JP2005025669A - Image database system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an image database system capable of easily relating medical remark data to a target portion of medical image data read in preparing the medical remark data and performing a sure diagnostic evaluation. <P>SOLUTION: The image database system is provided with a position specification means for specifying an optional position of an image displayed on a viewer, a report display means for displaying a template for inputting remark data corresponding to the position specified by the position specification means so that the position specified by the position specification means is indicated and a report information storage means for storing the remark or diagnostic data inputted to the template in an image database server as report information. The report information is stored in the image database server together with link information table data for relating image data corresponding to the inputted remark or diagnostic data to the specified position data of the image data. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to an image database system that stores a large amount of medical image information photographed by a modality apparatus such as a CT apparatus or an MRI apparatus as electronic information and contributes to diagnosis, and more specifically, relates to medical finding data and medical findings. The present invention relates to an image database system capable of easily associating medical image data read at the time of creating data with a target portion.

Conventionally, medical image data generated by a modality device and stored in an image server is reproduced on a screen by a viewer equipped with a dedicated high-resolution display, and a diagnostician interprets an image reproduced by the viewer. The findings data was input by operating the finding creation terminal connected to the report server that manages the report data. The report data created in this way is stored in the report server in a state linked to the image data displayed in the viewer via the link data, and the report and the target image are displayed at the same time on the finding creation terminal. There have been proposals that can be configured and those that can be displayed on the viewer in synchronization with the report displayed on the finding creation terminal.
JP 2001-273364 A

  When the above report and target image are displayed on the finding creation terminal at the same time, a clear target image is not displayed due to the limitation of the resolution of the terminal, and it is difficult to evaluate the validity of the diagnosis by visually observing the finding creating terminal later. If the report is displayed on the viewer in synchronization with the report displayed on the observation creation terminal, it is not possible to clearly identify which part of the target image the observation data was input. Similarly, there is a problem that it is difficult to evaluate the validity of the diagnosis.

  In view of the above-described problems, the present invention can easily associate medical finding data with a target portion of medical image data read when creating medical finding data, and accurately perform diagnosis evaluation. The object is to provide a possible image database system.

  In order to achieve the above object, a first characteristic configuration of an image database system according to the present invention includes a storage unit for storing medical image data and the storage as described in claim 1 in the claims. An image database server storing attribute information including key information associated with medical image data accumulated in the unit, and a viewer for acquiring and displaying medical image data from the image database server, Position designation means for designating an arbitrary position of the displayed image and a template for inputting finding data for the position designated by the position designation means are designated to the viewer by the designated position by the position designation means. Report display means for displaying the findings or diagnostic data input in the template Report information storage means for storing as report information in an image database server, the report information together with image data corresponding to the input findings or diagnostic data and link information table data associated with designated position data for the image data It is configured to be stored in the image database server.

  According to the configuration described above, the observation data can be input via the viewer, and the position of the diagnosis target image displayed on the viewer by the position specifying unit is specified, and the position is specified by the report display unit. Since the template is displayed, the diagnostician can input finding data and diagnostic data without error. Since the input report information is stored in the image database server together with the image data and link information table data associated with the specified position data for the image data, even if the report data is evaluated later, the image Since the report is displayed so as to indicate the diagnosis target position of the data, the diagnosis can be surely evaluated.

  As described in claim 2 of the same column, the second feature configuration is that, in addition to the first feature configuration described above, the link information table data includes a display condition of image data by a viewer, With this configuration, a doctor who refers to the finding data can reproduce and display an image under the same display condition as the image display condition selected by the diagnostician at the time of interpretation.

  In the third feature configuration, as described in claim 3 of the same column, in addition to the first or second feature configuration described above, the report display means may include a single or a plurality of findings on image data to be diagnosed. Or report summary information display means comprising diagnostic data and thumbnail images of the image data, the report information storage means includes primary registration data by a primary diagnostician and confirmed registration data by a secondary diagnostician in the report summary information. Is stored in the image database server by adding diagnostic level data that can be identified.

