JP2002085355A - Image diagnostic apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide technique for reducing a tester's burden in performing detailed observation for a lesion part after the position of the lesion part is roughly specified by the conventional add image display. SOLUTION: This image diagnostic apparatus has a means for collecting reconfigured images obtained by slicing a measurement object, a means for adding plural reconfigured images collected by the above means, a means for generating a display image from the processed image after addition, and a means for displaying a display image on a display screen. The apparatus is provided with a means for setting the addition range of the reconfigured images, and a means for outputting the reconfigured images in the present range to the adding means, wherein the reconfigured images selected by the setting means are output to the adding means, and the adding means adds the reconfigured images in the output range and outputs the same to the display image generating means.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an image diagnostic apparatus, and more particularly to an image diagnostic apparatus which is effective when applied to an image diagnostic apparatus which adds and displays a reconstructed image of a subject collected by an X-ray CT apparatus or an MRI apparatus. It is about technology.

[0002]

2. Description of the Related Art In a head diagnosis using a conventional single-slice type X-ray CT apparatus, first, X-ray CT measurement is performed on a relatively thick slice of about 10 mm, and the obtained tomographic images are sequentially obtained. By displaying it on the image display means,
The lesion site was identified. Next, the region including the lesion site was X-ray CT with a relatively thin slice of about 2 to 2.5 mm.
The examiner made an accurate diagnosis by measuring and realizing close observation of the lesion site.

With the recent technological progress, multi-slice type X-ray CT apparatuses capable of simultaneously measuring a plurality of slices have become widespread. The X-ray CT measurement using the multi-slice type X-ray CT apparatus includes a scanning drive unit having an imaging system including an X-ray source and a multilayer detector, and a mechanism for supporting the subject and moving in the body axis direction. A bed provided with the scanner, control means for controlling the scan driver and the bed, data collecting means for collecting projection data detected by the multilayer detector, and X-ray absorption coefficient distribution of the subject from the collected projection data. Calculation means for reconstructing the image as a reconstructed image, display means for imaging and displaying the reconstructed X-ray absorption coefficient distribution, and an operator providing values necessary for the multi-slice X-ray CT apparatus. An operation console provided with a keyboard, a mouse, and the like for setting or inputting instructions.

However, in the present specification, a multilayer detector is a detector array in which one detector cell (detection element) or two or more detector cells are arranged in a line in the rotation direction of the imaging system. , A one-dimensional detector or a two-dimensional detector arranged in two or more stages in the direction of the rotation axis, wherein the detector cells are arranged so as to form a part of the surface of a cylinder or a polyhedron. At present, most of the single-slice X-ray tomography apparatuses that have been put into practical use have a so-called single-layer detector type in which a large number of detection elements use detectors arranged on an arc along the rotation direction. It was an X-ray CT apparatus. On the other hand, the multi-layer detectors are further arranged in rows or layers in the direction of the rotation axis, and are therefore referred to as multi-layer type or multi-slice type. In the specification of the present application, data of an image obtained by an X-ray detector is projection data, a CT image reconstructed from projection data or an NMR image obtained by MRI is a reconstructed image, The generated image for display is a tomographic image,
The image obtained by the addition process is referred to as an added tomographic image (or an added image).

In the collection of projection data by a multi-slice type X-ray CT apparatus, an imaging operation for rotating the imaging system 360 degrees around the subject to capture projection data, that is, an X-ray image of the subject, and an imaging system are described. In order to move the subject in the body axis direction, the moving distance of the bed is set (the number of layers in the rotation axis direction of the detection element).
X (an opening width of one layer of the detection element) is alternately repeated to pick up an X-ray image of the subject, thereby shortening the time required for imaging and reducing the time required for the subject. Exposure was reduced.

This multilayer detector usually has a configuration in which the opening width in the rotation axis direction is set to about 2.5 mm.
For this reason, the slice thickness of each tomographic image obtained from projection data imaged by a multi-slice type X-ray CT apparatus is as follows:
The opening width of the detector was about 2.5 mm. Therefore, as in a conventional single-slice X-ray CT apparatus, a tomographic image of a relatively thick slice of about 10 mm is sequentially displayed on the display means to specify the lesion site, and then the region including the lesion site is reduced to two. In order to enable a detailed observation of a lesion site using a tomographic image of a relatively thin slice of about 0.5 mm, a conventional multi-slice type X-ray CT apparatus uses a tomographic image (2.5 mm slice thickness adjacent). Or a reconstructed image) to generate a tomographic image having a desired slice thickness.

