JP6799851B2 - Sample processing method and sample processing kit - Google Patents

Description

The present invention relates to a sample processing method and a sample processing kit.

In recent years, in life science research, it is necessary to accurately analyze where a molecule exists in a biological sample and what kind of molecule exists in an interesting place in the biological sample. Is required.

In addition, when analyzing a biological sample, mass spectrometry imaging is required to display what kind of molecule is contained in the sample observed with a microscope, instead of simply taking out the sample and analyzing it. Has been done.

As a mass image device (method) that meets the above requirements,
(1) Using a laser microdissection device (hereinafter, may be referred to as “LMD”) provided with a drive control unit for controlling the drive of the sample movement mechanism and / or the heat-meltable film movement mechanism.
(2) The position coordinates of the sample to be collected and the position coordinates of the heat-meltable film to which the collected sample is attached are set in advance, and the interval at which the collected sample is attached to the heat-meltable film is wider than the interval between the original samples. By doing so, the spatial resolution when analyzing the sample can be improved.
(3) By directly mass spectrometrically analyzing the heat-meltable film to which the sample is attached, a sample with comprehensive position information can be cut out from a certain part on the biological tissue, and a peak mixed with unnecessary substances can be obtained. Capable of suppressed and highly sensitive mass spectrometry,
(4) From the position coordinates of the sample to be collected and the position coordinates of the heat-meltable film to which the collected sample is attached, the position information between continuous tissue sections can be accurately reproduced, and three-dimensional mass spectrometric imaging can be realized. ,
Is known (see Patent Document 1).

International Publication 2016/1633385

Patent Document 1 describes the following points as a method for analyzing a sample adhered to a heat-meltable film by LC-MS.
(1) Since the commercially available heat-meltable film is a flat film without partitions, when the reagent solution for analysis is dropped on the heat-meltable film to which the sample is adhered, the analysis is performed on the heat-meltable film. The reagent solution may diffuse and cause contamination.
(2) Therefore, the surface of the heat-meltable film is formed in regions having different hydrophilicity, and the region having high hydrophilicity is formed so as to be surrounded by the region having low hydrophilicity, whereby the reagent solution for analysis is thermally meltable. Does not contaminate on film.

By the way, a volatile extract may be used as an extract for extracting a sample adhered to a heat-meltable film. In that case, if the extract is dropped in order on a large number of samples adhered to the heat-meltable film, there is a problem that the first dropped extract evaporates.

The present application has been made to solve the above problems, and as a result of diligent research, a heat-meltable film in which a sample is adhered to a microtiter plate in which a well filled with a sample treatment liquid is formed is formed. It was newly found that the sample can be processed regardless of whether the treatment liquid is volatile or non-volatile by pressing the surfaces into close contact with each other.

That is, an object of the present application is to provide a sample processing method and a sample processing kit.

The present application relates to a sample processing method and a sample processing kit shown below.

(1) A treatment method for treating a sample adhered to a heat-meltable film.
Adhesion process between the heat-meltable film and the microtiter plate, in which the surface of the heat-meltable film to which the sample is adhered is pressed against the microtiter plate on which the well filled with the sample treatment liquid is formed to adhere.
A sample processing step of treating the sample with the treatment liquid,
A processing method that includes at least.
(2) The heat-meltable film is formed on the substrate,
A substrate peeling step of peeling the substrate and the heat-meltable film between the adhesion step and the sample processing step, or after the sample processing step.
The processing method according to (1) above, which comprises.
(3) The treatment method according to (1) or (2) above, which comprises a sampling step of adhering a sample to a heat-meltable film before the adhesion step.
(4) The sampling step is performed using a laser microdissection device,
The laser microdissection device is
A sample moving mechanism for moving a sample piece, a heat-meltable film moving mechanism for moving a heat-meltable film, and a heat-meltable film moving mechanism, and
A drive control unit that controls the drive of the sample movement mechanism and the heat-meltable film movement mechanism,
Including at least
In the sampling step, the drive control unit moves the sample moving mechanism and the heat-meltable film so that the position of the sample adhered to the heat-meltable film corresponds to the position of each well of the microtiter plate. Control the mechanism,
The processing method according to (3) above.
(5) The treatment method according to any one of (1) to (4) above, wherein the treatment method is any one of a sample extraction method, a sample pretreatment method, and a sample analysis method.
(6) The treatment method according to any one of (1) to (4) above is a sample extraction method or a sample pretreatment method.
Includes an analysis step of analyzing a sample extracted by the sample extraction method or a sample treated by the sample pretreatment method.
Sample analysis method.
(7) A heat-meltable film and a microtiter plate on which wells are formed,
A kit for sample processing, including.
(8) The opening of the well and the connecting portion of the opening are flat surfaces without steps.
The sample processing kit according to (7) above.
(9) The sample processing kit according to (7) or (8) above, wherein the heat-meltable film is formed on a substrate.
(10) The size of the heat-meltable film was formed in the region where the well of the microtiter plate was formed, or the region where the well was formed and the outer peripheral portion formed on the outer periphery of the well. The area is the same as one of the equally divided sizes,
The sample processing kit according to any one of (7) to (9) above.
(11) The shape of the microtiter plate is square or rectangular.
The heat-meltable film has a shape that can be arranged in parallel with the microtiter plate.
The sample processing kit according to (9) or (10) above.
(12) A contact portion for positioning when the heat-meltable film and the microtiter plate are brought into close contact with each other is formed on at least a part of the outer peripheral portion of the microtiter plate.
The sample processing kit according to any one of (7) to (11) above.