  With the above-described configuration, the test results can be managed as report summary information for each test unit, and the diagnosis level can be managed by registered data, so that the disclosure management of information from the diagnostician to the patient's doctor can be easily performed. is there. For example, the report summary that has been confirmed and registered can be accessed by the attending physician, the report summary up to the first registration cannot be accessed by the attending physician, and can be used to control access rights such that the responsible image diagnostician and the responsible image diagnostician can access It is.

  As described above, according to the present invention, it is possible to easily associate the medical finding data with the target portion of the medical image data read when creating the medical finding data, and accurately perform the diagnosis evaluation. A possible image database system can be provided.

  An embodiment of an image database system according to the present invention will be described below. As shown in FIG. 1, the image database system includes a basic frame (basic minimum tower) and a plurality of expansion frames (additional towers).

  The basic frame is stored in each storage unit 1, a storage unit group consisting of four storage units 1 that store medical image data, a control unit group consisting of two control units 2 that manage each storage unit 1, and Image database server comprising two image database servers 3 that store attribute information including key information associated with the medical image data and relay the medical image data with the externally connected viewer 11 The DICOM gateway group including two DICOM gateways 4 for relaying medical image data by the DICOM protocol between the group and the plurality of modality devices 10 externally connected to the image database server 3 includes switches 5 and 6. Connected to each other via network Configured Te, provided with a two load balancers 7 for load balancing control them per group based on the header information of the request over the network, and provided with power supply unit 8 and the display switch 9. Here, the number of each unit or server is merely an example, and may be more than or less than the number.

  The expansion frame includes a power supply unit, a plurality of storage units, and a switch, and is configured to be expandable so that large-capacity image data can be stored.

  The storage unit 1, the control unit 2, the image database server 3, and the DICOM gateway 4 are connected to the first network via the first switch 5 that processes jobs related to external requests from the viewer 11 or the modality device 10. N1 and the second network N2 through a second switch 6 for processing jobs related to internal requests are connected to each other via a network. The networks N1 and N2 are OSI reference standard models, and the physical layer and data link layer of the network are configured with 1000BASE-T Ethernet (registered trademark), the transport layer and the network layer are configured with TCP / IP, and more than the session layer. The upper layer is configured to operate with the DICOM protocol, which is a diagnostic imaging standard in the medical field, or other local upper protocols.

  The two load balancers 7 are connected by a local communication line (RS232-C), and normally one unit operates. For example, if there is no difference in the performance of the components of each group, there is a difference in round robin method and performance. For example, a load balancing control is performed so that the load of each component is equalized by a weighted round robin method, response time algorithm, etc., and when a failure is detected via the local communication line, a backup load balancer is activated. It is configured.

  Hereinafter, the operation of the present system will be described by taking, for example, an image storage request from the modality device, an image read request, a response operation to an image browsing request from the viewer, and the like.

  The modality device 11 starts an association by transmitting an image accumulation request by the DICOM protocol at the virtual IP address (VIP) assigned to the group constituted by the two DICOM gateways 4. The load balancer 7 selects the DICOM gateway 4 that operates normally and has the smallest load, intercepts the packet having the virtual IP address as the destination address, and rewrites the actual IP address of the selected DICOM gateway 4. The image accumulation request is received by the selected DICOM gateway 4 by the above processing. The return packet can be communicated by the reverse operation. Here, the load of the DICOM gateway 4 is distributed by the load balancer 7 in units of one association.

  As shown in FIG. 2 and FIG. 3, the DICOM gateway 4 that made the request uses the received image information as an examination example UID (consisting of a vendor prefix code, product unique number, serial number, etc.), patient name, patient ID. The image data is divided into attribute information and image information including the receipt number, examination date, examination time, and date of birth of the patient, and a predetermined lossless compression algorithm (here, PNG (Portable Network Graphics) is used) A plurality of compressed images with different compression ratios (in this case, 512 × 512 pixel original image, 256 × 256 pixel 1/4 image, 128 × 128 pixel 1/16 image) ), And transfer to the control unit 2.

  The control unit 2 receives the transferred image data, stores the image data according to an algorithm described later, and returns the storage address to the DICOM gateway 4. The DICOM gateway 4 transfers the attribute information to the image database server 3 together with the storage address of the image data returned from the control unit 2, and instructs data update processing.