[0007]

SUMMARY OF THE INVENTION As a result of studying the above prior art, the present inventor has found the following problems. In the conventional multi-slice type X-ray CT apparatus, it is necessary to start an image addition processing program before performing the image addition processing. In the image addition processing program, an image list as shown in FIG. 1 is displayed on the display means, and the examiner specifies the number of tomographic images (or reconstructed images) to be added based on the image list. After that, an addition process is performed for each of the designated number of images, and information on the image data after the addition process is added to the above-described image list. Next, the image generation program is started, and the data of the reconstructed image after the addition processing is read based on the information on the reconstructed image after the addition processing added to the image list, and the display image ( (Processed image) is generated and displayed on the display means.

More specifically, after a tomographic image of a relatively thick slice is displayed on an image display means using a conventional multi-slice type X-ray CT apparatus, a lesion site is specified, and a detailed observation of the lesion site is performed. In order to make an accurate diagnosis of the lesion site by performing the above, the examiner had to specify the number of additions from the addition processing program. For this reason, after identifying a bleeding site, such as a diagnosis of a head related to a blood vessel requiring urgency, the status of the bleeding site is grasped, and the relationship between the bleeding site and surrounding blood vessels is sequentially grasped. Therefore, it was necessary to sequentially reduce the slice thickness of the tomographic image, but every time the slice thickness of the tomographic image was changed, it was necessary to switch between the addition processing program and the image generation program, which became a heavy burden on the examiner. I was

[0009] With the recent advance of medical technology, X
In displaying tomographic images collected by a line CT apparatus or an MRI apparatus, a so-called cine display in which tomographic images collected by measurement and tomographic images generated by addition are displayed while being sequentially shifted in an adjacent order to the examiner. Methods for three-dimensionally recognizing an imaging range including a lesion site have been developed.

However, in the image adding process in the conventional image diagnostic apparatus, as shown in FIG. 1, the range of tomographic images to be added indicated by No. 1 to No. 32 input from the console and the number of four tomographic images are input. Based on the
An addition image A obtained by adding the four reconstructed images No. 1 to No. 4 and an added image B obtained by adding the reconstructed images No. 5 to No. 8 are generated. Therefore, the obtained added images A to H include image information that is called four-dimensional tomographic images, each of which is called image information in the depth direction. Therefore, information in the depth direction is missing between the added images A to H.

For this reason, in the cine display of the added image using the conventional image diagnostic apparatus, the image information in the depth direction is lost every time the added image is switched. There is a problem that it takes time to learn the original image recognition.

An object of the present invention is to provide a technique capable of reducing the burden on the examiner when performing detailed observation of a lesion after roughly specifying the location of the lesion in the conventional addition image display. To provide. Another object of the present invention is to provide a technique capable of maintaining continuity in cine display of an added image in which image information in the depth direction is included in one tomographic image. Another object of the present invention is to provide a technique capable of easily changing the addition range for observing the state of the lesion itself and observing the state of the lesion and its surroundings. The above and other objects and novel features of the present invention will become apparent from the description of the present specification and the accompanying drawings.

[0013]

SUMMARY OF THE INVENTION Among the inventions disclosed in the present application, the outline of a representative one will be briefly described.
It is as follows. (1) means for collecting a reconstructed image obtained by slicing a measurement object, means for adding a plurality of reconstructed images collected by the means, means for generating a display image from the processed image after the addition, In an image diagnostic apparatus having means for displaying a display image on a display surface, means for setting an addition range of the reconstructed image, and means for outputting the reconstructed image in the set range to the addition processing means The reconstructed image selected by the setting means is output to the addition processing means, and the addition processing means adds the reconstructed images in the output range and outputs the processed image to the display image generating means.

(2) An image diagnostic apparatus configured to add a plurality of reconstructed images of a measurement object captured by an imaging device and display the processed images on a display unit, wherein each of the plurality of reconstructed images is captured. Means for storing the image list indicating the position and the plurality of reconstructed images, means for setting an addition range of the reconstructed images, and reading the reconstructed images in the range set from the means from the storage means, A means for adding the read reconstructed image and a means for generating a tomographic image to be a display image from the processed image obtained by the addition are provided.

(3) In the image diagnostic apparatus according to the above (1) or (2), capturing the reconstructed image while maintaining the number of reconstructed images within the addition range set by the setting means. Means are provided for sequentially changing the addition range for each adjacent reconstructed image at intervals.

(4) In the image diagnostic apparatus according to (1) or (2), when the reconstructed image of two slices or more is set as the addition range by the addition range setting means, the addition is performed. Means are provided for sequentially changing the addition range so that at least one slice of the reconstructed images of the range is included.

(5) In the image diagnostic apparatus according to the above (2), the imaging positions of the plurality of reconstructed images stored in the external storage means are determined by an instruction to start the process of adding the reconstructed images. Means for reading the indicated image list and the plurality of reconstructed images into main storage means of the apparatus,
The addition processing means reads the reconstructed image in the range set by the addition range setting means from the main storage means, and performs addition processing on the read reconstructed image.

