JP2007289335A - Medical image diagnosis support device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a medical image diagnosis support method and device capable of more highly precisely extracting a lung emphysema area taking into consideration the extracting error of a CT value due to gravity. <P>SOLUTION: The medical image diagnosis support method comprises a lung field area extracting processing step S1, a trachea/bronchial area data eliminating step S2 in an extracting area data, a gut tube eliminating processing executing step S3, a lung field area dividing step S4, a threshold value setting processing step S5 for obtaining a threshold value setting curve dividing so as to form a plurality of partial spaces in a direction in which gravity acts, a step S6 executing lung emphysema area detecting processing using the CT value from the threshold value setting curve, and a step S7 of calculating out at least one of the area, the average value, the standard deviation, the upper limit value or lower limit value of a 95% confidence interval of an average value of the lung field area or the area, the ratio, the average value, the standard deviation the upper limit value or lower limit value of the 95% confidence interval of an average value of the lung field area in each tomogram unit from the extracted lung field area, the divided lung field area, and the support information of the extracted lung emphysema area. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a medical image diagnosis support method and apparatus, and more particularly to a medical image diagnosis support apparatus capable of detecting an emphysema region.

  Conventionally, a medical image diagnosis support method and apparatus used by a doctor to obtain support information related to an emphysema area has a fixed CT value threshold value that is fixed or specified by the operator each time the emphysema area is extracted from the lung field area. It is done using. In order to grasp the progress of the emphysema area, the outline of the emphysema area on the CRT display is traced with a pointing device such as a mouse, and the number of pixels in the traced area is counted to grasp the size of the emphysema area. (For example, see Patent Document 1 and Patent Document 2). In addition, an analysis apparatus (see, for example, Patent Document 3) that corrects an extraction error for reasons such as individual differences has been proposed.

JP 2003-10171 A JP 2004-49498 A Japanese Patent Application No. 2004-222711

  However, the conventional medical image diagnosis support method and apparatus perform higher-accuracy measurement because the CT value threshold for extracting the emphysema area from the lung field area is fixed or set by the operator each time. I couldn't. That is, the CT value extraction error due to gravity generated by the photographing posture or the posture of the subject on the bed is not taken into consideration.

  SUMMARY OF THE INVENTION Accordingly, an object of the present invention is to provide a medical image diagnosis support method and apparatus capable of extracting a pulmonary emphysema region with higher accuracy in consideration of an extraction error of a CT value due to gravity generated by a subject's imaging posture or posture. Is to provide.

  In order to achieve the above object, the present invention obtains a lung field region extraction process step for performing lung field region extraction processing based on image data, and a threshold value considering an extraction error based on gravity depending on the posture or body position of the subject. Lung field region analysis processing step for performing a threshold setting process for, and then, emphysema region detection processing step for performing detection processing of the emphysema region from within the lung field region using the threshold obtained in the lung field region analysis processing step, And a support information display step for displaying the emphysema area on the display as support information.

  The present invention includes a lung field region extraction unit that performs lung field region extraction processing based on image data, and a pulmonary emphysema region detection unit that performs detection processing of the pulmonary region from within the lung field region extracted by the lung field region extraction unit, To obtain a threshold value considering an extraction error based on gravity depending on the posture or body position of a subject in a medical image diagnosis support apparatus having support information display means for displaying the emphysema area on the display as support information by the emphysema area detection means And a pulmonary emphysema region detecting means for performing pulmonary emphysema region detection processing using the threshold value obtained by the pulmonary region analyzing means.

  According to the present invention, the lung field analysis means divides the lung field so as to form a plurality of partial spaces in a direction in which gravity acts on the subject, and obtains the threshold value for each partial space. It is characterized by that.

  Furthermore, the present invention relates to the area, average value, standard deviation, upper limit value and lower limit value of 95% confidence interval of the average value in each tomographic image unit, and the area and ratio of the emphysema region in each tomographic image unit. And a measurement result analyzing means for calculating at least one of an average value, a standard deviation, and an upper limit value and a lower limit value of a 95% confidence interval of the average value as support information.

  In the medical image diagnosis support method of the present invention, a lung field region analysis processing step for performing a threshold setting process for obtaining a threshold value in consideration of an extraction error based on gravity due to the posture or body position of the subject is added. By performing the emphysema area detection process using the threshold value obtained in the lung field area analysis processing step, the measurement accuracy is improved by the threshold value considering the extraction error based on gravity depending on the posture or body position of the subject, and more accurately The emphysema area can be extracted.