A sample adhered to a heat-meltable film can be treated by the treatment method described in the present application.

FIG. 1 is a diagram showing an example of an embodiment of a sample processing kit. FIG. 2A is a side view showing an example of a heat-meltable film formed on a substrate, and FIG. 2B is a cross-sectional view taken along the line aa of FIG. 2A. FIG. 2C is a side view showing another embodiment of the heat-meltable film formed on the substrate, and FIG. 2D is a cross-sectional view taken along the line bb of FIG. 2C. FIG. 3 is a cross-sectional view of the plate 20. FIG. 4A is a diagram showing an example of an embodiment of a sample processing kit. FIG. 4B is a diagram showing other embodiments of the sample processing kit. 5 (A) to 5 (C) are diagrams showing other embodiments of the sample processing kit. FIG. 6 is a diagram showing an outline of an example of LMD. 7 (A) and 7 (B) are schematic views for explaining a method of collecting a sample using LMD. 8 (A) and 8 (B) explain the relationship between the position coordinates of the sample at the location where the die section laser beam is irradiated and the position coordinates of the heat-meltable film to which the sample is adhered, and the drive control by the drive control unit. It is a figure for. FIG. 9A is a drawing substitute photograph, which is a photograph in which the heat-meltable film is adhered to the plate in Example 2. FIG. 9B is a drawing substitute photograph showing a state in which the treatment liquid stays at the portion where the sample is adhered. FIG. 10 is a graph showing the quantitative results of Example 2, Comparative Examples 1 and 2.

Hereinafter, the sample processing method (hereinafter, may be simply referred to as “treatment method”) and the sample processing kit (hereinafter, may be simply referred to as “kit”) will be described in detail.

FIG. 1 is a diagram showing an example of an embodiment of the kit 1. Kit 1 includes at least a heat-meltable film 10 and a microtiter plate (hereinafter, may be simply referred to as "plate") 20. At least two or more wells 21 are formed on the plate 20. The number of wells 21 is not particularly limited. General 6, 24, 96, 384, etc. may be appropriately determined according to the purpose. Further, the shape of the opening of the well 21 is not particularly limited, and may be appropriately determined such as a circular shape or a substantially square shape. The heat-meltable film 10 may be used alone, or may be formed on a substrate in order to improve the convenience of handling.

FIG. 2A is a diagram showing an example of a heat-meltable film 10 formed on the substrate 11, and FIG. 2B is a cross-sectional view taken along the line aa of FIG. 2A. In the embodiments shown in FIGS. 2A and 2B, the size of the heat-meltable film 10 and the size of the substrate 11 are the same. FIG. 2C is a diagram showing another embodiment of the heat-meltable film 10 formed on the substrate 11, and FIG. 2D is a cross-sectional view taken along the line bb of FIG. 2C. In the embodiment shown in FIGS. 2C and 2D, the heat-meltable film 10 is formed on a part of the substrate 11. As will be described later, the size of the heat-meltable film 10 is preferably the size obtained by equally dividing the plate 20. In the case of the embodiments shown in FIGS. 2C and 2D, since the substrate 11 is larger, the portion of the substrate 11a on which the heat-meltable film 10 is not formed can be sandwiched during handling. .. Therefore, it is possible to reduce the possibility of touching the heat-meltable film 10 to which the collected sample is adhered by hand or the like.

The heat-meltable film 10 is not particularly limited as long as it can adhere to the plate 20, and examples thereof include ethyl vinyl acetate (EVA), polyolefin, polyamide, acrylic, and polyurethane. The heat-meltable film 10 adheres to the plate after adhering the sample. In order to improve the adhesion, the heat-meltable film 10 may be heated and firmly adhered to the plate, but if the heat-meltable film 10 is heated at a high temperature, the collected sample may be thermally denatured. Further, when collecting a sample using LMD, it is preferable to carry out the sample at a temperature at which the sample is not thermally denatured. Therefore, the material of the heat-meltable film 10 preferably has a low melting point, and for example, a material having a melting point of about 50 to 70 ° C. is preferable.

When LMD is used for collecting a sample, an organic dye such as a naphthalene cyanine dye may be added to the heat-meltable film 10 in order to selectively absorb the spectrum of the wavelength range of the dissection laser light source. A suitable organic dye may be selected according to the wavelength range of the die section laser light source to be used. The heat-meltable film 10 may be produced by appropriately blending the above materials and organic dyes, or a commercially available heat-meltable film may be used. Examples of commercially available heat-meltable films include heat-meltable transfer films (manufactured by Electroseal) and heat-meltable EVA films (manufactured by Sigma-Aldrich Japan).

