The present invention relates to a method and a device for extracting a specified region in an image, and in particular to a technique for extracting a region to which a desired image processing is to be applied.
In recent years, images being obtained with image diagnostic apparatuses such as X-ray, X-ray CT or MRI have been widely used, not only at the time of diagnosis, but also at the time of treatment. There has especially been an increase in studies for extracting automatically a specified organ out of display images for the purpose of diagnosis or treatment. For example, displaying the coronary artery pattern running in the vicinity of cardiac surface in 3-dimensional representation would be extremely useful at clinical sites.
However, in the case of segmenting the organ regions or extracting the specified regions, there is still a need for doctors to rely on their anatomical knowledge for diagnosis and recognition. Particularly, in the case of identifying an organ region, a method to approximate a simple graphic to a contour of the organ according to the anatomical knowledge of an organ to be identified is implemented. For example, as disclosed in Patent Document 1, on an ultrasonic diagnostic image, the internal volume of the left ventricle of a heart is obtained by approximating an ellipse to the contour of a left ventricle and by determining the left ventricle region.
However, the shapes of organs are generally quite complicated, thus making it difficult to precisely approximate the contours of them using a simple graphic in all cases. Approximation with a simple graphic will surely cause some errors, and the operation for the approximation would be repetitive and complicated work.
Also, the method being disclosed in Patent Document 1 relates to an elliptical internal region, and it causes a problem in the case of extracting a coronary artery located in the cardiac surface region using MIP (Maximum Intensity Projection) processing, because there are occasions upon attempting MIP processing by specifying the region encompassing the heart including the surface region that the coronary artery becomes invisible due to the high signal region of the cardiac internal region being projected.
Patent Document 1: JP-A-2000-210284
The objective of the present invention is to provide a method and a device for extracting a region wherein the extraction of a specified region in the image can be executed with high accuracy by a simple operation.
In order to achieve the above-mentioned objective, the method for extracting a region relating to the present invention that is for extracting a specified region in an image includes:
(a) a step for displaying an image;
(b) a step for selecting a desired region in the image;
(c) a step for selecting an element graphic to correspond with at least a partial contour of a partial region within a desired region;
(d) a step for approximating at least a partial contour of the element graphic to at least a partial contour of the partial region;
(e) a step for repeating steps (c)˜(d) at least twice; and
(f) a step for making at least a partial contour of the respective element graphics after approximation as a first contour.
This is for extracting at least a partial contour of a desired region as a first contour by approximating at least a partial contour of an element graphic to at least a partial contour of a partial region within the desired region.
Also, the second contour is obtained based on the first contour, and a region including at least a stratified region that is held between the first and the second contours is extracted.
By implementing this procedure, the method for extracting a region related to the present invention can determine a contour of a desired region (the first contour) with a simple operation and with high accuracy. Further, a region including the stratified region held between at least the first contour and the second contour can be easily extracted as a specified region.
As a result, through performing a desired image processing on the specified region by the method for extracting the organ region related to the present invention, it is possible to perform an efficient and accurate image processing in a short period of time. Especially, in the case of obtaining an image of a blood vessel such as a coronary artery running on the cardiac surface region, a clear and satisfactory image can be efficiently obtained by extracting only the surface region of a heart by the present invention.
To achieve the above-mentioned objective, a device for extracting a region related to the present invention is configured as below. The device for extracting a region comprises:
a display means for displaying an image:
an input means for the indication corresponding to the image to be inputted; and
a calculating means for performing a desired image processing on the image;
wherein the display means displays a plurality of element graphics along with the image, the input means has the indication for approximating at least a partial contour of the respective element graphics inputted, and the calculating means makes a contour combining at least a partial contour of the respective element graphics after approximation as a first contour.
Also, the calculating means obtains a second contour based on the first contour, and extracts the region including the stratified region held between at least the first contour and the second contour.
These configurations are related to the device for actualizing the above-mentioned method for extracting the region, and such configured device for extracting the region would have the same effects as of the above-mentioned method.
