substrate and a microfluid chip attached on a microfluidic channel depending on the attachment form of the probe.

Particularly, research on multiplexing analysis technology is actively performed to quantify DNA, RNA, protein, and the like simultaneously using the biochip, and to obtain various information at a low cost by reducing analysis time. In addition, interest in cost reduction through analysis using trace amounts of sample is increasing.

Generally, in order to detect whether hybridization of the probe with a target substance in a sample is selectively hybridized to a detection molecule, a fluorescence substance for obtaining a directly measurable signal, a radioactive A substance, a magnetic particle, or the like.

However, since these labeling materials are generally expensive, researchers' attention to cost reduction through trace analysis has focused on multiple analytical techniques capable of obtaining various information at the same time using a very small sample.

One of such multiple analysis techniques is to use a positional microarray to analyze gene information by forming a specific probe or code region in X and Y coordinates, which is advantageous for ultra high density analysis .

It is also possible to use a multiple analysis technique, a suspension array, by color coding using various dye solutions (or fluorescent materials) that emit different emission colors, Of the sample can be processed.

However, the above-described flat microarray technology or color coding method has a disadvantage in that it is difficult to recognize and quantify accurate gene information because its reproduction is poor and real-time PCR analysis is not easy. In addition, detection information on genetic information is inaccurate due to interference between detected information and the like, depending on the detection method of the detection signal according to the labeling substance, the direction and sensitivity of the detector, and the method for detecting a high sensitivity using a very small amount of sample There are insufficient aspects.

In addition, techniques for particle-based diagnosis are presented by using multiple analysis techniques. When particles of small size are used, the reaction surface area can be widened to increase reactivity, and each particle can be used as a platform of different target, It is advantageous that various assays can be carried out.

With this particle-based diagnostic technique, Korean Patent Application Publication No. 10-2009-0091117 entitled "Multi-Functionally Encoded Particle for High Performance Analysis" describes a method of flowing a fluorescently labeled monomer along a microfluidic channel, After the probe-lead-off monomer is flowed along the micro flow channels, they are polymerized and exposed to ultraviolet rays transmitted through a photomask to form particles having a code region and a probe region.

However, since the probe region and the code region are separated from each other, it is difficult to distinguish between the probe region and the quantitative region, and a resolution and a resolution are limited due to the use of a photomask and a lens. Therefore, It is not easily formed.

In addition, since the above method forms particles having a probe region and a code region by a photomask intermittently along a microfluidic channel, the loss of material between the particles generated by the photolithography process along the microfluidic channel So that there is an uneconomical problem.

In addition, the particles prepared by the above method have a disadvantage in that real-time PCR can not be realized and accurate quantification and recognition of gene information can not be performed.

In recent years, as a technique filed by the present inventor, there is a description of a " biosize utilizing micro structure including an encoder into which a pattern is input. &Quot; The present invention relates to a biosensor-utilizing microstructure including an encoder for providing a specific pattern for distinguishing microstructures from each other in a biosensor, and is capable of easily identifying and reading microstructure information without disturbance caused by conventional fluorescence And various types of target nucleic acids can be monitored or detected in real time at the same time, so that it is possible to detect information using a very small sample.

In the conventional art, the shape of the microstructure is formed in the form of a particle. Generally, the microstructure is manufactured in a spherical shape of transparent material so that the pattern of the encoder can be read from the outside. So that the pattern of the encoder can always be positioned parallel to the X-axis direction by using the difference in density between the material constituting the encoder and the matrix so as to be recognized.

In order to arrange the encoder patterns in the X-axis direction, an encoder material having a different density is prepared, a patterning process is performed on a silicon substrate or the like to form an encoder, a microfluidic channel is separately manufactured, Forming a droplet-type structure by a flow-focusing method, and then curing the microstructure to manufacture an encoder-containing microstructure.

However, the above-described manufacturing method is complicated and difficult to manufacture, such as fabricating a microstructure after forming an encoder pattern, again, and even if the density difference between the matrix material and the encoder material is used, The density of the encoder material may be changed depending on the direction, and the center of gravity may be formed differently, so that the encoder pattern may not always be arranged parallel to the X-axis direction.

This is because, as described above, the detection information may be inaccurate depending on the detection signal measurement method according to the labeling material, the direction and sensitivity of the detector, and the reproducibility of the experiment is poor. There is an insufficient problem as a solution.

