JP2011203009A - Image processing apparatus, program, and image processing method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an image processing apparatus, capable of correcting the form of brain after operation to that before operation, even when there is a formal change in brain before and after operation, and properly comparing cerebral blood flow, etc.SOLUTION: The image processing apparatus inputs images of cerebral blood flow before and after operation, converts the images of cerebral blood flow before and after operation into anatomical standard images, and stores a conversion parameter used for the conversion of the image of cerebral blood flow before operation into the anatomical standard image. Subsequently, by using the conversion parameter used for the conversion of the image of cerebral blood flow before operation, the image processing apparatus inversely converts the anatomical standard image of the image of cerebral blood flow after operation to obtain a corrected image of the image of cerebral blood flow after operation corresponding to the form of brain before operation, determines increase or decrease in cerebral blood flow by comparing the image of cerebral blood flow before operation with the corrected image obtained by the inverse conversion, and displays information showing the increase or decrease in cerebral blood flow while being overlapped with an image of the form of brain before operation.

Description

  The present invention relates to an image processing apparatus for a head diagnostic image, and more particularly to a technique for correcting a morphological change in the brain caused by surgery or the like.

  In the treatment of neurosurgery, the brain may be directly manipulated by craniotomy. For example, EC-IC bypass (extracranial-intracranial artery bypass) is a method for treating cerebrovascular disorders. EC-IC bypass surgery is said to be effective in the chronic phase, especially in cases where the circulatory reserve is significantly reduced.

  A head diagnosis image before and after the operation is used for evaluating whether the operation is effective. For example, when the above-described EC-IC bypass operation or the like is performed, whether blood flow is sufficiently recovered by comparing the cerebral blood flow before and after the operation, whether hyperperfusion has occurred, or the like Confirm.

  A cerebral blood flow image is used to evaluate the cerebral blood flow. Specifically, cerebral blood flow images are captured before and after surgery, and the images before and after surgery are compared locally (Non-Patent Documents 1-4).

Tatsuya Ishikawa, et.al. `` Cerebral haemodynamics and long term prognosis after extracranial-intracranial bypass surgery '' Journal of Neurology, Neurosurgery, and Psychiatry, 1995; 59: 625-628 Hiroaki Shimizu et al. “Sequential cerebral blood flow SPECT findings after EC-IC bypass” The Mt. Fuji Workshop on CVD Vol.24 (2006) Kuniaki Ogasawara et al. “Effect of bypass for chronic carotid artery occlusive lesion based on quantitative evaluation by 133XeSPECT” Surgery for stroke 27: 14-18,1999 Takashi Kuroda et al. "Diagnosis of cerebral blood flow failure in chronic cerebral ischemia" Neurosurgery 18 (2): 167-173, 1990

  However, when a surgical operation is performed, the morphology of the brain may change before and after the operation. When the morphological change of the brain occurs, it is extremely difficult to evaluate the head diagnostic image based on the local comparison between the preoperative image and the postoperative image.

  In addition, when an abnormality is found in the postoperative image, it is effective to obtain the morphological position information of the abnormal part by superimposing it with a morphological image such as MRI before the operation. However, when a morphological change of the brain is caused by surgery, it is difficult to collect information by superimposing such images.

  Therefore, in view of the above background, the present invention corrects the postoperative or preoperative brain morphology even when a morphological change of the brain occurs, for example, a head capable of appropriately comparing cerebral blood flow, etc. An object of the present invention is to provide a diagnostic image.

  The image processing apparatus of the present invention includes an image input unit that inputs a preoperative head diagnostic image and a postoperative head diagnostic image, an image conversion unit that converts the head diagnostic image into an anatomical standard image, A storage unit for storing the anatomical standard image obtained by the conversion by the image conversion unit, a conversion parameter used for conversion from the head diagnostic image to the anatomical standard image, and the preoperative head Corrected image of postoperative head diagnostic image corresponding to preoperative brain morphology by inversely transforming anatomical standard image of postoperative head diagnostic image using conversion parameters used for diagnostic image conversion And an image display unit for displaying the corrected image obtained by the inverse transform by the image inverse transform unit. The head diagnosis image is an image used for head diagnosis, for example, an image captured by SPECT, PET, MRI, CT, or the like.

