JP2005333889A - Method for necrocytosis and device therefor - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a necrocytosis method and necrocytosis device to efficiently and surely necrotize a target cell. <P>SOLUTION: The necrocytosis method is composed of a specimen holding step to place a specimen cell on a microscope, a cell image acquiring step to acquire a digital image of the specimen, a cell image processing step to determine the laser radiation position, and a laser radiation step to radiate laser light to the specimen. The cell image processing step is composed of a step to determine the presence of a cell in a pixel for each pixel of the image and binarize the image data, a step to find the boundary of two adjacent pixels having different values in the binarized image data and find an isolated closed curve, a step to process the binarized image data under the assumption of the presence of cells in the whole inner side of the isolated closed curve, and a step to divide the binarized and processed image data into regions of predetermined size, calculate the gravity center coordinates of the region recognized to hold the cell and setting the gravity center position as the laser radiation position. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a method and an apparatus for necrosing unnecessary specific cells among cultured cells by a laser, and more particularly to a method and an apparatus for more efficiently necrosing specific cells using cell image data.

  With the recent development of medicine, cell therapy has been applied in various situations. For example, hematopoietic tumors such as malignant lymphoma and leukemia are treated with high-dose chemotherapy and radiation to treat hematopoietic tumors, while hematopoietic stem cells are transplanted to treat bone marrow damage that occurs as a side effect. Means are used. In addition, stem cell therapy such as chondrocyte treatment for transplanting chondrocytes for cartilage defects and nerve cell therapy for transplanting nerve cells for neurodegenerative diseases has been performed. In such stem cell therapy, it is necessary to remove unwanted cells from the transplanted cells before transplantation.

  For example, in the above-described hematopoietic stem cell treatment in hematopoietic organ tumors, it is preferable to collect and culture the patient's own stem cells and transplant the cultured stem cells from the viewpoint of preventing graft-versus-host disease. In such a case, the collected stem cells may also contain cells containing cancer cells. If transplanted without removing the cancer cells, the hematopoietic tumor will recur.

  Patent Document 1 discloses a method of labeling such unnecessary cells and necrotizing the cells by irradiating the labeled cells with laser light.

Special table 2003-529340 gazette

In order to necrotize cells by laser beam irradiation, it is necessary to reliably irradiate the cell nucleus of the cell with the laser beam to destroy the cell nucleus. However, the area (hereinafter referred to as spot) where the laser beam is irradiated onto the cells is constant, but the size of the cells varies. Therefore, there is a problem that if the size of the cell is increased, the probability that the laser beam hits the cell nucleus is reduced and the necrosis rate of the cell is lowered. In addition, unlike plant cells, human cells do not have cell walls and are covered with a soft cell membrane, so their shapes vary, and even if the central part of a cell is irradiated with laser light, Did not always hit the cell nucleus.
Therefore, there has been no method for reliably necrotizing cells in the past.
This invention is made | formed in view of the said situation, Comprising: It aims at providing the cell necrosis method and cell necrosis apparatus which can make the target cell necrosis efficiently and reliably.

According to the first aspect of the present invention, there is provided a sample placing step of placing a sample cell containing a sample that has been labeled so that the target cell emits a fluorescent color on a microscope, and a digital of the sample contained in the sample cell. A cell image acquisition step of acquiring an image, a cell image processing step of determining a laser irradiation position from the digital image, and a laser irradiation step of irradiating a laser beam to the laser irradiation position determined in the cell image processing step, In the cell image processing step, for each pixel of the digital image, identifying the presence or absence of cells according to the fluorescence luminance of the pixel, binarizing the digital image data, and in the binarized digital image data Determining the boundary where different values are adjacent to each other, finding an isolated closed curve, and processing the binarized image data by assuming that there are cells inside the isolated closed curve. Dividing the processed binarized image data into regions of a predetermined size, calculating barycentric coordinates of regions recognized as having cells in the segmented regions, and calculating the barycentric position The cell necrosis method is characterized in that the laser irradiation position is used.
According to a second aspect of the present invention, after the step of processing the binarized image data, the step of counting the number of pixels inside the isolated closed curve of the processed image data and calculating the inner area of the isolated closed curve; The cell necrosis method according to claim 1, further comprising a step of removing an isolated closed curve having an inner area of the isolated closed curve equal to or less than a predetermined value.
The invention according to claim 3 is characterized in that the segmented area is defined to have a size equal to or larger than a rectangular area having a circumscribed circle as the laser beam spot and smaller than a rectangular area having an inscribed circle as the laser beam spot. The cell necrosis method according to claim 1 or 2.