(6) In the diagnostic imaging apparatus according to any one of the above (1) to (5), the adding range setting means may include the number of added reconstructed images and the center of the reconstructed image. , The addition range of the reconstructed image is set.

According to the aforementioned means, when the examiner sets the addition range from the setting means, the reconstructed image in the set range is output from the output means to the addition processing means.
Here, the reconstructed image output from the output unit is subjected to addition processing by the addition unit, and the added processed image is output to the tomographic image generation unit. The tomographic image generating means generates a tomographic image as a display image from the processed image after the addition, and the tomographic image is displayed on the display surface.

That is, the reconstructed image at the slice position not set by the setting means, that is, the reconstructed image at the imaging position not requested by the examiner, is excluded from the addition processing and the display image generation processing. Therefore, since the number of reconstructed images, which is the number of data required for the addition processing and the display image generation processing, is limited to the number of images required to generate an image desired by the examiner, a tomographic image is displayed on the screen. The load of the addition processing and the processing of generating the display image required up to this point is reduced. As a result, the load for generating an addition image, which is a display image for roughly specifying the position of a lesion, is reduced, and thus the lesion identified by observing a tomographic image of a relatively thick slice can be described in detail. The display of a thin slice for observation can be switched to a tomographic image in real time.

The reconstructed image in the range set (specified) by the setting means is output to the addition processing means, and the reconstructed image in the output range is subjected to addition processing by the addition processing means and then output to the display image generating means. The configuration eliminates the need to switch between the addition processing program and the image generation program as in a conventional diagnostic imaging apparatus. The burden can be reduced.

The reconstructed image in the range set (specified) by the setting means is output to the addition processing means, and after the addition processing means adds the reconstructed image in the output range to the display image generating means. With this configuration, it is possible to easily change the addition range for observing the state of the lesion itself and observing the surrounding state including the lesion.

At this time, by setting the addition range of the reconstructed image based on the number of added reconstructed images and the position of the center reconstructed image, the setting of the addition range is facilitated. Therefore, it is possible to further reduce the burden on the examiner required for switching the addition range.

Further, there is provided means for sequentially changing the addition range for each adjacent tomographic image at the imaging interval of the reconstructed image while maintaining the number of addition of the reconstructed images in the addition range set by the setting means, or When the reconstructed image of two slices or more is set as the addition range by the addition range setting means, the addition range is sequentially set so that the reconstructed image of at least one slice is included in the reconstructed images of the addition range. By providing a means for changing, even when performing cine display of an added image, it is possible to leave image information of at least one reconstructed image in each added image to be continuously switched. Therefore, it is possible to maintain the continuity of the image at the time of the cine display of the added image. Therefore, even if the examiner who has relatively little experience in diagnosing the image performs the cine display of the added image, it can be recognized as a three-dimensional image of the imaging range including the lesion site.

[0025]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the drawings together with embodiments (examples) of the invention. In all the drawings for describing the embodiments of the present invention, components having the same functions are denoted by the same reference numerals, and their repeated description will be omitted.

(Embodiment 1) FIG. 2 is a view for explaining a schematic configuration of an image diagnostic apparatus according to Embodiment 1 of the present invention. Hereinafter, an image diagnostic apparatus according to Embodiment 1 will be described with reference to FIG. Will be described. As shown in FIG. 2, the image diagnostic apparatus according to the first embodiment includes an arithmetic processing unit 11 and a reconstructed image data recording unit such as a magnetic disk for storing reconstructed image data captured by an X-ray CT apparatus (not shown). 13 and a keyboard 16 for inputting data and the like to the arithmetic processing means 11
A mouse 15 for designating a range of an image to be processed; a well-known imager 14 for printing (printing) a tomographic image displayed on a screen 24 of the display means 22 on a film described later; 11, a memory 12 serving as a main memory, an image list 1 stored in a reconstructed image data recording unit 13, an added image 23 subjected to addition processing, and supplementary information including an effective slice thickness after addition processing and its center position. On a screen 24.

