JP2009063509A - Nerve cell image analyzer and nerve cell image analysis software - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a nerve cell image analyzer and a nerve cell image analysis software capable of accurately analyzing at high speed, a projecting portion or a tubular portion in a cell, such as a dendrite, an axon, and an axon collateral on the tip of the axon in a nerve cell. <P>SOLUTION: The nerve cell image analyzer performs a prescribed automatic analysis processing to an image acquired from an image acquisition means for acquiring a light image emitted from the nerve cell as the image. The analyzer has a step S1 of dividing a nerve cell image acquired through the image acquisition means into a plurality of domains including a circular domain, a step S2 of extracting a prescribed parameter amount characterizing a domain relative to each divided domain, a step S3 of acquiring a matrix showing correlation between adjacent domains, a step S4 of detecting a route and a branch state of the nerve cell by using the acquired matrix, and a step S5 of calculating a statistic of acquired information. In the analyzer, a structure of the nerve cell is analyzed through processing in each step. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a nerve cell image analysis apparatus and nerve cell image analysis software for analyzing a structure of a protrusion or a relatively long tubular portion such as a dendrite or an axon in a nerve cell.

FIG. 11 is an explanatory diagram schematically showing the structure of a nerve cell.
A nerve cell is roughly divided into three parts: a cell body 51, a dendrite 52, and an axon 53. The cell body 51 is a site corresponding to the main body of the cell and has a cell nucleus 51a. The dendrite 52 is a protrusion-like part that branches off from the cell body 51 like a tree branch, and has a function of receiving a signal in a nerve cell. The axon 53 is a relatively long tubular portion extending from the cell body 51 and has a function of outputting a signal in a nerve cell. At the tip of the axon 53, a branch called an axon side branch 53a is formed. A synapse (not shown), which is an information transmission unit, is formed at the connection between the branched tip (axon ending) 53b of the axon 53 and the dendrites of other nerve cells. Then, the nerve cell transmits a stimulus from another nerve cell received from the dendrite 52 through the synapse to the other nerve cell from the axon 53 through the synapse.
As described above, the protrusion-like or tubular part in the nerve cell has an important role in the function of the cell. Further, the length and the number of branches of the projecting or tubular parts are considered as important parameters for evaluating the state of cells.

  By the way, conventionally, in the analysis of these neurons, researchers themselves visually observe cell images such as specifying the position of protrusions and tubular parts and measuring the length of protrusions and tubular parts. This is a great work burden for researchers. Therefore, an apparatus that can automatically analyze nerve cells is desired.

However, a certain number of cell images are automatically acquired, the frequency of the acquired cell image data is converted, and the feature parts of the animal and plant cells are extracted by dividing the frequency into frequency components. As an example of a cell image analysis apparatus that can accurately separate and extract dendrites and quantify the length and number of branches of dendrites and positional information of dendrites, for example, an apparatus described in the following Patent Document 1 is proposed. Has been.
JP 2001-307066 A

  However, the extraction of the structure of protrusions and tubular parts in these nerve cells can be performed even if the cell image analysis apparatus of Patent Document 1 is performed on cells in a cultured state. It is difficult to distinguish because it overlaps with the cell body, or there are many cases where the branch-like protruding part and the tubular tip part overlap each other. There is a problem that it is difficult to distinguish. Moreover, since the structure of the protrusion-like part or the tubular part in the nerve cell is complicated in the first place, even if the analysis using the cell image analyzer of Patent Document 1 is successful, there is a problem that it takes too much time. there were.

  The present invention has been made in view of the above-described conventional problems, and it is possible to accurately identify the protruding portion or tubular portion of a cell such as a dendrite or axon in a nerve cell and an axon side branch at the tip of the axon. It is another object of the present invention to provide a nerve cell image analysis apparatus and nerve cell image analysis software capable of analyzing at high speed.

  In order to achieve the above object, a nerve cell image analysis apparatus according to the present invention performs a predetermined automatic analysis process on an image obtained from an image obtaining means for obtaining an image of light emitted from a nerve cell as an image. An image analysis device, the step of dividing a nerve cell image obtained through the image acquisition means into a plurality of regions including a circular region, and extracting a predetermined parameter amount characterizing the region for each divided region A step of acquiring a matrix indicating a correlation between adjacent regions, a step of detecting a route and a branching state of a nerve cell using the acquired matrix, and a step of calculating a statistic of the obtained information The structure of the nerve cell is analyzed through the processing in each of these steps.

  In the nerve cell image analyzing apparatus of the present invention, the step of dividing the nerve cell image into a plurality of regions including a circular region is predetermined for the nerve cell image obtained through the image acquisition means. And detecting a boundary between a region of the nerve cell and a region other than the nerve cell in the nerve cell image, and an inscribed circle with the boundary having a maximum radius in the region of the nerve cell Furthermore, the operation of providing an inscribed circle with the boundary having the maximum radius in the area of the nerve cell excluding the inscribed circle is repeated a predetermined amount, and then the area of the nerve cell is changed to the inscribed circle. It is preferable to divide the region and its peripheral region into regions.

  In the nerve cell image analysis apparatus of the present invention, the feature parameter extracted in the step of extracting the amount of a predetermined feature parameter that characterizes each divided region is at least a center in each circular region. It is preferable to have a point.