The substrate 11 is not particularly limited as long as it can be laminated with the thermosetting film 11, but when LMD is used for sampling, it is preferable that the die section laser light can pass through, for example, glass or a light transmitting resin. It may be produced in. The heat-meltable film 10 may be laminated on the substrate 11 by using a spin coat or the like. When the sample is placed on the heat-meltable film 10 with a pipette or the like, the substrate 11 may be light-impermeable, and may be formed of, for example, opaque glass, resin, metal, or the like. When the sample is placed with a pipette or the like, the sample is placed on the heat-meltable film 10 as shown in FIG. 2A so that the position of the placed sample and the position of the well 21 correspond to each other. The marker 12 indicating the position on which the sample is placed may be formed.

FIG. 3 is a cross-sectional view of the plate 20. The surface of the heat-meltable film 10 to which the sample is adhered is pressed against the plate 20 to adhere to the surface. At that time, if there is a step in the connecting portion 23 between the opening 22 of the arbitrary well 21 of the plate 20 and the opening 22 of the adjacent well 21, a gap is formed between the heat-meltable film 10 and the plate 20. , The treatment liquid filled in each well 21 may be contaminated. Therefore, it is preferable that at least the opening 22 of the adjacent wells 21 and the connecting portion 23 of the opening 22 have a flat surface without a step. In the present application, the "plane without step" means that the connecting portions 23 are substantially the same plane. However, the term "flat surface without steps" means that all of the connecting portions 23 of the plates 20 are substantially the same plane. For example, the wells 21 are divided into blocks, and the connecting portions 23 of each block are "flat without steps". It may be "flat".

Further, a step may be formed on the plate 20 other than the connecting portion 23. For example, the outer peripheral portion 24 may be formed on the outer side of the outermost well 21, and the contact portion 25 of the heat-meltable film 10 may be formed on a part of the end portion of the outer peripheral portion 24. By forming the abutting portion 25, it becomes easy to align the heat-meltable film 10 when it is brought into close contact with the plate 20.

The shape of the plate 20 is not particularly limited as long as the well 21 can be formed. For example, various shapes such as a circle and a polygon are possible, but a square or a rectangle is preferable in consideration of operability and the like. The shape of the bottom surface of the well 21 is not particularly limited as long as it does not interfere with the sample processing or the reaction process. For example, various shapes such as a flat bottom, a U bottom, and a V bottom are possible, but the U bottom or the V bottom is preferable in consideration of operability and the like.

When a single heat-meltable film 10 is used, the shape of the heat-meltable film 10 may be larger than the region where at least the wells 21 of the plate 20 are formed. When a sample is collected using the LMD, if the heat-meltable film 10 is too large, the heat-meltable film moving mechanism of the LMD also becomes large, and the LMD becomes large. Therefore, the heat-meltable film 10 may be smaller than the region where the well 21 is formed. In that case, in consideration of operability, the size of the heat-meltable film 10 is the region where the well 21 is formed or the region where the well 21 and the outer peripheral portion 24 are formed (hereinafter, two regions are referred to as "two regions". It may be described as "divided area"), and it is preferable to set it as one of the equally divided sizes. Equal division may be divided so that the dividing lines intersect on the dividing region, or may be divided so that the dividing lines are parallel. In the case of equal division, it may be divided into two divisions, three divisions, four divisions, five divisions, six divisions, or any other number.

FIG. 4A is a diagram showing an example of the embodiment of the kit 1, and shows an example in which the heat-meltable film 10 is divided into four so that the dividing lines intersect on the divided region. In the embodiment shown in FIG. 4A, the heat-meltable film 10 is brought into contact with all the ends of the outer peripheral portion 24 of the plate 20 in order to facilitate the alignment when the heat-meltable film 10 is brought into close contact with the plate 20. An example in which the part 25 is formed is shown. In this case, the divided region may be inside the contact portion 25. The contact portion 25 may or may not be formed on a part of the outer peripheral portion 24. FIG. 4B shows a preferred embodiment when the heat-meltable film 10 is formed on the substrate 11, and the substrate 11 is easily peeled off from the heat-meltable film 10 which is finally adhered to the substrate 11. The contact portion 25 is not formed on the portion corresponding to at least one side of the above. In other words, the contact portion 25 may be formed on the outer peripheral portion 24 other than the portion corresponding to the length of at least one side of the substrate 11. In the embodiment shown in FIGS. 4A and 4B, both the heat-meltable film 10 and the plate 20 are rectangular, but the plate 20 is square, polygonal, or circular, and the heat-meltable film 10 is formed. May have a shape in which the plate 20 (divided region) is equally divided.