  In the medical image diagnosis support apparatus of the present invention, lung field region analysis processing means for performing threshold value setting processing for obtaining a threshold value considering an extraction error based on gravity depending on the posture or body position of the subject is added, and this lung field region analysis is performed. By detecting the emphysema area using the threshold value obtained by the processing means, the measurement accuracy is improved by the threshold value considering the extraction error based on gravity due to the posture or body position of the subject, and the emphysema area is extracted with higher accuracy can do.

  In the medical image diagnosis support apparatus according to the present invention, the lung field region is divided so as to form a plurality of partial spaces in the direction in which gravity acts on the subject, and a threshold value is obtained for each partial space. By increasing the partial space, it is possible to extract the emphysema region with higher accuracy by improving the measurement accuracy with a threshold that takes into account the extraction error based on gravity depending on the posture or body position of the subject.

  In the medical image diagnosis support apparatus according to the present invention, support information related to the emphysema region can be quantitatively captured from each measurement item specifically determined as support information, and the degree of progress can be recognized quantitatively.

The best mode for carrying out the present invention will be described below with reference to the drawings.
FIG. 1 is a hardware configuration diagram showing a medical image diagnosis support system using a medical image diagnosis support apparatus according to an embodiment of the invention.
The medical image diagnosis support system 1 is based on a medical tomographic imaging apparatus 2 such as an X-ray CT apparatus or an MR apparatus, an image database 4 that stores image data acquired by the medical tomographic imaging apparatus 2, and the image data. A medical image diagnosis support apparatus 10 that displays a created image, support information, and the like on a display 15 is connected to each other via a network 3 such as a LAN.

  The medical image diagnosis support apparatus 10 mainly includes a central processing unit (CPU) 11 that controls the operation of each component, a main memory 12 that stores a control program and serves as a work area during program execution, and an operating system ( OS), peripheral device drive, magnetic disk 13 storing various application software including a program for performing processing for obtaining support information for emphysema from image data, and display memory for temporarily storing display data 14, a display 15 such as a CTR monitor or a liquid crystal monitor for displaying an image based on data from the display memory 14, a keyboard 16, a mouse 17 as a position coordinate input device, and a state of the mouse 17 are detected. Information such as the position of the mouse pointer on the display 15 and the state of the mouse 17 The includes a controller 18 for outputting to the CPU 11, and a common bus 19 for connecting the respective components described above.

  The medical image diagnosis support apparatus 10 reads image data from the image database 4 via the network 3, but is a storage device connected to the medical image diagnosis support apparatus 10, such as an FDD, a CD-RW drive, an MO drive, and a ZIP drive. The tomographic image data may be read from the image data, or the image data may be acquired directly from the medical tomographic imaging apparatus 2 via the network 3.

  The medical image diagnosis support apparatus 10 described above includes a lung field region extraction unit 24 that performs lung field region extraction processing on image data read from an image database or the like as shown in FIG. The trachea / bronchial region deleting unit 25 for performing processing for deleting tracheal / bronchial region data in the lung field region data extracted by the lung field region extracting unit 24, and the intestinal region deleting unit 26 for executing intestinal tract deletion processing, A lung field region dividing unit 27 that performs processing for dividing the lung field region, and a plurality of partial spaces are formed in a direction in which gravity acts in order to correct an extraction error based on gravity due to the imaging posture or body position of the subject. Lung field region analysis means 28 for performing threshold value setting processing for dividing and obtaining a threshold value setting curve, and C based on the threshold value setting curve calculated by the lung field region analysis means 28 Pulmonary emphysema region detection means 29 for performing emphysema region detection processing using the values, and the area of the lung field region in each tomographic image unit based on the extracted lung field region, the divided lung field region, and the support information of the extracted pulmonary emphysema region , Mean value, standard deviation, upper limit value and lower limit value of 95% confidence interval of mean value, and area, percentage, mean value, standard deviation, upper limit value and lower limit value of 95% confidence interval of mean value It comprises a measurement result analyzing means 30 for calculating any one of them, and a support information display means 31 for displaying an original image, an image as support information, and other information on a display.