  In the nerve cell image analysis apparatus of the present invention, the feature parameter extracted in the step of extracting a predetermined feature parameter that characterizes the divided region for each divided region is further at least each of the circular regions. It is preferable to have at least one of the radius of the inscribed circle in FIG.

  In the nerve cell image analyzer of the present invention, the matrix in the step of obtaining the matrix indicating the correlation between the adjacent areas is obtained by taking the total number of the areas with the number of the divided areas as the x component, It is preferable that the number of adjacent regions is the y component and the maximum number of branches in the region is taken.

  In the nerve cell image analysis apparatus of the present invention, the matrix values in the step of obtaining a matrix indicating the correlation between the adjacent areas are sequentially set to the adjacent areas starting from an arbitrary area in the divided area. The numbers 1 to N are assigned, the assigned numbers 1 to N are assigned to the x component in order, and the region adjacent to the region corresponding to the number in each x component is assigned to the y component in order. Is preferred.

  In the nerve cell image analysis apparatus of the present invention, the step of detecting the route and branching state of the nerve cell using the acquired matrix determines an arbitrary start area in the divided area and the start area A region farthest from the first region is determined as a final region, a series of regions from the final region to the start region is determined as a first route, and the remaining regions are branched from the first route. Is determined as the second start region, and the region farthest from the second start region is determined as the second end region, and the second end region is determined from the second end region. It is preferable that a series of areas up to the start area is determined as the second route, and a process substantially similar to the process of determining the second route is repeated for the remaining areas.

  In the nerve cell image analyzer of the present invention, the step of extracting the statistics of the obtained information includes at least one of the total extension of each route, the total number of routes, the total number of branches, and the number of branches in each route. It is preferable to acquire such.

  Further, the nerve cell image analysis software according to the present invention is used for a nerve cell image analysis apparatus that performs a predetermined automatic analysis process on an image obtained from an image obtaining unit that obtains an image of light emitted from a nerve cell as an image. A neuron image analysis software, the step of dividing the neuron image obtained through the image acquisition means into a plurality of regions including a circular region, and a predetermined parameter amount characterizing the region for each of the divided regions Extracting a matrix, a step of acquiring a matrix indicating a correlation between adjacent regions, a step of detecting a route and a branching state of a nerve cell using the acquired matrix, and calculating a statistic of the obtained information And the structure of the nerve cell is analyzed through the processing in each of these steps.

  In the nerve cell image analysis software of the present invention, the step of dividing the nerve cell image into a plurality of regions including a circular region is predetermined for the nerve cell image obtained through the image acquisition unit. And detecting a boundary between a region of the nerve cell and a region other than the nerve cell in the nerve cell image, and an inscribed circle with the boundary having a maximum radius in the region of the nerve cell Furthermore, the operation of providing an inscribed circle with the boundary having the maximum radius in the area of the nerve cell excluding the inscribed circle is repeated a predetermined amount, and then the area of the nerve cell is changed to the inscribed circle. It is preferable to divide the region and its peripheral region into regions.

  In the nerve cell image analysis software of the present invention, the feature parameter extracted in the step of extracting the amount of a predetermined feature parameter that characterizes each divided region is at least a center in each circular region. It is preferable to have a point.

  In the nerve cell image analysis software of the present invention, the feature amount parameter extracted in the step of extracting the amount of the predetermined feature amount parameter characterizing the divided region for each divided region is further at least each of the circular regions. It is preferable to have at least one of the radius of the inscribed circle in FIG.

  Further, in the nerve cell image analysis software of the present invention, the matrix in the step of obtaining the matrix indicating the correlation between the adjacent areas is obtained by taking the total number of the areas by using the number of the divided areas as an x component, It is preferable that the number of adjacent regions is the y component and the maximum number of branches in the region is taken.

  In the nerve cell image analysis software of the present invention, the matrix values in the step of obtaining a matrix indicating the correlation between the adjacent areas are sequentially set to the adjacent areas starting from an arbitrary area in the divided area. The numbers 1 to N are assigned, the assigned numbers 1 to N are assigned to the x component in order, and the region adjacent to the region corresponding to the number in each x component is assigned to the y component in order. Is preferred.

  In the nerve cell image analysis software of the present invention, the step of detecting the route and branching state of the nerve cell using the acquired matrix determines an arbitrary start region in the divided region and the start region. A region farthest from the first region is determined as a final region, a series of regions from the final region to the start region is determined as a first route, and the remaining regions are branched from the first route. Is determined as the second start region, and the region farthest from the second start region is determined as the second end region, and the second end region is determined from the second end region. It is preferable that a series of areas up to the start area is determined as the second route, and a process substantially similar to the process of determining the second route is repeated for the remaining areas.

  In the nerve cell image analysis software of the present invention, the step of extracting the statistics of the obtained information includes at least one of the total extension of each route, the total number of routes, the total number of branches, and the number of branches in each route. It is preferable to acquire such.

  According to the present invention, a nerve cell capable of accurately and rapidly analyzing a protrusion-like part or a tubular part of a cell, such as a dendrite or axon in a nerve cell and an axon side branch at the tip of an axon An image analyzer and nerve cell image analysis software are obtained.