Hereinafter, the first embodiment of a device and method for extracting regions related to the present invention will be described referring to the attached drawings.
central processing unit (CPU) 10 for controlling the operation of the respective constituent elements;
main memory 11 for storing the controlling program of the whole device;
magnetic disk 12 for storing a plurality of tomographic (image) data and programs;
display memory 13 for temporarily storing image data for display;
CRT display 14 as a display device for displaying images based on image data from display memory 13;
mouse 15 and its controller 16 for operating the soft switch on an image;
keyboard 17 provided with keys and switches for setting various types of parameters;
speaker 18; and
common bus 19 for connecting the above-mentioned respective constituent elements.
Though the present invention illustrates the case of only magnetic disk 12 being connected as a memory device besides main memory 11, other devices such as floppy disk drive, hard disk drive, CD-ROM drive, magnetic optical (MO) disk drive, ZIP drive, PD drive or DVD drive may be connected instead. Further, it may be set so that it is connectable to various types of communication network 1a such as LAN (Local Area Network), Internet, or telephone lines via communication interface, and that image data can be interchangeable between devices such as other computers or X-ray CT device 1b. Also, the region-extracting device of the present invention may interchange image data with region-extracting devices capable of collecting tomographic information of an object to be examined such as X-ray CT or MRI via communication network 1a such as the above-mentioned LAN.
Next, an example of the basic operation in the first embodiment of a region-extracting device related to the present invention as illustrated in
Detailed particulars of processing content in the respective steps illustrated in the flow chart of
An image is displayed in step S100. In concrete terms, for example, the tomographic image data being imaged by X-ray CT device is read out from magnetic disk 12 and displayed to CRT 14 illustrated in
In step S101, a desired region is selected on the displayed image in step S100. The desired region, for example, can be of a heart. In this step, in the case of manually implementing the approximation on the contour of a desired region, an operator determines which region (desired region) in the image should be approximated for extracting the contour, as described below. In other words, the region to be the target of extracting a contour is determined. This step can be omitted by executing the next step S102 directly.
In step S102, element graphics to approximate at least a partial contour of the partial region within a desired region being selected in step S101 are selected. The partial regions here, for example, can be myocardium or right ventricle of a heart as shown in
In step S103, at least a partial contour of an element graphic is approximated to at least a partial contour of a partial region.
The first procedure for approximating this element graphic to an outer contour of a partial region within a desired region will be described referring to
First, ellipse 301 is allocated so that the right part of ellipse 301 is approximated most to the right part of myocardium outer contour 311 (
In other words, this first procedure is to allocate the ellipses one at a time independently to the outer contour of the respective partial regions within the heart. In this case, the allocation of the respective ellipses may be determined mutually and independently after all of the ellipses 301˜304 are displayed together with an image, or the operation to mutually and independently determine the allocation of the ellipse may be repeated as additionally displaying each ellipse on an image.
Next, the second procedure for approximating element graphics to the outer contour of the respective partial regions within a desired region will be described according to
An example as shown in
Then one ellipse 511 passing through these four points or the vicinity of them is selected and displayed. A degree of approximation of the ellipse to the right part of myocardium outer contour 311 is further improved by adjusting the position, size or shape of ellipse 511. The allocation of the subsequent ellipses are determined in a similar manner by placing a plurality of points on a contour of a desired region or on the contour of the partial region thereof, and by selecting and displaying the ellipses passing through these points or the vicinity of them.
Also, an example as shown in
Though an example of selecting ellipses as element graphic was described in the above-mentioned example referring to
In addition, a method similar to, for example, an operation method of one ellipse shown in
Also, though an example for using ellipses as element graphics was described above, it is possible to use some other shapes. An example of this case is shown in
In step S104, a judgment of whether a contour approximation of a desired region is completed or not is carried out. When completed (yes), step S106 will proceed. When not completed (no), the procedure returns to step S102, the selection of element graphics corresponding to at least a partial contour of a partial region to be approximated and the approximation process by the element graphics being selected are carried out in each of previously mentioned steps S102 and S103, and this will be repeated until the contour approximation of the desired region is completed.