FIG. 3 is a flowchart showing a support method executed by the medical image diagnosis support apparatus 10 described above.
The CPU 11 shown in FIG. 1 operates according to this flowchart. First, the operator inputs the patient's ID number from the keyboard 16 while the subject's ID input screen is displayed on the display 14 of the medical image diagnosis support apparatus 10. Then, the image data corresponding to the ID number of the patient to be diagnosed is read from the image database 4 from the image data captured in advance by the medical image modality. At this time, based on the signal from the input means 20 such as the keyboard 16, the display determination means 21 shown in FIG. 2 detects that it is emphysema analysis information display, and the original image display means 23, emphysema analysis information display means 22, Is activated.

In step S1, the lung field extraction unit 24 of the emphysema analysis information display unit 22 executes a lung field extraction process on the read image data.
In this lung field region extraction processing, as shown in detail in FIG. 4, first, threshold processing is performed on the image data read in step S11 to create binarized image data. Here, the threshold value may be set in advance so that the target region is clearly separated, and the CT value indicating the most frequent frequency within the CT value range of the image data is set as the median value, and the threshold value is set. The threshold value may be automatically set by searching for the lower limit value and the upper limit value. In the subsequent step S12, two-dimensional labeling processing is performed on the binarized image data created previously to create label image data. Thereafter, in step S13, an area determination process is performed for extracting the label area data of the maximum area as a calculation target area using the generated label image data. In the subsequent step S14, a body region data is created by performing a filling process in the extracted label region. In step S15, the previously extracted label region data and body region data are subjected to discrimination recognition processing to extract lung field region data. Thereafter, the center of gravity of the body region is calculated.

Next, the tracheal / bronchial region deleting unit 25 shown in FIG. 2 is used to execute the tracheal / bronchial region deleting process in step S2 shown in FIG.
As shown in FIG. 5, the details of the trachea / bronchial region deletion process are as follows. In step S16, the trachea / bronchial region data in the lung field region data extracted in step S1 is first deleted. As this processing, in the lung field region of one image data, a small region isolated near the center of gravity is deleted, or tracheal / bronchial region data is obtained using a method described in Japanese Patent Application No. 2003-313424. Extraction may be performed. In subsequent step S17, determination deletion processing is performed to delete data in a region where the lung field region data extracted in step S1 and the trachea / bronchial region data extracted in step S16 overlap.

Next, the intestinal tract deletion process of step S3 shown in FIG. 3 is executed using the intestinal tract region deletion means 26 shown in FIG.
As this processing, the method described in Japanese Patent No. 2845995 may be adopted starting from the center of gravity of the lung field region data extracted in step S1, or the intestinal tract deletion processing method shown in FIG. 6 may be adopted. . In the latter intestinal tract deletion process, it is determined in step S18 shown in FIG. 6 whether or not there is an overlapping region at the same position in the upper and lower slices in the lung field region data extracted in steps S1 and S2. If there is an overlapping area, the process proceeds to another slice in step S20, and if there is no overlapping area, the process proceeds to step S19 to delete area data that does not overlap vertically.

Next, the lung field region dividing process of step S4 shown in FIG. 3 is executed using the lung field region dividing means 27 shown in FIG.
In this lung field segmentation processing, the lung field may be divided into upper lung field, middle lung field, lower lung field, or upper lung field, lower lung field, but each image is as shown in the flowchart of FIG. The data may be divided into the lung field and the lung field. That is, in the lung field region dividing process shown in FIG. 7, first, in step S21, the edge portion of the lung field region data extracted from each image data in the previously extracted lung field region data is recognized. Next, in step S22, a circular area centered on the edge portion pixel recognized in step S21 is set as a mask area. The radius of the mask area is set to an initial value of 2 cm, but the operator may set this value. In the next step S23, discrimination / recognition processing between the previously extracted lung field region data and the mask region set in step S22 is performed. When the lung field region and the mask region overlap, the lung field outer region is set. When the lung field region does not overlap, the lung field inner region is set.

Next, the lung field region analysis unit 28 shown in FIG. 2 is used to execute the lung field region analysis process in step S5 shown in FIG.
In this processing, the lung field region analysis processing shown in FIG. 8 is performed based on the region extracted in the previous lung field region extraction processing. That is, first, in step S24, a linear shadow region is extracted from the lung field region obtained by the previous lung field region extraction process. As this extraction method, image enhancement is performed by a Prewitt filter, an enhancement region is extracted by binarization processing, and only a region connected by an empirically set length is extracted as a linear shadow.