FIG. 5A is a diagram showing another embodiment of the kit 1, in which the plate 20 is formed into a square or a rectangle and is divided into a size in which the heat-meltable film 10 is arranged in parallel on the divided region. .. In other words, the shape of the heat-meltable film 10 is also rectangular or square. In the embodiment shown in FIG. 5A, the heat-meltable film 10 is brought into contact with all the ends of the outer peripheral portion 24 of the plate 20 in order to facilitate the alignment when the heat-meltable film 10 is brought into close contact with the plate 20. Although an example in which the portion 25 is formed is shown, the contact portion 25 may or may not be formed on a part of the outer peripheral portion 24. FIG. 5B shows a preferred embodiment when the heat-meltable film 10 is formed on the entire surface of the substrate 11, and the outer periphery of the substrate 11 is easily peeled off from the heat-meltable film 10 which is finally adhered to the substrate 11. The contact portion 25 is not formed on the portion corresponding to at least one side of the substrate 11 of the portion 24. In other words, the contact portion 25 may be formed other than the portion corresponding to the length of at least one side of the substrate 11 of the outer peripheral portion 24. 5 (C) is a diagram showing an embodiment of a plate 20 suitable for using the heat-meltable film 10 formed on a part of the substrate 11 shown in FIGS. 2 (C) and 2 (D). In the embodiment shown in FIG. 5C, abutting portions 25 are formed on three sides of the plate 20. After the heat-meltable film 10 is brought into close contact with the plate 20, the heat-meltable film 10 may be peeled off from the substrate 11 by sandwiching the portion of the substrate 11a with fingers. When forming the substrate 11a, in order to improve workability, the substrate 11a may be formed only on one side of the heat-meltable film 10. In other words, the size of the substrate 11 is the size obtained by stretching only one side of the heat-meltable film 10.

In addition, alphabets and numbers may be written on the plate 20 in order to specify the position of the well 21. When alphabets and numbers are produced by steps, they may be formed on the contact portion 25 so as not to be flush with the connecting portion 23. When forming alphabets or numbers on the outer peripheral portion 24, they may be formed at a position provided with a distance that does not affect the adhesion of the heat-meltable film 10, or may be printed so as not to cause a step. When alphabets and numbers are formed on the outer peripheral portion 24, when the heat-meltable film 10 is equally divided, the region including the outer peripheral portion 24 may be equally divided in addition to the region forming the well 21. .. In that case, the size of the outer peripheral portion 24 may be adjusted so that the equally divided dividing lines do not pass between the wells 21.

The well 21 is filled with a treatment liquid for the collected sample. The treatment liquid is not particularly limited as long as the collected sample can be treated and the heat-meltable film 10 is insoluble. When the sample is extracted from the heat-meltable film 10, the sample extract may be used as the treatment liquid. When denaturing the extracted sample, the extract and the denaturant may be mixed, or a denaturing reagent may be added to the extract. When analyzing the extracted sample, the extract and the analytical reagent solution may be mixed, or the analytical reagent may be added to the extract. On the other hand, when the sample is analyzed on the heat-meltable film 10 without extracting the sample adhered to the heat-meltable film 10, the analysis reagent solution may be used as the treatment liquid. Further, when the sample is modified on the heat-meltable film 10, a modifying solution may be used as the treatment solution.

Examples of the extract include a mixed solution of acetonitrile and water; alcohols such as methanol and ethanol; and the like. The denaturing solution (denaturing reagent) includes surfactants such as sodium dodecyl sulfate (SDS) and cetyltrimethylammonium bromide (CTAB); acids / alkalis; guanidine salts; urea; organic solvents; chemicals such as alkylating agents. Modifiers; enzymes and the like. Examples of the analytical reagent solution (analytical reagent) include enzymes, substrates for enzyme reactions, labeled antigens or antibodies as necessary, reagents for hybridization and the like.

The plate 20 may be made of a material that does not dissolve in the filled treatment liquid. For example, resins such as polypropylene and polystyrene may be mentioned, but other resins may also be used. Further, it may be made of a non-resin material such as glass.

Examples of the sample include liquid samples such as blood, saliva, and urine collected from a living body, living tissues such as muscle, bone, brain, and organ, food, soil, bacteria, and viruses.

Next, an embodiment of a method for treating a sample adhered to a heat-meltable film will be described. The processing method is
(1) Adhesion step between the heat-meltable film and the microtiter plate, in which the surface of the heat-meltable film to which the sample is adhered is pressed against the microtiter plate on which the well filled with the sample treatment liquid is formed to adhere to the microtiter plate.
(2) A sample processing step of treating the sample with the treatment liquid,
At least contains.

In addition, as another embodiment of the processing method, if necessary,
(3) A substrate peeling step of forming a heat-meltable film 10 on a substrate 11 and peeling the substrate 11 and the heat-meltable film 10 between the adhesion step and the sample processing step, or after the sample processing step.
And / or
(4) A sample sampling step of cutting out a sample from a sample piece and adhering it to a heat-meltable film 10 before the adhesion step.
May be further included.

When a sample extract is used as the treatment liquid, the treatment method can be said to be a sample extraction method. Samples of proteins, peptides, nucleic acids and the like extracted by the extract may be analyzed by an analyzer (method) described later.

When a mixed solution of a sample extract and a denaturing solution (denaturing reagent) is used as the treatment solution, the treatment method can also be said to be a sample analysis pretreatment method. For example, a sample of a protein, peptide, nucleic acid, etc. extracted by an extract is pretreated with a denaturing solution (denaturing reagent) to denature (single-stranded nucleic acid, release of three-dimensional structure of protein, etc.), and then performed. It can be analyzed by the analyzer (method) of the period.

When a mixed solution of a sample extract and an analytical reagent solution (analytical reagent) is used as the treatment solution, the treatment method can also be said to be a sample analysis method. For example, a sample of a protein, peptide, nucleic acid or the like extracted from the extract can be analyzed in the well 21 by an enzymatic reaction, hybridasen sean or the like.