Disclosure of Invention Technical Problem [8] The present invention has been made in order to solve the above problems, and it is an object of the present invention to provide a method and apparatus for manufacturing biosensor microparticles using a mask patterning process, a spotting process and an imprinting process, And to provide microparticles for biosensors that can be produced by the method.

According to an aspect of the present invention, there is provided a method of manufacturing a semiconductor device, comprising the steps of: forming a photosensitive resin layer on a substrate; forming a first mold having a relief encoder pattern formed of a photosensitive resin by a mask patterning process; A second step of forming an imprinted resin layer on the recessed encoder pattern region formed on the master mold and forming a master mold having imprinted encoder patterns formed on the imprinted resin by an imprinting process; a third step of spotting the droplets to form droplets, and a fourth step of curing the droplets formed on the master mold, separating the droplets on the master mold and forming microparticles having an encoder pattern on the bottom surface, ; And a method for producing microparticles for bioassay, The bio-control and the microparticles for the assay with the technical gist.

After the second step, it is preferable to hydrophilize the surface of the engraved encoder pattern region in the master mold, or to hydrophobic treat the surface of the region except the engraved encoder pattern region in the master mold.

In addition, it is preferable that the droplet in the third step has a flat three-dimensional shape on the bottom surface, and the droplet in the third step is preferably hemispherical or semi-elliptical.

Further, it is preferable to further form pores in the microparticles in the fourth step, and to arrange an opaque metal layer or a photosensitive resin layer on the encoder pattern of the microparticles in the fourth step.

The present invention provides a microparticle for biosensor in which probe region and encoder region are not separated in the same substrate but overlapped by using mask patterning process, spotting and imprinting process, and real-time PCR can be applied Therefore, it is possible to accurately quantify and recognize genetic information analysis.

In addition, the accuracy of the encoder pattern (5 μm or less) is ensured by the mask patterning process, more than 10 ⁹ encodings are possible, and various information of the ultra fine sample can be detected. Since the droplet is formed by the process, the waste of the probe material can be reduced and the cost can be reduced.

In addition, the microparticles according to the present invention are formed in a flat shape on the bottom surface, so that the patterned encoder area is always oriented horizontally with respect to the bottom surface, so that the encoder can be fixed in a certain direction, And it is possible to improve the reproducibility of the experiment such that high sensitivity can be detected even if a trace amount of sample is used.

In addition, the present invention can detect hybridization of a target substance with a contrast and darkness change of an encoder pattern regardless of whether or not a label substance is used, regardless of whether the label substance is used or not, It is possible to reduce the cost of the system.

FIG. 1 is a schematic view of a method for producing microparticles for a bioassay according to the present invention. FIG.
FIG. 2 is a side view of a droplet formed on a master mold manufactured according to an embodiment of the present invention; FIG.
FIG. 3 is a photograph (a) of a master mold manufactured according to an embodiment of the present invention, and photographs (b), (c) and (d) of microparticles.
Figure 4 is a photograph of microparticles according to various embodiments of the present invention.
FIG. 5 is a graph showing a BF image (a) after PCR, a fluorescence image (b), and (c) before and after PCR for microparticles according to an embodiment of the present invention;
FIG. 6 is a schematic view (a cross-section, (b) a bottom view) of microparticles constituting a composite structure manufactured according to an embodiment of the present invention;

The present invention relates to a micro-particle for multiplexing biosensors capable of simultaneously quantifying and recognizing biosensors, DNA, RNA, proteins, etc., and thereby obtaining various information at a low cost while reducing analysis time. Wherein the probe region and the encoder region are formed in a superposed manner in the same substrate using a mask patterning process, a spotting process, and an imprinting process, without separating the probe region and the encoder region.

Accordingly, the present invention enables the production of microparticles for bioassay using a simple and economical method compared with the prior art, and in particular, since the probe region and the encoder region are not separated, real-time PCR can be applied, There are advantages of quantification and recognition.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings. 2 is a side view of a droplet formed on a master mold manufactured according to an embodiment of the present invention; FIG. 2 is a cross-sectional view of a droplet formed on a master mold according to an embodiment of the present invention; (B), (c) and (d) of the microparticles. Figure 4 is a photograph of the master mold prepared according to one embodiment of the present invention, FIG. 5 is a graph showing microphages according to various embodiments. FIG. 5 is a graph showing the BF image (a) after PCR for the microparticles according to the embodiment of the present invention, the fluorescence images before and after the PCR FIG. 6 is a schematic view ((a) sectional view and (b) bottom view) of the microparticles constituting the composite structure manufactured according to the embodiment of the present invention.