In step S105, a contour, by which at least a part of the respective element graphics after approximation are combined, is set as a first contour. For example, as shown in
In step S106, a second contour is obtained based on the first contour being acquired in step S105. For example, a second contour can be acquired through enlarging or reducing the first contour with a predetermined magnification. The second contour will be on the outside of the first contour if the magnification is bigger than 1, and the second contour will be on the inside of the first contour if the magnification is smaller than 1. The second contour can also be set by enlarging or reducing the respective element graphics being used for obtaining the first contour in step S105 with predetermined magnification, and then combining the outer contour parts of these respective ellipses being enlarged or reduced which are not mutually overlapping. Or, it can also be set by combining the outer contour parts of the respective ellipses that are not mutually overlapping, after changing a size, position or shape of the respective element graphics being used for obtaining the first contour in step S105. This last example will now be illustrated referring to
Though an example of approximating the whole contour of a desired region by a plurality of element graphics was described above, only a partial contour of the desired region may also be approximated. In this case also as mentioned above, a partial contour of the desired region is approximated by at least a partial contour of the respective element graphics.
In step S107, a region held between the first contour and the second contour respectively acquired in step S105 and step 106 is set as a stratified region encompassing the desired region, and the region at least including this stratified region is extracted.
For example, as shown in
Particularly, in the case of enlarging or reducing the second contour by a predetermined magnification of the first contour, the outside of the stratified region of the first region (that is the surface area of the desired region) is extracted if the predetermined magnification is bigger than 1, and the inside of the stratified region of the first contour is extracted if the predetermined magnification is smaller than 1. The magnification in the case of extracting a stratified region of the outside can be, for example, 1.2 times. Also, the magnification in the case of extracting a stratified region of the inside can be, for example, 0.8 times.
Or, as shown in
Also, though the example in the case of second contour 1302 being on the outside of the first contour was described in
Additionally, in the case of approximating a partial contour of a desired region, a partial contour thereof, the stratified region being specified by the partial contour or the region in the vicinity of the contour is to be extracted.
As described above, according to the first embodiment of the present invention, contour-extraction of a desired region can be implemented in a short period of time with a simple operation and high accuracy, without being deceived by image-noise or the unclear border of organs. It also enables an effective image processing with high precision by extracting regions including at least stratified regions based on the contours being extracted, and performing a desired image processing being specified to the region thereof.
Next, the second embodiment of the region-extracting device and method related to the present invention will now be described. In this embodiment, a region including at least a stratified region encompassing a desired region is extracted from the respective plural slices of a tomographic image, and the plurality of regions being extracted from the respective tomographic images is synthesized to create a 3-dimensional region. This 3-dimensional region is then specified, and the desired image processing will be performed.
The description on the configuration of the region-extracting device in the second embodiment will be omitted since it is the same as the one of the first embodiment. Also, an example of the basic operation in the second embodiment will be described based on the flow chart shown in
Described below is an example of the detailed processing content regarding each step illustrated in the flow chart in
In step S200, 1 is set on counter k that is for repeatedly processing a plurality of tomographic images, and an initialization is implemented. For example, in the case of sequentially processing N-slices of tomographic image data being acquired by imaging a heart region by X-ray CT device, from the tomographic image data of the first slice, the process on and after the next step is to be implemented.
In step S201, k-th tomographic image including a desired region as a target region for the contour-extracting process is displayed on the display device. In concrete terms, for example, k-th tomographic image data being imaged by an X-ray CT device is read out from magnetic disk 12 and displayed to CRT 14 shown in
An example of tomographic image display is illustrated in
After displaying an image, an operator determines which region (desired region) should be the target for extracting a contour. A heart can be, for example, selected for the desired region. This step is equivalent to steps S100 and S101 in
In step 202, a patterned graphic for extracting a contour is selected. Or, on the contrary, the patterned graphic may be ultimately created, after a plurality of element graphics have been individually selected. This step is equivalent to step S102 in
It is common that organ shapes of objects to be examined are vastly different and diverse. Thus it is preferable to provide a plurality of patterned graphics to respond flexibly to as many different shapes as possible, so that a suitable pattern can be selected for extracting a contour from a wide range of patterned graphics.
The examples of the patterned graphics are illustrated in
Moreover, another example of patterned graphic is illustrated in
The number of element graphics should be one or more. If it is one, an element graphic itself becomes a patterned graphic.