When a modified sample is used as the treatment liquid, the treatment method can also be said to be a sample analysis pretreatment method. For example, nucleosomes can be denatured on the heat-meltable film 10 to perform pretreatment to expose nucleic acids, and then analysis such as in situ LCR (PCR) can be performed.

When a sample analysis reagent solution is used as the treatment solution, the treatment method can also be said to be a sample analysis method. For example, the sample on the heat-meltable film 10 can be analyzed by enzymatic reaction, hybridization or the like.

The close contact process may be performed manually or may be automated. Further, in the adhesion step, since the heat-meltable film 10 is firmly adhered to the connecting portion 23, the heat-meltable film 10 may be heated. The heat treatment may be performed by heating the heat-meltable film 10 on a hot plate or the like.

The sample treatment step is not particularly limited as long as the sample can be treated with the treatment liquid. For example, after the heat-meltable film 10 is brought into close contact with the plate 20, the heat-meltable film 10 may be placed on the lower side so that the treatment liquid and the sample come into contact with each other. Further, if necessary, the plate 20 may be shaken in a state where the treatment liquid and the sample are in contact with each other.

The substrate peeling step is not particularly limited as long as the heat-meltable film 10 can be peeled from the substrate 11 so that the heat-meltable film 10 in close contact with the plate 20 does not peel off from the plate 20.

In the sampling step, when the heat-meltable film 10 shown in FIG. 2 (A) is used, the sample may be manually or automatically spotted at the position of the marker 12. In addition, LDM can also be used in the sampling step.

FIG. 6 is a diagram showing an outline of an example of LMD. The LMD 30 shown in FIG. 6 includes at least a heat-meltable film moving mechanism 40, a sample moving mechanism 50, a laser irradiation unit 60, and a drive control unit (not shown).

The heat-meltable film moving mechanism 40 has a heat-meltable film mounting table 41 on which the heat-meltable film 10 (the substrate 11 on which the heat-meltable film 10 is formed) can be placed, and a heat-meltable film mounting table 41. It includes a driving source (not shown) for moving in the horizontal direction (X, Y-axis direction) and a driving force transmission mechanism for transmitting the driving force of the driving source to the heat-meltable film mounting table 41. As the drive source, a pulse motor, an ultrasonic motor, or the like may be used. Further, as the driving force transmission mechanism, a known one such as a driving force transmission mechanism used in an inverted microscope or the like may be used.

The sample moving mechanism 50 has an arm 52 on which a sample piece 51 can be placed at one end and can be attached to an arm strut at the other end, and the arm 52 is rotated in the horizontal direction (X, Y axis direction) and vertically ( An arm strut 53 that can move in the Z-axis direction), a drive source (not shown) for rotating and moving the arm 52 in the horizontal direction and in the vertical direction, and rotating and moving the arm 52 by transmitting the driving force of the drive source. Includes a driving force transmission mechanism for As the drive source, a pulse motor, an ultrasonic motor, or the like may be used. Further, as the driving force transmission mechanism, a known arm mechanism capable of rotating in the horizontal direction and moving in the vertical direction, such as an arm mechanism for moving a sample of an automatic analyzer, may be used. The sample moving mechanism 50 is not limited to the embodiment illustrated in FIG. 6, and is not particularly limited as long as the sample can be moved in the horizontal direction and the vertical direction.

As the die section laser light source used in the laser irradiation unit 60, it is preferable to use a single-mode fiber output laser light in order to minimize the irradiation spot, and a high NA long focus objective for near infrared light for focusing. It is preferable to use a lens. The pulse width is 0.1 ms to 100 ms, preferably 5 ms, the wavelength is 785 nanometers to 900 nanometers, preferably 808 nanometers, the output is 0.2 watts to 0.3 watts, and the irradiation. The laser power is preferably one capable of generating 0.1% to 100%, preferably 80% to 100% of pulsed laser light, and specific examples thereof include Z-808-200-SM (manufactured by Lucille). .. In the LMD shown in FIG. 6, the laser irradiation unit 60 is arranged above the sample moving mechanism 50 of the LMD, but it may be arranged below. Further, a laser beam may be irradiated from the side opposite to the laser irradiation unit 60 by using an optical system (not shown).

FIG. 7 is a schematic view for explaining a method of collecting a sample using LMD. FIG. 7A shows a state before the sample piece 51 and the heat-meltable film 10 are brought into contact with each other, and is an example of using a frame 54 which is a pressing means for pressing the sample piece 51 against the heat-meltable film 10. It shows. The frame body 54 has a substantially convex cross section, and is inserted into the frame body insertion hole formed at the tip of the arm 52 so as to be slidable. A slide 55 on which the sample piece 51 is placed can be detachably attached to the lower portion of the frame body 54, and for example, a locking groove, a locking spring mechanism, and the like are formed. On the other hand, on the heat-meltable film moving mechanism 40 of the LMD 30, a substrate 11 and a heat-meltable film 10 for transferring a sample formed on the substrate 11 are placed.