As shown in FIG. 1, a method of manufacturing microparticles for a bioassay according to the present invention includes forming a photosensitive resin layer on a substrate, forming a first mold having a relief encoder pattern made of a photosensitive resin by a mask patterning process, A second step of forming an imprint resin layer on the first mold and fabricating a master mold which is formed of an imprint resin by an imprinting process to form an engraved encoder pattern; A third step of spotting a solution of biotissue solution on the engraved encoder pattern to form a droplet, and a step of curing the droplet formed on the master mold, separating the droplet on the master mold, And forming a microparticle having an encoder pattern formed thereon.

The microparticle in the present invention is used in an apparatus for detecting and analyzing a target nucleic acid in a bioassay, and it is a microparticle such as nano (10 ^-6 ), micro (10 ^-3 ), milli (10 ^-2 ) And includes information on the amount of the target nucleic acid or the fixed primer reacting therewith, that is, a probe region for quantitatively detecting the bioassay information, and an encoder region for recognizing the species.

A method of manufacturing microparticles for a biosensor according to the present invention comprises the steps of forming a photosensitive resin layer on a substrate and fabricating a first mold having a relief encoder pattern formed of a photosensitive resin by a mask patterning process Step 1, step (a)).

The substrate may be of any type as long as it can be used as a flat substrate such as metal, silicon, glass and polymer, and a substrate having an appropriate area according to the size and the number of the encoder patterns to be formed is prepared.

A photosensitive resin layer is coated on the substrate to form an encoder pattern, and the thickness of the photosensitive resin layer is formed in consideration of the depth of the concave portion of the encoder pattern.

As the photosensitive resin layer, any resin can be used as long as it can be used in the mask patterning process by photolithography, and radiation curable epoxy acrylate, urethane acrylate, polyester acrylate, and a substituent having a controlled refractive index can be used , SU-6, SU-7, and SU-8.

After the photosensitive resin layer is formed on the substrate, the photosensitive resin portion that has not been cured by the exposure process is selectively removed through a mask after the exposure using a mask in which the encoder pattern is drawn in advance, and only the cured photosensitive resin remains Thereby forming a positive embossed encoder pattern.

Here, the positive embossed encoder pattern refers to a pattern corresponding to the final encoder pattern. Since the final encoder pattern is formed by the master mold described later, the embossed encoder pattern having the opposite phase is called the embossed encoder pattern.

Thus, the mask patterning process completes the first mold in which the embossed encoder pattern made of the photosensitive resin is formed. The precision (not more than 5 탆) of the encoder pattern is ensured, and more than 10 ⁹ encodings are possible. Since the liquid droplet is formed by the spotting process only on the engraved encoder pattern formed on the master molder, the waste of the probe material can be reduced and the cost can be reduced.

Next, an imprint resin layer is formed on the first mold, and a master mold having imprinted encoder patterns is formed by an imprinting process (second step, step (b)).

The imprint resin layer is poured onto the first mold and pressed with a roller or the like to imprint the engraved encoder pattern of the first mold on the imprint resin layer.

After the imprinting, the imprint resin layer is photo-cured to fix the pattern of the imprint resin. When the imprint resin is peeled off, the engraved encoder pattern (pattern corresponding to the relief encoder pattern of the first mold) The formed master mold is completed.

For the photocuring, a photocurable resin is used for the imprint resin layer. The photocurable resin used for the imprint resin layer is the same as the resin used for the photosensitive resin layer, or more specifically, polydimethylsiloxane ( polydimethylsiloxane, PDMS) solution and a curing agent are used.

On the other hand, it is preferable that the surface of the engraved encoder pattern region is hydrophilized in the master mold, or the surface of the region except the engraved encoder pattern region in the master mold is subjected to hydrophobic treatment.

This is because hydrophilic processing is performed on the engraved encoder pattern area or hydrophobic processing is performed on areas other than the engraved encoder pattern area that is not spotted and the solution for biosensing is spotted to be described later to thereby accurately set the area to be spotted So that droplets can be easily formed without precise control of the spotting apparatus.