  FIG. 1 is a block diagram schematically showing the overall configuration of a nerve cell image analysis apparatus provided with nerve cell image analysis software according to an embodiment of the present invention, and FIG. 2 is obtained in the nerve cell image analysis apparatus of FIG. It is a flowchart which shows the process sequence which analyzes the structure of the nerve cell which has a protrusion-like or tubular part from a cell image. FIG. 3 is a flowchart showing a specific processing procedure in the circular area dividing step in the processing procedure shown in FIG. FIG. 4 is an explanatory diagram showing the determination method of the maximum inscribed circle in the processing procedure shown in FIG. 3, where (a) is a circle that touches one of the boundaries, and (b) is a state in which a plurality of circles that are inscribed in the boundary overlap. , (C) is the state where the circle with the largest radius in the overlapping area of (b) is selected as the maximum inscribed circle, (d) is the area excluding the area of the maximum inscribed circle shown in (c) In FIG. 5, the state where the circle having the maximum radius is selected as the next maximum inscribed circle is shown. FIG. 5 is an explanatory diagram conceptually showing the contents of the processing procedure shown in FIG. 3 for each step. FIG. 5A is a diagram illustrating binarization of an image region to detect a boundary between a nerve cell and a region other than the nerve cell. Step, (b) sequentially determines the maximum inscribed circle with the boundary in the binarized nerve cell area, (c) divides the nerve cell area into areas including each inscribed circle Each stage is shown. FIG. 6 is an explanatory diagram showing problems in the case of using a conventional general method for analyzing a bent part in a nerve cell, and a method using the nerve cell image analysis apparatus of the present embodiment. FIG. An example of a tubular part configured in a straight line, (b) is an analysis of three points that are very short from each other using the conventional method for the tubular part shown in (a). An example of the direction or angle of cell extension (or bending), (c) is a cell that is analyzed when three points that are long distances from each other are taken using a conventional general method on a tubular part. (D) is an example of the cell extension (or bending) direction and angle analyzed when the method using the neuronal cell image analysis apparatus of this embodiment is used. Show. FIG. 7 is an explanatory diagram showing problems in the case of using a conventional general method in analyzing a complicated structure in which a protruding part or a tubular part in a nerve cell is entangled. An example of a state in which tubular parts of cells are intertwined in a complicated manner, (b) conceptually shows an example of a problem when analyzing the structure of a nerve cell in the state shown in (a) by the conventional method FIG. 4 (c) is a diagram conceptually showing another example of a problem in the case of analyzing the structure of a nerve cell in a state where tubular portions are intertwined in a complicated manner by a conventional method. FIG. 8 is an explanatory diagram of a matrix showing the correlation between adjacent regions in the processing procedure shown in FIG. 2, in which (a) shows a numbered region in the nerve cell, and (b) shows (a). A matrix is shown in which the number of divided areas is an x component and the number of adjacent areas in the area is a y component. FIG. 9 is an explanatory diagram showing a method for determining cell routes, branches, etc. in the processing procedure shown in FIG. 2, wherein (a) is a schematic diagram showing the area of a nerve cell in a maximum inscribed circle, and (b) is a schematic diagram. (a) is a diagram showing a state in which a predetermined region in a neuron cell region is numbered as a start region, (c) is an explanatory diagram showing an end region with respect to the neuron start region shown in (b) is there. FIG. 10 is an explanatory view schematically showing a final result of analyzing the nerve cell shown in FIG.

As shown in FIG. 1, the nerve cell image analyzer of the present embodiment moves an image sensor such as a microscope 1 for cell observation, a CCD camera 2, and a slide glass or a multiplate for holding nerve cells. An image acquisition means having an electric stage (not shown) and a personal computer (hereinafter referred to as “personal computer”) 3 connected to the microscope 1 and the imaging device 2 are provided.
The image acquisition means is configured so that an image of light emitted from a nerve cell can be guided to the CCD camera via the microscope 1 and acquired as an image via the CCD camera 2.
The personal computer 3 controls the function of controlling the operation of the microscope 1 via the software 4 for instructing the operation control, and the nerve cell image obtained via the CCD camera 2 via the nerve cell image analysis software 5. It has a function of performing a predetermined automatic analysis process.

  In addition, the cell image analysis apparatus of the present embodiment is capable of fully automatically performing processing in the preparation stage of analysis, such as imaging of a nerve cell image via an image acquisition unit, prior to automatic analysis of nerve cells. The cell image acquisition means is configured to capture images of nerve cells held on a slide glass or multiplate fully automatically according to conditions such as the imaging position preset by the user and the number of images acquired Has been.

  And the cell image acquisition means comprised in this way acquires a nerve cell image automatically as follows. The user presets in advance detailed observation conditions such as selection of an objective lens provided in the microscope 1 and selection of a fluorescent filter via software 4 for instructing operation control of the microscope apparatus. The cell image acquisition means follows a preset operation control, for example, moves the electric stage by a predetermined amount to move the desired sample to the observation position, automatically adjusts the focal position at this position, An image is picked up using an image pickup device and stored as image data in the personal computer 3.