In the state before pressing shown in FIG. 7A, the upper portion 541 of the frame body 54 is formed larger than the frame body insertion hole, so that the frame body 54 is locked to the arm 52. Then, as shown in FIG. 7B, lowering the arm 52 downward also lowers the frame 54, and even after the sample piece 51 comes into contact with the heat-meltable film 10, lowering the arm 52 lowers the frame. The sample piece 51 can be pressure-bonded to the heat-meltable film 10 by the weight of 54. Then, in the crimped state, the sample is cut out from the sample piece at the irradiated portion by irradiating the die section laser light, and the cut out sample is adhered to the heat-meltable film 10 by moving the arm 52 upward. be able to.

The degree of pressure bonding between the sample piece 51 and the heat-meltable film 10 may be adjusted by the weight of the frame body 54. The frame body 54 may be made of metal. Further, when irradiating the die section laser light through the frame body 54, the frame body 54 may be made hollow or made of glass or the like. The shape of the frame 54 is not particularly limited as long as it can be slidably inserted into the arm 52, and may be appropriately adjusted to be circular, square, rectangular, or the like according to the shape of the slide on which the sample piece 51 is placed. The frame 54 is not essential. For example, the sample piece 51 may be brought into close contact with the heat-meltable film 10 by attaching the sample piece 51 to the tip of the arm 52 and lowering the arm 52.

In the embodiments shown in FIGS. 6 and 7, the heat-meltable film moving mechanism 40 and the sample moving mechanism 50 are provided so that the sample piece 51 is on the upper side and the heat-meltable film 10 is on the lower side. It may be provided in reverse.

FIG. 8 is a diagram for explaining the relationship between the position coordinates of the sample cut out by irradiating the die section laser beam and the position coordinates of the heat-meltable film 10 to which the sample is adhered, and the drive control by the drive control unit. .. For example, when a sample is continuously cut out from the sample piece 51 of FIG. 8A as shown in a, b, and c, (i) the heat-meltable film moving mechanism 40 is used to disection the heat-meltable film 10 with a die section laser. Move to the position where the light is irradiated. (Ii) Next, the sample moving mechanism 50 moves the sample at the position shown in a of the sample piece 51 to a position where the sample a of the heat-meltable film 10 shown in FIG. Then, the sample piece 51 is pressed against the heat-meltable film 10 by lowering the arm 52 in the vertical direction. (Iii) By irradiating the die section laser light, the sample collected from the portion a of the sample piece 51 is adhered to the position a'of the heat-meltable film 10, and then the arm 52 is raised in the vertical direction. The sample piece 51 is separated from the heat-meltable film 10, and the sample a to be collected is adhered to a predetermined portion of the heat-meltable film 10. With respect to the collected samples b and c, the collected samples b and c can be adhered to the heat-meltable film 10 b'and c'by repeating the above steps (i) to (iii).

As shown in FIG. 8, individual samples collected from the sample piece 51 can be adhered to the heat-meltable film 10 at a position different from the position of the sample before collection. Therefore, the heat-meltable film moving mechanism 40 and the sample moving mechanism are set by the drive control unit so that the positions (a', b', c') of the sample to be adhered to the heat-meltable film 10 are the positions corresponding to the wells 21. By controlling the drive of 50, when the heat-meltable film 10 is brought into close contact with the plate 20, the collected individual samples and the wells 21 can be brought into close contact with each other in a one-to-one correspondence relationship. Further, when the distance between the samples adhered to the heat-meltable film 10 (the distance between the wells 21: B μm) is larger than the distance between the individual samples before collection (A μm), the spatial resolution of the analysis can be improved. In FIG. 8, the “interval” (B μm) is the distance between the center of the well 21 and the center of the adjacent well 21, but if the individual samples collected and the well 21 have a one-to-one correspondence, the interval is appropriately adjusted. You may.

The LMD 30 may be provided with a storage unit such as a memory. After analyzing the processed sample, the position coordinates of the sample before sampling and the position coordinates of the heat-meltable film 10 (well 21 number) for adhering the sample are stored in the storage unit in association with each other. Three-dimensional imaging can be created. Further, when plates 20 having different distances between the wells 21 are used, the distance between the wells 21 of each plate 20 (the distance between the samples adhered to the heat-meltable film 10) can be stored. Further, the LMD 30 may be provided with an image pickup device such as a CCD camera for photographing a sample, and a display unit for displaying an image captured by the image pickup device and information stored in the storage unit.

In the processing method of the present application, the heat-meltable film 10 acts as a lid by adhering to the plate 20. Therefore, even when the treatment liquid is volatile, it is possible to prevent the treatment liquid from vaporizing. The sample treated with the treatment liquid can be analyzed using various analyzers (analytical methods) as needed (analytical step). In the analysis step, the heat-meltable film 10 may be peeled off from the plate 20 and analyzed by various analyzers (analytical methods). When an extract is used as the treatment liquid, the heat-meltable film 10 may be pierced with a syringe or the like of an autosampler, and the sample extracted from the well 21 may be sucked out for analysis.

The analyzer (analytical method) is not particularly limited as long as it can analyze the extracted (processed) sample. For example, an analyzer including chromatography such as LC-MS, HPLC-fluorescence spectroscope, HPLC-electrochemical detector; electron beam microanalyzer; element analyzer such as X-ray photoelectron spectrometer; gene by PCR or LCR. A nucleic acid sequence analyzer that amplifies and analyzes the DNA sequence contained in the sample using a sequencer; microchip analysis of a DNA chip that hybridizes DNA using the nucleic acid contained in the sample as a template, and an antibody chip that reacts an antibody with a protein. Equipment; etc.