  The above is a configuration for correcting the postoperative head diagnostic image to the form of the preoperative head diagnostic image, but correcting the preoperative head diagnostic image to the form of the postoperative head diagnostic image. In this case, the image reverse conversion unit, contrary to the above, uses the conversion parameters used when the post-operative head diagnostic image is converted into the anatomical standard image, and The corrected image of the preoperative head diagnostic image corresponding to the postoperative brain morphology may be obtained by inversely transforming the anatomical standard image.

  According to the present invention, the anatomical standard image of the post-operative head diagnostic image is inversely converted using the conversion parameters used when the pre-operative head diagnostic image is anatomically standardized. The later head diagnostic image can be matched to the same brain form as the preoperative head diagnostic image. Thereby, for example, by comparing the cerebral blood flow images before and after the operation as the head diagnosis image, the change in the cerebral blood flow before and after the operation can be appropriately obtained.

It is a figure which shows the outline | summary of the process of this Embodiment. It is a figure which shows the functional block of the image processing apparatus which concerns on this Embodiment. It is a figure which shows the hardware constitutions of the image processing apparatus which concerns on this Embodiment. It is a figure which shows the structure of the program which concerns on this Embodiment. It is a figure which shows operation | movement of the image processing apparatus which concerns on this Embodiment. It is a figure which shows another operation | movement of the image processing apparatus which concerns on this Embodiment. (A) It is a figure which shows the cerebral blood-flow image before a surgery. (B) It is a figure which shows the postoperative cerebral blood-flow image corrected by the method of this invention. (C) It is a figure which shows the result of having measured the change of the cerebral blood flow before and behind the operation which was correct | amended by the method of this invention. (A) It is a figure which shows the cerebral blood-flow image before a surgery. (B) It is a figure which shows the post-operative cerebral blood-flow image which is not correct | amending. (C) It is a figure which shows the result of having measured the change of the cerebral blood flow before and behind an operation, without performing correction | amendment.

  Hereinafter, an image processing apparatus according to an embodiment of the present invention will be described with reference to the drawings. In the present embodiment, an image processing apparatus that compares a pre-operative cerebral blood flow image with a post-operative cerebral blood flow image to obtain a change in cerebral blood flow will be described as an example. It is also possible to process head diagnostic images other than cerebral blood flow images.

  FIG. 1 is a diagram showing an outline of processing of the image processing apparatus according to the present embodiment. The image processing apparatus according to the present embodiment first acquires a preoperative cerebral blood flow image and performs anatomical standardization of the preoperative cerebral blood flow image. Anatomical standardization is performed by known methods such as Minoshima S et.al., J. Nucl.Med., 1994, 35, p1528-1537 or Friston KJ et.al, Human Brain Mapping, 1995, 2, p189- The method described in 210 can be used. At this time, conversion parameters used for anatomical standardization are stored. Here, the conversion parameter includes the linear conversion parameter L.P. lib and the nonlinear deformation parameter S.L. There is a lib.

  Next, the image processing apparatus acquires a post-operative cerebral blood flow image, performs anatomical standardization of the post-operative cerebral blood flow image, and obtains an anatomical standard image. The image processing apparatus inversely converts the anatomical standard image of the post-operative cerebral blood flow image using the conversion parameters used when converting the pre-operative cerebral blood flow image. As a result, a corrected image obtained by correcting the post-operative cerebral blood flow image into the form of the pre-operative cerebral blood flow image is obtained. The image processing apparatus compares the pre-operative cerebral blood flow image with the corrected post-operative cerebral blood flow image, and obtains a change in cerebral blood flow in each part of the brain. The outline of the processing of the image processing apparatus according to the present embodiment has been described above.

  FIG. 2 is a diagram illustrating functional blocks of the image processing apparatus 10 according to the present embodiment. The image processing apparatus 10 includes an image input unit 11 that inputs an image captured by the SPECT apparatus 20, a storage unit 16 that stores various information such as an input image, and the input image as an anatomical standard image. An image conversion unit 12 for conversion, and an image reverse conversion unit 13 for reversely converting an anatomical standard image of a post-operative cerebral blood flow image into an image of a brain form of a patient before operation are provided. The storage unit 16 of the image processing apparatus 10 stores pre- and post-operative images input from the SPECT apparatus 20, conversion parameters used when the pre-operative images are anatomically standardized, and pre- and post-operative images. An anatomical standard image is stored. The image conversion unit 12 outputs the conversion parameters used when the preoperative cerebral blood flow image is converted into an anatomical standard image, and stores it in the storage unit 16.