Outline of Analysis Processing Procedure And in the nerve cell image analysis apparatus of the present embodiment, the obtained nerve cell image is analyzed by the following procedure via the nerve cell image analysis software 5.
As shown in FIG. 2, the analysis processing for the structure of the protruding portion or the tubular portion in the nerve cell is performed by dividing the nerve cell image obtained through the image acquisition means into a plurality of regions including a circular region ( A step of “circular region division” (step S1), a step of extracting a predetermined parameter amount characterizing the region for each divided region, such as the center point of each circular region and the average luminance (“feature amount extraction”) (Step S2), a step (Step S3) of acquiring a matrix indicating a correlation between adjacent regions (Step S3), and a step of detecting the route and branching state of the nerve cell using the acquired matrix (Step S4). From the information obtained as a result, a step of calculating statistics such as the total number of protrusion-like parts and tubular parts in the nerve cell, the average length, the number of branches, etc. (step 5) It is adapted to perform in order.

Next, details of processing performed at each step in the analysis processing procedure shown in FIG. 2 will be described.
Step of dividing a nerve cell image into a plurality of regions including a circular region (step S1)
In step S1, a division process based on a circular region is performed. Specifically, as shown in FIG. 3, the step of binarizing the area of the acquired cell image (step S11), the step of determining the inscribed circle having the maximum radius (step S12), the area including the inscribed circle Each step is performed in the order of the step of dividing (step S13).

Step of binarizing the area of the acquired cell image (step S11)
In step S11, the acquired nerve cell image is binarized by an appropriate method, and the boundary between the area of the nerve cell and the area other than the nerve cell in the nerve cell image is detected. For example, an area where nerve cells are present has a higher luminance value obtained on the pixel than a non-existing area, and the average value of luminance values at each point in the cell image is used as a threshold value. As shown in (a), the boundary is detected by using a technique such as “1” for a luminance point that is equal to or higher than the average value and “0” for a luminance point that falls below the average value.

A step of determining an inscribed circle having a maximum radius (step S12)
In step S12, a circle inscribed in the boundary is provided in the nerve cell region. An inscribed circle having a maximum of a plurality of radii is obtained by providing an inscribed circle having a maximum radius among the circles inscribed in the boundary so as not to overlap. Here, the inscribed circle having the maximum radius is a circle as shown in FIGS. 4 (c) and 4 (d).

In the binarized value “1” region (that is, the region of the nerve cell in the image of the nerve cell), a circle as shown in FIG. Will be included. However, in such a circle, it is not possible to distinguish between the area where the nerve cells are present and the area where the nerve cells are not present on the side that does not touch the boundary. Can not do it. It should be noted that the point that becomes the center of such a circle has a longer distance to the boundary on the side where the circle does not touch.
On the other hand, if a circle inscribed in the boundary is provided, it is possible to distinguish between the area where the nerve cell exists and the area where the nerve cell does not exist on both sides of the boundary. Accurately grasp. Then, when providing a circle inscribed in the boundary, in the binarized value “1” region (that is, the region of the nerve cell in the nerve cell image), the point that is the shortest distance from the boundary on both sides is determined. Will do. This distance is the maximum value of the radius of a circle that touches the boundary around each point of the binarized value “1”.

Therefore, if the maximum value of a circle that touches the boundary around each point of the binarized value “1” is taken, this circle becomes an inscribed circle.
However, if an inscribed circle is simply provided in the binarized value “1” region, a plurality of inscribed circles overlap as shown in FIG. 4B. It is not possible to divide each area including the inscribed circle.
Therefore, as shown in FIG. 4C, the inscribed circle having the maximum radius among a plurality of overlapping inscribed circles is determined as the inscribed circle provided in the binarized value “1” region. Then, as shown in FIG. 4D, the inscribed circles are sequentially provided in the same manner in the binarized value “1” region excluding the region provided with the inscribed circle.
That is, an inscribed circle having the maximum radius is provided in the nerve cell region excluding the points included in the inscribed circle having the maximum radius, and the points included in the inscribed circle are removed. By repeating these processes, as shown in FIG. 5B, a plurality of inscribed circles having local maximum radii are determined in the respective regions.

A step of dividing each region including the inscribed circle (step S13)
In step S13, the area of the nerve cell is divided for each area including the inscribed circle area and its peripheral area. In other words, among the points in the binarized value “1” region in the image, each point is closest to each of the points located outside the inscribed circle having the maximum radius determined in step S12. An inscribed circle is detected, and as shown in FIG. 5C, the region including each inscribed circle is divided so that these points are included in the nearest inscribed circle region. Thereby, all the points in the area | region of a nerve cell will be divided into any area | region containing an inscribed circle.

A step of extracting a predetermined parameter amount that characterizes each divided area (step S2)
In step S2, parameter quantities characterizing each region such as the center point of each circular region and average luminance are extracted.
As the parameter amount characterizing each area divided in the circular area dividing step S1, the center point of the area, the radius of the inscribed circle, the average luminance, and the like can be considered.
In particular, when the position of each region is represented by the center point of each circular region (that is, the center point of the inscribed circle in each region), the direction or angle of the divided adjacent region extends (or bends). Position information can be detected almost accurately.

  The direction or angle in which the cell extends (or bends) in the image is generally known conventionally without using the method of representing the position of each region at the center point of the inscribed circle in each region described above. It can be obtained by using a method of taking three points in an image and calculating based on the inner product. Then, from the angle obtained by the method, it is possible to analyze the detailed structure of the protruding portion or the tubular portion in the nerve cell. Since these structures normally have a structure that is almost a straight line as shown in FIG. 6A, the obtained analysis results have a certain degree of accuracy.