The above-mentioned patterned graphics being illustrated in
Or, as described in the above-mentioned second procedure referring to
The patterned graphic or element graphic being selected as described above is displayed along with an image. Practically, data of the patterned graphic or element graphic are stored, for example, in main memory 11 or display memory 13 indicated in
In step S203, a contour of a pattern graphic is approximated to a contour of a desired region. To accomplish this process, each contour of a plurality of element graphics is approximated to a contour of the desired region. Specifically, at least a partial contour of the respective element graphics are approximated to at least a partial contour of the respective desired regions. Or, in the case where a desired region includes a plurality of partial regions, at least a partial contour of at least one element graphic is approximated to a contour of at least one partial region. In this way, after approximating a plurality of element graphics to a contour of a desired region, the outer contours of the respective element graphics that are not overlapping are interlinked and set as a contour of a patterned graphic. This step is equivalent to step S103 of
The procedure to approximate this patterned graphic to a contour of a desired region can be executed by approximating the respective element graphics configuring this patterned graphic to a contour of a desired region, using the previously mentioned first procedure or the second procedure. Here, another procedure (third procedure) will be described.
The third procedure for approximating the patterned graphic to an outer contour of a heart based on
An outer contour of a heart can also be obtained ultimately using a plurality of ellipses according to the above-mentioned third procedure. The outer contour of a heart being obtained using one of the first˜third procedures are shown in
Also, an example for approximating another example of patterned graphic shown in
Outer contour 704 of a heart being obtained as stated above is shown in
The respective ellipses 301˜304 can be rotated around midpoints 301o˜304o by moving rotors 301r˜304r denoted with squares being outside of the respective ellipses 301˜304 using a pointing device such as a mouse, trackball or light pen. Also, the size or shape of the ellipses can freely be changed, since the position of the long axis point and the short axis point of respective ellipses 301˜304 are movable using a pointing device such as a mouse. At this time, long axis point 302a of ellipse 302 and long axis point 303a of ellipse 303 should coincide upon moving. In the same way, long axis point 303b of ellipse 303 and short axis point 304a of ellipse 304 should also coincide upon moving. In this way, the respective ellipses 301˜304 are allocated so that the shapes of these four ellipses are most approximating to the outer contour of a heart on the tomographic image in
Previously the case of using the ellipses as element graphics for configuring the patterned graphic to execute the approximation to a contour, but as shown in
According to the changes in the patterned graphics or element graphics caused by the approximation operation as described above, for example, CPU 10 modifies the data of patterned graphics or element graphics being stored in main memory 11 or display memory 13.
In addition, though an example of approximating the entire contour of a desired region by patterned graphics was described above, only a partial contour in a desired region may be approximated. Also, a partial region of a desired region may be approximated using only a part of a patterned graphic. Also in this case, a partial contour of a desired region would be approximated by a part of the respective element graphics configuring patterned graphics.
In step S204, a contour of the patterned graphic being approximated in step S203 is extracted as a contour of a desired region (a first contour). In the previously mentioned example of extracting an outer contour of a heart, as shown in
Next, a second contour is obtained based on the first contour of a desired region. This second contour can be obtained using a method such as the one described in previously mentioned step S106.
This step is equivalent to step S105 and S106 in
In step S205, the region including at least the stratified region being specified by two contours that are extracted in step S204 is extracted. This stratified region becomes a region that encompasses at least a part of the desired region. In concrete terms, any one of the following regions, only the stratified region, the region on the side of the first contour including the stratified region, or the region on the side of the second region including the stratified region, can be extracted. This step is equivalent to step S107 of
In this embodiment also, as shown in
Additionally, in the case of approximating a partial contour of a desired region by the patterned graphic, the partial contour thereof, the stratified region, or the vicinity region of the contour being specified by the partial contour thereof would be extracted.
In step S206, whether counter k is under N or not is confirmed. This means to determine whether the number of the slices that processed the contour extraction had reached the predetermined number N or not. If not reached (yes) step S209 is to be carried out and counter k is incremented, if reached (no) step S207 is to be carried out.
In step 207, a 3-dimensional stratified region encompassing the respective desired regions or a 3-dimensional region including this 3-dimensional stratified region is synthesized, using the stratified region being extracted on every slice of tomographic images or the region including this stratified region. In the case of approximating a partial contour of a desired region, a part of 3-dimensional stratified region encompassing a desired region or the 3-dimensional contour-vicinity region would be synthesized.