  The image processing apparatus 10 obtains the cerebral blood flow comparison unit 14 that compares the pre-operative cerebral blood flow image with the post-operative cerebral blood flow image to determine the increase or decrease of the cerebral blood flow, and the cerebral blood flow comparison unit 14. And an image display unit 15 that superimposes and displays information indicating the increase or decrease in cerebral blood flow on the morphological image of the brain of the patient before surgery. The cerebral blood flow volume comparison unit 14 uses a corrected image of the cerebral blood flow image that has been reversely converted into the preoperative brain form by the image reverse conversion unit 13 as a postoperative cerebral blood flow image, and the preoperative brain. Compare with blood flow image. Specifically, in the pre-operative cerebral blood flow image and the post-operative cerebral blood flow image, the pixel values of corresponding portions are compared and calculated, and the increase or decrease in cerebral blood flow is calculated.

  FIG. 3 is a diagram illustrating a hardware configuration of the image processing apparatus 10 according to the present embodiment. The image processing apparatus 10 is configured by connecting a CPU 30, a memory 31, a communication interface 32, a monitor 33, and a keyboard 34 via a bus 35. In addition to this, the image processing apparatus 10 may include a CD-ROM drive, a USB interface, and the like. The communication interface 32 is used to connect to the SPECT apparatus 20. As a result, large-capacity image data can be received from the SPECT apparatus 20. The memory 31 stores a program 36 for realizing the functions of the image processing apparatus 10 according to the present embodiment.

  FIG. 4 is a diagram showing the configuration of the program 36. The program 36 includes an image input module 40, an image conversion module 41, an image reverse conversion module 42, a cerebral blood flow comparison module 43, and a cerebral blood flow display module 44. By executing the image input module 40 with the CPU 30, the computer realizes the functions of the image input unit 11 described above. By executing the image conversion module 41 by the CPU 30, the computer realizes the functions of the image conversion unit 12 described above. By executing the image reverse conversion module 42 by the CPU 30, the computer realizes the function of the image reverse conversion unit 13 described above. By executing the cerebral blood flow comparison module 43 by the CPU 30, the computer realizes the function of the cerebral blood flow comparison unit 14 described above. By executing the cerebral blood flow display module 44 by the CPU 30, the computer realizes the function of the cerebral blood flow display unit 15 described above. Accordingly, the CPU 30 reads out and executes the program 36 from the memory 31, thereby realizing the functions of the image processing apparatus 10, and the processes of the image processing apparatus 10 described below are performed.

  FIG. 5 is a diagram illustrating an operation of the image processing apparatus 10 according to the embodiment. The image processing apparatus 10 receives and inputs the cerebral blood flow image of the patient imaged by the SPECT apparatus 20 from the SPECT apparatus 20 before the operation (S10). The image processing apparatus 10 stores the input preoperative cerebral blood flow image in the storage unit 16 (memory) (S10). The image conversion unit 12 of the image processing apparatus 10 reads a preoperative cerebral blood flow image from the storage unit 16, performs anatomical standardization of the read cerebral blood flow image, and anatomically analyzes the preoperative cerebral blood flow image. A standard image is generated (S12). The image conversion unit 12 stores the generated preoperative anatomical standard image and the conversion parameters used for the conversion in the storage unit 16 (S14).

  After the operation, the image processing apparatus 10 receives and inputs the cerebral blood flow image of the patient imaged by the SPECT apparatus 20 from the SPECT apparatus 20 (S16). The image processing apparatus 10 stores the input postoperative cerebral blood flow image in the storage unit 16 (S16). The image conversion unit 12 of the image processing apparatus 10 reads a post-operative cerebral blood flow image from the storage unit 16, performs anatomical standardization of the read cerebral blood flow image, and anatomically analyzes the post-operative cerebral blood flow image. A standard image is generated (S18). The image conversion unit 12 stores the generated postoperative anatomical standard image in the storage unit 16 (S20).

  Next, the image reverse conversion unit 13 of the image processing apparatus 10 reads out the postoperative anatomical standard image and the conversion parameters used for the anatomical standardization of the preoperative cerebral blood flow image from the storage unit 16. The image reverse conversion unit 13 reversely converts the postoperative anatomical standard image using the read conversion parameter, and corrects the postoperative cerebral blood flow image to the form of the preoperative cerebral blood flow image. Is generated (S22). The image reverse conversion unit 13 inputs the generated corrected image to the cerebral blood flow rate comparison unit 14.