  In addition, the direction and angle of cell extension (or bending) in the image can be determined with respect to, for example, a structure in which a plurality of tubular parts overlap and branch when analyzing a branching state in a protruding part or a tubular part. This information is necessary for determining whether such a tubular portion of the route overlaps to create such a structure.

However, for example, as shown in FIG. 6 (b), the distance between the tubular parts as shown in FIG. 6 (a) is very short as compared to a cell in which the tubular portion is configured to be almost linear as a whole. When three points are taken and calculated based on the inner product, the direction or angle of the cell in the image that extends (or bends) tends to cause a large error relative to the direction or angle of the whole cell that extends (or bends). Become.
On the other hand, as shown in FIG. 6 (c), when three points having a long distance are taken and calculated based on the inner product, a large error is included with respect to the direction and angle of bending locally in the cell. become.
Therefore, in order to accurately detect the detailed structure of the protruding portion or the tubular portion of the nerve cell, it is necessary to use an accurate detection method other than the method of taking the above three points.

Further, for example, as shown in FIG. 6 (b), even if the bending direction or angle of a local part is detected by taking three points at the boundary part in the tubular part, the tubular part is detected. The width and the structure of the tubular part are not uniform. For example, the boundary portion facing the boundary portion having three points shown in FIG. 6B is not necessarily bent at the same bending direction and angle as the boundary portion having three points. For this reason, if the three points are taken as the boundary portion in the tubular part, a large error is likely to occur in the analysis result of the detailed structure of the protruding part or the tubular part of the nerve cell.
For this reason, when calculating the direction or angle in which the cells in the image extend (or bend) using a technique that takes three points in the image and calculates based on the inner product, which is generally known in the past, In order to accurately analyze the detailed structure of the protruding portion or the tubular portion of the nerve cell, an artificial work such as correction of the calculation result is required.

  In contrast, as in the neuron image analysis apparatus of the present embodiment, the position information is represented for each divided area, and the position information for each area is represented by the center point of the inscribed circle. The center point of the inscribed circle and the distance connecting the center points are the position suitable for accurately calculating the cell extending (or bending) direction and angle, and the distance (distance about the diameter of the inscribed circle). It has become. For this reason, by using the center point of these inscribed circles, it is possible to accurately calculate the direction and angle in which cells extend (or bend), and to accurately analyze detailed structures such as protrusions and tubular parts Can do.

  The center point of the inscribed circle in each divided area is determined according to the thickness of each divided area. For this reason, when the position of each region is represented by the center point of each circular region (that is, the center point of the inscribed circle in each region) as in the cell image analysis apparatus of the present embodiment, a thin tubular shape is obtained. For the part, there is an advantage that the cell extending direction (or the bending direction) and the angle can be calculated finely. In this way, it is possible to calculate using only the points necessary for accurately calculating the cell extending (or bending) direction and angle, and taking the above-mentioned three generally known points. In the case of using the method of calculating in this way, points are not provided at unnecessary portions or points are not provided at necessary portions. And since the direction and angle in which cells extend (or bend) can be calculated accurately, it is not necessary to perform manual operations such as correcting the calculation results after calculating the above angles, etc., and almost automatic analysis is performed. Will be able to.

  Further, if information such as the average luminance of each region divided in the cell image analysis apparatus of the present embodiment is extracted as a parameter amount, basic information such as whether or not the tubular part is in contact with the luminance is used. Information can be acquired, and projections and tubular parts of cells can be accurately traced.

  In the neuron image analysis apparatus of the present embodiment, the function of extracting the parameter amount such as the center point of each circular region and the average luminance for each of the divided regions is a projection or tubular shape in the cell. This is particularly effective when analyzing a complicated structure in which a plurality of parts are intertwined.

For example, as shown in FIG. 7 (a), when the tubular part in the cell 2 and the tubular part in the cell 3 are entangled with the tubular part in the cell 1, the observer views the cell image. It is possible to trace each tubular part in each cell one by one. However, this places a burden on the observer as described above.
However, in order to automatically trace each tubular portion in each cell, when using the above-described generally known method of taking three points, the interval between the three points is relatively When taking a long distance, a case where it is difficult to recognize how each tubular portion branches is likely to occur. For example, as shown in FIG. 7 (b), using the three points of the point in the vicinity of the cell body in the cell 1, the point tangled with the cell 2 and the cell 3, and the arbitrary points of the cells 1 to 3 respectively. Even if the cell extending direction (or bending direction) and angle are calculated, it is difficult to analyze the fact that each tubular part in each cell is one by one.
Further, when the distance between the three points is short, for example, as shown in FIG. 7 (c), in the case where the tubular portion of the cell is bent at a steep angle, the point in the cell is bent at a steep angle. As each tubular part is cut, these points are recognized as joints of different tubular parts, and as a result, it is easy to misunderstand that the tubular part is cut at many points.
In that respect, according to the nerve cell image analysis apparatus of the present embodiment, the amount of parameters such as the center point of each circular region and the average luminance for each divided region is the direction in which the cells extend (or bend). Therefore, it is possible to accurately analyze a complicated structure in which a plurality of protrusions and tubular parts in a cell are intertwined.