In step S208, a desired image processing is performed, by limiting to the synthesized 3-dimensional stratified region or image data of 3-dimensional region including this 3-dimensional stratified region.
By performing a desired image processing based on the 3-dimensional stratified region being acquired in step S207 or image data being included in 3-dimensional region including the 3-dimensional stratified region, in other words, by limiting the target for performing image processing to image data of these regions, it is possible to perform an effective image processing with high accuracy.
As an example of the image processing, a 3-dimensional image illustrating the blood vessel pattern running in the vicinity of a cardiac surface is shown in
According to the device and method relating to this embodiment, comparing to the method such as being disclosed in (non-patent document) for extracting the blood vessel pattern running in the vicinity of the cardiac surface using a tabular region with a predetermined thickness, it is possible to indicate the blood vessel pattern in 3-dimensions which enhances the clear visibility of the image. Also, as another example of image processing, an example for implementing a Bull's-eye display of the blood vessel pattern running in the vicinity of the cardiac surface is shown in
Additionally, in the case of approximating a partial contour of a desired region, a desired image processing would be performed being limited to a part of 3-dimensional stratified region or a 3-dimensional contour-vicinity region.
Non-Patent Document 1: Alex Etienne et al., “Soap-Bubble” (Visualization and Quantitative Analysis of 3D Coronary Magnetic Resonance Angiograms), published by International Society for Magnetic Resonance in Medicine, volume 48, Issue 4, Pages 658-666, October 2002.
Described above is the example of the basic operation for the second embodiment of the region-extraction device relating to the present invention. Though the example described is one of configuring patterned graphics by a plurality of element graphics, one element graphic itself may be used as a patterned graphic. In this case, a contour of a desired region would be approximated through changing the position, size or shape of one element graphic. Also, though the example for extracting the 3-dimensional stratified region or the region including this 3-dimensional stratified region from a plurality of tomographic images was mentioned above, only one tomographic image may be used instead. In this case, 2-dimensional stratified region or the region including this 2-dimensional region would be extracted from one tomographic image. An example for extracting regions such as a 3-dimensional stratified region from a small number of tomographic images will be described later in the fifth and six embodiments.
As described above, according to the second embodiment of the present invention, in addition to the advantageous effects being described in the first embodiment, the extraction of 3-dimensional regions can be further improved in simplicity, time-saving in operation and high accuracy in image processing. Also, an effective image processing with high accuracy becomes possible by limiting the target to a 3-dimensional region. The present invention is especially effective in the case of targeting organs with complicated shapes such as the heart, or obtaining images of blood vessels such as the coronary artery that are running over the surface of a heart.
Next, the third embodiment of region-extracting device and method relating to the present invention will be described.
The present embodiment is for extracting a contour of a desired entire region and the stratified region thereof, by first extracting one or more partial regions being included in a desired region and then combining and synthesizing the respective extracted partial regions. The differences from the previously mentioned second embodiment are that there are no steps S202 and S203 in
The description on the region-extracting device in the third embodiment will be omitted since the configuration of it is the same as the one in the first embodiment shown in
In step S204-3, after independently extracting the respective one or more partial regions being included in a desired region, by synthesizing at least a part of the desired region using the respective extracted partial regions, at least a partial contour of the desired region being synthesized (a first contour) is obtained. Next, a contour of which the first contour is either enlarged or reduced in size by a predetermined magnification (a second contour) is obtained. The second contour also may be obtained, after enlarging or reducing at least a partial desired region being synthesized, from at least a part of the enlarged or reduced desired region. If the magnification is bigger than 1 the second contour will be outside of the first contour, and if it is smaller than 1 the second contour will be inside of the first contour.
Next, for example, enlarged (reduced) outer contour image 1605 is obtained by enlarging or reducing the size of outer contour image 1604 as a seldom-moving point or a gravity point of outer contour image 1604 being a center, and the outer contour thereof (the second contour) is also acquired. Or, the second contour may be obtained through enlarging or reducing the size of the above-mentioned first contour with a predetermined magnification.