  The cerebral blood flow rate comparison unit 14 reads out a preoperative cerebral blood flow image from the storage unit 16 and compares it with the corrected image input from the image inverse conversion unit 13 to obtain an increase or decrease in cerebral blood flow rate (S24). The image processing apparatus 10 displays the comparison result of the cerebral blood flow on the image display unit 15 (S26). At this time, the image display unit 15 superimposes and displays information indicating the increase or decrease in cerebral blood flow on the morphological image of the brain of the patient before surgery. For example, by coloring a color determined according to the rate of increase in cerebral blood flow, it is possible to easily grasp the degree of improvement in cerebral blood flow in each part of the brain. In addition, in the pre- and post-operative cerebral blood flow images, “stage” information indicating the severity of the cerebrovascular disorder may be obtained, and the obtained information may be displayed.

  Here, an example of comparing cerebral blood flow before and after surgery and coloring according to the rate of increase in cerebral blood flow is explained, but without comparison of cerebral blood flow, It is also possible to simply display a corrected image of the blood flow image and the post-operative cerebral blood flow image.

  The image processing apparatus 10 according to the present embodiment inversely converts an anatomical standard image of a post-operative cerebral blood flow image using a conversion parameter used when anatomically standardizing a pre-operative cerebral blood flow image. By doing so, the post-operative cerebral blood flow image can be matched with the same form as the pre-operative cerebral blood flow image, and a local change in cerebral blood flow before and after the operation can be obtained appropriately. Thereby, the artifact resulting from the morphological change before and after the operation is greatly improved, and the measurement accuracy of the local cerebral blood flow change rate can be improved. In the present embodiment, since the increase or decrease in cerebral blood flow is displayed by being superimposed on the form of the patient's brain instead of the anatomical standard image, which part of the image of the brain of the patient to be diagnosed is displayed. It is possible to properly grasp how much the blood flow of the patient changed before and after the operation.

  In the present embodiment, an example in which the postoperative cerebral blood flow image is corrected to the form of the preoperative cerebral blood flow image by inversely transforming the anatomical standard image of the postoperative cerebral blood flow image has been described. It is also possible to correct the anatomical standard image of the blood flow image to the form of the postoperative cerebral blood flow image by inversely transforming it. In this case, the conversion parameters used when the postoperative cerebral blood flow image is anatomically standardized are used for the inverse conversion.

  FIG. 6 is a diagram illustrating an operation of correcting a preoperative image into a postoperative image form. The image processing apparatus 10 receives and inputs the cerebral blood flow image of the patient imaged by the SPECT apparatus 20 before the operation from the SPECT apparatus 20 (S30). The image processing apparatus 10 stores the input preoperative cerebral blood flow image in the storage unit 16 (memory) (S30). The image conversion unit 12 of the image processing apparatus 10 reads a preoperative cerebral blood flow image from the storage unit 16, performs anatomical standardization of the read cerebral blood flow image, and anatomically analyzes the preoperative cerebral blood flow image. A standard image is generated (S32). The image conversion unit 12 stores the generated preoperative anatomical standard image in the storage unit 16 (S34).

  After the operation, the image processing apparatus 10 receives and inputs the cerebral blood flow image of the patient imaged by the SPECT apparatus 20 from the SPECT apparatus 20 (S36). The image processing apparatus 10 stores the input postoperative cerebral blood flow image in the storage unit 16 (S36). The image conversion unit 12 of the image processing apparatus 10 reads a post-operative cerebral blood flow image from the storage unit 16, performs anatomical standardization of the read cerebral blood flow image, and anatomically analyzes the post-operative cerebral blood flow image. A standard image is generated (S38). The image conversion unit 12 stores the generated postoperative anatomical standard image and the conversion parameters used for the conversion in the storage unit 16 (S40).

  Next, the image reverse conversion unit 13 of the image processing apparatus 10 reads out from the storage unit 16 the anatomical standard image before the operation and the conversion parameters used for the anatomical standardization of the cerebral blood flow image after the operation. The image reverse conversion unit 13 reversely converts the preoperative anatomical standard image using the read conversion parameter, and corrects the preoperative cerebral blood flow image to the form of the postoperative cerebral blood flow image. Is generated (S42). The image reverse conversion unit 13 inputs the generated corrected image to the cerebral blood flow rate comparison unit 14.