Step of obtaining a matrix ("region correlation matrix") indicating the correlation between adjacent regions (step S3)
In step S3, a matrix for determining the correlation of each region is acquired.
This matrix can be expressed by, for example, a component (x, y) where x is the number of regions and y is the maximum number of branches in the region (the maximum number of regions adjacent to the region).
Specifically, for example, it is assumed that there is a cell image in which an inscribed circle as shown in FIG. In FIG. 8A, the leftmost inscribed circle (including the area) is set to 1, and the numbers 2, 3,...
A matrix for determining the correlation of each region for the cell image shown in FIG. 8A is shown in FIG. 8B. Since the number of regions is 9, the values of the region numbers 1 to 9 are taken along the x-axis direction in the first row. In the second and subsequent rows, the numbers of adjacent areas in each area are taken along the y-axis direction. For example, the region adjacent to the region 1 is only the region 2. Further, adjacent regions in region 2 are region 1, region 3, and region 4.

Information on adjacent regions is information essential for tracing, for example, a projecting part or a tubular part, and is also information necessary for determining the presence / absence of branching and the number of branches.
When the correlation between adjacent regions is formed into a matrix as in the nerve cell image analysis apparatus of the present embodiment, analysis regarding these branches can be performed at high speed.
For example, when the position information in the image is used as it is, the branch position needs to be recalculated every time the cell extending direction (or bending) or angle in each region is calculated.
On the other hand, if the matrix for determining the correlation of each region is acquired, the branch position can be easily grasped, so that the above-described trouble of recalculating the branch position can be saved.

  In addition, since the matrix is expressed by a component (x, y) where x is the number of regions and y is the maximum number of branches in the region (the maximum number of regions adjacent to the region), the number of regions is (x, x) matrix (for example, when the number of regions is 10, 10 in the row and column) It takes a total of 100 elements, and it is composed of a smaller amount of data than the case of “1” when there is an adjacent area in all elements, and “0” when there is no adjacent area) Therefore, the calculation can be speeded up, and when the elements of the matrix are repeatedly used for the calculation, the effect of the speeding up becomes large.

  In addition, the radius of the inscribed circle in the predetermined area formed by dividing the tubular part or the projecting part and the radius of the inscribed circle in the area adjacent to the part are the tubular part or the projecting part. It can be considered that the structure takes almost the same value. For this reason, like the nerve cell image analysis apparatus of the present embodiment, when the correlation between adjacent regions is matrixed, the length of a tubular portion or a protruding portion can be measured according to the number of regions, This is also effective for calculating a relative distance between predetermined regions.

For example, using a matrix indicating the correlation between adjacent regions in the nerve cell image analysis apparatus of the present embodiment, the shortest route can be calculated as follows.
This distance is set to 1 with respect to an appropriate start area (FIG. 9A). Further, the matrix elements adjacent to each other are taken as the second, and adjacent areas are sequentially obtained for all the elements, and number N is assigned (FIG. 9B). When the radius of the inscribed circle in each region is substantially the same, the distance from the start region in the Nth region is proportional to N, and is (N-1) × radius of the inscribed circle × 2. This distance is more accurate than a distance obtained by connecting a straight line from the center of the Nth region to the center of the start region, for example. Therefore, according to the nerve cell image analysis apparatus of the present embodiment, the distance from the start region can be accurately calculated even for a curved route as shown in FIG.

  Moreover, if a matrix including information on adjacent regions is acquired as in the nerve cell image analysis apparatus of the present embodiment, the branch position of a tubular part or a protrusion-like part can be accurately grasped by analyzing only the matrix. be able to. That is, in the region at the branching position, there are three or more adjacent regions (that is, there are three or more y components). For example, in the x and y matrix for the numbered cells as shown in FIG. 8 (a), as shown in FIG. 8 (b), there are three y components in the second area (area 1, area). 3, region 4) There are four y components in the fifth region (region 4, region 6, region 7, region 9). As a result, it can be seen that the second and fifth regions are at branch positions.

A step of detecting the route and branching state of the nerve cell using the acquired matrix (step S4)
In step S4, the route, branch position, branch number, etc. of the nerve cell are detected.
The route of the nerve cell is, for example, a group of regions farthest from the start region (that is, a region where the number of regions in which adjacent regions are continuous from the start region is the largest (here, N)). Cell by taking the N-1th, N-2,... Points in order from this end point to the start point, with the region farthest from the start region (ie, the Nth region) as the end point. Can get the root of the foot. This route is the first route (route 1 in FIG. 9B).

  Furthermore, for the remaining area adjacent to the first route, the first area that branches off is the start area, the farthest distance from the start area is the end point, and the end point is directed to the start point. Then, the route can be obtained by sequentially taking the N-1th, N-2,... Points (route 2 in FIG. 9B).

  By the above operation, for example, the number of protrusions of nerve cells is detected as M (where M is the number of routes). Each area is assigned a number from 1 to M for each route. These processing results are output to a predetermined memory or display area.

A step of calculating statistics such as the total number, the average length, the number of branches, etc. of the protrusion-like or tubular parts in the nerve cell (step S5)
In step S5, a statistic is calculated. The final statistic is determined based on the information output in step S4, and the total extension of the mth route can be obtained by the sum of the diameters of the inscribed circles between the areas assigned the number m. it can. For example, the total extension of the part of route 1 shown in FIG. 10 is calculated as the sum of the diameters of the respective inscribed circles from the start region (start point 1) in route 1 to the end region (end point 1) in route 1.