Patent Document 1: JP-A-2002-253652
Patent Document 2: JP-A-2003-30575
In the above, an example of automatically extracting the respective partial regions based on the method, for example, being described in (Patent Document 2) or (Patent Document 3), but the extraction may also be implemented using the patterned graphics being described previously in the second embodiment.
In step S205-3, making the region being held between the contour of an entire desired region (the first contour) being obtained in step S204-3 and the enlarged (reduced) contour thereof (the second contour) as a stratified region of the desired region, the region including at least this stratified region is obtained.
In
The above is a description of the steps different from the basic operation of the second embodiment shown in
As mentioned above, according to the third embodiment, in addition to the advantageous effects in the first embodiment, it is possible to obtain stratified regions automatically and the extraction process of stratified regions can be implemented easily and quickly. Particularly in the case of targeting organs with a complicated shape such as a heart, burdens of an operator can be reduced by saving the labor such as the complicated setting process required for the conventional region-extraction.
Next, the fourth embodiment of the region-extracting device and method relating to the present invention will be described. The present embodiment is for extracting stratified regions, by first extracting one or more partial regions being included in a desired region, synthesizing at least a part of the respective desired regions from the extracted respective partial regions and the partial regions being enlarged (or reduced) with a predetermined magnification, and obtaining contours from at least a part of the desired regions which are two different-sized and synthesized. The differences from the previously mentioned second embodiment are, as is in the previously mentioned third embodiment, that there are no steps S202 and S203 in
In step S204-4, after independently extracting the respective one or more partial regions being included in a desired region, by synthesizing at least a part of the desired region using the respective extracted partial regions, at least a partial contour of the desired region being synthesized (a first contour) is obtained. Next, the extracted respective partial regions are enlarged (or reduced) with a predetermined magnification, and by using them at least a part of the enlarged (reduced) desired regions are synthesized. At least a partial contour of the enlarged (reduced) desired regions (the second contour) is obtained.
In the above, an example of automatically extracting the respective partial regions based on the method, for example, being described in (Patent Document 2) or (Patent Document 3), but the extraction may also be implemented using the patterned graphics being described previously in the second embodiment.
In step S205-4, making the region being held between at least a partial contour of a desired region (the first contour) being obtained in step S204-4 and the enlarged (reduced) contour thereof (the second contour) as a stratified region of the desired region, the region including at least this stratified region is obtained.
In
The above is the description on the steps different from the basic operation of the second embodiment shown in
As described above, the fourth embodiment of the present invention provides the same advantageous effects as the previously mentioned embodiment 3.
Next, the fifth embodiment of the region-extracting device and method relating to the present invention will be described.
The present embodiment is for obtaining contours of a desired region based on the several tomographic images out of the plurality of them, and obtaining contours of the desired region other than those of previously mentioned by interpolation from the contours that are previously obtained (herein after referred as “the first contour-interpolation processing”). Or, in the case there is a spacing between the slices, which means that there is no imaged region between the adjacent slices, it is for obtaining a contour of a desired region in not-imaged regions by interpolation from the contours of the desired regions being extracted based on the tomographic images of the imaged slices (hereinafter referred to as “the second contour-interpolation process”). The difference from the second˜fourth embodiment is only the process contents corresponding to the contour-extracting process of step S204 in
The description on the region-extracting device in the fifth embodiment will be omitted since the configuration of it is the same as the one in the first embodiment shown in
In step S204-5, one of the above-mentioned first contour-interpolation process or the second contour-interpolation process will be implemented.
The above is a description of the steps of the second˜fourth embodiments shown in
As described above, according to the fifth embodiment of the present invention, in addition to the advantageous effects of the first˜fourth embodiments, it is possible to save time in carrying out the extraction of 3-dimensional stratified regions. The above-mentioned interpolation process can extract stratified regions in a shorter period of time than the extraction from the tomographic images, thus saving more time compared to the case of obtaining the stratified region of each and all of the slice tomographic image and synthesizing the 3-dimensional stratified images. Also, in the case of extracting contours using the previously mentioned patterned graphics, there is no need for implementing the approximation process on each of the tomographic image, which enables reduction in labor by an operator. Additionally, the same advantageous effects are provided also in the case of the above-mentioned second outer contour interpolation process.