In particular, the arithmetic processing means 11 is realized by, for example, a program operating on a known information processing apparatus, and reconstructs reconstructed image data and the image list 1 to be diagnosed based on an instruction to start image diagnosis. A well-known transfer unit (not shown) for transferring the image data from the image data storage unit 13 to the memory 12, and a value and a center of the number of added images set in advance in the reconstructed image data storage unit 13 by input from the keyboard 16 in addition to the reconstructed image data A known setting means for reading and setting the value of the position of the reconstructed image into the memory 12 and displaying the image on the screen 24 based on the number of added images set in the memory 12 and the position of the reconstructed image at the center. A frame generation unit (not shown) for generating a frame (frame image) for indicating the addition range on the image list 1 and a memo based on the imaging position and the imaging number displayed on the image list 1 Extracting means (not shown) for extracting an imaging number surrounded by a frame based on the number of added images (value of the number of added images) set at 12 and the position of the reconstructed image at the center (value of the reconstructed image position); Addition processing means (not shown) for calculating an average value of pixel values for each of the same pixel positions of the reconstructed image data corresponding to the imaging number extracted by the extraction means, and an effective slice of the obtained reconstructed image data after the addition processing A well-known auxiliary information generating unit (not shown) for generating additional information of the reconstructed image data after addition processing obtained by calculating the thickness and the position, and an image for display from the obtained reconstructed image data after addition processing A well-known image generating means (not shown) for generating a tomographic image, a converting means for converting the tomographic image and the accompanying information as an image for display, and the image list 1 into a signal for display and outputting to the display means 22; keyboard Based on the input from the first setting means 17 and the second setting means 18 and the image update button 20, the number of additions set in the memory 12 and the position of the central reconstructed image are calculated. And a well-known calculation means for setting the value in the memory again. However, the effective slice thickness and position are calculated by the following equations 1 and 2, respectively. Effective slice thickness = (slice thickness of reconstructed image data) × (addition number) Expression 1 position = (sum of imaging positions of reconstructed image data in addition range) / (addition number) Expression 2

Next, the operation will be described based on an operation flow for explaining the operation of the arithmetic processing means 11 shown in FIG. The start of this operation flow is the start of image diagnosis by input from the keyboard 16 or the mouse 15.
Based on this start instruction, the transfer unit transfers the reconstructed image data and the image list 1 to be diagnosed from the reconstructed image data storage unit 13 to the memory 12 (step 901).

Next, the setting means sets the added number (added number value).
And the position of the reconstructed image at the center (the value of the position of the reconstructed image)
Is read from the reconstructed image data storage unit 13 into the memory 12 (step 902). However, the number of added images and the position of the reconstructed image serving as the center are values set in advance by input from the keyboard 16, and the number of added images and the position of the reconstructed image serving as the center are other than the reconstructed image data. In the first embodiment, the image data is stored in the reconstructed image data storage unit 13. Next, the conversion means displays the image list 1 transferred to the memory 12 in step 901 on the screen 24 of the display means 22 (step 903).

Subsequently, the frame generating means generates a frame to be displayed in the image list 1 based on the values of the number of added images and the central reconstructed image position set in the memory 12 (step 9).
04). Thereafter, based on the imaging position and the imaging number displayed in the image list 1 and the added number and the central reconstructed image position set in the memory 12, the extraction unit stores the reconstructed image stored in the memory 12. The imaging number of the reconstructed image data to be added, that is, the imaging number surrounded by a frame on the screen 24 is extracted from the data (step 905).

Next, the addition processing means calculates the average value of the pixel values at the same pixel position of the reconstructed image data corresponding to the extracted imaging number (step 906), and the additional information generation means calculates the average value. The effective slice thickness of the reconstructed image data after the processing and the center position thereof are calculated to generate additional information (step 907).

Next, the image generation means generates a tomographic image (addition image) as an image for display from the reconstructed image data after the addition processing (step 908), and the conversion means obtains the obtained tomographic image (addition image). ), The supplementary information and the image list 1 are converted into display signals and output to the display means 22 to be displayed on the screen 24 of the display means 22 (step 9).
09).

After this display, input from the first setting means 17 and the second setting means 18 and the image update button 20 arranged on the keyboard 16 is awaited (step 91).
0), the first setting means 17 and the second
When an input is made from the setting means 18 and the image update button 20, the calculating means calculates the added number and / or the center reconstructed image position set in the memory 12 based on the input, and After the added number of images and / or the reconstructed image position at the center are set in the memory 12, the process returns to step 904, and thereafter, step 9 is performed until the end of the image diagnosis is input from the keyboard 16 or the mouse 15.
Steps 04 to 911 are repeated (step 911).

FIG. 3 is an explanatory view showing the image list and the added image displayed on the display means of the diagnostic imaging apparatus according to the first embodiment of the present invention. As shown in FIG. 3, the image list 1 stored in the reconstructed image data recording means 13 is displayed on the screen 24 of the display means 22, and the reconstructed image data start position 101a and the reconstructed image data end position 101b Is the range of the reconstructed image to be processed.

The number of files of the reconstructed image data in the range surrounded by the frame 102b of the image list 1 shown in FIG.
The range surrounded by the frame 102b is an addition range, and the reconstructed image data surrounded by the frame 102b is subjected to addition processing by the arithmetic processing unit 11, and the tomographic image obtained by this addition processing is used as the added image 23 of the display unit 22. It is displayed on the screen 24.