  The number of branches is determined based on the number of routes output in step S4. In addition, the branch point is an adjacent region having a route number other than the m-th among regions to which the m-th route number is assigned using the matrix relative position obtained in step S3 and indicating the correlation between adjacent regions. In some cases, a branch point is determined as a branch. Alternatively, as described above, a branch point is determined from a region where there are three or more adjacent regions (that is, there are three or more y components).

  By calculating the statistics in this way, various parameters such as the total length of each route, the total number of routes, the total number of branches, the number of branches included in each route, and the total length of branched routes can be obtained. it can.

  Therefore, according to the nerve cell image analysis apparatus and the nerve cell image analysis software of the present embodiment, the protrusion-like region or tube in the cell, such as a dendrite or axon in the nerve cell and an axon side branch at the tip of the axon. It is possible to accurately and rapidly analyze this part.

  This is useful in the medical, medical, and biological fields where it is required to analyze the structure of protrusions and relatively long tubular parts such as dendrites and axons in nerve cells.

1 is a block diagram schematically illustrating an overall configuration of a nerve cell image analysis apparatus including nerve cell image analysis software according to an embodiment of the present invention. FIG. 2 is a flowchart showing a processing procedure for analyzing a structure of a nerve cell having a protrusion-like or tubular part from a cell image acquired by the nerve cell image analyzing apparatus of FIG. It is a flowchart which shows the specific process sequence in the circular area | region division | segmentation step in the process sequence shown in FIG. FIG. 4 is an explanatory diagram showing a method for determining the maximum inscribed circle in the processing procedure shown in FIG. 3, (a) is a circle that touches one of the boundaries, (b) is a state in which a plurality of circles that are inscribed in the boundary overlap, (c ) Is the state in which the circle with the largest radius in the overlapping area of (b) is selected as the maximum inscribed circle, and (d) is the area in the area excluding the area of the largest inscribed circle shown in (c). Each state shows that the largest circle is selected as the next largest inscribed circle. FIG. 4 is an explanatory diagram conceptually showing the contents of the processing procedure shown in FIG. 3 for each step, in which (a) binarizes an image region and detects a boundary between a nerve cell and a region other than the nerve cell; b) sequentially determines the maximum inscribed circle with the boundary in the binarized nerve cell region, and (c) separately divides the nerve cell region into regions including each inscribed circle. Show. FIG. 4 is an explanatory diagram showing problems in the case of using a conventional general method, and a method using the nerve cell image analysis device of the present embodiment, for analysis of a bending portion in a nerve cell. An example of a configured tubular part, (b) is analyzed when three points that are very short from each other are taken using the conventional general method for the tubular part shown in (a). (C) is an example of the direction or angle of cell extension (or bending), (c) is the cell extension analyzed when three points having a long distance to each other are taken with respect to the tubular part using a conventional general method ( (D) shows an example of the direction and angle of the cell to be analyzed and analyzed in the case of using the method of the neuron image analyzer of the present embodiment. . An explanatory diagram showing the problems of using a conventional general method when analyzing a complex structure in which a protruding part or a tubular part in a nerve cell is entangled, (a) is a tubular part in the nerve cell (B) is a diagram conceptually showing an example of problems when analyzing the structure of the nerve cell in the state shown in (a) by the conventional method, (b) c) is a diagram conceptually illustrating another example of a problem in the case of analyzing the structure of a nerve cell in a state where tubular portions are intertwined in a complicated manner by a conventional method. FIG. 3 is an explanatory diagram of a matrix showing the correlation between adjacent areas in the processing procedure shown in FIG. 2, in which (a) is a numbered area in a neuron, and (b) is a divided area shown in (a). The matrix is shown with the number of x as the x component and the number of the adjacent region in the region as the y component. FIG. 3 is an explanatory diagram showing a method for determining cell routes, branches, and the like in the processing procedure shown in FIG. 2, (a) is a schematic diagram showing a region of a nerve cell by a maximum inscribed circle, and (b) is (a). FIG. 7 is a diagram showing a state in which a predetermined region in a neuron region is numbered as a start region, and (c) is an explanatory diagram showing an end region relative to the start region of the neuron shown in (b). It is explanatory drawing which shows typically the final result which analyzed the nerve cell shown in FIG. It is explanatory drawing which shows the structure of a nerve cell roughly.

Explanation of symbols

1 Microscope for cell observation 2 Imaging device (CCD camera)
3 PC 4 Software 5 for instructing operation control of microscope apparatus 5 Neuronal image analysis software 51 Cell body 51a Cell nucleus 52 Dendrite 53 Axon 53a Axon side branch 53b Axon termination

Claims (16)