  The cerebral blood flow rate comparison unit 14 reads the post-operative cerebral blood flow image from the storage unit 16 and compares it with the corrected image input from the image reverse conversion unit 13 to obtain an increase or decrease in cerebral blood flow rate (S44). The image processing apparatus 10 displays the comparison result of cerebral blood flow on the image display unit 15 (S46). At this time, the image display unit 15 superimposes and displays information indicating the increase or decrease in cerebral blood flow on the morphological image of the post-operative patient's brain. For example, by coloring a color determined according to the rate of increase in cerebral blood flow, it is possible to easily grasp the degree of improvement in cerebral blood flow in each part of the brain. In addition, in the pre- and post-operative cerebral blood flow images, “stage” information indicating the severity of the cerebrovascular disorder may be obtained, and the obtained information may be displayed.

  Here, an example of comparing cerebral blood flow before and after surgery and coloring according to the rate of increase in cerebral blood flow is explained, but without comparison of cerebral blood flow, It is also possible to simply display a corrected image of the blood flow image and a post-operative cerebral blood flow image.

  In the present embodiment, an example in which SPECT images are compared has been described. However, the present invention is not limited to SPECT images, but can be applied to PET images and MRI images. In the present embodiment, an example in which cerebral blood flow images are compared has been described. However, for example, pre- and post-operative images of epilepsy focus removal surgery can be compared.

  In the above-described embodiment, an example in which the head diagnosis image before and after the operation is compared has been described. However, the present invention is not limited to the comparison of the head diagnosis image before and after the operation, and the shape of the head changes. It can be used when comparing front and back head diagnostic images. In this case, the form after the change may be corrected to the form before the change, or the form before the change may be corrected to the form after the change. Here, as the form before the change in the former case or the form after the change in the latter case, the first head diagnosis image is the one to have the form aligned, the second is the one to correct the form Image processing will be described using a head diagnosis image. Both the first head diagnostic image and the second head diagnostic image are converted into an anatomical standard image. At this time, the conversion parameters used for converting the first head diagnostic image into the anatomical standard image are stored. Subsequently, inverse transformation is performed using the conversion parameters stored in the anatomical standard image of the second head diagnostic image, and the second head diagnostic image is corrected to the form of the first head diagnostic image. To do. By performing such processing, it is possible to appropriately correct the head diagnostic image whose form has changed, not only before and after the operation, and to locally compare the images before and after the form change. .

  EXAMPLES The present invention will be described below with reference to examples, but the present invention is not limited to the following contents. In this example, cerebral blood flow images before and after surgery of a 72-year-old woman who performed EC-IC bypass surgery were corrected by the method of the present invention and compared. As a comparative example, a comparison result of a cerebral blood flow image without correction is also shown.

  A subject was administered 222 MBq of N-isopropyl-4-iodoamphetamine hydrochloride (123I) injection solution (manufactured by Nippon Mediphysics Co., Ltd.), and a brain blood flow image was taken using a Toshiba GCA9300 SPECT device.

  7A is a diagram showing a preoperative cerebral blood flow image, FIG. 7B is a diagram showing a postoperative cerebral blood flow image corrected by the method of the present invention, and FIG. It is a figure which shows the result of having corrected by the method of invention and comparing the cerebral blood flow. FIG. 8A shows a preoperative cerebral blood flow image, FIG. 8B shows a post-operative cerebral blood flow image without correction, and FIG. 8C shows no correction. It is a figure which shows the result of having compared the cerebral blood flow rate. In the figure, the part indicated by the arrow is the anterior cerebral artery region. In this case, there was actually almost no change in blood flow in the anterior cerebral artery region, but in the case where correction was not performed, it was -14.98%, which was clearly underestimated. On the other hand, in the example in which the postoperative image is corrected by the method of the present invention, the blood flow change in the anterior cerebral artery region is -2.92%, which is close to the actual value, and a considerable improvement is seen. It was.

  As described above, the present invention has the effect that it is possible to appropriately determine changes in cerebral blood flow before and after surgery, and is useful for, for example, blood flow evaluation before and after EC-IC bypass surgery. .