On the other hand, the reconstructed image data start position 101a and the reconstructed image data end position 101 of the image list 1
b is a first setting means 1 which can be moved to an arbitrary position by a mouse 15 and is composed of a trackball provided with a rotary encoder provided on a keyboard 16, for example.
7 can be changed, and the addition range of the reconstructed image data can be sent by rotating the second setting means 18 composed of a trackball having a rotary encoder.

That is, when the first setting means 17 is rotated, the frame 102a is centered on the center slice position of the reconstructed image data, that is, the position of the reconstructed image as the center, as shown by a frame 102b shown by a broken line in FIG. When the second setting means 18 is rotated, the frame 103a is moved to a frame 103b shown by a broken line in FIG. 3 to enlarge or reduce the number of added images. The addition range can be sent arbitrarily.

Next, the operation of the image diagnostic apparatus according to the first embodiment will be described with reference to the flowchart shown in FIG. 4 and the operation explanatory diagrams shown in FIGS. Multi-slice X-ray C
The reconstructed image data generated from the projection data collected by the rotation imaging by the T apparatus is stored in the reconstructed image data recording unit 13.
When the operation for observing and diagnosing the tomographic image generated from the reconstructed image data is started, the processing according to the flowchart shown in FIG. The slice list of the reconstructed image data is displayed as the image list 1 on the screen 24 of the display unit 22 as shown in FIG.

The number of additions and the addition range of the reconstructed image data can be set in the frame 104a displayed together with the image list 1 on the screen 24 shown in FIG. 17 is rotated to the right, for example, as shown in FIG.
04b, and the reconstructed image data is increased to a desired number. As a result, the added image generated from the reconstructed image data to which the desired number has been added is displayed on the screen 24 of the display means 22 as one tomographic image is displayed as the added image 23 as shown in FIG. The examiner observes the obtained added image 23 or makes a diagnosis.

If no abnormality such as a lesion is found by the diagnosis, the second setting means 18 is rotated in step 402 to sequentially move the frame 104b to the reconstructed image data end position 101b. Thereby, the display means 22
Is displayed on the screen 24 along with the movement of the frame 104b.
Since the tomographic images generated from the reconstructed data in the range surrounded by are displayed on the screen 24 one after another as the added image 23, continuous and real-time observation is performed without impairing the continuity of the displayed added image 23. Will be able to do it.

On the other hand, if an abnormality such as a lesion is found by the above-described operation and it is necessary to observe the lesion in more detail, the mouse 15 is operated in step 403, and as shown in FIG. Possible range (position 106a to position 1)
06b), the reconstructed image data start position 10
1a and the image data end position 101b are moved.
Then, in this state, the first setting means 17 is rotated to the left, for example, as shown in (d) of FIG. 6, to reduce the frame 107a to the frame 107b, and reduce the number of added images for more detailed observation ( Step 404). by this,
On the screen 24 of the display means 22, the number of added images is reduced and displayed as an added image 23 which is a single tomographic image. By observing the displayed added image 23 in detail,
Abnormalities such as lesions can be accurately diagnosed.

When the added image displayed on the screen 24 of the display means 22 is sent, as shown in FIG.
The second setting means 18 is rotated, for example, rightward (step 405). As a result, the added images 23 displayed on the screen 24 of the display unit 22 are successively moved. Therefore, by continuously observing the displayed added images 23, the continuity of the added images 23 is not impaired. Abnormalities such as lesions can be diagnosed in real time.
When a reaches the reconstructed image data end position 106b, by further rotating the second setting means 18, the frame 110a is moved to the reconstructed image data start position 106a.
Then, if necessary, the addition image 23 can be observed again from the reconstructed image data start position 106a. It should be noted that the number of added images, that is, the number of frames 11 per input with respect to the continuously input frame 110a feed instruction.
The feed amount of 0a is not limited to one slice, and the feed amount per input of the frame 110a is made variable based on the feed amount per input input from the keyboard 16, for example. By the addition image 23
Can be varied, so that the continuity of the sequentially displayed added images 23 is not impaired (ie,
Feeding of the added image 23 (in a state where at least one or more tomographic image data is included in the added image 23 displayed adjacently) can be realized, and abnormality such as a lesion can be diagnosed in a short time. As a result, even if the examiner has relatively little experience in diagnosis,
It is possible to make a diagnosis while maintaining the continuity in which the image of the lesion is expressed as jumping into the eye.

On the other hand, when the added image generated by adding the reconstructed image data in the designated range is displayed on the screen 24 of the display means 22 and the observation of the added image is completed,
In step 406, the added image is reconstructed image data recording means 1.
Save to 3. The addition data is stored by pressing the image storage button 21 provided on the keyboard 16 as shown in FIG.
The image data of the added image 23 (added image data) displayed in 4 is stored in the reconstructed image data recording means 13. Note that the image data is not limited to display image data of a tomographic image, which is a display image, and it is needless to say that reconstructed image data obtained by addition processing may be used.