A neuron image analysis apparatus that performs a predetermined automatic analysis process on an image obtained from an image acquisition unit that acquires an image of light emitted from a neuron as an image,
Dividing the nerve cell image obtained through the image acquisition means into a plurality of regions including a circular region;
Extracting a predetermined parameter amount characterizing the area for each divided area;
Obtaining a matrix indicating the correlation between adjacent regions;
Detecting a route and branching state of a nerve cell using the acquired matrix;
Calculating the statistics of the obtained information;
Have
A nerve cell image analyzing apparatus characterized in that a structure of a nerve cell is analyzed through processing in each of these steps.   The step of dividing the nerve cell image into a plurality of regions including a circular region performs a predetermined binarization process on the nerve cell image obtained through the image acquisition means, Detecting a boundary between a region of the nerve cell and a region other than the nerve cell, providing an inscribed circle with the boundary having a maximum radius in the region of the nerve cell, and further excluding the inscribed circle The process of providing an inscribed circle with the boundary having the maximum radius in the cell area is repeated by a predetermined amount, and then, the area of the nerve cell is divided into each area including the inscribed circle area and its peripheral area. The nerve cell image analysis apparatus according to claim 1, wherein:   The feature amount parameter extracted in the step of extracting the amount of a predetermined feature amount parameter characterizing the divided region for each of the divided regions has at least a center point in each of the circular regions. The nerve cell image analyzer described in 1.   The feature parameter extracted in the step of extracting an amount of a predetermined feature parameter that characterizes the divided region for each of the divided regions is further at least one of a radius of an inscribed circle and an average luminance in each of the circular regions The nerve cell image analysis apparatus according to claim 3, wherein   The matrix in the step of obtaining a matrix indicating the correlation between the adjacent regions is obtained by taking the total number of the regions with the number of the divided regions as the x component, and the maximum branch of the region with the number of the adjacent regions as the y component. It takes several minutes, The nerve cell image analysis apparatus according to any one of claims 1 to 4.   The matrix values in the step of obtaining a matrix indicating the correlation between the adjacent areas are given as 1 to N numbers in order to adjacent areas starting from an arbitrary area in the divided area. 6. The nerve cell image according to claim 5, wherein the number of .about.N is assigned in order to the x component, and the number of the area adjacent to the area corresponding to the number in each x component is assigned in order to the y component. Analysis device.   The step of detecting the route and branching state of the nerve cell using the acquired matrix determines an arbitrary start area in the divided area and sets an area farthest from the start area as an end area. A series of areas from the end area to the start area is determined as a first route, and an area where branching starts from the first route is determined as a second start area for the remaining areas. And determining a region farthest from the second start region as a second end region, and a series of regions from the second end region to the second start region as a second route. 7. The nerve cell image analyzing apparatus according to claim 6, wherein the determination is further performed, and a process substantially similar to the process of determining the second route for the remaining area is repeated.   8. The step of extracting a statistic of the obtained information acquires at least one of the total extension of each route, the total number of routes, the total number of branches, and the number of branches in each route. The neuron image analysis apparatus described. A nerve cell image analysis software used in a nerve cell image analysis apparatus that performs a predetermined automatic analysis process on an image obtained from an image acquisition unit that acquires an image of light emitted from a nerve cell as an image,
Dividing the nerve cell image obtained through the image acquisition means into a plurality of regions including a circular region;
Extracting a predetermined parameter amount characterizing the area for each divided area;
Obtaining a matrix indicating the correlation between adjacent regions;
Detecting a route and branching state of a nerve cell using the acquired matrix;
Calculating the statistics of the obtained information;
Have
A neuronal image analysis software characterized in that the structure of a neuronal cell is analyzed through processing in each of these steps.   The step of dividing the nerve cell image into a plurality of regions including a circular region performs a predetermined binarization process on the nerve cell image obtained through the image acquisition means, Detecting a boundary between a region of the nerve cell and a region other than the nerve cell, providing an inscribed circle with the boundary having a maximum radius in the region of the nerve cell, and further excluding the inscribed circle The process of providing an inscribed circle with the boundary having the maximum radius in the cell area is repeated by a predetermined amount, and then, the area of the nerve cell is divided into each area including the inscribed circle area and its peripheral area. The nerve cell image analysis software according to claim 9, wherein:   The feature amount parameter extracted in the step of extracting a predetermined feature amount parameter characterizing the region for each of the divided regions has at least a center point in each of the circular regions. The neuronal image analysis software described in 1.   The feature parameter extracted in the step of extracting an amount of a predetermined feature parameter that characterizes the divided region for each of the divided regions is further at least one of a radius of an inscribed circle and an average luminance in each of the circular regions 12. The nerve cell image analysis software according to claim 11, comprising:   The matrix in the step of obtaining a matrix indicating the correlation between the adjacent regions is obtained by taking the total number of the regions with the number of the divided regions as the x component, and the maximum branch of the region with the number of the adjacent regions as the y component. The nerve cell image analysis software according to claim 9, which takes several minutes.   The matrix values in the step of obtaining a matrix indicating the correlation between the adjacent areas are given as 1 to N numbers in order to adjacent areas starting from an arbitrary area in the divided area. 14. The nerve cell image according to claim 13, wherein the number of .about.N is assigned to the x component in order, and the number of the area adjacent to the area corresponding to the number in each x component is assigned to the y component in order. Analysis software.   The step of detecting the route and branching state of the nerve cell using the acquired matrix determines an arbitrary start area in the divided area and sets an area farthest from the start area as an end area. A series of areas from the end area to the start area is determined as a first route, and an area where branching starts from the first route is determined as a second start area for the remaining areas. And determining a region farthest from the second start region as a second end region, and a series of regions from the second end region to the second start region as a second route. 15. The nerve cell image analysis software according to claim 14, wherein the determination is further performed, and substantially the same process as the process of determining the second route for the remaining area is repeated.   16. The step of extracting the statistics of the obtained information obtains at least one of the total extension of each route, the total number of routes, the total number of branches, and the number of branches in each route. The neuronal image analysis software described.

Images