The invention according to claim 4 is a laser light source, a microscope capable of observing a cell sample labeled so that the target cell is fluorescently colored, an imaging device for capturing an image of the cell sample observed with the microscope, A computer that captures digital image data obtained by the imaging device, and a group of mirrors including an electronically controlled mirror that can adjust the optical axis while guiding laser light emitted from the laser light source into the microscope, The computer identifies the presence or absence of cells in each pixel according to the fluorescence luminance of each pixel of the digital image data, binarizes the digital image data, and the binary digital image data has different values. As a result, the binarization is performed on the assumption that the isolated boundary is found, the isolated closed curve is found, and the cells are all present inside the isolated closed curve. Means for processing digital image data, dividing the processed digital image data into regions of a predetermined size, and calculating center-of-gravity coordinates of regions recognized as having cells in the divided regions; A cell necrosis device comprising means for adjusting an optical axis of a control mirror so that the laser is irradiated to the barycentric coordinates, and a laser beam from the laser light source is irradiated to the barycentric coordinates.
According to a fifth aspect of the present invention, the computer processes the binarized image data after processing the binarized image data and before dividing the processed digital image data. 5. The cell necrosis device according to claim 4, wherein the number of pixels is counted, the internal area of the isolated closed curve is calculated, and the isolated closed curve having an isolated closed curve internal area of a predetermined value or less is removed.
The invention according to claim 6 is characterized in that the segmented area is defined to have a size equal to or larger than a rectangular area having a circumscribed circle as the laser beam spot and smaller than a rectangular area having an inscribed circle as the laser beam spot. The cell necrosis device according to claim 4 or 5.

According to the first and fourth aspects of the invention, since the laser beam can be irradiated to almost the entire area of the cell regardless of the size and shape of the cell, the cell can be surely necrotized.
According to invention of Claim 2 and 5, it is prevented that a laser beam is irradiated to an unnecessary part, and it is prevented that the cell which does not need to be necrotized is damaged.
According to the third and sixth aspects of the present invention, since the segmented area is substantially equal to the spot size of the laser beam, the laser beam that protrudes from the cell outline can be minimized, and the cells that do not need to be necrotized are damaged. It is possible to further reduce the risk of occurrence. In addition, the laser beam is reliably irradiated to the entire cell area, and the divisional number for irradiating the entire area of the cell with the laser beam is minimized, so that the cell can be necrotized efficiently and reliably.

Hereinafter, an embodiment of a cell necrosis method according to the present invention will be described with reference to the drawings. FIG. 1 is a schematic view of a cell necrosis device according to the present invention.
The cell necrosis device (1) includes a mirror group (4) that reflects laser light emitted from a laser light source (2), a microscope (3), and a laser light source (2) by a plurality of mirrors and introduces the laser light into the microscope (3). ), An imaging device (5) for capturing an enlarged cell image by the microscope (2), and a computer (6) for processing image data obtained by the imaging device (5).

The laser light source (2) is not particularly limited as long as it can cause necrosis of cells. Nd: YAG laser, femtosecond titanium sapphire laser, femtosecond fiber laser, nanosecond YAG laser, nanosecond / picosecond VYO ₄ Examples thereof include pulse lasers such as lasers and excimer lasers.

The light emitted from the laser light source (2) is first split into two optical paths by the half mirror (42) constituting the mirror group (4). Here, an optical path indicated by a solid line in FIG. 1 is a first optical path (43), and an optical path indicated by a dotted line is a second optical path (44). Both the laser beams passing through the first optical path (43) and the second optical path (44) pass through the electronic control mirror (41). The electronic control mirror (41) is connected to the computer (6), and each electronic control mirror (41) is independently controlled in optical axis.
Examples of the electronically controlled mirror (41) include a galvanometer mirror that can be rotated around an axis provided in the mirror, and a reflecting mirror attached to a piezo actuator using a piezo element that is proportionally displaced according to voltage. It can be used as appropriate.
In this way, the laser light from the laser light source (2) is split and both the split laser lights are guided into the microscope (3).