When the added image 23 displayed on the screen 24 of the display means 22 is to be printed on the film 25, the film output button 1 provided on the keyboard 16 is used.
By operating 9 as shown in FIG.
The added image 23 is assigned to the frame 25a of the film 25, is printed on the frame 25a of the film 25 by the imager 14 (step 407), and the image update button 20 provided on the keyboard 16 is pressed in FIG.
In step 408, the image is advanced by the number of added images, and the updated added image 2 is updated.
3 is displayed on the screen 24 of the display means 22. Note that the image advance can be performed by rotating the second setting unit 18. However, by operating the image update button 20, the image is not overlapped and the gap is not generated between the added images 23 without overlapping the frames 112 a. Feeding can be performed. In addition, it goes without saying that the image diagnostic apparatus according to the first embodiment can be applied to an MRI apparatus, and furthermore, an image diagnostic apparatus including a plurality of measurement apparatuses such as an X-ray CT apparatus and an MRI apparatus. Applicable.

As described above, in the diagnostic imaging apparatus according to the first embodiment, when the examiner sets the addition range from the first and second setting means 17 and 18 arranged on the keyboard 16, the setting is made. The reconstructed image data in the specified range is output from the memory 12 to the addition processing means by the extraction means functioning as the output means. Here, the addition processing means automatically performs the addition processing on the reconstructed image data output from the extraction means, and outputs the added reconstructed image data to an image generation means serving as a tomographic image generation means as a display image. By doing so, it is possible to limit the number of data required for the addition processing, that is, the number of reconstructed image data, to the number necessary to generate an image in a range desired by the examiner, so that the load required for the addition processing is reduced. Can be reduced.

That is, it is possible to reduce the load for generating the added image 23 which is a display image for roughly specifying the position of the lesion, so that the tomographic image of a relatively thick slice and the lesion The display can be switched in real time with a thin slice tomographic image for performing detailed observation, and the burden on the examiner can be reduced, and the observation and diagnosis of the added image 23 can be performed quickly. Further, it is possible to easily change the addition range for observing the state of the lesion itself and observing the surrounding state including the lesion.

At this time, the addition range of the reconstructed image is set based on the number of added reconstructed image data and the center position of the reconstructed image, that is, the slice position (imaging position) of the reconstructed image data. With this configuration, the addition range can be easily set, so that the burden on the examiner required to switch the addition range can be further reduced.

Further, the first and second setting means 17, 1
While maintaining the number of additions of the reconstructed image data in the addition range set by 8, the addition range is set for each adjacent tomographic image at the imaging interval of the reconstructed image corresponding to the aperture width of the multilayer detector of the X-ray CT apparatus. When a reconstructed image for two slices or more is set as an addition range by the addition range setting means or a reconstructed image for at least one slice of the reconstructed image data of the addition range is provided. Since the means for sequentially changing the addition range so as to include the data is provided, even when the cine display of the addition image is performed, at least one addition image 23 that can be continuously switched is provided. Since image information of reconstructed images for the number of sheets can be left, continuity of images at the time of cine display of the added image 23 can be maintained. Therefore, even when an examiner who has relatively little experience in diagnosing an image performs cine display of the added image 23, three-dimensional image recognition of an imaging range including a lesion can be performed.

(Embodiment 2) FIG. 10 is an operation flow for explaining the operation of the arithmetic processing means 11 in the image diagnosis apparatus of Embodiment 2, and the image diagnosis of Embodiment 2 will be described below with reference to FIG. The operation of the device will be described. However, the configuration of the image diagnostic apparatus according to the second embodiment is the same as that of the image diagnostic apparatus according to the first embodiment except for the configuration of the arithmetic processing unit 11. The operation will be described in detail.

The arithmetic processing means 11 of the second embodiment transfers the reconstructed image data and the image list 1 to be diagnosed from the reconstructed image data storage means 13 to the memory 12 based on the instruction to start the image diagnosis (not shown). The memory 12 stores the value of the number of added images and the value of the position of the central reconstructed image set in the reconstructed image data storage unit 13 in advance in the reconstructed image data storage unit 13 in advance by input from the keyboard 16 by a well-known transfer unit.
And setting based on the image capturing position and the image capturing number, which are the data of the image list 1 stored in the memory 12, and the number of added images and the position of the reconstructed image as the center set in the memory 12. Extraction means (not shown) for extracting an imaging number to be added to the addition range, and addition (not shown) for calculating an average value of pixel values at the same pixel position of reconstructed image data corresponding to the imaging number extracted by the extraction means Processing means, and a well-known auxiliary information generating means (not shown) for calculating the effective slice thickness and position of the obtained reconstructed image data after the addition processing and generating additional information of the obtained reconstructed image data after the addition processing And a well-known image generating means (not shown) for generating a tomographic image as a display image from the obtained reconstructed image data after the addition processing, and displaying the tomographic image and additional information as the display image Conversion means for outputting the converted display unit 22 to the signal, the first being arranged in the image keyboard 16
A well-known method of calculating the number of added images set in the memory 12 and the position of the central reconstructed image based on inputs from the setting means 17 and the second setting means 18 and the image update button 20, and setting the calculated value again in the memory And calculation means.