Next, the sixth embodiment of the region-extracting device and method relating to the present invention will be described.
The present embodiment is, in the case that there is a spacing between the adjacent slices, which means that there are regions that are not imaged between the adjacent slices, for obtaining a stratified region of a desired region which is not imaged by the interpolation from the stratified region in the desired region being extracted based on the imaged slices of the tomographic images (hereinafter referred to as “the first stratified region interpolation process”). Or, it is for obtaining a stratified region of a desired region based on the several tomographic images out of a plurality of them, and the stratified region of the desired region in the other tomographic images is calculated by the interpolation based on the obtained stratified region (hereinafter referred as “the second stratified region interpolation process”). The difference between the second˜fourth embodiments is only the process contents for the synthesizing process of the stratified regions in the step S207 of
The description of the region-extracting device in the sixth embodiment will be omitted since the configuration of it is the same as the one in the first embodiment shown in
In S207-6, either the above-mentioned first stratified region interpolation process or the second stratified region interpolation process is implemented.
For example, in the case of having stratified regions 1705˜1707 being extracted by the process in
In other words, for the regions with no tomographic images, it is possible to obtain stratified regions by implementing the interpolation process from the stratified region of both sides of the regions thereof (the first stratified region interpolation process). Or, a stratified region of a desired region can be obtained based on several tomographic images out of a plurality of them, and as for the stratified region of the desired region in the other tomographic images, the stratified region in the tomographic image of which the actual stratified region could not be obtained can be acquired through the interpolation process from the stratified region of both sides of the tomographic image (the second stratified region interpolation process).
The above is the description on the step being different from the basic operation of the second embodiment shown in
As described above, according to the sixth embodiment of the present invention, the same advantageous effects are provided as those of the previously mentioned fifth embodiment.
Next, the seventh embodiment of the region-extracting device applied to the present invention will be described. In the present embodiment at least one of the previously mentioned second˜sixth embodiments is included, and processes such as manual contour extraction or extraction of stratified regions are further added. Thus the present embodiment will be described focusing on the differences between the previously mentioned second˜sixth embodiments. The parts that are mutually corresponding to the second˜sixth embodiments will be omitted, by encoding them the same.
The description on the configuration of the region-extracting device in the seventh embodiment will be omitted since it is the same as the one in the first embodiment shown in
In step S2000, an image including the target region for contour extraction is displayed on the display device. In concrete terms, image data such as X-ray CT image is read out from, for example, magnetic disk 12 and displayed to CRT 14 shown in
An example of an image display is illustrated in
In steps S2001˜S2003, a means for extracting a stratified region encompassing the desired area (region) is selected.
In step S2001, the determination on whether “automatic extraction” is selected or not is conducted.
In this step, whether icon 2103 of “automatic extraction” is clicked with a device such as mouse 15 or not is determined, and if the answer is “yes” step S2005 is carried out and if “no” next step S2002 is carried out.
In step S2002, the determination on whether “pattern extraction” is selected or not is conducted.
In this step, whether icon 2104 for “pattern extraction” is clicked with a device such as mouse 15 is determined, and if the answer is “yes” step S2010 is carried out and if “no” next step S2003 is carried out.
In step S2003, the determination on whether “manual tracing extraction” is selected or not is conducted.
In this step, whether icon 2105 of “manual tracing extraction” is clicked with a device such as mouse 15 is determined, and if the answer is “yes” step S2013 is carried out and if “no” next step S2004 is carried out.
In step S2004, the determination on whether “end” is selected or not is conducted.
In this step, whether icon 2106 of “end” is clicked with a device such as mouse 15 is determined, and if the answer is “yes” the process is ended and if “no” the step is returned to S2001.
In step S2005, upon icon 2103 for “automatic extraction” is being selected, a region such as a ventricle or myocardium of a heart is automatically extracted from a tomographic image with black and white or color imaging which is being displayed, by a method described in (Patent Document 2) or (Patent Document 3) being applied by the applicant of the present application.