  In the next step S25, the medical tomographic imaging apparatus shown in FIG. 1 shows the subject lying on his back, for example, on the bed, as in the partial space setting examples shown in FIGS. 9 (a) to 11 (r). In the tomographic image taken in step 2, the lung field region is divided so as to form a plurality of partial spaces in the direction from the dorsal side located below the subject to the ventral side located above. The direction in which the plurality of partial spaces are formed differs depending on the imaging posture or body position of the subject and is not always the direction from the back to the abdomen, but in either case, gravity acts on the subject on the bed. It divides | segments so that several partial space may be formed in the direction to do.

  For example, in FIG. 9A, both lung field regions are formed so as to form three partial spaces 32a to 32c in the tomographic image from the dorsal side located below the gravity action direction to the ventral side located above. In FIG. 9B, both lung field regions are divided so as to form five partial spaces 32a to 32e in the same gravitational action direction, and in FIG. 9C, the same gravitational action direction. The two lung field regions are divided so as to form 10 partial spaces 32a to 32j. Further, as shown in FIGS. 9D to 9F, the division plane 43 may be used to divide each lung region so that a partial space is formed in the direction of gravity action.

  Further, as shown in FIG. 10 (g), after dividing into the lung field lumen 44a and the lung field outer space 44b, the lung field region is divided so as to form three partial spaces 32a to 32c in the same gravity action direction. 10 (h), it is divided so as to form five partial spaces 32a to 32e in the same gravitational action direction, and in FIG. 10 (i), ten partial spaces 32a to 32j are divided in the same gravitational action direction. It is divided to form. Further, as shown in FIGS. 10 (j) to 10 (l), the division plane 43 may be used to divide each lung region so as to form a partial space in the direction of gravity action. Further, as shown in FIG. 11 (m) to FIG. 11 (r), division planes 43a to 43e may be added to the vicinity of the mediastinum, the center of the lung field, and the chest wall for each lung field region. Further, the partial space may be divided based on the lung field region division information obtained in step S4.

  In the subsequent step S26, statistics for calculating the average CT value of the region excluding the linear shadow region data obtained by the linear shadow region extraction processing in step S24 from the above-described lung field region data in the partial space set in step S25. Perform analysis processing. This statistical analysis process is performed for each of a plurality of partial spaces formed in the direction from the dorsal side located below the subject to the ventral side located above to calculate the average CT value, and the CT value shown in FIG. Distribution 33 is obtained.

  In the next step S27, interpolation processing is performed based on the statistical analysis processing result obtained in step S26. By this interpolation processing, a threshold correction curve 34 for the average CT value is obtained as shown in FIG. As this interpolation processing method, there are a correction by a least square method, a correction by a higher-order spline curve, and the like. Subsequently, in step S28, a threshold setting process for extracting the emphysema region is performed based on the threshold correction curve 34 obtained in step S27. This threshold value setting method is performed by changing the initial threshold value of the threshold value correction curve 34 like the threshold value setting curve 35 shown in FIG. Although the CT value −910 is used as the initial threshold here, the threshold may be determined by discriminating and analyzing the CT value distribution of the lung field region excluding the linear shadow region.

  As shown in FIG. 12, the threshold setting curve 35 is obtained when, for example, a subject lying on the bed is photographed by the medical tomographic imaging apparatus 2 shown in FIG. Then, a difference occurs in the CT value due to the influence of gravity. Therefore, if the influence of gravity is ignored and a threshold value is set as one fixed value, an error occurs between the ventral side and the dorsal side. However, it is divided so as to form a plurality of partial spaces as shown in FIGS. 9 to 11 in the direction from the dorsal side located below the subject to the ventral side located above, and a threshold value is set for each partial space. Since the calculation is performed, it is possible to obtain an accurate threshold setting curve 35 that takes into account a phenomenon in which the CT value differs between the ventral side and the dorsal side under the influence of gravity depending on the imaging posture or body position of the subject.

  The threshold setting curve 35 is divided so that the number of partial spaces in the same direction increases when the lung field region is divided so as to form a plurality of partial spaces in the gravity action direction described in FIGS. The more you do, the more you can eliminate the influence of gravity. This division can be increased until the partial space becomes a pixel unit. However, since the division is affected by noise when the pixel is divided into pixel units, the limit of the division space in the above-mentioned direction is, for example, up to 5 pixels. Is desirable.

Next, the emphysema area detection process in step S6 shown in FIG. 3 is executed using the emphysema area detection means 29 shown in FIG.
FIG. 13 is a flowchart specifically showing this emphysema area detection process. First, in step S29, the local CT value variation calculation and determination process shown in FIG. 14 is executed for the previously extracted lung field area. To do. That is, in step S32, the region of interest 36 as shown in FIG. 15 is set for the lung field region obtained by the previous lung field region extraction process. Here, the initial size of the region of interest 36 is a radius of 3 pixels, but can be changed by an operator. In the next step S33, the standard deviation of the CT value in the set region of interest 36 is calculated. In the subsequent step S34, the calculated standard deviation is compared with a preset threshold value. If the calculated standard deviation is larger than the threshold value, the next region of interest is set and the processing from step S33 is repeatedly executed. However, if the calculated standard deviation is smaller than a preset threshold value, it is extracted as a target area in step S35.

  Next, CT value threshold processing and determination processing in step S30 shown in FIG. 13 are performed. In this method, threshold processing is performed on the previously extracted lung field region to create a binarized image, and determination processing is performed based on the binarized image. The threshold here is set by the threshold setting curve 35 of FIG. 12 using −910 which is lower than the average CT value in the lung field of a healthy person. Thereafter, in the region extracted by this threshold processing, a region having a diameter of less than 3 mm is deleted, but the threshold of less than 3 mm may be set by the operator. In the subsequent step S31, a determination deletion process is performed for extracting an area overlapping the area extracted in the previous step S29 and the area extracted in the previous step S30 as an emphysema area.

  The pulmonary emphysema region extracted in this way takes into consideration the phenomenon in which the CT value differs due to the influence of gravity depending on the imaging posture or body position of the subject as described in the threshold setting curve 35 shown in FIG. Therefore, extraction with high accuracy is possible. In addition, since the results of local CT value variation calculation and determination processing shown in FIG. 14 are taken into account, extraction with higher accuracy is possible.

Next, the measurement result analysis process of step S7 shown in FIG. 3 is performed using the measurement result analysis means 30 shown in FIG.
Based on the information of the lung field extracted in steps S1 to S3, the lung field divided in step S4, and the emphysema area extracted in step 6, the area, average value, and standard of the lung field in each tomographic image unit. The upper limit value and lower limit value of the 95% confidence interval of the deviation and the average value, and the upper limit value and lower limit value of the area, ratio, average value, standard deviation, and 95% confidence interval of the average value are calculated. Moreover, the analysis result of each whole lung field and each lung field unit is calculated. Here, since all the measurement items described above are analyzed in the lung field region and emphysema region, support information for detailed diagnosis can be obtained, but in other embodiments, selected from each of these items A plurality or at least one item may be analyzed. Further, although the confidence interval of the average value is initially set to 95%, the present invention is not limited to this and may be arbitrarily set by the operator.

Next, the analysis information display process of step S8 shown in FIG. 3 is executed using the support information display means 31 shown in FIG.
That is, as in the screen display example shown in FIG. 16, the image database 4 is displayed by the image 38 as the support information in which the emphysema area 38a extracted in FIG. 13 is emphasized by the display color and the original image display means 23 shown in FIG. The original image 37 based on the image data read out from the image and the general supplementary character information 39 are displayed together. Here, a display example in which the original image 37 and the image 38 as support information are juxtaposed is shown, but only an image in which the emphysema areas are superimposed on one screen may be displayed.

  FIG. 17 shows another screen display example by the support information display means 31. As the support information in which the above-described original image 37 and the emphysema area 38a based on the emphysema area detection processing in step S6 are emphasized by display colors. An image 38, general supplementary character information 39, and character information 40 of each measurement item based on the measurement result analysis process in step S7 are displayed.

  FIG. 18 shows still another screen display example by the support information display means 31, in which 10 series images 41 a to 41 j in units of series are displayed as support information.

  Further, FIG. 19 shows still another screen display example by the support information display means 31, and when any three slice images 41a to 41c are selected on the display screen of the images 41a to 41j shown in FIG. The display areas of the images 41a to 41j are switched to the screen display as shown in FIG. The image 42 as support information is obtained by displaying the emphysema area on the line with respect to the sagittal image on the line 45.

  When the images 38, 41a to 41j, 42 as the support information are displayed by the support information display means 31 described above, the emphysema area varies depending on the degree of progression based on, for example, the method described in Japanese Patent Application Laid-Open No. 2003-10171. You may make it display according to color.

  The medical image diagnosis support method and apparatus according to the present invention can be applied not only to the medical image diagnosis support system shown in FIG. 1 but also to other medical image diagnosis support systems. The medical image diagnosis support method according to the present invention stores a program according to the flowchart described in FIG. 3 in a magnetic disk of a new medical image diagnosis support apparatus, or the above-described method in a magnetic disk of an existing medical image diagnosis support apparatus. It can also be used by installing a program.

It is a block block diagram which shows the medical image diagnosis assistance system by one embodiment of this invention. It is a block block diagram which shows the principal part of the medical image diagnosis assistance apparatus shown in FIG. It is a flowchart which shows the process sequence of the medical image diagnosis assistance method by one embodiment of this invention. It is a flowchart which shows the detail of the lung field area | region extraction process shown in FIG. It is a flowchart which shows the detail of the trachea / bronchial region deletion process shown in FIG. It is a flowchart which shows the detail of the intestinal tract area | region deletion process shown in FIG. FIG. 4 is a flowchart showing details of lung field region division processing shown in FIG. 3. FIG. It is a flowchart which shows the detail of the lung field area | region analysis process shown in FIG. It is explanatory drawing which shows the example of a division | segmentation in the partial space setting process shown in FIG. It is explanatory drawing which shows the other example of a division | segmentation in the partial space setting process shown in FIG. It is explanatory drawing which shows the further example of a division | segmentation in the partial space setting process shown in FIG. It is explanatory drawing of the threshold value setting process shown in FIG. 4 is a flowchart showing details of an emphysema area extraction process shown in FIG. 3. It is a flowchart which shows the detail of the fluctuation | variation calculation / determination process of the local CT value shown in FIG. FIG. 14 is an explanatory diagram of a local CT value variation calculation process shown in FIG. 13. It is a front view of the display which shows the example of a display screen by the assistance information display process shown in FIG. It is a front view of the display which shows the other example of a display screen by the assistance information display process shown in FIG. It is a front view of the display which shows the further example of a display screen by the assistance information display process shown in FIG. It is a front view of the display which shows the further example of a display screen by the assistance information display process shown in FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Medical image diagnosis assistance system 2 Medical tomographic imaging apparatus 4 Image database 10 Medical image diagnosis assistance apparatus 11 CPU
DESCRIPTION OF SYMBOLS 13 Magnetic disk 15 Display 22 Emphysema analysis information display means 23 Original image display means 24 Lung field extraction means 25 Tracheal / bronchial area deletion means 26 Intestinal tract area deletion means 27 Lung field area division means 28 Lung field area analysis means 29 Pulmonary emphysema area detection Means 30 Measurement result analysis means 31 Support information display means 32a to 32e Subspace 34 Threshold correction curve 35 Threshold setting curve 37 Original image 38 Image 38a Emphysema area

Claims (3)

  Lung field extraction means for performing lung field extraction processing based on image data, emphysema area detection means for detecting emphysema area from within the lung field extracted by the lung field extraction means, and detection of this emphysema area Threshold setting processing for obtaining a threshold in consideration of an extraction error based on gravity depending on the posture or body position of a subject in a medical image diagnosis support apparatus comprising support information display means for displaying an emphysema region by means on a display as support information A medical image diagnosis support apparatus, comprising: a lung field region analysis unit for performing pulmonary emphysema region detection processing, wherein the pulmonary emphysema region detection unit performs processing for detecting a pulmonary emphysema region using a threshold value obtained by the lung field region analysis unit.   The lung field region analyzing means divides the lung field region so as to form a plurality of partial spaces in a direction in which gravity acts on a subject, and obtains the threshold value for each partial space. The medical image diagnosis support apparatus according to claim 1. The area, average value, standard deviation, upper limit value and lower limit value of 95% confidence interval of the average value in each tomographic image unit, and the area, ratio, average value, standard of the emphysema region in each tomographic image unit The medical image diagnosis according to claim 1, further comprising a measurement result analysis unit that calculates at least one of an upper limit value and a lower limit value of a 95% confidence interval of the deviation and the average value as support information. Support device.

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