Next, the operation of the arithmetic processing means 11 according to the second embodiment will be described based on the operation flow shown in FIG. The start of this operation flow is the start of image diagnosis by input from the keyboard 16 or the mouse 15, and based on this start instruction, the transfer means stores the reconstructed image data to be diagnosed and the image list 1 into the reconstructed image data. Mean 13
To the memory 12 (step 1001).

Next, the setting means sets the added number (added number value).
And the position of the reconstructed image at the center (the value of the position of the reconstructed image)
Is read from the reconstructed image data storage unit 13 into the memory 12 (step 1002). However, the number of added images and the position of the reconstructed image serving as the center are values set in advance by input from the keyboard 16, but are stored in the reconstructed image data storage unit 13 as in the first embodiment.

Next, based on the imaging position and the imaging number stored in the memory 12, and the number of images to be added and the reconstructed image position as the center set in the memory 12, the extraction means determines the number of images to be added to the addition range. The imaging number of the constituent image data is extracted (step 1003).

Next, the addition processing means calculates the average value of the pixel values at the same pixel position of the reconstructed image data corresponding to the extracted imaging number (step 1004). The effective slice thickness and its position of the reconstructed image data after the processing are calculated to generate additional information (step 1005).

Next, the image generating means generates a tomographic image as a display image from the reconstructed image data after the addition processing (step 1006), and the converting means displays the obtained tomographic image and additional information for display. Is output to the display means 22 so that the tomographic image and the accompanying information are displayed on the screen 2 of the display means 22.
4 (step 1007).

After this display, input from the first setting means 17 and the second setting means 18 and the image update button 20 arranged on the keyboard 16 is awaited (step 100).
8) If an input is made from the first setting means 17 and the second setting means 18 and the image update button 20 in step 1008, the calculation means sets the addition set in the memory 12 based on the input. After calculating the number of images and / or the position of the reconstructed image serving as the center, and setting the obtained number of added images and / or the position of the reconstructed image serving as the center in the memory 12, the process returns to step 1003. Steps 1003 to 1009 are repeated until the end of the image diagnosis is input (step 100)
9).

As described above, in the diagnostic imaging apparatus according to the second embodiment, the supplementary information generating means displays the supplementary information generated from the effective slice thickness and the position of the reconstructed image data after the addition processing on the display means 22. It is configured to be displayed on the screen 24. Therefore, based on the effective slice thickness of the reconstructed image data after the addition processing displayed as the supplementary information and the center position thereof, the examiner numerically determines the effective slice thickness of the tomographic image displayed as the addition image and the center position thereof. Therefore, the same effect as in the first embodiment can be obtained.

In the image diagnostic apparatus according to the second embodiment,
As described above, the examiner can display a desired tomographic image without displaying the image list 1 and the frame indicating the addition range on the screen 24 of the display unit 22. It is possible to obtain a special effect that observation and diagnosis based on the observation result can be performed by focusing on the displayed tomographic image.

Further, in the image diagnostic apparatus of the second embodiment, the examiner displays a desired tomographic image without displaying the image list 1 and the frame indicating the addition range on the screen 24 of the display means 22 as described above. With this configuration, the screen 24, which is a limited display area, can be used for displaying a tomographic image. Therefore, the area for displaying the tomographic image can be enlarged, so that the examiner can obtain more information by observing the tomographic image once. As a result, the diagnostic efficiency can be improved.

In the first and second embodiments, the case of diagnosing the head has been described. However, the scope of application is not limited to this, and the case where the chest, abdomen, or the whole body is to be photographed is also applicable. It goes without saying that it is applicable. In the first and second embodiments, the addition tomographic image (addition image 23) is generated from the reconstructed image data stored in the reconstructed image data recording unit 13 that stores the reconstructed image data. Is not limited to, for example, X
In the case of the line CT apparatus, it goes without saying that the above-described effect can be obtained even if the addition range is selected based on the collected projection data and information indicating the collection position.

In the first and second embodiments, the X-ray detector includes, for example, an X-ray image intensifier (hereinafter referred to as “X-ray II”), an imaging optical system, and a television camera. Two-dimensional detector, a two-dimensional detector including a fluorescent plate, an imaging optical system, and a television camera, a fluorescent plate, a two-dimensional photodiode array, and a two-dimensional thin film transistor (TF).
T), a two-dimensional detector including a selenium film and a two-dimensional thin film transistor array, and the like can also be used. Further, a conventional one-dimensional X-ray detector may be used.