DESCRIPTION OF SYMBOLS 10 Image processing apparatus 11 Image input part 12 Image conversion part 13 Image reverse conversion part 14 Cerebral blood flow volume comparison part 15 Image display part 16 Storage part 20 SPECT apparatus

Claims (18)

An image input unit for inputting a preoperative head diagnostic image and a postoperative head diagnostic image;
An image conversion unit for converting a head diagnostic image into an anatomical standard image;
A storage unit for storing the anatomical standard image obtained by the conversion by the image conversion unit, and a conversion parameter used for conversion from the head diagnostic image to the anatomical standard image;
The postoperative head corresponding to the preoperative brain morphology by inversely transforming the anatomical standard image of the postoperative head diagnostic image using the conversion parameters used for the conversion of the preoperative head diagnostic image An image inverse transform unit for obtaining a corrected image of the diagnostic image;
An image display unit for displaying the corrected image obtained by the inverse transformation by the image inverse transformation unit;
An image processing apparatus for a head diagnostic image comprising: A head diagnostic image comparison unit that compares pixel values of corresponding positions in the corrected image obtained by the inverse transformation by the image inverse transformation unit and the preoperative head diagnostic image;
The image processing apparatus according to claim 1, wherein the image display unit displays a comparison result.   The image processing apparatus according to claim 1, wherein a cerebral blood flow image is used as the head diagnostic image. Using a cerebral blood flow image as the head diagnostic image,
The head diagnostic image comparison unit compares pre-operative and post-operative cerebral blood flow images with pixel values at corresponding locations in the corrected image obtained by the inverse transformation by the image inverse transformation unit. Increase or decrease in cerebral blood flow in
The image processing apparatus according to claim 2, wherein the image display unit displays information indicating increase / decrease in cerebral blood flow volume superimposed on a pre-operative brain morphological image. An image input unit for inputting a preoperative head diagnostic image and a postoperative head diagnostic image;
An image conversion unit for converting a head diagnostic image into an anatomical standard image;
A storage unit for storing the anatomical standard image obtained by the conversion by the image conversion unit, and a conversion parameter used for conversion from the head diagnostic image to the anatomical standard image;
The preoperative head corresponding to the postoperative brain morphology by inversely transforming the anatomical standard image of the preoperative head diagnostic image using the conversion parameters used for the conversion of the postoperative head diagnostic image An image inverse transform unit for obtaining a corrected image of the diagnostic image;
An image display unit for displaying the corrected image obtained by the inverse transformation by the image inverse transformation unit;
An image processing apparatus for a head diagnostic image comprising: An image input unit for inputting the first head diagnostic image and the second head diagnostic image;
An image conversion unit for converting a head diagnostic image into an anatomical standard image;
A storage unit for storing the anatomical standard image obtained by the conversion by the image conversion unit, and a conversion parameter used for conversion from the head diagnostic image to the anatomical standard image;
Using the conversion parameters used for the conversion of the first head diagnostic image, the anatomical standard image of the second head diagnostic image is inversely converted to correspond to the first head diagnostic image form. An image inverse transform unit for obtaining a corrected image of the head diagnostic image of 2;
An image display unit for displaying the corrected image obtained by the inverse transformation by the image inverse transformation unit;
An image processing apparatus for a head diagnostic image comprising: A program for displaying a head diagnosis image on a computer,
Inputting a preoperative head diagnostic image;
Converting pre-operative head diagnostic images into anatomical standard images;
Storing a conversion parameter used for conversion from the preoperative head diagnostic image into the anatomical standard image in a storage unit;
Inputting post-operative head diagnostic images;
Converting a post-operative head diagnostic image into an anatomical standard image;
The conversion parameter is read from the storage unit, and the postoperative head corresponding to the preoperative brain morphology by inversely converting the anatomical standard image of the postoperative head diagnostic image using the read conversion parameter Obtaining a corrected image of the part diagnostic image;
Displaying the corrected image obtained by the inverse transformation;
A program that executes Comparing pixel values of corresponding locations in the preoperative head diagnostic image and the corrected image;
Displaying the result of the comparison;
The program according to claim 7 which causes a computer to execute.   The program according to claim 7 or 8, wherein a cerebral blood flow image is used as the head diagnostic image. Using a cerebral blood flow image as the head diagnostic image,
The step of comparing the head diagnostic image is to determine the increase or decrease in cerebral blood flow volume before and after surgery by comparing the pixel value of the corresponding location in the correction image and the preoperative brain blood flow image,
The program according to claim 8, wherein the step of displaying the comparison result displays information indicating an increase or decrease in cerebral blood flow amount superimposed on a pre-operative brain morphological image. A program for displaying a head diagnosis image on a computer,