Generally, the hydrophilic treatment forms an oxide film layer by using at least one of oxide-based materials such as SOG, TEOS, LTO, silicon oxide, titanium oxide, and aluminum oxide on the engraved encoder pattern region using a mask, The treatment is performed by any one of deposition of a hydrophobic substance, coating of a hydrophobic substance, silanizing treatment, and plasma treatment using a mask in a region other than the engraved encoder pattern region.

Next, a droplet is formed by spotting the bio-absorbing solution on the engraved encoder pattern formed on the master mold (step 3 and step (c)).

That is, since the droplet is formed by spotting the bio-absorbing solution only on the region where the engraved encoder pattern is formed in the master mold, the waste of the bio-absorbing solution (i.e., the probe material) can be reduced.

The bio-essing solution is formed of a transparent material capable of reading an encoder pattern from the outside, and is made of polyethylene glycol-diacrylate (PEG-DA), polyacrylamide (PA) and agarose and agarose.

In addition to the above polymer, a polymerase chain reaction (PCR) primer, a cyanine dye, EtBr, TaqMan ( ^TM ), which provides quantitative information of a nucleic acid that is complementarily bound and amplified with a target nucleic acid, probe, a fluorescence marker such as a oligo-nucleotide probe (Molecular Beacon probe), and the like.

In this way, the solution for biosorption of the present invention acts as a matrix of the microparticles according to the present invention, and the types of the substrate itself or the primers or probes contained in the substrate are differently formed, Or information on the type, size or amount of immobilized primer reacting therewith.

In addition, since the shape of the droplet is spotted on the master mold, the bottom surface has a flat three-dimensional shape, specifically, hemispherical or semi-elliptical.

Here, the spatting uses a spatting device which can be finely controlled by a solenoid valve or the like, and the size of droplets can be controlled by controlling the spotting time and the flow rate.

Next, after the droplet formed on the master mold is cured, the droplet is released on the master mold to form micro-particles having an encoder pattern on the bottom surface (step 4).

A sacrificial layer may be separately formed therebetween for separation of the cured droplets on the master mold. When the cured droplet is released in the master mold in a peel-off manner, The formation of the microparticles in which the final encoder pattern is formed is completed.

Since the encoder pattern is generated by the mask patterning process, the precision of the encoder pattern (less than 5 탆) is ensured and more than 10 ⁹ encodings are possible, which enables detection of various information on very fine samples.

Since the microparticles are dropped into droplets and cured by spotting, the bottoms of the microparticles are formed into a three-dimensional shape of a flat shape, preferably hemispherical or semi-elliptical, The encoder pattern by the mold is imprinted and appears.

Since the center of gravity of this type of microparticles always maintains the level of the bottom surface, that is, the bottom surface of the encoder pattern is brought into contact with the ground and vice versa, It is recognized horizontally with respect to the ground.

Therefore, since the detector for the labeling substance is always used in the direction perpendicular to the microparticles, it is possible to ensure the accuracy of the detection information and to improve the reproducibility of the experiment, such as the detection of high sensitivity even using a trace amount of sample do.

The microparticles of this type have a probe region for quantitatively detecting bioassay information and an encoder region for recognizing the type of bioassay information by an encoder pattern formed on the bottom face are not separated in the substrate , So that it is possible to simultaneously detect quantitation and recognition by recognizing an encoder pattern.

That is, it is possible to manufacture microparticles for bioassay using a mask patterning process, a spotting process, and an imprinting process in a simpler and more economical manner than the conventional technology. In particular, since the probe region and the encoder region are not separated, The reaction in the exponential phase can be monitored and monitored in real time, so that the initial amount of the target nucleic acid can be accurately quantified.

On the other hand, an opaque metal layer or a photosensitive resin layer is arranged on the encoder pattern of the microparticles in the fourth step, so that various types of biosensor information can be detected. That is, not only the detection information by fluorescence but also the acquisition of detection information by a general bright field is facilitated.

Specifically, the photosensitive resin layer includes an epoxy-based negative photoresist, for example SU-8. The metal layer may include at least one of a conductive metal and a conductive polymer, and may form a magnetic material. The magnetic material may include one or more of iron, nickel, cobalt, Dynabeads, and Bacterial magnetic particles.

Further, roughness processing is further performed on the encoder pattern of the microparticles in the fourth step, so that scattering of light occurs more easily upon detection of fluorescence, so that more accurate information can be detected.

In addition, pores are further formed in the microparticles in the fourth step, so that only the surface of the microparticles can be used up to the interior rather than being used for amplification and detection, thereby maximizing the reactivity.

The pore forming method in such microparticles is a method of mixing a porogen in the solution for biosorption and removing the porogen after curing the droplet.

The porous induction polymer may be polyethylene glycol (PEG), and the pores may include a fluorescent marker that provides quantitative information of the nucleic acid to be amplified.

Meanwhile, another droplet may be formed on the droplet after the droplet formed on the master mold is cured. As shown in FIG. 6, the droplet included in the inside is referred to as a first droplet for convenience, The formed droplet is called the second droplet.

A second droplet formed on the master mold is cured, and then a solution of a biotissue solution different from that used in the step (c) is spotted on the first droplet to form a second droplet Thereby forming droplets (step (d)).

After the second droplet is cured, the composite structure composed of the first droplet and the second droplet is separated on the master mold to form composite microparticles having an encoder pattern formed on the bottom surface (step (e)). .

Such a method may be useful when it is desired to simultaneously detect information on the type, size or amount of two or more kinds of target nucleic acids or immobilized primers reacting with the target nucleic acid in one microparticle, Different materials may be used, an encoder pattern may be formed only in the first droplet, or different encoder patterns may be formed in the first droplet and the second droplet, respectively. It is also possible to implement the third droplet if necessary.

The method of reading the encoder pattern of the microparticles manufactured as described above, that is, the method of reading the information of the encoder is not limited, but a CCD camera or the like can be used. It is also possible to read the information of the encoders individually for each microparticle or to simultaneously read the encoder information of a plurality of microparticles arranged in the array.

In addition, a bio experiment material such as a primer, a target nucleic acid, and the like and a microparticle according to the present invention are put into a solution, and the bioassay is carried out. After arranging the bioassay in an array, an encoder pattern included in each microparticle is read And analyze bioassay results.

Alternatively, a bio experiment material such as a primer or a target nucleic acid and the microparticles according to the present invention may be arrayed in an array, and the microparticles arranged in the array may be bioassayed to read an encoder pattern included in each microparticle, Allow the assay results to be analyzed.

Hereinafter, embodiments of the present invention will be described.

First, SU-8 resin (SU-8 3025, Microchem) was poured as a photosensitive resin onto a silicon substrate and coated at 500 rpm for 10 seconds and at 200 rpm for 30 seconds.

Then, soft baking was performed for 15 minutes on a hot plate at 95 DEG C, and 250 mJ UV exposure was selectively performed using a mask in which an encoder pattern was previously drawn. After exposure, the substrate was baked for 5 minutes on a hot plate at 65 ° C for 1 minute at 95 ° C for 5 minutes, and then unexposed SU-8 was removed using an SU-8 developer (Microchem) Work was performed. Then, the wafer was further baked on a hot plate at 200 ° C for 5 minutes.

Thereby, a first mold having a relief encoder pattern formed on a silicon substrate was produced.

Then, an imprint resin layer was formed on the first mold on which the relief encoder pattern was formed. A prepolymer prepared by mixing polydimethylsiloxane (PDMS) solution and a curing agent (product name: SYLGARD® 184, manufactured by DOWITECH Silicone) at 10: 1 was poured onto the first mold as the imprint resin.

The gas was removed in a vacuum chamber for 60 minutes, then cured in an oven at 80 DEG C for 90 minutes, and separated from the first mold to prepare a master mold having an engraved encoder pattern made of PDMS.

Then, a droplet was formed by spotting the bio-adsorption solution on the engraved encoder pattern formed on the master molder.

20% by volume of PEG 700 DA (manufacturer: Sigma Aldrich), 40% by volume of polyethylene glycol 600 (PEG 600), 5% by volume of Darocur 1173 (Sigma Aldrich) as a photoinitiator, 0.15% Of a 3X TE buffer containing tween-20. Then, 5% by volume of EtBr (reagent which binds to the double-stranded nucleic acid and exhibits fluorescence together with the amplification (Interchelator)) is further mixed with the total volume of the biosorption using solution.

The open time of the spotting device was adjusted to spout the bio-essing solution only on the engraved encoder pattern region formed in the master mold to form droplets containing the engraved encoder pattern region therein.

Then, the droplet was cured by irradiating ultraviolet rays (UV) at 6 to 8 mW / cm ² for 20 minutes, released on the master mold, and microparticles having an encoder pattern formed on the bottom surface .

FIG. 2 is a side view of a droplet formed on a master mold manufactured according to an embodiment of the present invention. It can be seen that the shape of a droplet by spotting indicates a hemispherical shape with a flat bottom surface.

3 (a) is a photograph of a master mold manufactured according to an embodiment of the present invention, and FIGS. 3 (b) and 3 (c) are photographs of a master mold formed by spotting a bio- FIG. 3 (d) is a photograph of the microparticles prepared by curing the droplet and separating droplets from the master mold, and shows a photograph of the microparticles produced by the mask patterning process and the imprinting process, It can be confirmed that an encoder pattern of FIG.

FIG. 4 is a photograph of microparticles according to various embodiments of the present invention, for microparticles in which various encoder patterns are formed. These microparticles were formed in a hemispherical shape with a flat bottom surface, and it was found that the encoder patterns of all the microparticles could be read in the vertical direction of the microparticles.

5 (a) is a BF (bright field) image (a) after PCR for microparticles according to an embodiment of the present invention, and it can be confirmed that the encoder pattern can be read by a CCD camera.

FIGS. 5 (b) and 5 (c) show fluorescence images before and after the PCR. As the PCR cycle was increased, the fluorescence color became bright and the encoder pattern became clearer.

Claims (12)

A first step of forming a photosensitive resin layer on a substrate and fabricating a first mold having a relief encoder pattern formed of a photosensitive resin by a mask patterning process;
A second step of forming an imprinted resin layer on the first mold and a master mold having imprinted resin patterns formed by imprinting by an imprinting process;
A third step of forming droplets by spotting a solution of the biotissue application on the engraved encoder pattern area formed in the master mold; And
A fourth step of curing a droplet formed on the master mold to form a three-dimensional droplet having a flat bottom surface, separating the droplet on the master mold, and forming microparticles having an encoder pattern on the bottom surface; The method of claim 1, 2. The method of claim 1, further comprising, after the second step,
Hydrophilic processing of the surface of the engraved encoder pattern area in the master mold,
Wherein the surface of the region of the master mold excluding the engraved encoder pattern region is hydrophobically treated. The method according to claim 1, wherein the droplet in the third step
Wherein the bottom surface has a flat three-dimensional shape. The method according to claim 1, wherein the droplet in the third step
Wherein the microparticles are hemispherical or semi-elliptical. The method of claim 1, wherein pores are further formed in the microparticles in the fourth step. The method of claim 1, further comprising forming an opaque metal layer or a photosensitive resin layer on the encoder pattern of the microparticles of the fourth step. (A) forming a photosensitive resin layer on a substrate, and (a) fabricating a first mold having a relief encoder pattern formed of a photosensitive resin by a mask patterning process;
(B) forming an imprinted resin layer on the first mold and fabricating a master mold having imprinted resin patterns formed by imprinting by an imprinting process;
Forming a first droplet by spotting a solution of biotissue solution on the engraved encoder pattern region formed in the master mold;
A first droplet formed on the master mold is cured to form a three-dimensional droplet having a flat bottom surface, and then a biotissue using solution different from the biotissue using solution of the step (c) (D) forming a second droplet so as to include the first droplet therein; And
The second droplet is cured to form a droplet of a three-dimensional shape in which the bottom surface is flat, and then the complex structure composed of the first droplet and the second droplet is separated on the master mold, And (e) forming microparticles on the surface of the microparticles. The bottom surface is formed in a flat three-dimensional shape,
A probe region for quantitatively detecting bio-assay information,
Wherein an encoder region for recognizing the type of bio-assay information is formed in the substrate in an overlapping manner by an encoder pattern formed on the bottom surface,
The encoder pattern is formed using a master mold in which the engraved encoder pattern is formed,
Wherein the substrate is formed of a transparent material capable of reading an encoder pattern from the outside. 9. The method of claim 8,
Wherein the microparticles are hemispherical or semi-elliptical. 9. The method of claim 8, wherein on the encoder pattern of the microparticles,
An opaque metal layer or a photosensitive resin layer is further formed on the surface of the microparticle. 9. The method of claim 8,
And another type of probe area or encoder area is formed outside the microparticle, thereby forming a complex structure. The microparticle for biosensor according to claim 8, wherein pores are further formed in the microparticles.

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