The microscope (3) includes a microscope light source (31), a sample stage (32), an objective lens (33), and a dichroic mirror (34) that reflects light of a specific wavelength. An imaging device (5) is provided immediately above the objective lens (33). A sample cell (7) is placed on the sample stage (32), and a cell sample is accommodated in the sample cell (7). The sample stage (32) can be moved in the horizontal direction, and the desired region of the sample cell (7) can be observed by moving the sample stage (32).
As described above, the laser beam guided into the microscope (3) is reflected downward by the dichroic mirror (34), and is condensed to the sample cell (7) on the sample stage (32) through the objective lens (33). The

The white light emitted from the microscope light source (31) is incident on the sample cell (7), and the transmitted image reaches the imaging device (5) via the objective lens (33) and the dichroic mirror (34). Immediately after the transmitted image passes through the dichroic mirror (34), a filter (51) is provided to remove laser light inside the microscope (3) and disturbance light outside the microscope (3).
As the imaging device (5), a CCD camera or a CMOS camera can be used, whereby the transmission image can be digitally processed.
The image digitized by the imaging device (5) is sent to the computer (6) and subjected to image processing as will be described later.

In the sample cell (7), a labeled cell sample is stored so that cells to be necrotized can be identified. In this example, cancer cells are the target cells.
First, for labeling, a labeled antibody having an affinity for a substance expressed on the surface of cancer cells is introduced into a cell sample. Examples of labeled antibodies include antibodies or antigens such as anti-integrin antibodies, anti-CD44 antibodies, anti-MUC-1 antibodies, anti-cytokeratin antibodies, anti-epithelial cell growth factor antibodies, anti-insulin-like growth factor antibodies, anti-insulin-like growth factor receptor antibodies. Part of antibody including recognition site, polypeptide or oligopeptide such as collagen, oligopeptide including RGD sequence, glycoprotein such as fibronectin, polysaccharide such as hyaluronic acid, phosphomannan, mannose-6-phosphate pentamer, etc. Oligosaccharides, monosaccharides such as mannose-6-phosphate, and vitamin acids such as retinoic acid. In view of not interacting with normal cells such as leukocytes and erythrocytes, anti-insulin-like growth factor receptor antibodies and mannose-6-phosphate pentamers are preferred.
The labeled antibody adheres only to the cancer cells and covers the periphery of the cancer cells.
With the labeled antibody attached to the cancer cells, an enzyme such as peroxidase or aliphosphatase, or a fluorescent reagent such as fluorescein isothiocyanate or tetramethylrhodamine isothiocyanate is added to the sample. The fluorescent reagent adheres to the labeled antibody, and as a result, the cancer cells are fluorescently colored, and the cancer cells are labeled.

FIG. 2 is a diagram showing a binarization process of the cell necrosis method according to the present invention. FIG. 2 (a) shows an image of cells taken into the computer (6) via the imaging device (5), FIG. 2 (b) shows the first stage of the binarization process, and FIG. Shows the second stage of the binarization process, and FIG. 2D shows the third stage of the binarization process.
As described above, the cell sample is subjected to a labeling process, and the target cell (cancer cell in this embodiment) develops fluorescence. Therefore, only the cancer cells that are fluorescently colored are captured as image data in the computer (6) (see FIG. 2A).
In the computer (6), the image is meshed for each pixel. Then, with a predetermined fluorescence brightness as a threshold, “0” is assigned to a mesh corresponding to a pixel having a brightness lower than the fluorescence brightness, and “1” is assigned to a mesh corresponding to a pixel having a higher brightness ( (Refer FIG.2 (b)). In FIG. 2B, the mesh assigned “1” is painted black, and the mesh assigned “0” is painted white.
In the state shown in FIG. 2B, the boundary between the mesh assigned “0” and the mesh assigned “1” is recognized. An isolated closed curve is recognized by connecting this boundary. In the labeling process, when the labeled antibody or the fluorescent reagent adhering to the labeled antibody is not sufficiently attached, another closed curve may be formed inside one closed curve. Are recognized as isolated closed curves.
After the isolated closed curve is recognized, “1” is assigned to the mesh inside the isolated closed curve (see FIG. 2C). Thereafter, the number of meshes to which “1” in the isolated closed curve is assigned is counted, and the area inside the isolated closed curve is calculated. In addition, when this isolated closed curve internal area is below a predetermined set value, it is excluded from laser irradiation objects. In this way, it is possible to prevent the laser beam from being irradiated on a portion other than the target cell.