Inputting a preoperative head diagnostic image;
Converting pre-operative head diagnostic images into anatomical standard images;
Inputting post-operative head diagnostic images;
Converting a post-operative head diagnostic image into an anatomical standard image;
Storing the conversion parameters used for conversion from the post-operative head diagnostic image into the anatomical standard image in a storage unit;
Reading the conversion parameter from the storage unit, and using the read conversion parameter, the preoperative head corresponding to the postoperative brain morphology by inversely converting the anatomical standard image of the preoperative head diagnostic image Obtaining a corrected image of the part diagnostic image;
Displaying the corrected image obtained by the inverse transformation;
A program that executes A program for displaying a head diagnosis image on a computer,
Inputting a first head diagnostic image;
Converting the first head diagnostic image into an anatomical standard image;
Storing a conversion parameter used for converting the first head diagnostic image into the anatomical standard image in a storage unit;
Inputting a second head diagnostic image;
Converting the second head diagnostic image into an anatomical standard image;
The conversion parameter is read from the storage unit, and the anatomical standard image of the second head diagnosis image is inversely converted using the read conversion parameter to correspond to the first head diagnosis image form. Obtaining a corrected image of two head diagnostic images;
Displaying the corrected image obtained by the inverse transformation;
A program that executes A method of displaying a head diagnosis image by an image processing device,
The image processing apparatus inputs a preoperative head diagnostic image;
The image processing device converting a preoperative head diagnostic image into an anatomical standard image;
The image processing apparatus stores in a storage unit conversion parameters used for conversion from the preoperative head diagnostic image to the anatomical standard image;
The image processing apparatus inputs a postoperative head diagnostic image;
The image processing device converting a post-operative head diagnostic image into an anatomical standard image; and
The image processing apparatus reads the conversion parameter from the storage unit, and uses the read conversion parameter to inversely convert an anatomical standard image of a postoperative head diagnostic image into a preoperative brain form. Obtaining a corrected image of the corresponding postoperative head diagnostic image;
The image processing apparatus displaying the corrected image obtained by the inverse transformation;
An image processing method comprising: The image processing device comparing pixel values of corresponding locations in the preoperative head diagnostic image and the corrected image;
The image processing device displaying the result of the comparison;
An image processing method according to claim 13.   The image processing method according to claim 13 or 14, wherein a cerebral blood flow image is used as the head diagnostic image. Using a cerebral blood flow image as the head diagnostic image,
The step of comparing the head diagnostic image is to determine the increase or decrease in cerebral blood flow volume before and after surgery by comparing the pixel value of the corresponding location in the correction image and the preoperative brain blood flow image,
The image processing method according to claim 14, wherein the step of displaying the comparison result displays information indicating increase / decrease in cerebral blood flow volume superimposed on a pre-operative brain morphological image. A method of displaying a head diagnosis image by an image processing device,
The image processing apparatus inputs a preoperative head diagnostic image;
The image processing device converting a preoperative head diagnostic image into an anatomical standard image;
The image processing apparatus inputs a postoperative head diagnostic image;
The image processing device converting a post-operative head diagnostic image into an anatomical standard image; and
The image processing apparatus stores in a storage unit conversion parameters used for conversion from the post-operative head diagnostic image to the anatomical standard image;
The image processing apparatus reads the conversion parameter from the storage unit, and uses the read conversion parameter to reversely convert an anatomical standard image of a preoperative head diagnostic image into a postoperative brain form. Obtaining a corresponding corrected image of the preoperative head diagnostic image;
The image processing apparatus displaying the corrected image obtained by the inverse transformation;
An image processing method comprising: A method of displaying a head diagnosis image by an image processing device,
The image processing device inputs a first head diagnostic image;
The image processing apparatus converting the first head diagnostic image into an anatomical standard image;
Storing the conversion parameter used by the image processing apparatus for converting the first head diagnostic image into the anatomical standard image in a storage unit;
The image processing apparatus inputting a second head diagnostic image;
The image processing device converting the second head diagnostic image into an anatomical standard image;
The image processing apparatus reads the conversion parameter from the storage unit, and inversely transforms the anatomical standard image of the second head diagnostic image using the read conversion parameter, thereby generating a first head diagnostic image. Obtaining a corrected image of the second head diagnostic image corresponding to the form of
The image processing device displaying the corrected image obtained by the inverse transformation;
An image processing method comprising: