JP2004286667A - Apparatus for arranging fiber and method for arranging fiber using the same, method for manufacturing fiber arranged body, and method for manufacturing microarray for immobilizing organism-related substance - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an apparatus for arranging fibers that can quickly, efficiently and accurately, and three-dimensionally arrange the fibers with high density in a very short time. <P>SOLUTION: The apparatus 10 for arranging fibers for three-dimensionally arranging the fibers 1 comprises a fiber-rewinding means 11 for rewinding the fibers 1, and a fiber-supplying means 12 for supplying the fibers 1 to the fiber-rewinding means 11. The fiber-supplying means 12 has a movable guide 16 for supplying the fibers, while relatively moving to the fiber rewinding means 11. The fiber rewinding means 11 has a bobbin 19 for rewinding the fibers 1 onto the circumference, while rotating with a shaft 19a as a center; and a flat plate for arranging fibers, where a plurality of flat plates for arranging fibers are laminated at a plurality of prescribed positions on the circumference of the bobbin 19 for rewinding fibers each and where the fibers 1 are arranged on each external surface. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a fiber arranging device for three-dimensionally arranging a plurality of fibers, a fiber arranging method using the same, a fiber wound material and a fiber array obtained by arranging the fibers by this method. Furthermore, the present invention relates to a method for producing a bio-related substance-immobilized microarray used for testing or detecting a specific bio-related substance from the fiber array.
[0002]
[Prior art]
As a method for analyzing the expression of a large number of genes at once, there is an analysis method called a DNA microarray method (or a DNA chip method).
In this method, a large number of DNA fragments are fixed on a plane substrate piece called a microarray or a chip while being arranged at a high density (hereinafter, referred to as a DNA chip). And a method for detecting and quantifying a nucleic acid based on a nucleic acid-nucleic acid hybridization reaction.
This method has been recognized and noted as a technique for minimizing the amount of a reaction sample and for making a variety of reaction samples into a form that can be rapidly and systematically analyzed and quantified with good reproducibility.
[0003]
As a specific method of the DNA microarray method, for example, a nucleic acid complementary to each other is obtained by hybridizing a sample obtained by labeling an expressed gene or the like of a cell to be studied with a fluorescent dye on a DNA chip. (DNA or RNA) may be bound to each other, and the site may be labeled with a fluorescent dye or the like, and then read at high speed with a high-resolution analyzer.
According to such a method, the amount of each gene in a sample can be quickly estimated.
[0004]
As a technique for immobilizing a bio-related substance such as a nucleic acid on a chip, for example, as described in Patent Document 1, there is a method using a fiber as a carrier for immobilizing a bio-related substance.
In this method, first, a fiber array in which a plurality of fibers as an immobilization carrier are arranged neatly and three-dimensionally is prepared, and the fiber array is sliced and thinned to arrange fibers at high density. A flaky chip has been obtained. Here, in order to manufacture a fiber array in which a plurality of fibers are arranged neatly, a plurality of jigs having holes of the same pattern as the target array pattern are used.
[0005]
Specifically, first, these jigs are arranged so as to be in contact with each other by aligning the positions of the holes, and the holes in the same positional relationship of the jigs are used as carriers for immobilizing a biological substance. Each fiber is penetrated. Next, the distance between the jigs is increased, the tension is applied to the three-dimensionally arranged fibers between the jigs, and the fibers are aligned. Then, a curable resin is filled between these fibers and cured to cure the fibers. Is fixed.
Then, by slicing the resin-fixed material, that is, the fiber array, substantially perpendicularly to the length direction of the fiber, a flaky bio-related substance-immobilized microarray is obtained. Here, a bio-related substance may be fixed to the fiber in advance, or a bio-related substance may be fixed to the fiber before slicing.
According to such a method, it is possible to produce a large number of bioarray-immobilized microarrays having the same sequence at one time.
[0006]
On the other hand, such a microarray immobilized with a bio-related substance is required to have a large number of fibers per unit area, that is, to have many types of immobilized bio-related substances per unit area. In order to increase the number of fibers, it is necessary to reduce the arrangement pitch between fibers. For that purpose, it is required that the fiber itself be made thinner and the hole diameter of a jig for inserting the fiber be made smaller.
[0007]
[Patent Document 1]
JP 2001-239594 A
[0008]
[Problems to be solved by the invention]
However, in the method disclosed in Patent Literature 1, as described above, it is necessary to use a plurality of jigs having a large number of holes and to insert and penetrate one fiber into each hole. For this reason, when the arrangement pitch, the hole diameter, and the fiber outer diameter are reduced, the following problem occurs.
In other words, during the process of guiding the fiber to be inserted into the hole to the hole or when inserting the fiber, the fiber is usually moved using fine tweezers or a nozzle, and at that time, the adjacent hole already inserted is used. In some cases hindered the movement of tweezers and nozzles. Such a tendency becomes remarkable especially when the arrangement pitch, the hole diameter, and the fiber outer diameter are reduced. Further, when the outer diameter of the fiber is reduced to reduce the hole diameter, the rigidity of the fiber is reduced, and there is a problem that the insertion into the hole becomes more difficult.
In the method disclosed in Patent Document 1, it is necessary to insert fibers one by one, and it takes a very long time to arrange all the fibers.
As described above, in the conventional process of manufacturing a fiber array using fibers as a carrier for immobilizing a bio-related substance, it is difficult to efficiently arrange fibers at high density. Such inefficiencies were a major problem in such cases.
[0009]
[Means for Solving the Problems]
The present inventors have made intensive studies in view of the above circumstances, and as a result, when manufacturing a fiber array using fibers as a carrier for immobilizing a bio-related substance, use of a specific fiber array device. As a result, the present inventors have found that fibers can be three-dimensionally arranged efficiently in a very short time with high density and high accuracy, and have completed the present invention.
[0010]
An apparatus for arranging fibers according to the present invention is an apparatus for arranging fibers for three-dimensionally arranging fibers, comprising: fiber winding means for winding fibers; and fiber supply for supplying the fibers to the fiber winding means. Means, wherein the fiber supply means includes a movable guide for supplying the fiber while moving relative to the fiber winding means, and the fiber winding means winds the fiber around while rotating. It is characterized by having a fiber winding bobbin and a fiber arrangement flat plate in which a plurality of fibers are stacked on a plurality of predetermined positions on a circumference of the fiber winding bobbin, respectively, and the fibers are arranged on each outer surface. And
On the outer surface of the flat plate for fiber arrangement, a plurality of concave stripes for arranging fibers one by one are formed substantially in parallel with each other, and the concave stripes are arranged with respect to the axis of the fiber winding bobbin. It is preferable to be stacked on the circumference so as to be vertical.
Among the laminates at the plurality of predetermined positions, an arrangement pitch of fibers arranged on an outer surface of the fiber arrangement flat plate constituting at least one laminate is the fiber arrangement flat plate constituting another laminate. May be different from the arrangement pitch of the fibers arranged on the outer surface.
Further, it is preferable that at least two positioning through holes are formed in the flat plate for arranging the fibers, and a column inserted into each of the positioning through holes is provided on the periphery.
[0011]
The fiber arranging method of the present invention is a fiber arranging method for arranging fibers three-dimensionally by using the fiber arranging device, wherein a first fiber arranging flat plate is arranged at each of the plurality of predetermined positions. And a second step of rotating the fiber winding bobbin a predetermined number of times, supplying fibers while moving the movable guide, and arranging the fibers on the arranged fiber arrangement flat plate. And a third step of laminating another fiber-arranging flat plate on each of the fiber-arranging flat plates on which fibers are arranged, and repeating the second and third steps a plurality of times. And
The fibers are preferably at least one selected from the group consisting of synthetic fibers, semi-synthetic fibers, regenerated fibers, inorganic fibers, and natural fibers.
The method for producing a fiber array according to the present invention is characterized in that the fibers arranged three-dimensionally by the fiber array method are fixed. At this time, it is preferable that a curable resin is filled between the fibers, cured, and fixed.
A biomaterial may be immobilized on the fiber in advance, or a biomaterial may be immobilized on the immobilized fiber.
The method for producing a microarray immobilized with a biological substance according to the present invention is characterized in that the fiber array is sliced in a direction intersecting with the fibers to be sliced.
The fiber wound material of the present invention is a fiber winding means having a fiber winding bobbin and a laminate of two or more fiber arrangement flat plates laminated at a plurality of predetermined positions on the periphery thereof, respectively. The fibers are arranged and wound on the outer surface of the fiber array flat plate.
Among the laminates at the plurality of predetermined positions, the arrangement pitch of the fibers arranged on the outer surface of the fiber arrangement flat plate constituting at least one laminate is the fiber arrangement flat plate constituting another laminate. May be different from the arrangement pitch of the fibers arranged on the outer surface.
[0012]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, the present invention will be described in detail.
[Fiber arrangement device]
FIG. 1 is a perspective view showing a state in which fibers 1 are three-dimensionally arranged using a fiber arrangement device 10 of the present invention.
The fiber arrangement device 10 includes a fiber winding means 11 for winding the fibers 1 and a fiber supply means 12 for supplying fibers to the fiber winding means 11, and these are attached to a base 13. It is configured.
The fiber supply means 12 of this example includes a fiber supply bobbin 14 around which the fiber 1 is wound, a guide roller 15 for feeding the fiber 1 downstream, and a movable guide 16 described in detail later. The fiber 1 from the supply bobbin 14 is supplied to the fiber winding means 11 via the guide roller 15 and the movable guide 16.
[0013]
Here, the movable guide 16 has a nozzle shape through which the fiber 1 is inserted as shown in an enlarged manner in FIG. 2, and can be moved in a vertical direction (Z-axis direction) and a horizontal direction (X-axis direction). It has become.
Specifically, reference numeral 17 in FIG. 1 denotes an X-axis stage whose cross section is formed of a rectangular prism and whose lower surface is fixed on a base 13 so that the length direction is horizontal. On the upper side, there is provided an X-axis moving table 17a that moves horizontally along this surface. Reference numeral 18 denotes a Z-axis stage having a rectangular section having a rectangular cross section, and having one side fixed to the X-axis moving table 17a so that the longitudinal direction is a vertical direction. On one side surface, there is provided a Z-axis moving table 18a that moves vertically along this surface. Since the movable guide 16 is fixed to the Z-axis moving table 18a, the movable guide 16 can move in the vertical and horizontal directions accompanying the movement of the Z-axis moving table 18a. The fibers 1 can be supplied to the means 11.
Note that the horizontal direction in which the movable guide 16 can move is a direction parallel to a shaft 19a of a fiber winding bobbin indicated by reference numeral 19, which will be described later.
[0014]
The movable guide 16 is provided with control means (not shown) for controlling the movement of the movable guide 16 so that the timing, direction, and distance at which the movable guide 16 moves can be arbitrarily controlled.
For example, every time the fiber winding bobbin 19 makes one rotation, the operator inputs in advance in which direction and how much to move the movable guide 16 from the operation panel 20 to the control means. On the other hand, a motor provided with a rotation angle detecting mechanism such as a rotary encoder is connected to the fiber winding bobbin 19 so that a signal is sent to the control means every time the fiber winding bobbin 19 makes one rotation. Keep it. In this way, the movable guide 16 moves in conjunction with the rotation of the fiber winding bobbin 19 in accordance with a command from the control means.
[0015]
It is preferable that the inner diameter of the nozzle-shaped movable guide 16 is larger than the outer diameter of the fiber 1 by 10 to 80%, preferably 30 to 50%. The outer diameter of the nozzle-shaped movable guide 16 is preferably formed to be 40 to 150%, preferably 70 to 100% larger than the inner diameter. Further, the length of the nozzle-shaped portion is preferably 5 to 30 times, preferably 10 to 20 times the outer diameter. The material of the nozzle-shaped movable guide 16 is preferably stainless steel.
[0016]
The fiber winding means 11 provided in the fiber arrangement device 10 of this example includes a fiber winding bobbin 19 for winding the fiber 1 around the circumference while rotating about a shaft 19a, and a fiber winding bobbin 19 And two or more sheets are laminated at a plurality of predetermined positions on the circumference of the sheet, and a fiber arrangement flat plate on which the fibers 1 are arranged on the outer surface.
[0017]
As shown in FIGS. 3A and 3B, the fiber winding bobbin 19 is formed of a hexagonal prism, is attached to the base 13 so that the axial direction is horizontal, and rotates around the shaft 19a. It is supposed to.
On each of the six side surfaces of the hexagonal column, four columns 21a, 21b are provided perpendicular to the surface, and the fiber winding bobbin 19 as a whole has a total of 24 columns 21a, 21b. I have. In particular, the struts 21a and 21b of this example are provided in pairs on each side surface near the boundary side with the adjacent side surface, and a pair having a small distance (pitch D) is provided.₁) And a wide set (pitch D)₂). Hereinafter, pitch D₁The strut provided in the step is called a precision pitch strut 21a, and the pitch D₂Are referred to as wide-width pitch columns 21b. In this example, each of the columns 21a for the precision pitch and the columns 21b for the widened pitch has six sets.
[0018]
In addition, the fiber arrangement device 10 of this example includes a total of 120 pieces of the two types shown in FIGS. 4A and 4B as the fiber arrangement flat plates 22a and 22b, each of which is 60 pieces.
The fiber arrangement flat plate (hereinafter, referred to as a precision pitch flat plate) 22a of FIG. 4A has ten identically shaped concave strips 23a in which the fibers 1 are arranged one by one. It is a rectangular one formed above. In the fiber arrangement flat plate (hereinafter, referred to as a widened pitch flat plate) 22b of FIG. 4B, ten concave strips 23b are formed on one surface substantially in parallel with each other, similarly to the precision pitch flat plate 22a. Although it is rectangular, it is formed so that the distance (pitch) between the concave strips and the thickness of the flat plate are larger than those of the precision pitch flat plate 22a.
In this example, the precision pitch flat plate 22a has a longer length (direction along the concave streak) and a smaller width than the widened pitch flat plate 22b. Further, in the precision pitch flat plate 22a, the width and the depth of the formed recess 23a are formed to be about 5% larger than the outer diameter of the fiber 1, and in the widened pitch flat plate 22b, the formed recess 23b is formed. The width and the depth are formed to be about 5 to 20% larger than the outer diameter of the fiber 1, so that the fiber 1 can be arranged more accurately in the precision pitch flat plate 22a.
[0019]
The precision pitch flat plate 22a of this example has a thickness of 0.42 mm, and has ten recesses of 0.3 mm width and 0.3 mm depth on one surface of a rectangular flat plate having a width of 10 mm and a length of 40 mm. The ridges 23a are formed at a pitch (distance) of 0.42 mm along the length direction of the rectangular flat plate. The flat plate 22b for widening pitch in this example has a thickness of 4.5 mm, and is formed on one surface of a rectangular flat plate having a width of 8 mm × a length of 170 mm and ten recesses having a width of 0.5 mm and a depth of 2 mm. The ridges 23b are formed at a pitch of 4.5 mm along the length direction of the rectangular flat plate.
[0020]
Near each side end of the fiber array flat plates 22a and 22b, one circular positioning through hole 24a, 24b is formed, and two positioning through holes in the precision pitch flat plate 22a are formed. Pitch D between holes 24a₃Is the pitch D between the columns 21a for precision pitch.₁It is formed in the same way. On the other hand, the pitch D between the two positioning through holes 24b in the widened pitch flat plate 22b.₄Is the pitch D between the widened pitch columns 21b.₂It is formed in the same way. Further, the outer diameter of each of the columns 21a and 21b is formed to be smaller than the inner diameter of each of the positioning through holes 24a and 24b by a clearance.
[0021]
Therefore, by fitting the positioning through hole 24a of the precision pitch flat plate 22a and the precision pitch support 21a and fitting the positioning through hole 24b of the wide pitch pitch flat plate 22b and the wide pitch support 21b, As shown in FIG. 5, the fiber arrangement flat plates 22a and 22b can be accurately arranged at a plurality of predetermined positions on the circumference of the fiber winding bobbin 19, respectively. Can be stacked on each of the fiber arrangement flat plates 22a and 22b thus arranged. In the laminated body 25 of the precision pitch flat plates 22a thus laminated, the fibers 1 are arranged at a small arrangement pitch, as will be described in detail later. It will be arranged with a larger arrangement pitch than the laminated body 25 of the pitch flat plates 22a.
When the fiber arranging flat plates 22a and 22b are arranged and laminated on the circumference of the fiber winding bobbin 19, the surface on which the concave stripes 23a and 23b are formed is set as the outer surface.
Further, in this example, the 60 precision pitch flat plates 22a are laminated on the six sets of precision pitch columns 21a by 10 steps, respectively, and the 60 wide pitch columns 22b are also stacked on the six sets of wide pitch columns 21b. Each of them is laminated in ten stages. And, since each of the fiber arranging flat plates 22a and 22b is formed with ten concave stripes 23a and 23b, the fiber 1 is finally converted to 10 by using the fiber arranging apparatus 10 of this example. It can be stacked in rows × 10 stages.
[0022]
In FIG. 5, a spacer 31 having the same shape as the precision pitch flat plate 22a and having no concave strip 23a formed thereon is fitted to the precision pitch support column 21a, and then ten precision pitch flat plates 23a are laminated.
[0023]
The material and manufacturing method of these fiber arrangement flat plates 22a and 22b are not limited as long as the concave stripes 23a and 23b of the correct size are formed. For example, as the precision pitch flat plate 22a, from the viewpoint of corrosion resistance and strength, a stainless steel flat plate having a concave shape formed by photo-etching or a resin such as polymethyl methacrylate is precision-molded using a precision mold. Those molded by injection molding are preferably used. As the flat plate for widening pitch 22b, the same plate as the flat plate for precision pitch 22a can be preferably used, and in view of cost and workability, stainless steel or aluminum flat plate is machined to form the concave strips 23a and 23b. Can also be used.
The cross-sectional shape of the formed ridges 23a and 23b is not limited to a rectangular shape as in the illustrated example, and the bottom of the ridge 21 is formed in a curved shape along the outer shape of the fiber 1 (U-shape). It may be trapezoidal or V-shaped.
[0024]
The fiber arrangement device 10 of the example of FIG. 1 includes such a fiber winding means 11 and a fiber supply means 12, and further applies a tension to the fibers 1 supplied to the fiber supply means 12. Tension applying means 27 is provided.
The tension applying means 27 of this example includes a torque motor 28 connected to the fiber supply bobbin 14 and a tensioner 29 provided on the downstream side of the guide roller 15, whereby the movable guide 16 is formed as described above. When supplying the fiber 1 while moving, a certain range of tension can be constantly applied to the fiber 1 so that the fiber 1 is not excessively strained or loosened.
[0025]
As described above, according to the fiber arranging apparatus 10 of this example, the fibers 1 can be accurately arranged in 10 rows × 10 stages, and in the laminate 25 of the precision pitch flat plates 22a, the fibers 1 Are arranged at a small arrangement pitch, and in the laminate 26 of the widened pitch flat plates 22b, the fibers 1 are arranged at a larger arrangement pitch than the laminate 25 of the precision pitch flat plates 22a. Therefore, by using such a fiber arrangement device 10, as will be described later in detail, one end side is arranged at a precise arrangement pitch, and the other end side is arranged at an arrangement pitch wider than this. You can get two bodies.
[0026]
Further, in this example, each of the fiber arrangement flat plates 22a and 22b has ten recessed stripes 23a and 23b, and the fiber arrangement flat plates 22a and 22b are laminated in ten steps to obtain a fiber arrangement. Can be arranged in 10 rows × 10 stages, but the number of the concave strips 23a and 23b and the number of laminating stages formed on one fiber arranging flat plate 22a and 22b are not limited as long as each is plural. Can be set as desired. Preferably, the number of the ridges 23a, 23b formed on each of the fiber array flat plates 22a, 22b is The number of laminating layers of the fiber arranging flat plates 22a and 22b is in the range of 5 to 100.
Further, the number of the recessed stripes 23a, 23b formed may be different for each of the fiber arrangement flat plates 22a, 22b used in each stage, and the number of fibers 1 arranged in each stage may be changed.
In this example, the pitch between the positioning through holes 24a in the precision pitch flat plate 22a is D₃The pitch between the positioning through holes 24b in the widened pitch flat plate 22b is D₄, But D₃= D₄It may be. In this case, the pitch of the columns 21a and 21b is also D₁= D₂It is necessary to
Furthermore, in this example, the fiber winding bobbin 19 is a hexagonal prism, but is not limited to a hexagonal prism as long as the fiber 1 can be wound by rotating about the shaft 19a. For example, it may be a prism having three to five or seven or more side surfaces, and may not be a prism. However, it is preferable to use a prism having 4 to 8 side surfaces, since the fibers 1 can be arranged while the fiber arrangement flat plates 22a and 22b are stably arranged and laminated on the periphery thereof.
[0027]
In the fiber arrangement flat plates 22a and 22b provided in the fiber arrangement device 10 of this example, the flat stripes 23a and 23b are formed on the flat plate, and the fibers 1 are arranged in the concave stripes 23a and 23b. Are precisely arranged at predetermined positions and are preferably used, but are not necessarily formed with the concave stripes 23a and 23b. For example, a configuration in which an adhesive layer or an adhesive layer is formed on a surface that becomes an outer surface when the fiber 1 is disposed on the periphery of the fiber winding bobbin 19, and the fiber 1 may be fixed. In order to form an adhesive layer or an adhesive layer, a method of applying an adhesive or an adhesive on the surface to be the outer surface of the flat plate, a method of attaching a commercially available double-sided tape on the surface to be the outer surface of the flat plate, and the like are mentioned. As the pressure-sensitive adhesive, the adhesive, and the double-sided tape, those made of a material that does not attack the fiber 1 are used. If a material that invades the fiber 1 is used, the fiber 1 may be broken while the fibers 1 are being arranged. As the adhesive, a water-soluble vinyl acetate-based adhesive is preferable.
[0028]
[Fiber arrangement method and fiber roll]
Next, a specific method for arranging the fibers 1 in 10 rows × 10 stages using the fiber arrangement device 10 in the illustrated example will be described.
First, positioning through holes 24a and 24b of the widened pitch flat plate 22b or the fine pitch flat plate 22a are fitted to all the widened pitch columns 21b and the precision pitch columns 21a of the fiber winding bobbin 19, and are arranged one by one. A first step is performed. At this point, a total of twelve wide-width pitch flat plates 22b and precision pitch flat plates 22a are arranged on the circumference of the fiber winding bobbin 19. The spacers 31 are arranged on the columns 21a for precision pitch as necessary before the flat plates 22a for precision pitch are arranged.
[0029]
Next, the fiber winding bobbin 19 is rotated a predetermined number of times, and the movable means 16 is moved by the control means to perform the second step of arranging the fibers 1 on the arranged fiber arrangement flat plates 22a and 22b. .
That is, first, by rotating the fiber winding bobbin 19 once, the movable guide 16 supplies the concave strips 23a and 23b at one end of each of the fiber arranging flat plates 22a and 22b arranged in the first step. The inserted fibers 1 are sequentially inserted. Here, the concave strip 23b at one end of the flat plate 22b for widening pitch and the concave strips 23a, 23b at one end of the flat plate 22a for precision pitch are not on the same circumference. The fiber 1 is supplied while moving in the axial direction.
After making one rotation in this way, the movable guide 16 is moved in the X-axis direction and the fiber winding bobbin 19 is continuously rotated in order to insert the fiber 1 into the adjacent ridges 23a and 23b.
In this example, ten flat strips 23a and 23b are formed on the fiber-arranging flat plates 22a and 22b, respectively. Therefore, by rotating the fiber winding bobbin 19 ten times, the concave strip on the other end is formed. The fibers 1 can be sequentially arranged at 23a and 23b, and the fibers 1 can be arranged at all the concave stripes 23a and 23b in the arranged fiber arrangement flat plates 22a and 22b.
It is preferable that a tension of 1 to 20 mN, preferably 5 to 10 mN is applied to the fibers 1 arranged in this manner by the tension applying means 27.
Further, it is preferable that the distance between the tip of the movable guide 16 and the fiber winding bobbin 19 is as short as possible from the viewpoint of accurate arrangement, and the tip of the movable guide 16 and the fibers 1 from the movable guide 16 are arranged. It is more preferable that the shortest distance (clearance) between the fiber arrangement flat plates 22a and 22b and the concave stripes 23a and 23b is always in the range of 0.1 to 2 mm.
[0030]
After finishing the second step in this way, a third step of laminating the other fiber-arranging flat plates 22a and 22b one by one on the respective fiber-arranging flat plates 22a and 22b on which the fibers 1 are arranged is performed.
That is, similarly to the case of the first step, the positioning through holes 24a of the widened pitch flat plate 22b or the fine pitch flat plate 22a are formed in all the widened pitch columns 21b and the fine pitch columns 21a of the fiber winding bobbin 19. , 24b, and the fiber arrangement flat plates 22a, 22b are laminated one by one on each set of the columns 21a, 21b. At this point, a total of 24 fiber arranging flat plates 22a and 22b are arranged on the circumference of the fiber winding bobbin 19.
[0031]
After the third step is completed, the fiber winding bobbin 19 is rotated again, and the movable guide 16 is also moved in the Z-axis direction (upward), so that the newly arranged fiber arrangement flat plate 19 is moved. A second step of sequentially arranging the fibers 1 in the concave stripes 23a and 23b is performed. Then, a third step is further performed.
[0032]
As described above, the second step and the third step are repeated a predetermined number of times, and finally ten fiber arranging flat plates 22a and 22b are laminated on each set of columns 21a and 21b, and the uppermost fiber arranging plate is formed. By arranging the fibers 1 in all the concave stripes 23a and 23b of the flat plates 22a and 22b, the fibers can be arranged in 10 rows × 10 steps. In addition, after arranging the fibers on the tenth stage, that is, the uppermost fiber arrangement flat plates 22a and 22b, when placing and laminating other fiber arrangement flat plates 22a and 22b thereon (third step), As long as it is not necessary, the fiber arranging flat plates 22a and 22b may be omitted, and instead of placing the fiber arranging flat plates 22a and 22b, the fiber arranging flat plates 22a and 22b have the same shape and the same size as those of the fiber arranging flat plates 22a and 22b except that the concave stripes 23a and 23b are not formed. A holding plate may be placed so that the uppermost fiber 1 does not protrude from the groove.
[0033]
By arranging the fibers in 10 rows × 10 stages in this manner, two or more fibers are respectively disposed at predetermined positions on the fiber winding bobbin 19 and a plurality thereof (12 positions in this example) as shown in FIG. It has fiber winding means provided with laminates 25 and 26 composed of laminated fiber array flat plates 22a and 22b, and the fibers 1 wound and wound on the outer surface of each fiber array flat plate 22a and 22b. Can be obtained. In particular, the wound fiber 30 of this example has a total of twelve laminates 25 and 26, but includes six laminates 25 each composed of a precision pitch flat plate 22a and six laminates each composed of a widened pitch flat plate 22b. The two laminates 26 have different arrangement pitches of the fibers 1 arranged on the outer surfaces of the fiber arrangement flat plates 22 a and 22 b constituting the two laminates 26. They are arranged at a pitch.
[0034]
[Method for producing fiber array body]
Next, one method of manufacturing two fiber arrays 32 as shown in FIG. 7 from the fiber winding 30 of FIG. 6 obtained by the above-described method will be described.
The fiber array body 32 is a portion of the fibers 1 arranged in 10 rows × 10 stages that are precisely arranged by the precision pitch flat plate 22a (a portion located between the laminates 25 composed of the precision pitch flat plate 22a). ) Are fixed in a block shape with the curable resin 33 while maintaining the arrangement state, and the arrangement state of the portion arranged by the widening pitch flat plate 22b is changed by the laminate 26 composed of the widening pitch flat plate 22b. It has been maintained. As will be described in detail later, the portion of the fiber array 32 fixed by the curable resin 33 is sliced in a direction crossing the fiber 1, preferably in a direction substantially perpendicular to the fiber 1, and thinned to obtain a diagram. As a result, a biologically-related substance-immobilized microarray 35 as shown in FIG. 8 is obtained. In FIG. 7, reference numeral 34 denotes a frame member, which is fitted so that the laminate 26 formed of the wide-width pitch flat plate 22b does not collapse.
[0035]
As a method of manufacturing such a fiber array 32 from the fiber winding 30 shown in FIG. 6, 10 rows × 10 stages of fibers 1 passed between the laminates 25 made of the precision pitch flat plates 22 a are surrounded. There is a method of using a potting block for.
The potting block is preferably made of a metal such as aluminum, for example, and is preferably formed into a tubular shape by combining four plate-like block pieces 36a, 36b, 36c, and 36d as shown in FIG. it can. When these four pieces are combined into a cylindrical shape, the surface serving as the inner wall surface and the surface where the block pieces contact each other have a sheet-like material made of Teflon (registered trademark), polyethylene, polypropylene, or the like having high non-adhesiveness. It is preferable to perform a release treatment by attaching the object 37 to each surface. When the release treatment is performed as described above, the curable resin liquid is poured into the hollow portion 36e of the potting block 36 later, and after the curing, the potting block 36 and the cured resin can be easily separated. it can. Instead of performing the mold release treatment on the metal block pieces 36a, 36b, 36c, and 36d in this manner, the potting block itself may be formed of a resin having high non-adhesiveness.
[0036]
A semi-conical notch 38 whose diameter increases toward one end is formed on one surface of the inner wall surface of the cylindrical potting block 36 as in this example. Into the hollow portion 36e of the potting block 36 to form a filling port for filling.
[0037]
As shown in FIG. 10, the potting block 36 surrounds the fibers 1 between the laminates 25 made of the precision pitch flat plates 22 a and has no filling port formed in the potting block 36. Is fixed so that one end thereof closely adheres to the laminate 25 of the one precision pitch flat plate 22a. In this case, a sealing member made of silicone rubber or the like having releasability and elasticity is provided so that a curable resin liquid to be filled later does not leak from a contact portion between the potting block 36 and the laminate 25. Intervene.
Thereafter, the curable resin liquid is poured into the hollow portion 36e of the potting block 36 from the filling port formed in the potting block 36 so that one end (opening end) on the side where the filling port is formed faces upward. . Thereafter, the castable resin liquid is hardened by leaving it at a predetermined temperature for a predetermined time.
[0038]
When the curable resin liquid is filled as described above, it is preferable that the curable resin liquid is previously stirred under vacuum to remove bubbles. By defoaming in this way, there is no void inside the cured resin, and the resin is sufficiently spread between the fibers 1. More preferably, the curable resin liquid is sufficiently defoamed as described above, and the above-described resin filling operation is preferably performed under reduced pressure.
[0039]
After the curable resin liquid filled in the potting block 36 is cured, the potting block 36 is disassembled into four block pieces 36a, 36b, 36c, and 36d, so that the fibers precisely arranged in 10 rows × 10 stages are formed. Can be fixed in a block shape with resin.
[0040]
Further, in the same manner as described above, the fibers 1 between the laminates 25 composed of the other precision pitch flat plates 22a in the fiber winding 30 are also fixed with the curable resin 33, and the state shown in FIG. And
Thereafter, the fibers 1 of 10 rows × 10 stages in the fiber wound material 30 are appropriately cut, and all the precision pitch flat plates 22a are removed. Further, the widened pitch flat plates 22b are also indicated by reference numeral 26a in FIG. By removing all but the two laminates, two fiber arrays 32 in the state of FIG. 7 can be obtained.
[0041]
As the type of the curable resin 33 used here, the curable resin liquid is a liquid having a low viscosity at room temperature, and the filling and curing of the hollow portion 36e of the potting block 36 can be performed at room temperature. It is preferable to use a blade which can be easily sliced to a certain thickness with a blade or the like and which has an appropriate hardness and elasticity such that the obtained slice does not chip or break. Examples of such a curable resin 33 include a two-component reaction curable resin such as a urethane resin.
[0042]
(fiber)
There is no particular limitation on the type of the fibers 1 arranged and fixed as described above, and synthetic fibers, semi-synthetic fibers, regenerated fibers, inorganic fibers, and other synthetic fibers, natural fibers, and composite fibers thereof. And the like.
Examples of synthetic fibers include polyamide-based fibers such as nylon 6, nylon 66 and aromatic polyamide, polyester-based fibers such as polyethylene terephthalate, polybutylene terephthalate, polylactic acid and polyglycolic acid, and acrylic-based fibers such as polyacrylonitrile. Various fibers, various fibers of polyolefin such as polyethylene and polypropylene, various fibers of polyvinyl alcohol, various fibers of polyvinylidene chloride, various fibers of polyvinyl chloride, polyurethane; phenolic fiber, polyvinylidene fluoride and poly Fluorine fibers such as tetrafluoroethylene, polyalkylene paraoxybenzoate fibers, fibers using (meth) acrylic resins such as polymethyl methacrylate, and fibers using polycarbonate resins. And the like.
[0043]
Examples of the semi-synthetic fibers include various cellulose-based fibers derived from diacetate, triacetate, chitin, chitosan, and the like, and various protein-based fibers called promix.
Examples of the regenerated fiber include various cellulosic regenerated fibers (rayon, cupra, polynosic) obtained by a viscose method, a copper-ammonia method, or an organic solvent method.
Examples of the inorganic fibers include glass fibers, carbon fibers, and metal fibers such as Au, Ag, Cu, and Al.
Examples of natural fibers include vegetable fibers such as cotton, flax, ramie, jute, animal fibers such as wool and silk, and mineral fibers such as asbestos.
[0044]
These fibers 1 can be used as appropriate for the production of the fiber array body 32. However, when arranging the fibers 1, tension is applied to the fibers 1 as described above. Polycarbonate fibers, polyester fibers, nylon fibers, aromatic polyamide fibers, etc. having high yield strength are preferably used.
In addition, fibers other than natural fibers can be obtained by known spinning techniques such as a melt spinning method, a wet spinning method, and a dry spinning method, or a technique combining these, and any of those obtained in this manner can be used. .
Further, these fibers 1 may be untreated fibers as they are, but if necessary, fibers having a reactive functional group introduced therein, or plasma treatment, γ-ray, electron beam, etc. Those subjected to radiation treatment may be used.
[0045]
The form of these fibers 1 is not particularly limited, and may be a monofilament or a multifilament. Further, a spun yarn obtained by spinning short fibers may be used. Further, hollow fibers, fibers having a porous structure, or the like may be used. The hollow fiber can be manufactured by a known method using a special nozzle or the like.
[0046]
The outer diameter of the fiber 1 is not particularly limited, and a fiber having a desired outer diameter can be used. However, if the outer diameter is too small, the fiber 1 is easily broken, and the handleability is reduced. On the other hand, the smaller the outer diameter of the fiber 1 is, the higher the density of the fiber 1 can be arranged. Therefore, the outer diameter of the fiber 1 is set according to the balance between the handleability and the desired arrangement density, and the outer diameter of the fiber 1 is preferably 500 μm or less, more preferably 300 to 100 μm. When a multifilament is used as the fiber 1, 83 dtex / 36 filament, 82 dtex / 45 filament, or the like can be used as it is.
[0047]
For example, when manufacturing the bio-related substance-immobilized microarray 35 from the fiber array body 32, when monofilaments having an outer diameter of 150 μm are used as the fibers 1 and arranged at an arrangement pitch of 200 μm, 1 cm²The number of fibers 1 that can be arranged in a square of 2400 is 2400. Therefore, by immobilizing one kind of bio-related substance on one fiber, 1 cm²2400 kinds of bio-related substances can be immobilized. Moreover, when monofilaments of porous fibers, hollow fibers or porous hollow fibers having an outer diameter of about 200 μm are arranged at an arrangement pitch of 200 μm, 1 cm²A fiber array 32 in which about 1000 fibers 1 are arranged per one fiber can be obtained. By fixing one kind of bio-related substance to one fiber 1, 1 cm²Each time, 1000 kinds of bio-related substances can be immobilized.
[0048]
[Production method of microarray immobilized bio-related substance]
Next, a method of manufacturing the bio-related substance-immobilized microarray 35 from the fiber array 32 obtained as described above will be described.
Here, in the case where a material on which a biological substance is immobilized in advance is used as the fiber 1, this fiber array 32 is sliced in a direction intersecting with the fiber 1 and sliced, thereby obtaining a thin slice as shown in FIG. As shown in the figure, the fiber 1 on which the biological substance is immobilized is fixed by the curable resin 33, and the flaky biological substance immobilized microarray 35 in which the cross section of the fiber 1 is exposed on both surfaces can be obtained. The means for slicing is appropriately selected, and a microtome, laser, or the like is used. The slicing direction may be any direction as long as it intersects with the fiber 1, but is preferably perpendicular to the length direction of the fiber 1.
When the bio-related substance immobilized on the fiber 1 is, for example, a nucleic acid, the obtained bio-related substance immobilized microarray 100 is reacted with a sample to perform hybridization, whereby the nucleic acid immobilized on the fiber is converted. A specific polynucleotide present in a specimen as a probe can be detected.
[0049]
When a multifilament or a spun yarn is used as the fiber 1, a bio-related substance can be fixed in the gap between the single fibers. When a hollow or porous fiber is used as the fiber 1, the fiber 1 is used. A bio-related substance can be fixed in a hollow portion or a void inside the inside.
[0050]
On the other hand, when a porous fiber, a hollow fiber, or a porous hollow fiber on which a bio-related substance is not immobilized is used as the fiber 1, as shown in FIG. A well plate 39 is prepared, and the end of each fiber 1 on the side where the arrangement state is maintained by the laminate 26 of the widened pitch flat plates 22b and the frame member 34 in the fiber arrangement body 32 of FIG. , One by one. Then, the other end of the fiber 1 is depressurized, and the liquid is sucked, whereby the liquid containing the bio-related substance is sucked up in the hollow portion or the porous portion of each fiber 1, and the bio-related substance is put into each fiber 1. Can be introduced. As the well plate 39, a commercially available one can be used.
At this time, if the arrangement pitch of the fibers 1 in the widening pitch flat plate 22b and the pitch of each section in the well plate 39 are previously set to be the same, the end of each fiber can be easily immersed one by one in each section. Can be.
In addition, the kind of the bio-related substance to be introduced into each fiber 1 may be different for all the fibers 1 of 10 rows × 10 stages, or may be partly the same kind, and can be set as appropriate. If they are all different, a biomaterial-fixed chip 35 on which 100 types of biomaterials are fixed can be obtained.
[0051]
As the bio-related substance introduced into the fiber 1 as described above,
(1) nucleic acids, amino acids, sugars or lipids,
(2) a polymer comprising at least one component among the substances of (1),
(3) a substance having an interaction with the substance of (1) or (2).
When a nucleic acid is used as a biological substance, preparation of DNA or RNA from living cells may be performed by a known method. For example, extraction of DNA is performed by the method of Blin et al. (Blin et al., Nucleic Acids Res. 3: 2303 ((1976))), and extraction of RNA is performed by the method of Favaroro et al. Methods Enzymol. 65: 718 (1980)).
In addition, linear or circular plasmid DNA or chromosomal DNA, DNA fragments obtained by cutting or chemically cutting these using restriction enzymes, DNA synthesized by an enzyme or the like in a test tube, or chemically synthesized DNA can be used. It can also be used.
[0052]
Further, as a liquid containing these bio-related substances, for example, an aqueous solution of acrylamide is used, and after sucking into the hollow portion or the porous portion of the fiber as described above, it is heated to 50 to 60 ° C. The gel supporting the related substance can be fixed to the hollow portion and the porous portion.