Further, in the first and second embodiments, the added image is generated by the addition processing of the reconstructed image. However, the generation of the added image is not limited to the addition processing of the reconstructed image. For example, it is needless to say that the same effect can be obtained by adding a tomographic image which is a display image.

As described above, the invention made by the present inventor is:
Although specifically described based on the embodiments of the present invention, the present invention is not limited to the embodiments of the present invention, and it is needless to say that various modifications can be made without departing from the gist of the present invention. .

[0064]

The effects obtained by typical ones of the inventions disclosed in the present application will be briefly described as follows. (1) It is possible to reduce the burden on the examiner when performing detailed observation of a lesion after roughly specifying the location of the lesion in the conventional addition image display. (2) It is possible to maintain continuity at the time of cine display of an added image in which image information in the depth direction is included in one tomographic image. (3) The addition range for observing the state of the lesion itself and observing the surrounding state including the lesion can be easily changed.

[Brief description of the drawings]

FIG. 1 is a diagram for explaining an image list used in a conventional image diagnostic apparatus.

FIG. 2 is a diagram for explaining a schematic configuration of the diagnostic imaging apparatus according to the first embodiment of the present invention;

FIG. 3 is an explanatory diagram illustrating an image list and an added image displayed on a display unit of the diagnostic imaging apparatus according to the first embodiment of the present invention.

FIG. 4 is a flowchart illustrating a procedure of an image adding process in the diagnostic imaging apparatus according to the first embodiment of the present invention.

FIG. 5 is an operation explanatory diagram showing an operation procedure of the image diagnostic apparatus according to the first embodiment of the present invention.

FIG. 6 is an operation explanatory view showing an operation procedure of the image diagnostic apparatus according to the first embodiment of the present invention.

FIG. 7 is an operation explanatory view showing an operation procedure of the image diagnostic apparatus according to the first embodiment of the present invention;

FIG. 8 is an operation explanatory view showing an operation procedure of the diagnostic imaging apparatus according to the first embodiment of the present invention.

FIG. 9 is an operation flow for explaining the operation of the arithmetic processing unit according to the first embodiment of the present invention.

FIG. 10 is an operation flow for explaining the operation of the arithmetic processing unit according to the second embodiment of the present invention.

[Explanation of symbols]

1 image list, 11 arithmetic processing means, 12 memory
13 ... reconstructed image data recording means, 14 ... imager, 1
5 mouse, 16 keyboard, 17 first setting means,
18: second setting means, 19: film output button, 20
... image update button, 21 ... image save button, 22 ... display means, 23 ... addition image, 24 ... screen, 25 ... film.

──────────────────────────────────────────────────続 き Continued on the front page (51) Int.Cl. ⁷ Identification symbol FI Theme coat ゛ (Reference) G06T 1/00 290 G01N 24/02 520Y F term (Reference) 4C093 AA22 AA26 BA08 CA17 CA21 CA36 DA01 DA03 DA04 EB01 EB02 EB12 EB13 EB17 EE08 FD11 FD12 FF28 FF36 FG05 FG11 FG13 FG16 FG20 FH02 FH04 4C096 AB26 AB37 DC28 DC33 DD09 DD11 DD13 DD16 DE02 DE04 FC11 FC16 5B057 AA09 BA03 BA23 BA24 CA02 CA08 CA12 CH16 CB02 DA08 DA17

Claims (3)

[Claims] 1. A means for collecting a reconstructed image obtained by slicing a measurement target, a means for adding a plurality of reconstructed images collected by the means, and a means for generating a display image from the processed image after the addition. An image diagnostic apparatus having means for displaying the display image on a display surface; means for setting an addition range of the reconstructed image; and outputting the reconstructed image in the set range to the addition processing means. The reconstructed image selected by the setting means is output to the addition processing means, and the addition processing means performs addition processing on the reconstructed image in the output range and outputs the processed image to the display image generation means. An image diagnostic apparatus characterized by the above-mentioned. 2. An image diagnostic apparatus configured to add a plurality of reconstructed images of a measurement target imaged by an imaging device and to display the processed images on a display unit, wherein each of the plurality of reconstructed images has an imaging position. Means for storing the image list and the plurality of reconstructed images, a means for setting an addition range of the reconstructed images, and a reconstructed image in a range set by the means is read from the storage means. An image diagnostic apparatus comprising: means for adding a read reconstructed image; and means for generating a tomographic image as a display image from the processed image obtained by the addition. 3. The image diagnostic apparatus according to claim 1, wherein the addition is performed at the imaging interval of the reconstructed image while maintaining the number of reconstructed images within the addition range set by the setting unit. An image diagnostic apparatus comprising means for sequentially changing a range for each adjacent reconstructed image.