Hereinafter, embodiments will be specifically described with reference to examples, but does not represent limiting or limiting the scope of the invention disclosed in the present application.

[Making a kit]
<Example 1>
EVA (manufactured by Toyo Adre Co., Ltd.) was used as the heat-meltable film, and the heat-meltable film layer was formed on the glass substrate by spin coating on the slide glass. The thickness of the heat-meltable film layer was 100 μm.
A 384-well microtiter plate was used as the plate. The plate was made of polypropylene. The connecting portion between the wells was formed so as to be substantially flat.
A kit was prepared by the above procedure.

[Sample processing (extraction)]
<Example 2>
1. 1. Preparation of sample piece As the sample piece, the brain of a C57BL6 mouse (10 months old, about 25 g) obtained by the following procedure was used.
(1) After anesthetizing the mouse with diethyl ether, the mouse was placed in the supine position and the limbs were fixed.
(2) After laparotomy, the diaphragm was incised and the left and right ribs were incised toward the head.
(3) The xiphoid process was pinched and inverted toward the head, fixed with forceps, and the heart was exposed.
(4) A winged needle was pierced into the left ventricle, and a 1 × PBS solution (physiological saline) was injected.
(5) The right atrial appendage was incised with scissors, and blood was removed and perfused with about 70 ml of physiological saline.
(6) After perfusion, the head was amputated and the brain was removed after craniotomy.
(7) The excised brain was cut in half by sagittal section, the cut surface was placed on the lower surface (cut surface), and then the brain was placed in an embedding agent (OCT compound) and frozen to prepare a frozen block.
(8) Sections were prepared from the frozen block to a thickness of 10 μm. The slide glass used was uncoated.
(9) The frozen section was dried by a freeze dryer (FDU-2200 manufactured by EYELA).

2. 2. Preparation of LMD Based on an upright microscope, a stepping motor (Bio Precision; manufactured by Roodle) as a drive source, 3D-A-LCS software (manufactured by Lucille) as a drive control unit, and Z-808- as a die section laser light source. An LMD was produced by attaching 200-SM (manufactured by Lucille). The pressing means was made of hollow stainless steel. The diameter of the hollow portion was about 9 mm, and the weight was about 33 g. In addition, a recess was provided on the outside of the hollow portion, and a rubber anti-slip was inserted.

3. 3. Cutting out a sample from a section and adhering it to a heat-meltable film According to the following procedure, a sample at a set location was collected from the prepared frozen section and adhered to a heat-meltable film.
(1) After turning on the power of the LMD and initializing the heat-meltable film moving mechanism, the heat-meltable film formed on the substrate was set in the heat-meltable film moving mechanism. Further, after the prepared pressing means was inserted into the hole at the tip of the arm of the sample moving mechanism, a slide glass having a sample section attached to the tip of the pressing means was attached with the sample surface facing down.
(2) The image of the frozen section was displayed on the display unit of the LMD, and the position coordinates for irradiating the disection laser light of the sample section were set.
(3) The position coordinates of the heat-meltable film were set so that the collected sample adhered to a predetermined position (the same as the distance between the wells, 4.5 mm) of the heat-meltable film.
(4) According to the program of Live Cell Imaging System V7 (manufactured by Lucille), according to the position coordinates of (2) and (3) above, the sample section is subjected to disection laser light (output: 300 mA, irradiation time: 5 msec, irradiation diameter). : 30 μm) was irradiated, and the cut-out sample was adhered and recovered to a preset portion of the heat-meltable film. The laser intensity was adjusted so that the diameter of the sample collected in this example was 60 μm.

4. Sample processing (extraction)
Each well was filled with 20 μl of treatment solution. An extract (a mixture of acetonitrile and water in a ratio of 1: 1) was used as the treatment liquid. Above 3. The heat-meltable film surface to which the sample was adhered, which was obtained in the above, was pressed against the plate. In order to bring the heat-meltable film and the plate into close contact with each other, the heat-meltable film was placed on the lower side and heated on a hot plate heated to 80 ° C. for 1 minute. After the heating was completed, the heat-meltable film was placed on the lower side so that the treatment liquid and the collected sample were always in contact with each other, and the sample was allowed to stand for 1 hour. FIG. 9A is a photograph showing a state in which the heat-meltable film is in close contact with the plate. A dye (crystal violet) was added to a part of the treatment liquid to be filled in the wells in order to make the state of the sample processing process easy to understand.

5. Quantitative analysis of the treated (extracted) sample 5 μl of the sample treated in the sample processing step was quantified using a mass spectrometer (AB Siex Co., Ltd .; API4000) in the treatment liquid. Quantification was performed 3 times using different well treatment solutions. The results are shown in FIG.