[0053]
As described above, when the fibers 1 are three-dimensionally arranged, as the fiber arrangement device 10, a fiber winding unit 11 for winding the fibers, and a fiber supply unit for supplying the fibers 1 to the fiber winding units 11. The fiber supply means 12 includes a movable guide 16 for supplying fibers while relatively moving with respect to the fiber winding means 11, and the fiber winding means 11 rotates around a shaft 19a while rotating. A fiber winding bobbin 19 on which the fiber 1 is wound, and a fiber arrangement flat plate on which a plurality of fibers are laminated on a plurality of predetermined positions on the circumference of the fiber winding bobbin 19, and the fiber 1 is arranged on each outer surface. By using the fibers having the fibers 22a and 22b, the fibers 1 can be arranged very efficiently with high density, high accuracy and in a short time, and the fiber array 32 can be industrially mass-produced. It becomes possible. That is, when such a fiber arranging apparatus 10 is used, it is not necessary to insert fibers one by one into a hole formed in a jig and penetrate the same as in the related art. Further, since there is no need to guide the fiber to be inserted to the hole with tweezers or the like, there is no problem that the fiber of the already inserted adjacent hole hinders the fiber insertion operation by tweezers or the like. Also, since the fibers 1 are not inserted into the holes but are arranged in the concave streaks 21, even if the fiber outer diameter is small and rigidity is low, the fibers 1 can be easily arranged and the density of the fibers 1 can be increased. It becomes.
[0054]
That is, by using the fiber arrangement device 10 described above, even if the fiber 1 has a small fiber outer diameter and is difficult to handle, the fiber arrangement can be performed with high density, accurately, and efficiently in a short time. 32 can be mass-produced, and as a result, a bio-related substance-immobilized microarray 35 capable of analyzing various kinds of samples can also be mass-produced.
[0055]
In addition, in particular, as the fiber arranging flat plates 22a and 22b, a plurality of recesses 23a and 23b for arranging the fibers 1 one by one are formed on the outer surface thereof in substantially parallel with each other. By using what is laminated on the circumference of the fiber winding bobbin 19 so that 23b is perpendicular to the axis 19a of the fiber winding bobbin 19, the fibers 1 can be more accurately and reliably arranged. Can be.
Further, by using the precision pitch flat plate 22a and the widening pitch flat plate 22b as the fiber arrangement flat plates 22a and 22b, for example, one end is arranged at a precise arrangement pitch, and the other end is wider than this. The fiber array 32 arranged at the pitch can be easily obtained. When such a fiber array 32 is used, a biological substance can be easily introduced into each fiber 1 using the well plate 39 as described above.
[0056]
【Example】
Hereinafter, the present invention will be specifically described with reference to examples.
<Example 1>
As a flat plate for fiber arrangement, the flat pitch flat plate 22b of FIG. 4 (b) is not provided at all, and only the fine pitch flat plate 22a of FIG. 4 (a) is provided in total of 120 pieces. Except for two points where only 12 sets (24 pieces) of the support columns 21a were erected, 10 rows × 10 pieces of polycarbonate hollow fibers having a diameter of 0.3 mm were formed using the fiber arrangement device 10 having the same configuration as that of FIG. Fiber windings arranged in a row were obtained.
The moving speed of the nozzle-shaped movable guide 16 in the X-axis direction is 12000 mm / min. The moving pitch was 0.42 mm, which is the same as the pitch of the concave stripe 23a in the precision pitch flat plate 22a. Further, a tension of 5 mN was applied to the hollow fibers arranged in this manner by a tension applying means. The shortest distance (clearance) between the tip of the movable guide 16 and the concave portion of the precision pitch flat plate 22a on which the fibers 1 are arranged from the movable guide 16 was set to always be 0.5 mm. The rotation speed of the fiber winding bobbin 19 was set at 10 rpm. The inner diameter, outer diameter, and length of the nozzle-shaped movable guide 16 were 0.4 mm, 0.7 mm, and 12 mm, respectively.
As a result, it was possible to obtain a wound fiber in which the fibers 1 were accurately arranged in 10 rows × 10 steps in an operation time of about 1 hour.
[0057]
<Example 2>
Using the fiber arrangement device 10 of FIG. 1, a fiber winding 30 as shown in FIG. 6 in which hollow fibers made of polycarbonate having a diameter of 0.3 mm were arranged in 10 rows × 10 stages was obtained.
The moving speed of the nozzle-shaped movable guide 16 in the X-axis direction is 12000 mm / min. The moving pitch is 0.42 mm, which is the same as the pitch of the recess 23a in the precision pitch flat plate 22a, for the precision pitch flat plate 22a, and is the concave pitch in the wide pitch pitch flat plate 22b for the wide pitch pitch flat plate 22b. The pitch was 4.5 mm, the same as the pitch of the ridge 23b. Further, a tension of 5 mN was applied to the hollow fibers arranged in this manner by a tension applying means. The shortest distance (clearance) between the tip of the movable guide 16 and the concave strips 23a and 23b of the fiber arrangement flat plates 22a and 22b on which fibers from the movable guide 16 are arranged is always 0.5 mm. Set. The rotation speed of the fiber winding bobbin 19 was set at 10 rpm.
As a result, it is possible to obtain a fiber winding 30 in which the fibers 1 are arranged in two types of arrangement pitches in one fiber winding 30 with 10 rows × 10 stages in an operation time of about 1 hour. Was completed.
[0058]
<Example 3>
The potting block 36 as shown in FIG. 9 is arranged in two places between the laminates 25 of the precision pitch flat plates 22a in the fiber wound product 30 obtained in Example 2, As shown in FIG. 10, a liquid of a polyurethane elastomer (Coronate 4403 / Nipporan 4276, mixed with Coronate 6: Nipporan 4 at a ratio) was poured and cured to obtain a state shown in FIG. After that, the fiber 1 is incised, the fiber arranging flat plates 22a, 22b are appropriately removed, and the like, and two block-like ones in which the fiber 1 is accurately arranged as shown in FIG. Was prepared. The operation time required about one hour before pouring the resin liquid.
[0059]
<Example 4>
The fibers 1 were arranged in the same manner as in Example 1 except that the torque motor 28 of the tension applying means 27 was not operated, and the clearance was set to 3 mm, to obtain a fiber wound product 30 as shown in FIG.
[0060]
<Example 5>
The fibers 1 were arranged in the same manner as in Example 1 except that the fibers 1 were supplied without passing through the tensioner 29 of the tension applying means 27, and a fiber winding 30 as shown in FIG. 6 was obtained.
[0061]
<Example 6>
The fibers 1 were arranged in the same manner as in Example 1 except that the clearance was set to 10 mm, to obtain a wound fiber 30 as shown in FIG.
[0062]
<Example 7>
Fibers 1 were arranged in the same manner as in Example 1 except that a plate having an adhesive layer made of a vinyl acetate-based adhesive was used as a flat plate for precision pitch, instead of forming a concave stripe, and FIG. 6 was obtained. Thereafter, the fiber 1 was fixed to the resin in the same manner as in Example 3, and two block-shaped hollow fiber arrays were formed.
[0063]
As described above, according to each of the examples, the fibers can be accurately arranged in a short time. In particular, according to Examples 1 to 3, particularly accurate arrangement of the fibers was possible. Further, in Example 3, a good fiber array in which the fibers were fixed while maintaining such a state was obtained.
On the other hand, in Examples 4 and 6, the arrangement state of the fibers was inferior to Examples 1 to 3. Further, in Example 5, there was a tendency that a large stress was applied to the fibers when the movable guide 16 was moved.