In step S2006, an outer contour image is obtained using extracted regions such as a ventricle or myocardium of a heart, by the method being illustrated in
In step S2007, stratified regions are extracted using the extracted outer contour image or the extracted partial regions such as a ventricle or myocardium of a heart, by the method being illustrated in
In step S2008, whether the operator had indicated the manual correction or not is determined, if manual correction is instructed (yes) step S2009 is carried out, and if not indicated (no) step S2015 is carried out.
In step S2009, upon manual correction had been instructed by the operator, the correction of the stratified region is implemented using a pointing device such as mouse 15. The correction of stratified regions can be executed by correcting, for example, the outer contour image being obtained in step S2006.
In step S2010, upon icon 2104 of “pattern extraction” is being selected with a device such as mouse 15 and the image being set with a patterned graphic configured by icon menu 2201 for selecting the patterned graphics as seen in
The function that icons 2202˜2207 in icon menu 2201 for selecting the patterned graphics is described below.
Icon 2202 is for additionally displaying ellipses that are element graphics one at a time and approximating a partial contour of a desired region, and also for approximating a contour by the first procedure being described in steps S202 and S203 of
Icon 2206 is for placing a plurality of points on a contour and displaying the patterned graphics or element graphics passing through those points or the vicinity of them as shown in
Icon 2207 is for placing one or more curves on the contour and displaying the pattern graphics or element graphics passing through those curves or the vicinity of them as shown in
By selecting the most appropriate icon from icon menu 2201 for selecting the patterned graphics being configured with the above-mentioned icons, contour extraction of a desired region on a tomographic image is executed based on the function corresponding to the selected icon.
Icons 2203˜2205 of the patterned graphics and other icons 2202, 2206 and 2207 may be separated and displayed as a menu of additional group.
In step S2011, upon an image with a setting of a plurality of ellipses as seen in FIGS. 3˜6,
Also, as shown in
When the extraction is ended, icon 2209 for “end” is clicked with a device such as mouse 15 and then step S2012 is carried out.
In step S2012, a stratified region is extracted using a method as shown in
When there is a plurality of slice tomographic images, after repeating the above-mentioned steps S2010˜2012, the synthesis of the stratified regions which is equivalent to step S207 in
In step 2013, upon icon 2015 for “tracing extraction” is being selected with a device such as mouse 15, a sample point is inputted on the display screen using a pointing device such as a mouse, trackball, or light pen, and a cardiac outer contour (the first contour) is extracted by manual tracing. Also, a contour (the second contour) is obtained based on the first outer contour. For obtaining this second contour, the same method can be used as the one in the previously mentioned first embodiment.
In step S2014, a stratified region is extracted by the method as shown in
In step S2015, MIP/3D process is implemented with regard to the stratified region being extracted by the respective above-mentioned steps.
In step S2016, an image being obtained by MIP/3D process is displayed on the screen.
As described above, according to the seventh embodiment of the present invention, in addition to the advantageous effects of the first˜six embodiments, the need for the extraction of even more complicated or different shapes of organs or regions can be responded with flexibility, by providing a plurality of patterned graphics in advance. Also, each means of contour-extraction, such as automatic or manual extraction, or contour-approximation using patterned graphics, has merits and demerits in its own region-extracting characteristics, hence providing them all would enable an operator to select an appropriate method for region-extracting corresponding to the diversity of shapes of organs or regions, or image quality of the tomographic images.
Each embodiment of the present invention had been described above, and the region-extracting device and method relating to the present invention is applicable not only to an image obtained by an X-ray CT device, but also to the image obtained by other devices such as magnetic resonance imaging or an ultrasound device. Also, not only a heart but many other organs or regions of the body can be a target region. The present invention is applicable not only to medical images but also to region-extraction in other commonly used images.
Moreover, patterned graphics were classified by the kind of lines such as dotted lines or dashed lines in the respective previously mentioned embodiments, but they can be classified also by the colors of lines such as read, blue or green, or the thickness of lines such as thin lines and thick lines.
Also, though an example of setting the region held between the first contour and the second contour by which the first contour is either enlarged or reduced as a stratified region was described, but the region held between the region by which the first contour itself is either enlarged or reduced and the second contour may also set as a stratified region.
Number | Date | Country | Kind |
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2003-417842 | Dec 2003 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP04/18796 | 12/16/2004 | WO | 6/14/2006 |