  The control unit 2 and the image database server 3 involved in the above-described operation are communicated via the first network N1 and are load-balanced by the load balancer 7 in the same manner as the DICOM gateway 4. Each operation described below is basically load-balanced by the load balancer 7 in the same manner as described above, but the description of the operation of the load balancer is omitted hereinafter.

  Next, when the DICOM gateway 4 receives an image provision request from the modality device 11, as shown in FIGS. 4 and 5, the DICOM gateway 4 receives from the image database server 3 based on any key information of the attribute information that identifies the request image. Acquire attribute information and a storage address, acquire a compressed image that is reversibly compressed from the storage unit 1 based on the storage address, decompress the compressed image, and send it back to the modality device 11 by the DICOM protocol together with the attribute information To do.

  As shown in FIG. 6 and FIG. 7, when there is an image data browsing request from the viewer 10 to the image database server 3, the image database server 3 receives the key information of any attribute information that identifies the request image. The attribute information and storage address are acquired and returned to the viewer 10. Thereafter, the viewer 10 accesses the storage unit 1 based on the received storage address to acquire desired image data. Here, if the viewer 10 is a DICOM viewer, the operation is performed through the DICOM gateway 4 described above. However, although the DICOM protocol is not used, if the local protocol by TCP / IP is supported, an arbitrary upper protocol can be used. Can be used.

  When the power is turned on, the control unit 2 does not go through the load balancer 7 (access to the control unit 2 is load-balanced by the load balancer 7), and sequentially goes to each storage unit 1 through the second network N2. The operation status inspection means for executing the operation status inspection and updating and storing the result in the operation status table of the image database server 3, and based on the update history of the operation status table data by the other control unit 2, Failure diagnosis means for performing failure diagnosis of the other control unit is provided.

  More specifically, the operation status checking means inquires of each storage unit 1 configured with several hard disks about the remaining disk capacity for each drive and the total remaining capacity of the unit, and arbitrarily for each drive. The disk failure of each drive is investigated and the result is updated and stored in the operation status table shown in FIG.

  In response to a data storage request to the storage unit 1, the control unit 2 selects and stores the data storage destination from the normally operating storage units identified based on the operation status table for the number of redundancy. Means are provided. More specifically, the redundant storage means examines the remaining disk capacity for each drive based on the operation status table, and selects and stores a drive having a large remaining disk capacity in different storage units by the number of redundancy. Here, the redundancy number is set to two. Therefore, the same data always exists in different storage units 1 in the system. According to yet another method, the remaining disk capacity is investigated for each storage unit, and two storage units 1 having a large remaining disk capacity are selected, and the remaining disk capacity is increased from the selected storage units 1. A drive may be selected to store the data. The data storage address is returned to the storage request sender. The image data storage request is returned to the DICOM gateway 4 and stored in the database server 3 together with or as attribute information of the image data by the DICOM gateway 4.

  Further, if there is a storage unit 1 or a drive that is determined to be abnormal by the operation status inspection unit, the control unit 2 is determined to be abnormal based on the storage address stored in the database server 3 in order to recover the data. Obtain the data storage address of another storage unit that stores the same data as the data stored in the storage unit or drive, and store the data stored in that data storage address as the same data. A storage unit 1 other than the storage unit 1 selected is selected from the normally operating storage units 1 identified based on the operation status table and copied.

  The failure diagnosis means of the control unit 2 accesses the operation status table regularly or irregularly, and based on the update history of the operation status table data by other control units 2, is performed within a predetermined time in the past from the time of access. When there is no update history, it is determined that the other control unit has failed. When a spare control unit is installed, one spare control unit is started up.

  Here, the operation state inspection means may be operated by one of the two operating control units, and the failure diagnosis means may be operated by the other control unit. In this case, a flag indicating the completion of the operation of the failure diagnosis means by the other control unit and the operation time data are recorded in the operation status table, and the one control unit checks the flag and the operation time data. Thus, the failure of the other control unit can be detected.

  The control unit 2 may be integrally configured on the same substrate as the storage unit 1. In this case, for example, two storage units can be set to be active, and the spare control unit can be switched to active when one failure is detected by the failure diagnosis means.

  Hereinafter, update processing and failure recovery processing of the image database server 3 will be described. The image database server 3 updates its own database in response to the data update processing performed via the first network N1, and also stores the database of the other image database server 3 via the second network N2. Update processing means for performing update processing is provided.

  The image database server 3 is provided with an update port and a search port for the load balancer 7, and both ports are open when normal. Further, the update processing means of one image database server 3 (DB1 in the figure) manages the final operation time of the update processing means of the other image database server 3 (DB2 in the figure), and all the tables are all stored. The last update date / time is written and managed in the record.

  As shown in FIGS. 8 and 9, the update processing means receives a storage request for image data attribute information and image data storage address from the DICOM gateway 4 via the load balancer 7 and an operation status table from the control unit 2. When there is a data update request such as a storage request (circled step 1 in FIG. 8), it updates its own database (circled step 2 in FIG. 8), and then others via the second network 2 The database of the image database server 3 is updated (step 3 in FIG. 8). When this operation is completed, an acknowledgment for the request is returned (step 4 in FIG. 8).

  The image database server is provided with a data update port and a data search port for the first network N1, and is used for data update at the time of recovery processing for the database of another image database server via the second network N2. Recovery processing means for closing the port is provided.

  This will be described in detail below. When the other image database server 3 is out of order, both the update port and the search port are closed, and the load balancer 7 requests processing from only one image database server 3. As shown in FIG. 10, in this case, only the update process of its own database is performed for the update request, and an acknowledge is returned.

  At the time of recovery from the above-mentioned failure state, one image database server 3 performs normal operation, and both ports of the other image database server 3 are closed. As shown in FIGS. 11 and 12, the other image database server 3 that recovers from the failure acquires the last update date and time updated by the other image database server 3 (step 1 in FIG. 11), The recovery start time is recorded (step 2 in FIG. 11). Next, the record of the update date and time acquired in the first step is acquired from one image database server 3, and its own database is updated (step 3 in FIG. 11). The recovery start time recorded in step 2 is set as the last update date / time of its own database (step 4 in FIG. 11), and the last update date / time in the fourth step is compared with the current date / time. Repeat steps. Here, n is an order of several minutes. If it is within n minutes, a restoration operation is requested to one image database server 3 (step 5 in FIG. 11). On the other hand, one image database server 3 closes the update port (step 6 in FIG. 11), and performs update processing of the database after the last update date and time of the other image database server 3 (in FIG. 11). Step 7), the update port is opened after completion of the update process (Step 8 in FIG. 11), and an end notification is transmitted to the other image database server 3. The other image database server 3 opens both ports and returns to normal operation (steps 9 and 10 in FIG. 11).

  The case where the primary diagnostician interprets the interpretation processing by the interpretation processing means, which is an application installed in the viewer 11, will be described based on the flowchart shown in FIG. An examination list table (not shown) stored in the image database server 3 is read (S60), and patient identification data (patient ID, name, date of birth, sex, etc.) and examination stored in the examination table. When the name field of the patient to be interpreted is clicked with a mouse from specific data (examination management number, examination date, examination type, examination site, etc.) (S61), as shown in FIG. Four head tomography images are displayed. Each time the page update button is clicked, the image is updated and displayed in units of four. When an image in which an abnormality is found is double-clicked, the image is enlarged and displayed as shown in FIG.

  When the abnormal part is recognized by examining the image and the diagnostic part is double-clicked (S62), as shown in FIG. 15A, the balloon-shaped template is instructed to indicate the position. Is displayed (S63). The template includes a column for describing the observation data and the diagnostic data. When data is input to the column and the registration button is clicked, the template is temporarily stored in a storage unit built in the viewer. If another abnormality is found in the target image, the process from step S62 to step S64 is repeated as shown in FIG. When completed (S65), the summary button is clicked from the pull-down menu displayed by clicking the report button on the menu bar, and the report summary image shown on the right side of FIG. 16 is displayed (S66). Note that the template is not limited to a balloon shape but may be any shape, but it is necessary to indicate a designated position.

  When the diagnosis result is input to the diagnosis summary and the content is confirmed by the doctor (S67), the primary registration button is clicked, and the report information is the image data corresponding to the input finding or diagnosis data and the image data. It is stored in the image database server 3 together with the link information table data associated with the designated position data (S68). As shown in FIG. 17, the link information table data includes, for example, an inspection ID for specifying an inspection, a management number of an inspection image by a modality device, and an image ID for specifying an image to be diagnosed among the inspection images. And X and Y coordinate data indicating the position to be reported and management data (Findings) of the balloon image. Image data, report data, and position data in the image are uniquely linked by the link information table data. Here, the link information table data includes data such as window width, level, magnification, display coordinates, and gradation so that the image display conditions of the target image displayed on the viewer at the time of finding input can also be managed. It is preferable to add. Thereby, a doctor who refers to the finding data can reproduce and display an image under the same display condition as the image display condition selected by the diagnostician at the time of interpretation.

  That is, the part for executing the processing from step S63 to step S66 described above constitutes a report display means for displaying the template for inputting the observation data so that the designated position by the position designation means is indicated, and the position in step S62. The position corresponding to the input process constitutes position specifying means for specifying an arbitrary position of the displayed image, and the part that executes the process of step S68 converts the findings or diagnostic data input to the template into the image database server. 3 is a report information storage means for storing report information.

  As shown in FIG. 16, the report display means includes a single or plural findings or diagnostic data for image data to be diagnosed, and a thumbnail image of the image data, which is composed of a part that executes the processing of step 66. The report summary information display means is configured such that when a thumbnail image displayed in the report summary is double-clicked, a full image to be diagnosed is displayed.

  Furthermore, the report information storage means is configured to add the diagnostic level data capable of identifying primary registration data by the primary diagnostician and confirmed registration data by the secondary diagnostician to the report summary information and store it in the image database server. Therefore, the diagnosis level can be managed. Specifically, the button shown in the lower right of FIG. 16 is a primary registration button, and when this button is clicked, it is stored as primary registration data, and the report summary image that is primarily registered by the person in charge of diagnosis is displayed on the viewer. The primary registration button is switched to the secondary registration button. This data is used for access management of report information. For example, the report summary that has been registered and registered can be accessed by the attending physician, the attending physician cannot access the report summary up to the primary registration, and the responsible image diagnostician and the responsible image Used to control access rights such that the diagnostician can access.

  The viewer 11 is based on the non-DICOM protocol, but in the case of the DICOM viewer, the viewer 11 is accessed via the above-described DICOM gateway. Also, the form of the image database server is not limited to that described above, and is appropriately configured.

Configuration diagram of an image database system according to the present invention Illustration of image storage procedure Flow chart of image storage procedure Illustration of image provision procedure Flow chart of image provision procedure Explanatory diagram of image search procedure by viewer Flow chart of image search procedure by viewer Operation explanatory diagram of image database server Flow chart of image database server Operation explanatory diagram of image database server Operation explanatory diagram of image database server Flow chart of image database server Explanatory drawing of operating status table Explanatory diagram of the viewer Explanatory diagram of the viewer Explanatory diagram of the viewer Illustration of link information table data Flow chart explaining the operation of the viewer

Explanation of symbols

1: Storage unit 2: Control unit 3: Image database server 4: DICOM gateway 5, 6: Switch 7: Load balancer 10: Modality device 11: Viewer

Claims (3)

A storage unit for storing medical image data; an image database server storing attribute information including key information associated with the medical image data stored in the storage unit; and medical image data from the image database server An image database system comprising a viewer that acquires and displays
A position designation means for designating an arbitrary position of the displayed image and a template for inputting finding data for the position designated by the position designation means are designated to the viewer by the designated position by the position designation means. Report display means for displaying on the display, and report information storage means for storing findings or diagnostic data input to the template as report information in the image database server,
The image database system in which the report information is stored in the image database server together with image data corresponding to input findings or diagnosis data and link information table data associated with designated position data for the image data. The image database system according to claim 1, wherein the link information table data includes display conditions for image data by a viewer. The report display means comprises report summary information display means comprising single or multiple findings or diagnostic data for image data to be diagnosed and thumbnail images of the image data, and the report information storage means comprises the report summary The image database system according to claim 1 or 2, wherein diagnostic level data capable of identifying primary registration data by a primary diagnostician and confirmed registration data by a secondary diagnostician is added to the information and stored in the image database server.