[0064]
<Comparative Example 1>
As a fiber arrangement jig, two stainless steel perforated plates having a thickness of 0.3 mm and having a diameter of 0.32 mm and a total of 49 holes arranged in seven rows and seven rows at a pitch of 0.42 mm and a total of 49 holes were used. For use, 49 hollow fibers made of polycarbonate (outer diameter 0.3 mm × length 1 m) were inserted into all the holes of the perforated plate, and the interval between the two perforated plates was set to 50 mm.
Then, the hollow fibers between the two perforated plates arranged in this way are arranged in a potting jig, and the same polyurethane elastomer (Coronate 4403 / Nipporan 4276) used in Example 3 is applied to the potting jig and the perforated plate. By pouring into the enclosed space, a block-shaped hollow fiber array having a length, width, and height of 20 mm × 20 mm × 50 mm was formed. It took about 6 hours before the resin solution was poured.
[0065]
【The invention's effect】
As described above, by using the fiber arrangement device of the present invention, fibers can be arranged accurately and at high density in a very short time. Further, in comparison with the conventional method of arranging the fibers by inserting the fibers into the holes of the jig, according to the present invention, it is also possible to prevent mistakes in the arrangement of the fibers.
Therefore, according to the present invention, a fiber array of fibers to which a bio-related substance is immobilized is efficiently produced, and this is sliced in a direction intersecting with the fibers, and sliced, so that the specific A biologically relevant substance-immobilized microarray capable of detecting the type and amount of a biologically relevant substance can be easily mass-produced.
[Brief description of the drawings]
FIG. 1 is a perspective view showing an example of a fiber arrangement device of the present invention.
FIG. 2 is an enlarged perspective view of a movable guide included in the fiber arrangement device of FIG.
3A is a perspective view and FIG. 3B is a front view of a fiber winding bobbin included in the fiber arrangement device of FIG.
FIG. 4 is a perspective view of (a) a precision pitch flat plate and (b) a widened pitch flat plate provided in the fiber arrangement device of FIG.
5 is a front view showing a state where the fiber arrangement flat plate of FIG. 4 is arranged and laminated at a predetermined position on the circumference of the fiber winding bobbin of FIG. 3;
FIG. 6 is a front view showing an example of a fiber wound product of the present invention.
FIG. 7 is a perspective view showing an example of a fiber array produced by the present invention.
FIG. 8 is a perspective view showing an example of a microarray immobilized with a biological substance manufactured by the present invention.
FIG. 9 is a perspective view showing an example of a potting block used in the present invention.
FIG. 10 is an explanatory view illustrating a method for producing a fiber array of the present invention.
FIG. 11 is an explanatory view illustrating a method for producing a fiber array of the present invention.
FIG. 12 is a perspective view showing one method of introducing a biological substance into each fiber of the fiber array.
[Explanation of symbols]
1 fiber
10 Fiber arrangement device
11 Fiber winding means
12 Fiber supply means
16 Movable guide
19 Textile winding bobbins
19a Shaft of bobbin for fiber winding
21a Precise pitch support
21b Support for wide pitch
22a Flat plate for precision pitch (flat plate for fiber arrangement)
22b Flat plate for wide pitch (flat plate for fiber arrangement)
23a, 23b concave streak
24a, 24b Through-hole for positioning
25,26 laminate
30 Textile rolls
32 fiber array
35 Biomaterial-immobilized microarray

Claims (13)

A fiber arrangement device for arranging fibers three-dimensionally,
Fiber winding means for winding the fiber,
Comprising a fiber supply means for supplying the fiber to the fiber winding means,
The fiber supply unit includes a movable guide that supplies fibers while relatively moving with respect to the fiber winding unit,
The fiber winding means includes a fiber winding bobbin for winding the fiber around the circumference while rotating, and a plurality of the fiber winding bobbin stacked at a plurality of predetermined positions on the circumference of the fiber winding bobbin. And a flat plate for arranging fibers. The flat plate for fiber arrangement has, on its outer surface, a plurality of concave stripes for arranging fibers one by one substantially parallel to each other, and the concave stripes are formed on the rotating shaft of the fiber winding bobbin. The fiber arrangement device according to claim 1, wherein the fiber arrangement device is laminated on the periphery so as to be perpendicular to the periphery. Among the laminates at the plurality of predetermined positions, the arrangement pitch of the fibers arranged on the outer surface of the fiber arrangement flat plate constituting at least one laminate is the fiber arrangement flat plate constituting another laminate. The fiber arrangement device according to claim 1, wherein the arrangement pitch is different from the arrangement pitch of the fibers arranged on the outer surface of the fiber. At least two positioning through-holes are formed in the flat plate for fiber arrangement, and a post inserted into each of the positioning through-holes is provided on the periphery of the bobbin for winding the fiber. Item 4. The fiber arrangement device according to any one of Items 1 to 3. A fiber arranging method for arranging fibers three-dimensionally, using the fiber arranging device according to any one of claims 1 to 4.
A first step of arranging one fiber arranging flat plate at each of the plurality of predetermined positions;
A second step of rotating the fiber winding bobbin a predetermined number of times, supplying fibers while moving the movable guide, and arranging the fibers on the arranged fiber arrangement flat plate,
A third step of laminating another fiber array flat plate on each of the fiber array flat plates on which fibers are arranged,
A fiber arranging method, wherein the second step and the third step are repeated a plurality of times. The fiber arrangement method according to claim 5, wherein the fibers are at least one selected from the group consisting of synthetic fibers, semi-synthetic fibers, regenerated fibers, inorganic fibers, and natural fibers. A method for producing a fiber array, comprising fixing the fibers three-dimensionally arranged by the fiber arrangement method according to claim 5. The method for producing a fiber array according to claim 7, wherein a curable resin is filled between the fibers, cured, and fixed. The method for producing a fiber array according to claim 7, wherein a biomaterial is fixed to the fiber in advance. The method for producing a fiber array according to claim 7 or 8, wherein a biomaterial is immobilized on the immobilized fibers. A method for producing a bio-related substance-immobilized microarray, comprising: slicing a fiber array produced by the method according to claim 9 or 10 in a direction intersecting with the fiber and slicing the fiber array. A fiber winding means having a fiber winding bobbin and a laminate of two or more fiber arrangement flat plates laminated at a plurality of predetermined positions on the periphery thereof,
What is claimed is: 1. A fiber roll comprising: fibers arranged and wound on an outer surface of each fiber array flat plate. Among the laminates at the plurality of predetermined positions, the arrangement pitch of the fibers arranged on the outer surface of the fiber arrangement flat plate constituting at least one laminate is the fiber arrangement flat plate constituting another laminate. 13. The wound fiber according to claim 12, wherein the pitch is different from an arrangement pitch of the fibers arranged on the outer surface of the fiber.

Images