<Comparative example 1>
The heat-meltable film to which the sample adhered obtained in "3. Cutting out the sample from the section and adhering to the heat-meltable film" of Example 2 was cut into 4.5 mm squares. The cut heat-meltable film and the same amount of the treatment liquid as in Example 2 were put into an Eppendorf tube, and the mixture was stirred with VORTEX (Vortex Gene2 manufactured by Scientific Industries) for 10 seconds. After stirring, a treatment solution was prepared by centrifuging at 15,000 g for 10 minutes. Using the treatment liquid, quantification was performed in the same procedure as in "5. Quantification of the treated (extracted) sample" of Example 2. The results are shown in FIG.

<Comparative example 2>
By printing a water-repellent ink (manufactured by Toyo Adre Co., Ltd .: SS25) on the heat-meltable film layer produced in Example 1 using an inkjet printer, the portion other than the portion to which the collected sample was adhered was hydrophobized. ..
Next, the sample is adhered to the heat-meltable film in the same procedure as in "3. Cutting out the sample from the section and adhering to the heat-meltable film" in Example 2, and the same as in Example 2 where the sample is adhered. 5 μl of the treatment solution was added dropwise with a pipette. FIG. 9B is a photograph showing how the treatment liquid stays at the portion where the sample is adhered. After about 5 seconds had passed after dropping the treatment liquid, the treatment liquid was collected with a pipette. The dropping and recovery of the treatment liquid was repeated 4 times.
Next, using the recovered treatment liquid, quantification was performed in the same procedure as in "5. Quantification of treated (extracted) sample" of Example 2. The results are shown in FIG.

As is clear from FIG. 10, by using the kit shown in the embodiment, a slightly higher processing (extraction) efficiency than the case of using the vortex of Comparative Example 1 was obtained. By the way, in the method of Comparative Example 1, since it is necessary to cut the heat-meltable film and perform a treatment (extraction) step for each individual sample, the treatment (extraction) work takes time. Further, in the method of Comparative Example 2, since it is necessary to treat (extract) the sample by pipetting for each individual sample, the treatment (extraction) work takes time, and in the case of a volatile treatment (extraction) liquid, the treatment is performed. The processing (extracting) liquid volatilizes during the (extracting) work. By using the kit shown in the embodiment, in addition to the effect that the processing (extraction) efficiency can be increased, the sample can be processed (extracted) simply by adhering the heat-meltable film to the plate and allowing it to stand, so that the work efficiency can be improved. It can be made more efficient. Furthermore, since the heat-meltable film acts as a lid, the sample can be stored.

By using the treatment method and the sample processing kit shown in the embodiment, the sample can be processed efficiently. Therefore, it is useful for sample analysis.

Claims (12)

It is a treatment method for treating a sample adhered to a heat-meltable film, and the treatment method is
Adhesion process between the heat-meltable film and the microtiter plate, in which the surface of the heat-meltable film to which the sample is adhered is pressed against the microtiter plate on which the well filled with the sample treatment liquid is formed to adhere to the microtiter plate.
A sample processing step of treating the sample with the treatment liquid,
A processing method that includes at least. The heat-meltable film is formed on the substrate and
A substrate peeling step of peeling the substrate and the heat-meltable film between the adhesion step and the sample processing step, or after the sample processing step.
The processing method according to claim 1, further comprising. Prior to the adhesion step, a sampling step of adhering the sample to the heat-meltable film is included.
The processing method according to claim 1 or 2. The sampling step is performed using a laser microdissection device.
The laser microdissection device is
A sample moving mechanism for moving a sample piece, a heat-meltable film moving mechanism for moving a heat-meltable film, and a heat-meltable film moving mechanism, and
A drive control unit that controls the drive of the sample movement mechanism and the heat-meltable film movement mechanism,
Including at least
In the sampling step, the drive control unit moves the sample moving mechanism and the heat-meltable film so that the position of the sample adhered to the heat-meltable film corresponds to the position of each well of the microtiter plate. Control the mechanism,
The processing method according to claim 3. The treatment method according to any one of claims 1 to 4, wherein the treatment method is any one of a sample extraction method, a sample pretreatment method, and a sample analysis method. The treatment method according to any one of claims 1 to 4 is a sample extraction method or a sample pretreatment method.
A sample analysis method comprising an analysis step of analyzing a sample extracted by the sample extraction method or a sample treated by the sample pretreatment method. A sample processing kit used in the processing method for processing a sample adhered to a heat-meltable film according to claim 1, wherein the sample processing kit is used.
Heat-meltable film and microtiter plate with wells formed,
A kit for sample processing, including. The opening of the well and the connecting portion of the opening are flat surfaces without steps.
The sample processing kit according to claim 7. The sample processing kit according to claim 7 or 8, wherein the heat-meltable film is formed on a substrate. The size of the heat-meltable film is the region where the wells of the microtiter plate are formed, or the region where the wells are formed and the region formed by the outer peripheral portion formed on the outer periphery of the wells. Same as one of the equally divided sizes,
The sample processing kit according to any one of claims 7 to 9. The shape of the microtiter plate is square or rectangular,
The heat-meltable film has a shape that can be arranged in parallel with the microtiter plate.
The sample processing kit according to claim 9 or 10. At least a part of the outer peripheral portion of the microtiter plate is formed with a contact portion for positioning when the heat-meltable film and the microtiter plate are brought into close contact with each other.
The sample processing kit according to any one of claims 7 to 11.