Next, “0” and “1” of the image data shown in FIG. 2C are reversed (in the example shown in FIG. 2D, black and white are reversed). Then, the image data is divided into a predetermined size.
FIG. 3 shows an example of setting the size of the segmented area.
As shown in FIG. 3, a rectangular region having a laser light circle (that is, a spot) on a cell as a circumscribed circle is defined as a minimum segmented region, and a rectangular region having a spot as an inscribed circle is defined as a maximum segmented region. It is preferable to determine the size of the segmented area by. If it is less than this size, the laser irradiation area will be smaller, increasing the possibility that the necrosis rate of the cells will be reduced, and if it is more than this size, the amount of laser light that radiates out of the cell outline will increase, causing necrosis. This is because the possibility of damaging unnecessary cells is increased.
The number of pixels assigned with “0” in the divided area is counted, and the area and the barycentric coordinates of the portion where the cell exists in each divided area are calculated (in FIG. 2C, the barycentric position is a triangular symbol). Is shown). At this time, a segmented area having a predetermined area or less may be excluded from the laser irradiation target.

After the barycentric coordinates are obtained in this way, laser light is emitted from the laser light source (2). The computer (6) adjusts the optical axis of the electronic control mirror (41) according to the calculated center-of-gravity coordinates, and the irradiation position of the laser light is controlled by the electronic control mirror (41) so that the laser light is directed toward the above-described center-of-gravity coordinates. Is irradiated.
Since the irradiation position of the laser beam is determined as described above, the laser beam brings light energy to the entire cell regardless of the shape and size of the cell, and necrotically kills the cell. In addition, since the center of gravity of each segmented region is irradiated with laser light, the amount of laser light that protrudes from the target cell is small, and damage to cells outside the target cell that are close to the target cell can be suppressed.

FIG. 4 is a flowchart showing a series of steps of the cell necrosis method according to the present invention.
The cell necrosis method includes a sample placement step, a sample stage operation setting step, a cell image acquisition step, a cell image processing step, and a laser irradiation step.
First, in the sample placement step, a milky white plate is placed on the sample stage (32) as an object for coordinate calibration in order to make the laser irradiation position coincide with the coordinates of the image data. A numerical value is input to the optical axis control parameter of the electronic mirror (41) of the computer (6) so that the laser beam is irradiated to the center of the image obtained by the imaging device (5). Then, the subject is irradiated with laser light, and the state is imaged by the imaging device (5). An image obtained by the imaging device (5) includes a spot of laser light, and the computer (6) obtains the center coordinate of the spot, and the center coordinate of the image is compared with the center coordinate of the spot for coordinate calibration. The correction value is calculated. In this way, the irradiation coordinates of the laser light coincide with the coordinates on the image processing.
Then, the sample cell (7) for storing the cell sample labeled as described above is placed on the sample stage (32).
Next, the operation of the sample stage is determined in the sample stage operation setting step.
FIG. 5 is a view of the sample cell (7) as viewed from above. In FIG. 5, the region (72) that can be observed with the objective lens (33) is indicated by a dotted line.
First, one end of the sample storage part (71) in which the sample of the sample cell is stored is set as the start point region (S). The other end is set as the end point region (E). The feed pitch of the sample stage (32) is set between the start point region (S) and the end point region (E). In setting the feed pitch, it is preferable to set the objective lens observable regions (72) so as to overlap each other. This is because all the samples accommodated in the sample cell (7) can be observed by setting in this way.
Thereafter, in the cell image acquisition step, the image of the objective lens observable region (72) is digitized by the imaging device (5), and the image data is sent to the computer (6).
In the cell image processing step, as described above, the image data is binarized, the cell image is segmented, and the barycentric coordinates of the segmented region are calculated.
Next, in the laser irradiation step, the optical axis setting of the electronic control mirror (41) is appropriately adjusted so that the laser beam is irradiated to the calculated barycentric coordinates, and the laser is irradiated. After the laser beam is irradiated to all the calculated center-of-gravity coordinates in the objective lens observable area (72), the sample stage (32) moves and a cell image is displayed with respect to the adjacent objective lens observable area (72). A series of steps from the acquisition step to the laser irradiation step is repeated. And all the cells to be necrotized in the sample cell are surely necrosed by the laser beam.
Note that settings such as the irradiation time, output, or number of pulses of laser light may be appropriately determined according to the type of target cell.

  The present invention is preferably applied to a cell necrosis method and a cell necrosis apparatus that can efficiently and reliably necrotize target cells.

It is a figure which shows the cell necrosis apparatus which concerns on this invention. It is a figure which shows the binarization process of the cell necrosis method which concerns on this invention. (A) shows an image of a cell taken into a computer via an imaging device, (b) shows a first stage of the binarization process, (c) shows a second stage of the binarization process, (D) shows the 3rd step of a binarization process. It is a figure which shows an example of the setting of the magnitude | size of the division area which concerns on this invention. It is a flowchart which shows a series of processes of the cell necrosis method which concerns on this invention. It is the figure which looked at the sample cell concerning the present invention from the upper part.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Cell necrosis apparatus 2 ... Laser light source 3 ... Microscope 4 ... Mirror group 41 ... Electronic control mirror 5 ... Imaging device 6 ····Computer

Claims (6)

A sample placement step of placing on a microscope a sample cell that contains a sample that has been labeled so that the target cell is fluorescently colored;
A cell image acquisition step of acquiring a digital image of the sample contained in the sample cell;
A cell image processing step for determining a laser irradiation position from the digital image;
A laser irradiation step of irradiating a laser beam to a laser irradiation position determined in the cell image processing step;
The cell image processing step, for each pixel of the digital image, identifying the presence or absence of cells according to the fluorescence intensity of the pixel, binarizing the digital image data;
In the binarized digital image data, identifying a boundary where different values are adjacent and finding an isolated closed curve;
Processing the binarized image data by assuming that all the cells inside the isolated closed curve are cells;
The processed binarized image data is divided into regions of a predetermined size, the barycentric coordinates of a region where cells are recognized to be present in the divided region are calculated, and the barycentric position is calculated by the laser irradiation. A method for necrosis of cells, characterized by being located. After the step of processing the binarized image data, counting the number of pixels inside the isolated closed curve of the processed image data, and calculating the area inside the isolated closed curve;
The cell necrosis method according to claim 1, further comprising the step of removing an isolated closed curve having an inner area of the isolated closed curve equal to or less than a predetermined value.   The size of the segmented region is determined to be not less than a rectangular region having a laser beam spot as a circumscribed circle and not more than a rectangular region having the laser beam spot as an inscribed circle. Cell necrosis method. A laser light source;
A microscope capable of observing a cell sample labeled so that the target cell is fluorescently colored;
An imaging device for imaging an image of a cell sample observed with the microscope;
A computer for capturing digital image data obtained by the imaging device;
While guiding the laser light emitted from the laser light source into the microscope, and comprising a group of mirrors equipped with an electronically controlled mirror that can adjust the optical axis,
The computer identifies the presence or absence of cells in each pixel according to the fluorescence brightness of each pixel of the digital image data, binarizes the digital image data,
In the binarized digital image data, a boundary where different values are adjacent to each other is identified, an isolated closed curve is found,
The binarized digital image data is processed by assuming that cells exist all within the isolated closed curve,
Means for dividing the processed digital image data into regions of a predetermined size, and calculating center-of-gravity coordinates of regions recognized as having cells in the divided regions;
Means for adjusting the optical axis of the electronic control mirror so that the laser is irradiated to the barycentric coordinates;
A cell necrosis device characterized by irradiating the barycentric coordinates with laser light from the laser light source. After the computer processes the binarized image data and before dividing the processed digital image data, the computer counts the number of pixels inside the isolated closed curve of the processed image data, Calculate the internal area of the closed curve,
5. The cell necrosis device according to claim 4, wherein an isolated closed curve having an inner area of the isolated closed curve equal to or less than a predetermined value is removed. 6. The size of the segmented region is determined to be not less than a rectangular region having a circumscribed circle as the laser beam spot and not larger than a rectangular region having an inscribed circle as the laser beam spot. Cell necrosis device.

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